Abstract
Oxygen sensors enable cells to adapt to limited oxygen availability (hypoxia), affecting various cellular and tissue responses. Prolyl-4-hydroxylase domain 1–3 (PHD1-3; also called Egln1-3, HIF-P4H 1–3, HIF-PH 1–3) proteins belong to the Fe2+- and 2-oxoglutarate-dependent dioxygenase superfamily and utilise molecular oxygen (O2) alongside 2-oxoglutarate as co-substrate to hydroxylate two proline residues of α subunits of the dimeric hypoxia inducible factor (HIF) transcription factor. PHD1-3-mediated hydroxylation of HIF-α leads to its degradation and inactivation. Recently, various PHD inhibitors (PHI) have entered the clinics for treatment of renal anaemia. Pre-clinical analyses indicate that PHI treatment may also be beneficial in numerous other hypoxia-associated diseases. Nonetheless, the underlying molecular mechanisms of the observed protective effects of PHIs are only partly understood, currently hindering their translation into the clinics. Moreover, the PHI-mediated increase of Epo levels is not beneficial in all hypoxia-associated diseases and PHD-selective inhibition may be advantageous. Here, we summarise the current knowledge about the relevance and function of each of the three PHD isoforms in vivo, based on the deletion or RNA interference-mediated knockdown of each single corresponding gene in rodents. This information is crucial for our understanding of the physiological relevance and function of the PHDs as well as for elucidating their individual impact on hypoxia-associated diseases. Furthermore, this knowledge highlights which diseases may best be targeted by PHD isoform-selective inhibitors in case such pharmacologic substances become available.
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PHD1-3-mediated regulation of HIF
Prolyl-4-hydroxylase domain (PHD) proteins 1–3 are cellular oxygen sensors that have first been discovered to confer hypoxia sensitivity to the hypoxia-inducible factor (HIF) transcription factors [12, 36, 58,59,60]. The PHDs enable the tissue and cellular adaptation to hypoxia via HIF-mediated enhancement of the expression of selected genes [63, 132, 161]. There are three known α (HIF-1α, HIF-2α and HIF-3α) and one HIF-β subunit, of which one α together with the β subunit form the dimeric HIF transcription factors HIF-1, HIF-2 or HIF-3 [39, 131, 132]. HIF-1α and HIF-2α are well-characterised, but less is known about HIF-3α. The following description focusses on HIF-1α as a best described example of the PHD-dependent regulation of HIF-α subunits. In normoxia, PHD1-3 hydroxylate two proline residues of HIF-1α, Pro402 and Pro564 (Fig. 1) [63]. Prolyl hydroxylated HIF-1α is recognised by the von Hippel-Lindau protein (VHL), which in turn recruits an E3 ubiquitin ligase [47, 63, 131, 132]. HIF-1α is then polyubiquitinated and subsequently degraded by the proteasome (Fig. 1), preventing HIF-mediated enhancement of gene expression [47, 63, 131, 132].
PHD1-3 belong to the Fe2+ and 2-oxyglutarate (2-OG)-dependent dioxygenase superfamily [63]. The PHDs utilise molecular oxygen (O2) as co-substrate and thus depend on the availability of O2 for their enzymatic activity [63]. HIF-α subunits are also regulated by an additional cellular oxygen sensor, the asparagine hydroxylase factor inhibiting HIF (FIH, Fig. 1) [168]. FIH belongs to the same superfamily as the PHDs and utilises O2 for its enzymatic activity, hydroxylating the asparagine residue Asn803 of HIF-1α [88, 132, 168]. HIF-1α asparagine hydroxylation abrogates binding of the histone acetyl transferases CBP/p300 that serve as transcriptional co-activators, therefore decreasing HIF-1 activity towards selected genes [88, 132, 168]. In hypoxia, the enzymatic activity of the PHDs and FIH is reduced; HIF-1α is therefore stabilised and migrates into the nucleus, forming the active HIF-1 heterodimer with HIF-1β (Fig. 1) [63]. HIF-1 then binds to hypoxia response elements (HREs), enhancing the transcription of hundreds of genes involved in various processes, including angiogenesis and energy metabolism [63, 132, 161].
Interestingly, the three PHD isoforms have shown different preferences towards the two HIF-1α prolyl hydroxylation sites. PHD1 and PHD2 hydroxylate both Pro402 and Pro564 of HIF-1α, whilst PHD3 preferentially modifies Pro564 [13, 50]. In addition, PHD2 and PHD3 gene expression is enhanced by HIF-1, forming a negative feedback loop for the regulation of HIF activity, whereas PHD1 gene expression is not altered in hypoxia [98, 142]. Of note, PHD2 is almost ubiquitously expressed, whereas the expression of PHD1 and PHD3 is more restricted [87].
Currently, six different PHD inhibitors (PHIs) are available in the clinics for treatment of renal anaemia: roxadustat, molidustat, vadadustat, daprodustat, desidustat and enarodustat [74]. PHI treatment increases the expression of the HIF-2 target gene erythropoietin (Epo) and therefore the amount of circulating red blood cells, counteracting renal anaemia [37]. Some selectivity of these drugs towards specific PHDs has been reported [101]. Roxadustat and enarodustat have been suggested to inhibit all PHDs to a comparable degree, whereas daprodustat preferentially inhibits PHD1 and 3, and molidustat shows a preference towards PHD2 and vadadustat for PHD3 [101]. However, such analyses are based on the investigation of purified enzymes and whether this apparent PHI selectivity also occurs in vivo is currently unclear, as it depends on the expression level of the corresponding PHDs together with the reached concentration of the PHIs in the targeted cells. Of note, all of these inhibitors increase the expression of Epo in the human kidney (which is quintessential for their use as treatment of renal anaemia) and PHD2 is the most relevant PHD for the regulation of Epo expression [25, 48]. Therefore, all currently available PHIs in the clinics must inhibit PHD2 within human renal Epo-producing cells in vivo. A potential differential selectivity may lead to diverse side effects, but the currently available data do not allow such conclusions and more studies are necessary.
Alongside the well-characterised regulation of HIF-α by the PHDs, it has also been reported that the PHDs regulate proteins outside the HIF pathway [80, 143]. A PHD-mediated regulation of substrates other than HIF has obviously profound implications for our understanding of the cellular adaptation to hypoxia as well as for the use of pharmacologic PHD inhibitors. However, the hydroxylation of non-HIF-α proteins by the PHDs is currently controversially discussed [7, 22, 80, 143], as it was not possible to reproduce these findings with purified proteins in vitro [22]. The assessment of the phenotype(s) of PHD knockout (KO) animals will contribute to solving this discussion, as the regulation of a target protein by one of the PHDs should ultimately be linked to the in vivo function of the respective PHD.
The function of each of the PHDs in vivo is of major relevance for our understanding of the regulation of the tissue and cellular response to hypoxia and to elucidate potential novel treatment options for hypoxia-associated diseases as well as for the understanding of possible side effects. In the following, we therefore summarise to the best of our knowledge the currently described phenotypes in rodents with deletion or RNA interference-mediated knockdown of single PHD isoforms. Regarding the relevance of PHD1-3 in cancer, different outcomes have been reported, depending on whether a PHD-encoding gene was deleted in tumour cells, in the host organism or in both [75]. The function of the PHDs and the HIF pathway in cancer has recently been expertly reviewed elsewhere [43, 106, 172]. In the chapters about cancer in this review, only reports are summarised that describe the effects of Phd gene inactivation in the host organism.
Phd1 (Egln2) deletion
The baseline phenotype summarises observations made in mice with Phd1 deletion without the induction of a pathology. The subsequent chapters focus on phenotypes of mice with various Phd1 deletions in disease models.
Baseline phenotype
Analysis of mice with constitutive global deletion of single Phd genes gives key insights into the functional role and relevance of the respective protein and can indicate what (side) effects may occur following treatment with a (currently not available) PHD isoform-selective pharmacologic inhibitor. Mice with constitutive whole-body deficiency of Phd1 (Phd1−/−) do not display any obvious phenotype under normal housing conditions during development [152] or adulthood [1, 4, 97, 149, 150], with intact skeletal muscles [4] and erythropoiesis (haematocrit, haemoglobin and erythropoietin levels) as well as normal blood gas values [4, 103], vascular system [150], heart [1], lung [117] and liver [91, 107, 130] morphology. Also, bone development and architecture were unaltered as shown in Phd1−/− mice and by conditional deletion of Phd1 in osteoprogenitors (OSX-Cre) or chondrocytes (Col2α1-Cre) [55, 173, 178]. Interestingly, in Phd1−/− mice whole-body oxygen consumption was reduced at rest and the mice demonstrated worse exercise endurance and impaired oxidative muscle performance due to a decreased oxygen consumption in skeletal muscle [4]. During aging, 1-year-old Phd1−/− mice showed a decreased serum cholesterol level and a reduced body weight [158]. The size and frequency of pulmonary neuroepithelial bodies (NEB; presumed hypoxia-sensitive oxygen sensors) were increased in Phd1−/− mice [116, 117] combined with an enhanced NEB serotonin (5-HT) production in normoxia and hypoxia [93]. NEBs may have functional relevance for the ventilatory response to hypoxia, especially perinatally [24]; nonetheless, no difference has been reported in the viability of Phd1−/− mice. In addition, the hypoxia ventilatory response in adult Phd1−/− mice is not altered [9].
In contrast to other observations, one group reported that Phd1−/− mice exhibit a lower body weight, food intake and liver weight [162], albeit the liver over body weight ratio was not altered [107]. Despite the decreased body weight, adult Phd1−/− mice displayed a larger white adipose tissue (WAT) mass, altered glucose homeostasis and a decreased insulin sensitivity [162]. Interestingly, β-cell-specific Phd1 deletion (Ins1-Cre) led to decreased β-cell mass and elevated β-cell apoptosis, but not to any defect in glucose homeostasis or insulin sensitivity [51].
In summary, Phd1 deletion does not affect the majority of organs at baseline, but impacts on energy metabolism, which however does not appear to be obvious without challenge.
Cardiovascular system
HIF activity is tightly linked to angiogenesis through regulation of the expression of corresponding genes, including vascular endothelial growth factor (VEGF) [185]. In addition, in tissue ischemia (as it, e.g. occurs during a so-called heart attack), the resulting hypoxia affects the activity of the PHDs and leads to stabilisation of HIF-α. This led to the analyses of the relevance of the different PHD proteins in ischemic diseases including the heart.
Phd1−/− mice display a reduced infarct size after ischemia/reperfusion (I/R) injury (Langendorff’s perfusion model) with decreased apoptosis in cardiomyocytes [1]. DNA-binding activity of HIF-1α is increased in Phd1−/− hearts following I/R, which was associated with enhanced expression of anti-apoptotic BCL-2 and endothelial nitric oxide synthase (eNOS). In addition, the DNA-binding activity of NF-κB was augmented as well as the nuclear translocation of β-catenin in cardiac tissue [1]. Based on this study, PHD1 may be a relevant pharmaceutical target in myocardial I/R injury. Interestingly, using whole-body inducible shRNA targeting both PHD1 and PHD3 in combination in mice, it was found that knockdown of PHD1 and PHD3 was not protective against myocardial infarction [61]. It remains unclear if the protective effect of Phd1 deletion alone is time-dependent and does not occur in acute settings or if the combinatorial deletion of both Phd1 and Phd3 has a different effect than Phd1 ablation alone. Of note, Phd3 KO alone has also been reported to be protective in cardiac ischemia (see below).
Combined deletion of Phd1 and low-density lipoprotein receptor (Ldlr) in mice led to decreased artherosclerotic plague sizes and reduced plasma cholesterol levels compared to Ldlr−/− mice, which was likely caused by enhanced cholesterol excretion into the intestines [97]. HIF-2α silencing via antisense oligonucleotides had no effect on the protection conferred by Phd1 deletion, indicating a HIF-2α-independent mechanism [97]. Conditional deletion of Phd1 in myeloid cells (LysM-Cre) had no effect on aortic plaque size or plaque type following a high-cholesterol diet [166]. In summary, whole-body Phd1 KO is advantageous in atherosclerosis, which is likely due to an altered regulation of plasma cholesterol levels.
Haematopoietic system
Constitutive whole-body [149], hepatic (Alb-Cre) [103, 163] or FOXD1 lineage cell (Foxd1-Cre) [73] deletion of Phd1 did not affect Epo or haematocrit levels.
Liver
Livers from Phd1−/− mice are largely protected against acute ischemia and I/R injury [130]. Hypoxic cell damage following ischemia, including hepatocyte swelling, vascularisation and karyolysis, was markedly decreased in the livers from Phd1−/− mice [130], suggesting a higher tolerance to hypoxia. In addition, mice lacking Phd1 were protected against hepatocyte apoptosis and necrosis, with reduced oxidative stress following I/R and decreased oxygen consumption [130]. Interestingly, both at baseline conditions and following I/R, global Phd1 KO led to higher HIF-2α than HIF-1α protein levels [130].
Simultaneous silencing (via tail vein injection of shRNAs) of Phd1 and Keap1 (an oxidative stress sensor) in hepatocytes reduced hepatic fibrosis induced by treatment with carbon tetrachloride (CCl4) [91]. Liver fibrosis was also attenuated in Phd1−/− mice following the induction of chronic bile duct injury through application of 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) [145]. Livers of Phd1−/− mice displayed a reduced recruitment of inflammatory leukocytes as well as a decreased number of profibrotic myofibroblasts combined with a lower expression of pro-mitogenic and pro-fibrogenic factors. These effects were likely caused (at least in part) by a mitigated activation of hepatic stellate cells [145].
After 80% hepatectomy in mice, Phd1−/− animals recovered their liver weight significantly faster than WT through increased proliferation of hepatocytes [107]. Enhanced proliferation in Phd1−/− hepatocytes was caused by increased HIF-2 and c-Myc activity [107]. Following low-fat diet (LFD), Phd1−/− mice developed hepatic steatosis with increased hepatic cholesterol and triglyceride (TG) content [162].
In summary, PHD1 deletion is protective in various liver pathologies, ranging from I/R injury over fibrosis to hepatectomy. The observation that Phd1 deletion may lead to hepatic steatosis may have to be taken into account, when PHD1 is considered therapeutic target. However, all phenotypes based on Phd1 deletion that could be used to reason against PHD1 as therapeutic target have been reported in a single publication, whereas the majority of investigations observed a protective effect of Phd1 KO in liver pathologies.
Energy metabolism
Following LFD, Phd1−/− mice demonstrated an increased body weight gain combined with a decreased insulin sensitivity [162]. Following high-fat diet (HFD), Phd1−/− mice displayed a larger body weight gain, but decreased cholesterol and blood glucose levels as well as an improved insulin sensitivity compared to wildtype (WT) mice [162]. Another study also reported that Phd1−/− mice are protected against HFD-induced glucose intolerance and hyperglycaemia [97]. Overall, the effect of PHD1 on energy metabolism may be diet-dependent, but PHD1 is generally linked to the regulation of body weight gain, glucose homeostasis and insulin sensitivity and deletion of Phd1 (and therefore potentially also PHD1 inhibition) is protective under conditions of high-fat diet.
Immune system
In Phd1−/− mice, no difference was found in their response to LPS-induced sepsis relative to wildtype mice [69]. Phd1 KO in haematopoietic and endothelial cells (Tie2-Cre) favoured a polarisation of macrophages in response to LPS towards a M2 phenotype with reduced secretion of chemokines [167]. Dendritic cells with Phd1 deletion (CD11c-Cre) demonstrated also a decreased response to LPS with reduced IL-1β secretion [167]. Overall, few studies have analysed the effect of Phd1 deletion on immune cell function in vivo with contrasting results (in different disease and KO mouse models). Therefore, further studies would be necessary to clarify the relevance of PHD1 for the immune system in vivo.
Nervous system
Phd1 deficiency did not affect the outcome of transient focal cerebral ischaemia in the first 24 h after 45 min of middle cerebral artery occlusion (MCAO) [14]. Interestingly, Phd1 deletion was protective in a model of permanent brain ischemia 24 h after MCAO, decreasing the infarct size [120]. Phd1 KO increased the activity of the pentose phosphate pathway and enhanced the cellular redox buffering capacity. Therefore, neurons lacking Phd1 were protected from reactive oxygen species (ROS) [120]. The protection against brain ischemia by Phd1 KO was suggested to be dependent on NF-κB activity and independent of HIF [120]. The long non-coding RNA (lncRNA) myocardial infarction associated transcript (MIAT) is upregulated in brain tissue after ischemic stroke. Following 90 min of MCAO in rats followed by reperfusion, overexpression of MIAT promoted I/R injury by enhancing infarct volume, neuron damage and apoptosis [85]. When MIAT overexpression was combined with Phd1 knockdown (intravenous injection), the degenerative effects of MIAT were abrogated, suggesting that Phd1 knockdown is protective [85]. In summary, PHD1 deletion is protective in ischemic brain injury, but only during long durations of ischemia. Interestingly, following peripheral (sciatic) nerve injury, Phd1−/− mice showed reduced cold hyperalgesia combined with increased axonal regeneration [139], indicating that pharmaceutical PHD1 inhibition may be a treatment option for peripheral nerve injury.
Skeletal muscle
Phd1−/− mice are protected against hind limb ischemia. Following femoral artery ligation, there was almost no necrosis or apoptosis detected within the skeletal muscle of Phd1−/− mice [4]. Phd1 deletion reduced oxidative stress and mitochondrial damage in ischemic myofibres, whereas ATP production was maintained, demonstrating a hypoxia tolerance of myofibres when Phd1 was absent [4]. Hypoxia tolerance and fibre protection were linked to upregulation of the metabolic regulator Pparα and elevated HIF-2α levels [4]. Another study analysing the effect of femoral artery ligation in Phd1−/− mice found increased motor function as well as improved recovery of perfusion together with increased arteriolar and capillary density, capillary/myocyte ratio and decreased fibrosis [126]. Acute decrease of PHD1 expression via shPHD1 injection (into both gastrocnemius and tibial anterior muscles) after femoral artery ligation increased leg capillary density; however, the proangiogenic effect was not as strong as with shPHD2 or shPHD3, which was likely regulated via stabilisation of HIF-1α [94]. Overall, a lack of Phd1 is protective against ischemic injury in skeletal muscle due to an altered energy metabolism and an enhanced angiogenesis.
Gastrointestinal tract
Phd1−/− mice are protected against dextran sulphate sodium (DSS)-induced colitis [154]. Phd1 KO increased colonic epithelial cell density and enhanced epithelial barrier function caused by decreased epithelial cell apoptosis [154]. Weight loss, disease activity index and colonic pro-inflammatory cytokines were reduced in the absence of Phd1 [154]. Conditional deletion of Phd1 in endothelial and haematopoietic cells was also protective against DSS-induced colitis [167]. Haematopoietic Phd1 deletion alone but not endothelial-selective deletion was sufficient for the protective effect, which promoted an anti-inflammatory M2 macrophage polarisation [167]. In a model of radiation-induced gastrointestinal toxicity, the deletion of Phd1 alone in the gastrointestinal epithelium (Villin-Cre) had no effect [157]. Haematopoietic Phd1 deletion (Vav-Cre) was not protective in a genetic mouse model of ileitis, induced by chronically enhanced production of the pro-inflammatory cytokine TNFα [28]. Phd1 deletion did also not affect ischemic colonic anastomoses but reduced the bursting pressure in septic colonic anastomoses [144]. However, disease activity or survival was not altered by Phd1 deletion in the septic colonic anastomoses model [144]. In a colon-associated colorectal cancer model (CAC; azoxymethane (AOM) and DSS treatment), Phd1−/− mice were again protected against colitis and demonstrated a reduced CAC growth [67]. In summary, these data suggest that PHD1 is a crucial regulator of colitis, affecting both the epithelial barrier as well as the inflammatory response. In addition, CAC growth was diminished, which is associated with prolonged colon inflammation. For colon anastomoses or in ileitis, PHD1 appears to not play a relevant role in disease progression.
Skin
In a model of acute skin inflammation (2-O-tetradecanoylphorbol-13-acetate treatment), Phd1−/− mice showed a decreased inflammatory response combined with an increased apoptosis [164], indicating PHD1 as a potential pharmaceutical target protein in skin inflammation.
Cancer
PHD1 expression can be induced by oestrogen [3, 133]. Interestingly, global Phd1 deletion improved survival in triple-negative breast cancer (TNBC) mice compared to wildtype [148]. Long-term but not short-term survival was improved, indicating that loss of Phd1 might be protective against TNBC only in slower growing tumours [148]. As indicated above, constitutive global Phd1 deletion in mice decreased CAC growth [67]. In summary, based on the few existing studies, Phd1 deletion and hence possibly also pharmacologic inhibition of PHD1 are protective at least in breast and colon cancer.
Phd2 (Egln1) deletion
Phd2 deletion leads to multiple different phenotypes depending on whether the KO occurred prior to, during or after development and depending on the cell type(s) targeted for Phd2 ablation. The baseline phenotype chapter summarises observations that have been made in mice with constitutive homozygous whole-body deletion of Phd2 (Phd2−/−) and in Phd2 hypomorph mice under baseline conditions. Analyses of heterozygous (Phd2+/−) and conditional Phd2 KO mice in normal housing conditions or any available Phd2 deletion in mice in disease conditions are described in the subsequent chapters.
Baseline phenotype
Global Phd2 KO is lethal in mice during embryogenesis [104, 152]. Phd2−/− embryos die between embryonic days 12.5 and 14.5 due to placental and heart defects. Defects of the placenta ranged from widespread penetration of the labyrinth by spongiotrophoblasts, decreased labyrinthine branching morphogenesis to abnormal trophoblast giant cell distribution [152]. Developmental heart defects included a thinner myocardium, underdeveloped trabeculae, an incompletely formed interventricular septum and an enlarged intraventricular lumen [152]. HIF-α protein levels were increased in the embryo with the exception of the heart [152]. PHD2 knockdown in one-cell murine zygotes by injection of lentiviruses carrying shPHD2 was lethal in some but not all developing embryos on embryonic day 14 [115]. The lethality was linked to placental and heart malformations similar to the observations made in mice with constitutive global Phd2 inactivation [115]. Of note, also induced somatic deletion of Phd2 (chicken-β-actin-CreER) is lethal in mice due to dilated cardiomyopathy and venous congestion [104].
Hypomorphic inactivation of Phd2 does not result in embryonic lethality, polycythaemia, enhanced angiogenesis or dilated cardiomyopathy [56]. Nonetheless, HIF-1α and HIF-2α protein levels as well as the expression of glycolytic enzymes were upregulated in the heart. Interestingly, hypomorphic Phd2 mice display no difference in their life span compared to wildtype mice, but demonstrate a reduced occurrence of liver diseases, inflammation and myocardial infarction without effect on cancer incidence [78]. During aging, hypomorphic Phd2 mice also demonstrated an improved diastolic function (1-year-old mice) and developed less cardiomyocyte hypertrophy (2-year-old mice) [127]. This effect was likely due to increased Notch signalling and Notch target gene expression [127].
Cardiovascular system
Induced global inactivation of Phd2 (ROSA26-CreERT2) in adult mice increased angiogenesis and angiectasia [150]. Moreover, mice with induced somatic Phd2 deletion (chicken β-actin-CreER, first tamoxifen application in utero) developed dilated cardiomyopathy [104]. Induction of global Phd2 deletion (chicken β-actin-CreER) at 3 weeks of age did not lead to a change in systolic function in 10-week-old mice with an only minimally enlarged heart [105], indicating that both the timing and duration of Phd2 deletion are relevant for the development of the phenotype. Interestingly, constitutive cardiac-specific deletion of Phd2 (αMHC-Cre) did not lead to a cardiac phenotype in mice [108].
Knockdown of PHD2 via intraperitoneal injection of small interfering RNAs (siRNAs) into mice reduced acute myocardial I/R injury [110, 111]. The infarct size was smaller and HIF-1α levels were increased in cardiac tissue [110]. PHD2 knockdown also decreased the infiltration of polymorphonuclear leukocytes into cardiac tissue as well as chemokine and ICAM-1 expression [111]. Intraventricular infusion of siPHD2 [34] as well as intramyocardial injection of shPHD2 [54] also decreased the myocardial infarct size. In addition, following intramyocardial injection of shPHD2, fractional shortening was improved and more small capillaries and venules were present in the infarct zone several weeks after the initial injury [54]. Following the induction of increased cardiac afterload in mice with cardiac-specific deletion of Phd2 (αMHC-Cre), the mice developed a cardiac hypertrophy and a more profound decompensation than control mice [108]. Interestingly, constitutive cardiac-specific deletion of Phd2 using MLCv-Cre transgenic mice did not lead to a differential response to increased afterload [53]. Following acute myocardial ischemic injury, these mice were protected displaying a decreased infarct size, a reduced number of apoptotic cells and an improved cardiac function 3 weeks after ligation of the left anterior descending (LAD) artery [53]. A separate investigation further supported that cardiomyocyte-specific Phd2 deletion was protective in the LAD ligation-mediated ischemic injury model [119].
Isolated hearts from Phd2 hypomorph mice (92% reduction of cardiac PHD2 mRNA) were protected against induced I/R injury (induced during Langendorff’s perfusion), demonstrating a decreased infarct size, enhanced recovery of coronary flow and mechanical function [56]. Following LAD ligation, Phd2 hypomorph mice also displayed a reduced infarct size, an improved preservation of the systolic function of the left ventricle and an increased survival [68]. The number of cardiac capillaries was not altered but their size was increased together with an enhanced expression of endothelial HIF target genes [68].
Inducible whole-body shRNA-mediated knockdown of Phd2 in mice was protective in acute myocardial infarction [61]. This mouse model allowed the efficient induction of a Phd2 knockdown without increasing the haematocrit, an otherwise potentially confounding factor for analyses of the heart. Phd2 knockdown was only present during application of doxycycline and could therefore also be switched off [61]. Inhibition of PHD2 expression for 4 weeks prior and 6 weeks after acute myocardial infarction improved left ventricular ejection fraction and fractional area shortening without affecting the diastolic function [61]. Knockdown of Phd2 for 4 weeks prior to LAD-ligation decreased the infarct size but did not affect cardiac performance. Downregulation of Phd2 for 2 and 6 weeks after acute myocardial infarction improved left ventricular ejection fraction and fractional area shortening [61]. Overall, these results support the hypothesis that pharmacologic PHD2-selective pharmacologic inhibition is a novel treatment option in cardiac I/R injury.
HFD in mice hypomorphic for Phd2 combined with the deletion of the LDL receptor led to 50% reduction of atherosclerotic plaque areas, increased autoantibodies against oxidised LDL and reduced macrophage numbers in white adipose tissue without effect on serum cholesterol [123]. High-cholesterol diet in mice with conditional myeloid-specific Phd2 inactivation increased aortic root plaque size, decreased the macrophage content and enhanced fibrosis in plaques [166]. Conditional global Phd2 KO mice (Rosa26-CreERT2) were also protected against HFD-induced cardiac dysfunction [186]. In a murine model of hypertension-induced cardiovascular remodelling and fibrosis, myeloid-specific Phd2 deletion (LysM-Cre) was protective [57]. The mice displayed reduced cardiomyocyte hypertrophy and cardiac interstitial fibrosis combined with a decreased aortic thickening and macrophage infiltration [57]. Phd2 deletion in myeloid cells (LysM-Cre) combined with LDL receptor deletion enhanced angiogenesis and vessel maturation and reduced intra-plague haemorrhage within plagues that were formed following vein graft surgery into the carotid artery [138]. Following the induction of thrombosis using a combination of endothelial activation and flow restriction in vivo, induced global Phd2 KO (ROSA26-CreERT2) had no effect on venous thrombus neovascularisation, thrombus resolution or macrophage infiltration [44]. Together, these results indicate that Phd2 deletion is protective in diet-induced atherosclerosis and cardiac dysfunction.
Pulmonary arterial hypertension (PAH) is a common cause for right-sided heart failure. Endothelial cell-specific Phd2 KO in mice (Cdh5-Cre) resulted in spontaneous severe PAH [35, 65, 171] with premature mortality [65]. The muscularisation of pulmonary arteries was increased, the respiratory basement membrane was thickened and a right ventricular hypertrophy was developed [35, 65, 171]. In addition, alveolar fibrosis was observed [35]. The development of PAH was dependent on HIF-2α and independent of HIF-1α [65]. Using Tie2-Cre-mediated endothelial and haematopoietic cell-specific Phd2 deletion, the development of PAH including pulmonary vascular remodelling and right ventricular hypertrophy [27, 118, 155] as well as premature mortality [27] was also observed. In addition, in this model, it was found that the development of PAH was dependent on HIF-2α [27, 155, 191], which in turn may affect bone morphogenic protein (BMP) signalling [27, 89]. In contrast to the studies mentioned above, one group reported that conditional deletion of Phd2 in endothelial cells via Tie2-Cre leads to cardiac fibrosis and left ventricular hypertrophy [26].
Conditional inactivation of Phd2 in smooth muscle cells (smmhc-CreERT2) aggravated established PAH and increased hypoxia-induced vascular remodelling [15]. Using a novel Angpt4-Cre transgenic mouse line to inactivate Phd2 in arterial smooth muscle cells, an elevated right ventricular pressure was observed as well as a change in the vascular tone [35].
In summary, PHD2 is a key enzyme for the cardiovascular system with multiple effects on heart tissue and vessels. Inhibition of PHD2 is protective in acute myocardial ischemia, but the timing of PHD2 inhibition is relevant for a successful treatment. PHD2 inhibition in the heart in diseases with increased cardiac afterload is less promising. Conditional deletion of Phd2 in pulmonary endothelial and smooth muscle cells demonstrated that PHD2 plays a key role for the regulation of pulmonary arterial pressure and leads to the development of PAH via stabilisation of HIF-2α and pulmonary arterial remodelling. Moreover, PHD2 inhibition appears to be protective against the detrimental effects of HFD on the cardiovascular system.
Haematopoietic system
Conditional whole-body deletion of Phd2 increases plasma Epo levels, red blood cell (RBC) count haemoglobin and haematocrit levels [86, 104, 105, 113, 149, 152]. Mice with somatic inactivation of Phd2 died prematurely, due to dilated cardiomyopathy and venous congestion [104]. The congestive heart failure was likely caused by blood hyperviscosity and volume overload [104]. Acute global deletion of Phd2 led to erythrocytosis in both young (6–8 months) as well as aging (16–20 months) mice [86]. Injection of an adenovirus encoding a Cre enzyme into the tail vein of Phd2flox/flox mice resulted in increased serum Epo levels [121]. Epo mRNA was increased within the liver in the acute phase of Phd2 deletion; however, this was lost over time as long as functional PHD1 and PHD3 were present [121].
In mice with conditional Phd2 inactivation in renal EPO-producing cells, neurons and astrocytes (hCD68-IVS1-Cre), strong EPO production was observed combined with erythrocytosis [41]. Epo production in these mice was HIF-2α dependent [41]. To assess the first described human mutation in the Phd2 gene, which was associated with erythrocytosis, a mouse model was generated with a corresponding P294R knock-in mutation in the murine Phd2 locus (Phd2P294R/+ mice) [5]. Phd2P294R/+ mice displayed comparable erythrocytosis levels to Phd2+/− mice, which were HIF-2α-dependent [5]. In addition, homozygous and heterozygous Phd2 inactivation in renal cortical interstitial cells (Pax3-Cre) also induced erythrocytosis as well as homozygous Phd2 deletion in haematopoietic progenitor cells (Vav1-Cre) [5]. Conditional Phd2 deletion in renal FOXD1 stroma-derived cells (Foxd1-Cre) increased plasma Epo levels, haemoglobin and haematocrit [73]. HIF-2α protein levels were enhanced in renal FOXD1 cells with targeted Phd2 deletion, whereas HIF-1α protein levels were not altered [73]. Following obstructive nephropathy in mice with FOXD1-targeted Phd2 ablation, Epo expression was also increased but was not linked to myofibroblast transdifferentiation [71]. Interestingly, conditional deletion of Phd2 in the liver (Alb-Cre) did not enhance Epo levels or haematocrit [32, 103, 163]. These studies demonstrated that PHD2 is an important regulator of Epo via stabilisation of HIF-2α in specific Epo-producing cells in the kidney. Of note, inducible inactivation of Phd2 in renin-producing cells (mRen-rtTAm2 LC1-Cre) failed to induce Epo expression, whereas simultaneous deletion of both PHD2 and PHD3 increased Epo expression in juxtaglomerular and hyperplastic renin-positive cells [11], indicating that also renin-producing cells can induce the expression of Epo.
Induced global inactivation of Phd2 also increased the number of white blood cells in peripheral blood, which was combined with a strong increase of haematopoietic progenitors and haematopoietic stem cells in the spleen as well as a moderate but significant increase in liver and bone marrow [149]. Conditional deletion of Phd2 in early haematopoietic precursor cells (CD68-Cre) led to HIF-1α- and SMAD7-dependent self-renewal of multipotent progenitors [136]. Overall, these studies laid the foundation for our understanding about PHD2 as the key oxygen sensor for the regulation of Epo and therefore of RBC count, haemoglobin and haematocrit in vivo, which in turn affects the oxygen transport capacity of the blood. PHD2 also directly affects haematopoietic precursor cells and PHD2 is therefore a critical enzyme for the entire haematopoietic system.
Kidney
In HFD-fed mice with tamoxifen-mediated induction of proximal tubule (PT)-specific Phd2 deletion (N-Myc downstream-regulated gene 1 (Ndrg1)-CreER), peritubular capillary density was increased compared to HFD-fed control mice and HIF-target gene expression was enhanced [42]. Moreover, PT-specific Phd2-deletion reduced tubular damage, glomerulomegaly and albuminuria [42]. Therefore, PHD2 inhibition might be a treatment option for obesity-induced kidney injury.
Analysing the relevance of the PHD isoforms for kidney development, it was demonstrated that Phd2 deletion in FOXD1-expressing renal stroma cells (Foxd1-Cre) does not affect nephrogenesis [72]. Combined deletion of both Phd2 and Phd3, however, led to abnormal development of the kidney [72].
In an endothelial-specific Phd2 KO (VE-Cadherin (Cdh5)-Cre) mouse model, increased serum creatinine was observed together with arteriolar remodelling and increased interstitial fibrosis under normal animal housing conditions [170]. This was accompanied by glomerular arteriolar remodelling and increased renal interstitial fibrosis [170]. The Phd2 KO upregulated transforming growth factor-β (TGF-β) and Notch3 expression, which was suggested to be linked to the increased renal interstitial fibrosis [170]. In an angiotensin II (ANG II)-mediated renal injury and fibrosis model, Phd2-specific KO in endothelial cells (Cdh5-Cre) reduced iron accumulation and ROS formation in the kidney and was protective against renal fibrosis [189]. This was accompanied by increased HIF-1α and HIF-2α levels as well as a decreased ANGII type 1 receptor expression in endothelial cells [189], suggesting that PHD2 activity contributes to ANGII-mediated renal fibrosis and injury. Interestingly, in renal I/R injury, endothelial-specific Phd2 ablation (Cdh5-Cre) was protective, preserving kidney function and preventing the transition from acute kidney injury (AKI) to chronic kidney disease (CKD) in a HIF-1-dependent manner [124]. Induction of acute Phd2 deletion in endothelial cells (Cdh5(PAC)-CreERT2) indicated that the protective effect was independent of haematopoietic cells [124].
In summary, PHD2 inactivation in endothelial cells can lead to the development of interstitial fibrosis, but is protective against both ANG-II- and I/R-mediated renal injury and fibrosis. The vast majority of investigations with pharmacologic hydroxylase inhibitors have also reported a protective effect in various models of CKD [37], overall supporting that PHD2 is a pharmaceutical relevant target for the treatment of kidney injury and disease.
Liver
PHD2 activity in the liver plays an important role in the regulation of whole-body energy metabolism as described in the corresponding section below. Both in mice with induced systemic (chicken β-actin-Cre) and constitutive liver-specific (Alb-Cre) Phd2 deletion, mild hepatic steatosis was observed [105]. Murine Phd2 haploinsufficiency had no effect on liver regeneration following partial hepatectomy [107] or on fibrosis development during chronic bile duct injury [145]. Endothelial Phd2 KO in mice (Cdh5-Cre) led to liver steatosis and fibrosis combined with enhanced fat to body weight ratio and impaired glucose tolerance [190]. HFD did not lead to an additional aggravation of the steatosis [190]. In a model for alcoholic fatty liver disease (AFLD), Phd2 hypomorph mice displayed a decrease in adiposity, a maintained insulin sensitivity, an improved lipoprotein profile and a reduced WAT inflammation in comparison to mice with Phd2 [79]. In addition, the mice were protected against alcohol-induced liver damage and steatosis [79]. Thus, PHD2 plays an important role in the maintenance of liver tissue homeostasis and inactivation of hepatic PHD2 increases steatosis and potentially fibrosis under baseline conditions. However, PHD2 inhibition may be protective in liver diseases, such as AFLD.
Energy metabolism
Mice with adipocyte-specific Phd2 inactivation (aP2-Cre) displayed no obvious phenotype under standard housing condition [99]. Following HFD, the mice displayed a reduced weight gain compared to the control with decreased WAT weight and adipocyte size as well as increased blood glucose clearance [99]. Oxygen consumption was enhanced combined with a reduced respiratory exchange ratio (RER) during darkness [99]. In adipocytes, the expression of glycolytic enzymes and adiponectin was enhanced together with an increased expression of uncoupling protein-1 (Ucp-1) in brown adipose tissue (BAT) [99]. Analysis of adipocyte-specific Phd2 deletion in mice using fatty acid binding protein 4 (Fapb4)-Cre showed an increased adiposity and adipose vascularisation, normal glucose homeostasis and reduced circulating fatty acid levels with feeding of normal chow [102]. Phd2 ablation in BAT by in-situ injection of a virus containing targeted sgRNA reduced BAT thermogenesis in cold temperatures and increased HFD-mediated weight gain [83]. Endothelial Phd2 KO in mice (Cdh5-Cre) impaired glucose tolerance and enhanced the fat to body weight ratio [190].
Hypomorph Phd2 mice under both normal chow and HFD showed a decrease in adipocyte size, WAT weight, WAT inflammation, improved insulin sensitivity and glucose tolerance, reduced de novo lipid synthesis and decreased serum cholesterol levels [122]. Hypomorph Phd2 mice with additional deficiency of the LDL receptor were protected against HFD, displaying a reduced weight gain, WAT and liver weight, insulin resistance, adipocyte size, serum cholesterol levels and number of macrophages within WAT [123]. Induced global Phd2 KO (ROSA-CreERT2) in mice also decreased body weight gain and improved glucose tolerance after HFD [186]. Moreover, conditional whole-body KO of Phd2 led to more successful endurance training and faster running time [113]. Pancreatic β-cell specific Phd2 KO (insulin-1 promoter (Ins-1)-Cre) in mice resulted in glucose-induced increases in plasma insulin [51].
In mice with induced global Phd2 deletion (chicken β-actin-CreER), lactate levels were decreased compared to control mice after treadmill exercise [146]. Liver-specific Phd2 ablation (Alb-Cre) in mice led to an activation of the Cori cycle, which serves as a recycling system of lactate-glucose carbon between the muscles and liver [146]. Consequently, mice with hepatic Phd2 deletion displayed an enhanced blood lactate clearance following a lactate tolerance test as well as an increased production of glucose derived from lactate within the liver [146]. Moreover, these mice were protected against an otherwise lethal dose of lactate administered by injection [146]. In another study, it was found that mice with liver-specific Phd2 KO (Alb-Cre) had a different metabolic response to exercise than mice with hepatocyte-specific Hif1a deletion [95].
Overall, PHD2 is a key regulatory enzyme for organismal energy metabolism and its inhibition may be protective against obesity and obesity-associated pathologies.
Immune system
Conditional whole-body Phd2 KO (Rosa26-CreERT2) in mice was protective against a lethal dose of LPS leading to an improved cardiac function, enhanced pericyte/EC coverage and increased survival [187]. In a model of bacterial pneumonia using Streptococcus pneumonia, myeloid-specific inactivation of Phd2 (LysM-Cre) increased the inflammatory response resulting in increased lung injury [129]. This was caused by an enhanced neutrophil response, including an upregulated neutrophil functional capacity, motility and survival [129]. Mice with neutrophil-specific Phd2 deletion (MRP8-Cre) also displayed an enhanced inflammatory response following treatment with LPS. Lack of Phd2 augmented the neutrophil response through HIF-1 and increased the glycolytic flux [129]. In macrophages, Phd2 deletion reduced their phagocytic and migratory capacity, which was HIF-1-dependent and mediated by a differential regulation of glycolytic enzymes [46]. Mice with Phd2 haploinsufficiency showed no differential response to LPS-induced sepsis relative to control [69], which indicates that one functional Phd2 gene locus is sufficient to maintain (certain) immune responses.
Myeloid-specific inactivation of Phd2 (LysM-Cre) was also found to augment atherogenesis [166] and neointima formation [21]. Following a high-cholesterol diet, aortic root plaque size and macrophage apoptosis were increased in mice with Phd2 deletion in myeloid cells [166].
Systemic knockdown (KD) of PHD2 using tetracycline-inducible shRNA as well as conditional global Phd2 deletion (Rosa-ERTCre) resulted in leukocyte expansion and autoimmune features [183]. This phenotype was mediated through stabilisation of HIF-2α [183]. Regulatory T-cells (Tregs) from mice with Phd2 KD/KO were dysfunctional, potentially underlying the observed increase in immune activity [183]. Treg-specific Phd2 inactivation (Foxp3-Cre) led to a systemic inflammatory syndrome, including development of a rectal prolapse, shortening of the colon, splenomegaly and elevated IFN-γ expression [2]. This phenotype was mediated via HIF-2α [2]. In summary, PHD2 is an important regulator of Treg function, and its inactivation can lead to a severe dysregulation of the immune system.
Overall, PHD2 is an important regulator of immune cell function, which is at least in some cell types caused by the alteration of energy metabolism via HIF-1 stabilisation. Several investigations found an enhanced inflammatory response in both baseline or pathological conditions. Interestingly, this is overall not reflected in mouse models using PHIs [160]. Therefore, selective PHD2 deletion appears to have a different effect on the immune system than the inhibition of all three PHD isoforms (e.g. via PHIs).
Lung
In lipopolysaccharide (LPS)-induced lung inflammation, murine-induced endothelial cell-specific Phd2 deletion (Cdh5-CreER) was protective [38]. These animals displayed improved adherent junction integrity and endothelial barrier function, leading to reduced lung vascular permeability and inflammatory cell infiltration and preventing the formation of oedema [38]. This data suggests Phd2 inhibition as a therapeutic strategy for acute lung inflammation. Haploinsufficiency of Phd2 had no effect on pulmonary NEB number, but the NEB size was increased [116].
Carotid body
Phd2+/− mice demonstrated an increased ventilatory response to hypoxia with enlarged carotid bodies [9]. PHD2 was found to be the most important PHD isoform for the modulation of the hypoxia ventilatory response (HVR) [9]. Also, the induced global deletion of Phd2 (Rosa26-CreERT2) led to an exaggerated HVR, which was mediated via HIF-2α [52]. A subsequent analysis of induced Phd2 deletion in type I cells (tyrosine hydroxylase (TH) expressing cell lineage) of carotid bodies (tyrosine hydroxylase (TH), TH-IRES-CreER) found a multilineage expansion and features that resembled paragangliomas [40]. The observed changes of the carotid bodies were again dependent on HIF-2α [40]. Together, these analyses demonstrate an important regulation of carotid body hyperplasia and the HVR by PHD2 via HIF-2 with possible relevance for the development of paragangliomas.
Nervous system
Phd2+/− mice are protected from focal cerebral ischemia at 2 and 24 h following MCAO, displaying an enhanced restoration of cerebral blood flow (CBF) with improved functional outcomes, increased vascular density, less apoptotic cells and a reduced disruption of the blood–brain barrier [14]. Transient MCAO (acute I/R injury) in mice with constitutive neuron-specific Phd2 KO (Ca2+/calmodulin-dependent protein kinase IIα promotor (CaMKIIα)-Cre) led to a decreased infarct size and cell death of hippocampal neurons compared to control [77]. HIF-1α and HIF-2α protein levels were increased in the forebrain combined with increased expression of Epo, VEGF and glycolytic enzymes [77]. Nonetheless, vessel density was not altered within forebrain subregions [77]. Assessment of the relevance of neuron-specific Phd2 inactivation (CaMKIIα-Cre) on the recovery phase following MCAO also supports a protective effect. Mice with neuronal loss of Phd2 showed a reduced infarct area, an increased vascular density along the infarct area, an improved sensory and motor function, an increase of VEGF expression and a reduction of pro-inflammatory cytokines [84]. Overall, Phd2 inhibition is therefore a potential therapeutic strategy for ischemic brain injury.
Long-term potentiation (LTP) is a cellular mechanism considered to be of major relevance for learning and memory formation. Using the same constitutive neuron-specific Phd2 KO mouse model as described above (CaMKIIα-Cre), it was shown that ablation of Phd2 prevents mouse hippocampal LTP [23]. Thus, PHD2 inhibition may affect synaptic plasticity and therefore learning capabilities and memory formation. Interestingly, analysis of the cognitive function in the same murine neuron-specific Phd2 deletion model (CaMKIIα-Cre) showed an enhanced spatial learning under both baseline conditions and following chronic brain hypoperfusion (permanent occlusion of the left common carotid artery) [45]. Increased cognitive function was associated with an increased number of neuronal precursor cells [45]. No change was observed in vascular density, expression of synaptic plasticity-related genes (in the hippocampus) or in the morphology of dendritic spines [45]. Therefore, whereas it has consistently been reported that Phd2 deletion affects the activity of the hippocampus, the functional outcome of PHD2 inactivation is less clear. Of note, Phd2+/− mice displayed no difference compared to wildtype mice in axonal regeneration following peripheral (sciatic) nerve injury, but showed a reduced latency in compound muscle action potentials, indicating an improvement of axon function [139].
Specific deletion of Phd2 in NG2 glia cells and pericytes in the brain (NG2-Cre) had no effect on the brain vasculature [165]. Combinatorial PHD1-3 or VHL deletion in NG2 cells, however, led to an increase of capillary networks and proliferation of pericyte in several areas of the brain [165].
In summary, inactivation of Phd2 affects cognitive functions, brain vessel density and HIF-mediated gene expression in neurons, which is protective in neuronal I/R injury.
Skeletal muscle
In Phd2+/− mice, ischemic injury by femoral artery ligation resulted in a comparably severe necrosis in the skeletal muscle as in control mice [4]. shRNA-mediated silencing of Phd2 in tibial anterior and gastrocnemius muscles following right femoral artery ligation increased HIF-1α expression as well as the expression of VEGF and endothelial nitric oxide synthase (eNOS) [94]. Silencing of Phd2 enhanced vessel and capillary density as well as macrophage infiltration into the ischemic muscle, indicating that Phd2 inactivation supports muscle revascularisation [94]. The observed effects were likely mediated by enhanced HIF-1 activity [94]. Another investigation found that Phd2+/− mice were protected against hindlimb ischemia-induced necrosis by preformed collateral arteries [153]. Arteriogenesis was improved due to an increase in tissue-resident M2-like macrophages and enhanced smooth muscle cell recruitment [153]. Acute and chronic Phd2 haploinsufficiency in macrophages also led to arteriogenesis in the ischemic muscle, indicating that the protective effect of Phd2 ablation was due to the resulting regulation of macrophages [153].
Induced keratinocyte-specific Phd2 ablation (human keratin 14 promoter (KRT14)-CreERT) during femoral artery ligation improved distantly located vascular survival and arteriogenesis in ischemic hind limbs [151]. The protective effect could also be observed in type 1 and 2 diabetic mice and in mice with hepatocyte-specific Phd2 KO (Alb-Cre) [151]. Local Phd2 deletion selectively in keratinocytes of the hindlimb skin (by local administration of tamoxifen) was not protective against ischemic injury [151]. These results indicate that protection against ischemia by inactivation of Phd2 works remotely and that it may therefore not be necessary to access the actual target tissue for treatment.
Phd2 hypomorph mice showed increased HIF-1α and HIF-2α levels in skeletal muscles, increased capillary size without effects on capillary number and an upregulation of the expression of glycolytic genes [66]. After exercise, serum lactate levels were reduced faster [66]. Hind limb I/R injury led to reduced infarct size in Phd2 hypomorphic mice, which was likely due to the increase in capillary size as well as the HIF-mediated regulation of energy metabolism [66].
Conditional whole-body Phd2 KO mice demonstrated increased capillary density in skeletal muscle [113, 135] likely due to induction of VEGF [135]. Muscle fibres of KO animals transitioned towards slow type I fibres [135]. After mechanic muscle trauma, Phd2 hypomorph mice presented with faster muscle tissue regenerative capabilities, including enhanced activation of myogenic factors, accelerated macrophage infiltration into injured tissue areas and upregulation of stem cell proliferation markers [134].
In summary, genetic PHD2 inhibition is protective in muscle ischemia due to enhanced arteriogenesis, which may be affected by increased VEGF secretion as well as by the induction of pro-angiogenic macrophages.
Bone
Constitutive Phd2 deletion in osteoblasts in mice (Col1a2‐iCre) led to premature death 12 to 14 weeks after birth [19]. These mice displayed a shorter stature with decreased bone mineral density, bone area and bone mineral content in tibias and femurs but not in vertebrae. Within the femoral trabecular bones, bone volume and total volume as well as bone volume fraction were reduced [19]. This phenotype was suggested to be caused by diminished bone formation [19]. There was no alteration in proximal tibial epiphyses in 5-week-old mice following Col1a2‐iCre-mediated Phd2 deletion [17]. Conditional deletion of PHD2 in osteoprogenitors (OSX-Cre transgene) led to a less severe phenotype without the report of premature death and with the strongest changes observed with combinatorial deletions of PHD isoforms [173]. Conditional Phd2 inactivation in haematopoietic cells, osteoblasts and Epo-producing cells (CD68-Cre) led to a strong decrease of bone density in the distal femur and in vertebrae [125]. Analyses of mice with Phd2 deletion in osteoblasts (OSX-Cre) or osteoclasts (Vav-Cre) indicated that the observed bone malformations were not directly linked to an altered osteoblast or osteoclast activity caused by the inactivation of Phd2 [125]. It was suggested that the bone malformations observed in mice with CD68-Cre-mediated Phd2 deletion were caused by an Epo-mediated effect on osteoblast progenitors, because Epo levels were increased due to the deletion of Phd2 [125]. Analyses in Phd2+/− mice showed a decreased bone mineralisation and trabeculae bone mass [55].
Conditional deletion of Phd2 in osteocytes (Dentin Matrix Protein 1 (Dmp1)-Cre) increased the bone mass by enhanced bone formation and reduced resorption [140]. In addition, these mice were protected against bone loss caused by a decline in oestrogen levels [140]. Moreover, Phd2 ablation in osteocytes (Dmp1-Cre) increased fibroblast growth factor-23 (FGF23) levels (an important hormone regulating mineral ion handling) in the murine bone [112]. Deletion of Phd2 in murine periosteum-derived cells improved bone regeneration following implantation of the KO cells due to enhanced cell viability, which was likely caused by an altered energy metabolism [141]. This phenotype was independent of angiogenesis [141].
Chondrocyte-specific Phd2 conditional deletion (type 2 collagen-α1-Cre) led to enhanced trabecular bone mass of long bones by increased trabecular thickness and number with decreased trabecular separation [17, 20]. KO mice displayed increased bone formation rate in long bones, bone mineralisation and upregulated markers for chondrocyte hypertrophy [17, 20]. These results suggest that Phd2 plays an important role in endochondral bone formation [17, 20]. Moreover, in the same mouse model, articular cartilage thickness was decreased, combined with increased chondrocyte differentiation [18].
In summary, PHD2 activity is of key importance for the regulation of bone volume and density as well as for articular cartilage thickness, likely including multiple mechanisms and cell types.
Gastrointestinal tract
Phd2+/− mice as well as mice with constitutive Phd2 deletion in endothelial and haematopoietic cells (Tie2-Cre) did not show any difference compared to control mice in DSS-induced colitis [67, 154, 167]. Constitutive inactivation of Phd2 in intestinal epithelial cells (Villin-Cre) did not lead to spontaneous intestinal inflammation and was also not protective in a DSS-induced colitis model or in colitis-associated colon cancer [177]. Deletion of Phd2 in intestinal epithelial cells in mice was also not protective against radiation-induced gastrointestinal toxicity [157]. Mice with ablation of Phd2 in regulatory T-cells (Foxp3-Cre) spontaneously developed systemic inflammation (see above) [2]. These mice also showed an increased sensitivity to toxoplasmosis and DSS-induced colitis, likely because of an inefficient control of the inflammatory response [2].
Analysis of anastomotic leakage in Phd2+/− mice showed an improved healing of septic and ischemic colon anastomoses [144]. Phd2 haploinsufficiency reduced anastomotic leakage, increased the bursting pressure and was protective against sepsis-related mortality [144]. This protective effect was achieved by the induction of M2 polarisation of macrophages, which reduced immune cell recruitment [144].
Overall, whilst Phd2 is important for immune cell functions and thus for pro-inflammatory responses in vivo, Phd2 is dispensable for intestinal development and intestinal epithelial homeostasis.
Skin
The effect of Phd2 deletion on wound healing was analysed using different mouse models. Constitutive Phd2 KO in myeloid (LysM-Cre) or endothelial (Flk1-Cre) cells had no effect on wound closure in full-thickness excisional skin wounds (6-mm biopsy punches) [64]. In turn, specific constitutive Phd2 deletion in keratinocytes (K14-Cre) decreased the time for wound closure and increased migration of the hyperproliferating epithelium as well as proliferation of keratinocytes in the stratum basale [64]. These effects were at least in part mediated by HIF-1 as well as by decreased transforming growth factor β signalling [64]. Mice with constitutive Phd2 ablation in keratinocytes (K14-Cre) or induced Phd2 deletion in fibroblasts (Col1α2-CreER) each showed an accelerated wound healing in 6-mm full-thickness excisional wounds [193]. Both epidermal and dermal Phd2 KO were also protective in an ischemic pedicle flap model with more viable flaps being present in the Phd2 KO mice in comparison to mice with wildtype Phd2 alleles [193]. Injection of murine mesenchymal stromal cells transduced with shPHD2 into full-thickness excisional skin wounds also accelerated wound healing with enhanced cellularity and blood vessel density [70]. Phd2 deletion in FoxD1-lineage mesodermal cells (FoxD1-Cre) led to truncal alopecia by disturbing hair follicle development [128]. Overall, Phd2 inactivation in keratinocytes, fibroblasts and/or mesenchymal stem cells accelerates cutaneous wound healing. Thus, PHD2 is a promising potential therapeutic target for wound healing.
Eye
Oxygen treatment of preterm infants can lead to retinopathy including loss of micro-vessels in the retina, which can result in blindness. In neonatal control mice, exposure to 75% O2 reduced retinal micro-vessels [31]. Induced global Phd2 ablation (Rosa26-CreERT2) in mice from postnatal day 1 was protective against the effect of 75% O2 exposure on retinal micro-vessels with increased HIF-1α and HIF-2α protein levels compared to control mice [31]. This indicates that inhibition of PHD2 might be a therapeutic option for preterm infants with oxygen treatment to prevent retinopathy. Constitutive lack of Phd2 in astrocytes (GFAP-Cre) resulted in an increased number of retinal astrocytes, impaired vascular pruning and increased HIF-2α protein levels in neonatal mice [30]. Therefore, the HIF pathway may play an important physiological role in retinal astrocytes for the appropriate development of the retinal vasculature.
Cancer
Investigation of tumours derived from B16 melanoma, Panc02 pancreatic carcinoma or Lewis lung carcinoma (LLC) cells in Phd2+/− mice showed no effect on tumour growth, tumour cell apoptosis or proliferation; however, the occurrence of metastasis was reduced [100]. In Phd2+/− mice, tumour vessel endothelial lining and maturation were normalised (without effect on tumour vessel lumen size or density), preventing tumour cell intravasation, invasion and thus metastasis [100]. In mice with conditional haplodeficient Phd2 inactivation in endothelial cells (Tie2-Cre), the main findings could be repeated, including reduced metastasis and tumour vessel normalisation [100]. Moreover, haplodeficient Phd2 inactivation in endothelial cells in mice led to an improved chemotherapeutics delivery to tumours [81]. These results were repeated in mice with induced acute global heterozygous or homozygous deletion (Rosa26-CreERT2 transgene) of Phd2 [81]. In addition, the induced global Phd2 deletion led to an increased protection of healthy organs against detrimental side effects of chemotherapeutic agents in a HIF-dependent manner [81]. In a spontaneous metastatic mammary gland tumour model, Phd2+/− mice reduced metastasis by reducing cancer-associated fibroblast (CAF) activation, production of extracellular matrix and CAF-mediated contraction [76]. This effect was dependent on tumour vessel normalisation as well as PHD2 inactivation in tumour cells and not in CAFs themselves [76].
Induction of primary hepatic tumours by diethylnitrosamine (DEN) treatment in Phd2+/− mice resulted in enhanced hepatocarcinogenesis and increased development of cholangiocarcinoma with a larger number of metastasis, which was suggested to be caused by chronic HIF activation [49]. The beginning of neoplastic transformation was not altered by Phd2 haploinsufficiency in the same hepatic tumour model, indicating that PHD2 activity is relevant during tumour nodule formation, but not for neoplastic transformation [10].
Analysing the relevance of PHD2 in immune cells for tumour development, Phd2 was deleted in haematopoietic cells (CD68-Cre) and the mice were inoculated with LLC cells, leading to reduced tumour growth, decreased tumour cell apoptosis and enhanced proliferation [96]. In mice, Phd2 deletion in myeloid cells (LysM-Cre), in all T-cell populations (CD4-Cre) or in B-cells (CD19-Cre) had no effect on tumours from LLC cells [96]. However, combined Phd2 deletion in myeloid and T-cells (LysM/CD4-Cre) led to a decreased tumour growth [96]. This indicates that PHD2 activity in myeloid and T-cells supports tumour growth and that PHD2 inhibition may be a therapeutic option for lung cancer treatment.
Conditional melanocyte-specific deletion of Phd2 (Tyr-CreER) did not lead to any pigmented lesions [92]. However, in mice with a melanocyte-specific deletion of Phd2 combined with the expression of BRafV600E, melanoma with a 100% penetrance and metastasis in lymph nodes were observed [92]. These results indicate that PHD2 can enhance melanomagenesis in the presence of BRafV600E.
In mice with constitutive KO of Phd2 in the medulla of the adrenal gland (TH-Cre), alterations in developmental adrenal morphologies were reported combined with a gene expression pattern mimicking pseudohypoxic pheochromocytoma [33]. The observed changes were shown to be HIF-2α-dependent. Interestingly, induced Phd2 deletion in the adrenal medulla in adult mice did not lead to the aberrant gene expression pattern, demonstrating that the observed changes towards pseudohypoxic pheochromocytoma were likely occurring during adrenal gland development [33].
In a CAC model (AOM and DSS treatment), Phd2+/− mice showed no difference in the induced colitis but CAC growth was enhanced together with the number of tumour-associated macrophages [67]. The observed regulation was due to an upregulation of the expression of epiregulin in macrophages, a ligand for EGFR, as well as an increased extracellular signal-regulated kinase 1/2 and signal transducer and activator of transcription 3 signalling [67].
In summary, these data indicate that inhibition of PHD2 activity alone is detrimental for some tumours, including lung carcinoma and prostate cancer, which is (at least in part) due to its effects on vessel formation, myeloid and T-cells. In melanocytes, PHD2 inhibition may be protective to a certain degree against the development of melanomas but is detrimental in the presence of BRafV600E. Moreover, inactivation of PHD2 may support the growth and metastasis formation from hepatic tumour and cholangiocarcinoma as well as the growth of colon cancer. Interestingly, PHD2 activity appears to be necessary for the development of the adrenal gland, preventing a shift of the gene expression towards pseudohypoxic pheochromocytoma. Thus, PHD2 plays an important role in tumour growth and metastasis formation; however, its relevance and function depend on the cancer type.
Phd3 (Egln3 ) deletion
The baseline phenotype summarises observations made in mice with Phd3 deletion without the induction of a pathology. The subsequent chapters focus on phenotypes of mice with various Phd3 deletions in disease models.
Baseline phenotype
Mice with constitutive whole-body deletion of Phd3 (Phd3−/−) are viable but with a small reduction in the offspring being observable after mating of heterozygous mice [8, 152]. At baseline conditions, there were no obvious abnormalities during development [152] or adulthood apparent [8, 149, 150] with physiological Epo and haematocrit levels as well as red blood cell counts [149], white blood cell counts (including normal neutrophil and macrophage numbers) [69, 169], angiogenesis [150] and no obvious alterations in the morphologies of lung and kidney [69]. Also, bone development and architecture were normal following the specific constitutive deletion of Phd3 in osteoprogenitor cells (OSX-Cre) or chondrocytes (Col2α1-Cre) [173, 179]. In contrast, Phd3−/− mice showed an increased trabecular spacing and a decreased trabecular number as well as a decreased fractional bone volume in long bones and vertebrae [55]. Mice with enzymatically inactive Phd3 (R205K knock-in mutation) showed no obvious changes in development or fertility [62], similar to the Phd3−/− mice.
Interestingly, Phd3−/− mice display a neuronal phenotype [8]. The number of neurons was increased in the superior cervical ganglion (SCG), in the adrenal medulla and in the carotid body due to a decreased neuronal apoptosis [8]. Moreover, the function of the sympathoadrenal system was reduced with a decreased innervation of target tissues, secretory capacity of the adrenal medulla and reduced sympathoadrenal responses (e.g. of the iris, submandibular gland and pineal gland) combined with a decrease in systemic blood pressure [8]. The hypoxic ventilatory response was comparable to wildtype mice [9]. The phenotype was caused by the regulation of HIF-2α and was independent of HIF-1α [8]. Therefore, PHD3 plays a major role for the anatomic and functional integrity of the sympathoadrenal system [8]. Phd3−/− mice also displayed hypertrophy and hyperplasia of NEBs with increased NEB size and NEB cells [116]. The NEB alterations were comparable to the findings in Phd1 KO mice [116]. During aging, 1-year-old Phd3−/− mice showed increased triglyceride and cholesterol levels, liver weight, adiposity and body weight, enhanced WAT inflammation and insulin resistance and hyperglycaemia [158].
Overall, Phd3 deletion does not alter the majority of organ systems under baseline conditions. However, constitutive global Phd3 ablation impacts on the development and function of the sympathoadrenal system with corresponding effects on systemic blood pressure, iris size modulation and excretion from glands. Moreover, during aging, PHD3 counteracts metabolic dysfunction.
Cardiovascular system
To assess the relevance of PHD3 in ischemic heart injury, the response of Phd3−/− mice to LAD ligation was investigated. In this model of myocardial infarction, Phd3−/− mice showed improved cardiac function, increased capillary density, reduced cardiac fibrosis and increased HIF-1α DNA binding [114]. LAD ligation with subsequent release as model for I/R injury in induced whole-body Phd3 KO mice (chicken β-actin-CreER) resulted in attenuated tissue damage [176]. Myocardial injury and apoptosis of cardiomyocytes were decreased [176]. In a rat model of type 2 diabetes (HFD plus streptozotocin injection), shRNA-mediated PHD3 knockdown (jugular vein injection) reduced cardiac dysfunction [174]. Thus, Phd3 inactivation is protective in different models of cardiac injury, likely by decreasing cardiomyocyte apoptosis and by enhancing angiogenesis following injury.
Investigating further the relevance and function of PHD3 in the cardiovascular system, transgenic mice were generated with increased PHD3 expression. Cardiomyocyte-specific transgenic expression of PHD3 in mice (cPhd3tg) did not affect cardiac function or HIF activity at baseline conditions over an investigation period of 14 months [192]. Following LAD ligation, cPhd3tg hearts showed an increased infarct size linked to reduced HIF-1α and HIF-2α stabilisation [192]. In a mouse model of obstructive sleep apnoea, shPHD3 treatment had no effect, whereas lentiviral PHD3 overexpression reduced intermittent hypoxia-mediated cardiac perivascular collagen deposition and (partially) prevented cardiac dysfunction [188]. In a murine model of the effect of chronic intermittent hypoxia on cardiac pressure overload, lentiviral PHD3 overexpression improved the systolic function and alleviated cardiac remodelling [180]. These studies indicate that the effect of PHD3 overexpression may depend on the type of cardiac injury. The detrimental effect of PHD3 overexpression in cardiac ischemia further supports the finding that PHD3 deletion is protective.
In an atherosclerosis model, mice deficient for apolipoprotein E were fed HFD and either injected with lentivirus carrying shPHD3 or DNA for PHD3 overexpression [90]. PHD3 overexpression enhanced the area of aortic atherosclerotic lesions, the number of macrophages and smooth muscle cells and the number of apoptotic cells in atherosclerotic plaques [90]. Following a high-cholesterol diet in mice, Phd3 and Ldlr double KO did not alter atherosclerotic plaque size or necrotic, macrophage, collagen or oxygen content [29].
In summary, PHD3 activity plays an important role in the response of cardiac tissue to injury and PHD3 may be a therapeutic target in myocardial infarction, diabetes-induced cardiac dysfunction and in cardiac injury caused by obstructive sleep apnoea. Its relevance in atherosclerosis is less clear.
Haematopoietic system
There was no effect observed on erythropoiesis or haematopoiesis by constitutive global Phd3 deletion [149], or Phd3 ablation in hepatic [105, 163] or (renal) FoxD1 lineage cells [73]. Interestingly, in Phd3 and Ldlr double KO mice, haematocrit was increased at baseline conditions whereas WBC counts were maintained [29].
Liver
Following a partial hepatectomy, liver regeneration was not affected in Phd3−/− mice [107]. In a model of chronic bile duct injury, Phd3−/− mice showed no difference in biliary fibrosis [145]. Thus, PHD3 is not relevant for liver regeneration or (bile duct injury-mediated) hepatic fibrosis development or progression.
Energy metabolism
Mice with liver-specific Phd3 KO (tail vein injection of adenoviral Cre into Phd3fl/fl mice) demonstrated lower fasting insulin and glucose levels as well as an increased glucose tolerance [156]. In addition, the hepatic expression of several gluconeogenic enzymes (Pck1, G6pc, Ppargs1a) was reduced as well as the expression of enzymes involved in lipid metabolism (Srebf1c, Fas). Mechanistically, the observed changes were linked to increased HIF-2α stabilisation and Irs2 expression in the liver [156]. To investigate the influence of hepatic Phd3 depletion on diabetes, the mice were fed HFD. Both fasting blood glucose and fasting serum insulin improved in comparison to wildtype mice [156]. Liver-specific Phd3 KO (Alb-Cre) decreased gluconeogenesis during fasting periods, which was mimicked in PHD3 His196Ala (inactive PHD3) knock-in mice [182]. Both mouse models were resistant against high-fat and high-sucrose diet-induced gluconeogenesis and hyperglycaemia with improved insulin and glucose tolerance tests [182]. The observed phenotypes were suggested to be caused by PHD3-mediated hydroxylation of CREB-regulated transcriptional coactivator (CRTC) 2 [182].
Mice with constitutive global Phd3 deletion (CMV-Cre) displayed elevated fatty acid oxidation (FAO) in the skeletal muscle, especially after fasting [184]. Glycogen levels were maintained in the skeletal muscle, but they were reduced in the liver under normal feeding conditions. Under fasting conditions, O2 consumption and CO2 production were both enhanced whereas the respiratory exchange ratio (RER) was maintained [184]. In a strenuous exercise endurance challenge, both mice with global and skeletal muscle-specific (MCK-Cre) Phd3 deletion displayed increased exercise capacity [184]. Mechanistically, PHD3 was reported to hydroxylate acetyl-CoA carboxylase (ACC) 2 (which converts acetyl-CoA into malonyl-CoA) and the hydroxylation of ACC2 reduced FAO [184]. Combinatorial deletion of Phd3 and Ldlr in mice resulted in an increased body weight at baseline that was further significantly increased relative to control mice following high-cholesterol diet (HCD) [29]. After HCD, also enhanced triglyceride and plasma cholesterol levels were observed. In the liver, the expression of Fas and Cyp7a1 was increased, which may contribute to the dyslipidaemia [29].
Pancreatic β-cell specific Phd3 deletion (Ins-1-Cre) had no effect on glucose homeostasis under standard conditions [51, 109]. Nonetheless, β-cell mass was reduced and β-cell apoptosis was enhanced [51]. Following HFD, glucose homeostasis was impaired [109]. The metabolism of Phd3−/− β-cells shifted from glycolysis to fatty acid oxidation, which was linked to reduced insulin secretion after prolonged HFD [109].
Overall, Phd3 deletion protects against dietary-induced diabetes and according alterations in glucose homeostasis, which may be due to effects in the liver, on pancreatic β-cells and in the skeletal muscles. Moreover, the metabolic changes introduced by Phd3 ablation support exercise endurance. FAO was increased in the skeletal muscle following Phd3 KO, which may contribute to the protective effect against dietary-induced diabetes. These results principally support an approach to pharmacologically inhibit PHD3 as treatment for type 2 diabetes. However, one study reported that Phd3 deletion in combination with Ldlr ablation leads to dietary-induced dyslipidaemia. Therefore, inactivation of PHD3 may also have detrimental effects in certain (metabolic) conditions.
Immune system
The activity and function of neutrophils derived from Phd3−/− mice were preserved in both normoxia and hypoxia; however, neutrophil apoptosis was increased leading to a reduced Phd3−/− neutrophil survival during hypoxia [169]. In hypoxia, HIF transcriptional activity was not altered in Phd3−/− neutrophils relative to control. The increase of apoptosis in hypoxia in Phd3−/− neutrophils was linked to an increased expression of pro-apoptotic Siva1 and a reduced hypoxia-mediated stimulation of the Siva1 target protein BCL-XL [169]. In an LPS-induced acute lung injury model, neutrophil apoptosis was enhanced in Phd3−/− mice, leading to a decreased total neutrophil count in the inflamed tissue [169]. In DSS-induced colitis, neutrophilic inflammation was also decreased [169]. These findings suggest that PHD3 plays a key role in neutrophil survival and neutrophil-driven inflammation.
The inflammatory response in Phd3−/− mice was also assessed in models of abdominal sepsis. Following LPS- or bacterial-induced (caecal ligation and puncture model) sepsis, the survival of Phd3−/− mice was reduced compared to WT, Phd1−/− and Phd2+/− mice [69]. In Phd3−/− mice, plasma pro-inflammatory cytokine levels and macrophage recruitment to internal organs were increased during sepsis [69]. The decrease in survival during sepsis was linked to an increased activity of Phd3−/− macrophages, which in turn was dependent on both HIF-1α and NF-κB activity [69]. Phd3 deletion in macrophages altered their maturation and polarisation towards an M1 (pro-inflammatory) polarisation [69]. This increase in M1 polarisation was linked to an accelerated differentiation and was not observed in fully differentiated macrophages [147]. Phd3−/− macrophages showed (similar to neutrophils) no change in HIF activity [147]. Interestingly, Phd3 deletion, in contrast to its effect in neutrophils, decreased the apoptosis rate of macrophages [147]. Of note, in a model of hind limb ischemia in mice with myeloid-specific Phd3 deletion (LysM-Cre), Phd3−/− macrophages displayed an increase in M2 (anti-inflammatory) polarisation [6]. Phd3 deletion in CD11chi cells (CD11c-Cre) did not affect dendritic cell maturation, metabolism or survival in basal or stimulated conditions [159]. In a mouse model of LLC cancer in mice with genetic Phd3 inactivation (R205K mutation), macrophage M2 polarisation was prevented [62].
Mice with induced global Phd3 ablation (chicken β-actin-CreER) were protected against ionizing radiation effects on the thymus with reduced apoptosis of thymus cells [175]. The protection was reported to be mediated by preventing the hydroxylation of HCLK2, which in turn reduced DNA damage-induced apoptosis [175].
In general, Phd3 loss affects apoptosis in neutrophils and macrophages and therefore corresponding inflammatory responses. The effect of Phd3 deletion on macrophage polarisation may depend on the inflammatory context as well as whether the deletion is present in all cells or is myeloid-specific. Further analyses will be necessary to clarify this.
Lung
To assess the relevance of PHD3 for asthma pathogenesis, mice with constitutive selective Phd3 KO or overexpression in CD11chi cells were generated (CD11c-Cre) [159]. In a model of allergic airway inflammation, no modulation of the induced asthma was found. Interestingly though, the CD11c-specific Phd3 deletion prevented alveolar macrophages in competition with wildtype macrophages to optimally repopulate an empty alveolar niche [159].
Nervous system
In a mouse model of cerebral ischemia using MCAO, constitutive global Phd3 deletion aggravated regional cerebral blood flow, but did not change the functional outcome [14]. Thus, although PHD3 regulates neuronal apoptosis [8], it does not affect cerebral ischemic injury. Following peripheral (sciatic) nerve injury, Phd3−/− mice demonstrated increased axonal regeneration and reduced cold hyperalgesia, indicating that pharmaceutical PHD3 inhibition may be a treatment option for peripheral nerve injury [139].
Skeletal muscle
Several studies investigated the effect of different methods of Phd3 deletion in a model of hind limb ischemia using femoral artery ligation. Phd3−/− mice were not protected against ischemia-induced muscle cell death [4]. A separate study reported that shRNA-mediated knockdown of PHD3 enhanced vessel and capillary density as well as macrophage infiltration in the ischemic muscle [94]. These results were linked to increased HIF-1α stabilisation within the injury site [94]. Another investigation found that Phd3−/− mice also display enhanced vessel and capillary density, improving motor function by enhanced recovery of perfusion as well as decreasing tissue fibrosis [126]. Mechanistically, HIF-1α was increased combined with enhanced VEGF and Bcl-2 expression [126]. Murine myeloid-specific Phd3 deletion (LysM-Cre) had no effect on angiogenesis or the recovery of reperfusion, but led to a decreased infiltration of macrophages and to a reduced fibrosis in the ischemic muscle [6].
Using viral transduction of sgRNA targeting PHD3 in mice with skeletal muscle-specific Cas9 expression (MCK-Cre-Cas9), the induced PHD3 deletion increased the area of muscle fibres and overall muscle weight [82]. In mice with denervated muscle atrophy, sgRNA-mediated Phd3 KO mitigated the loss of muscle weight and the reduction of muscle fibres [82]. It was suggested that Phd3 deletion enhances the activity of the major transcriptional regulator of the cellular response to pro-inflammatory signals, NF-κB [82]. It has further been reported that muscle-derived stem/progenitor cells (MDSPC) from Phd3−/− mice display an increased myogenic potential [137].
Overall, the majority of reports support a protective effect of genetic Phd3 inactivation in hind limb ischemia, leading to increased vascularisation and decreased fibrosis. In addition, Phd3 deletion may also be counteracting muscle atrophy following denervation. Therefore, pharmacologic inhibition of PHD3 appears to be a promising approach for the treatment of various muscle pathologies.
Gastrointestinal tract
Investigating the relevance of PHDs for the development and progression of inflammatory bowel diseases, it was demonstrated that global homozygous Phd3 deletion in mice does not affect susceptibility or development of DSS-induced colitis [154]. Phd3 KO in haematopoietic and endothelial cells (Tie2-Cre) did also not influence DSS-induced colitis in mice [167]. In a model for colitis-associated colorectal cancer (AOM and DSS treatment), Phd3−/− mice showed no difference in disease activity or CAC growth [67]. In contrast, another study found that mice with Phd3 deletion in intestinal epithelial cells (Villin-Cre) spontaneously develop colitis and demonstrate an increased disease activity in DSS-induced colitis [16]. This phenotype was suggested to be caused by the PHD3-dependent regulation of the tight junction protein occludin [16]. The same group reported in a later study again that intestinal epithelial cell-specific Phd3 ablation was detrimental in DSS-induced colitis, but that surprisingly knock-in of catalytically inactive PHD3 (H196A) had no effect on disease activity, body weight development or shortening of the colon [181]. It was further shown that PHD3 regulates goblet cell generation in the murine intestine, which was suggested to occur independent of PHD3 enzymatic activity [181].
In a model of radiation-induced gastrointestinal toxicity, it was shown that ablation of Phd3 alone in the murine intestinal epithelium (Villin-Cre) had no effect on the progression or outcome of the toxicity [157]. In a model of intestinal anastomoses and anastomotic leakage, constitutive global Phd3 KO strongly enhanced gross structural anastomotic defects in mice [144].
In summary, there is strong evidence that PHD3 is dispensable in DSS-induced colitis (and CAC), whereas one group reported a functional relevance for PHD3 in colitis. In accordance with the majority of reports about the function of PHD3 in intestinal inflammation or injury, PHD3 is also not relevant for radiation-induced gastrointestinal toxicity. Interestingly, selective genetic inactivation of Phd3 is detrimental in intestinal anastomoses. Overall, PHD3 is likely dispensable in pathologies caused by intestinal epithelial barrier dysfunction.
Cancer
Inactivation of Phd3 by R205K knock-in mutation in mice reduced LLC cancer growth through regulation of Erk3, which is involved in the EGFR signalling pathway [62]. Inactivation of Phd3 prevented macrophage efferocytosis, migration and M2 polarisation [62]. Analysing the relevance of PHD3 in CAC, Phd3−/− mice displayed no difference in CAC growth [67].
Overall, to the best of our knowledge, the relevance of host Phd3 for cancer development and progression is not very well studied using KO mice. The existing studies indicate that host PHD3 activity supports LLC cancer growth whereas it is dispensable for CAC.
Conclusions
The cellular oxygen sensors PHD1-3 are regulatory proteins within the HIF pathway, regulating HIF-α protein stability. Cellular studies have indicated distinct roles for each of the PHDs for the regulation of HIF-1α and HIF-2α. Importantly, knockdown and knockout in rodents of either of the genes encoding Phd1, Phd2 or Phd3 have demonstrated an independent function and relevance of each isoform on the organismal level (Tables 1 and 2). In baseline conditions, PHD1 is not essential during development and has a key function in the regulation of oxidative metabolism in the skeletal muscle via HIF-2α (Table 1). PHD2 is the most relevant PHD isoform for physiology, as constitutive and induced global Phd2 deletion is lethal both during development and adulthood, whereas the ablation of PHD1 or PHD3 is well tolerated (Table 1). PHD2 is also the most relevant regulatory enzyme of HIF-α in vivo, as highlighted in mice lacking PHD2 by, e.g. increased erythropoiesis, angiogenesis and developmental heart defects. PHD3 is essential for the appropriate development of the sympathoadrenal system (Table 1).
The deletion of either of the PHD isoforms can lead to the stabilisation of HIF-1α or HIF-2α in vivo. However, the observed regulation of HIF-α levels appears to be cell-type and/or organ-specific in mice with Phd1 and Phd3 deletion and may additionally be disease/injury-specific. Some phenotypes in mice with Phd1 or Phd3 KO were linked to regulations independent of HIF, suggesting a functional relevance of the enzymatic function of the PHDs outside the HIF pathway. Nonetheless, additional investigations will be necessary to clarify this.
Interestingly, inactivation of Phd1 or Phd3 within mice was protective (or had no effect) against tumour growth and metastasis formation in the assessed cancers. Even Phd2 ablation was protective in some cancer types, whereas it may be detrimental in hepatic and colon cancer. HIF activity can support tumour growth [106, 172]; therefore, a major concern for the clinical use of PHD inhibitors is a putative supportive effect for cancer development or progression. However, the results from PHD KO mice suggest that it may be possible to target these enzymes without detrimental effects regarding tumour growth. Of note, treatment with (non-selective) hydroxylase inhibitors is protective in various tumour models [43].
Currently, no PHD isoform selective pharmacologic inhibitors are available and the clinical use of the existing PHIs for hypoxia-associated diseases other than renal anaemia is currently prevented by the enhancement of Epo expression. Epo appears to be the most sensitive gene in response to HIF activation; therefore, PHIs can be used at relatively low doses for the treatment of renal anaemia. However, the sensitivity of the Epo expression to PHD inhibition is a disadvantage for the treatment of other hypoxia-associated diseases with these PHIs, as a strong increase in erythropoiesis is in many diseases not necessarily desirable. Some diseases may still be treatable, if a targeted local release is possible without systemic exposure to the PHI. Otherwise, single and combinatorial pharmacologic targeting especially of PHD1, PHD3 and also FIH will need to be considered and investigated further, as systemic pharmacologic inhibition of these oxygen sensors can be protective in different diseases without eliciting an Epo response.
Overall, gene deletions in mice of Phd1, Phd2 or Phd3 have highlighted the physiological relevance especially of PHD2 and the great potential of these three enzymes as pharmacologic targets in many different hypoxia-associated diseases. PHD isoform-selective inhibitors would thus offer a unique possibility for the treatment of various hypoxia-associated diseases and their development would spark an exciting research area for their potential use as indicated by the numerous isoform-selective deletion models.
Data availability
Not applicable.
References
Adluri RS, Thirunavukkarasu M, Dunna NR, Zhan L, Oriowo B, Takeda K, Sanchez JA, Otani H, Maulik G, Fong GH, Maulik N (2011) Disruption of hypoxia-inducible transcription factor-prolyl hydroxylase domain-1 (PHD-1-/-) attenuates ex vivo myocardial ischemia/reperfusion injury through hypoxia-inducible factor-1alpha transcription factor and its target genes in mice. Antioxid Redox Signal 15:1789–1797. https://doi.org/10.1089/ars.2010.3769
Ajouaou Y, Azouz A, Taquin A, Denanglaire S, Hussein H, Krayem M, Andris F, Moser M, Goriely S, Leo O (2022) The oxygen sensor prolyl hydroxylase domain 2 regulates the in vivo suppressive capacity of regulatory T cells. Elife 11. https://doi.org/10.7554/eLife.70555
Appelhoff RJ, Tian YM, Raval RR, Turley H, Harris AL, Pugh CW, Ratcliffe PJ, Gleadle JM (2004) Differential function of the prolyl hydroxylases PHD1, PHD2, and PHD3 in the regulation of hypoxia-inducible factor. J Biol Chem 279:38458–38465. https://doi.org/10.1074/jbc.M406026200
Aragones J, Schneider M, Van Geyte K, Fraisl P, Dresselaers T, Mazzone M, Dirkx R, Zacchigna S, Lemieux H, Jeoung NH, Lambrechts D, Bishop T, Lafuste P, Diez-Juan A, Harten SK, Van Noten P, De Bock K, Willam C, Tjwa M, Grosfeld A, Navet R, Moons L, Vandendriessche T, Deroose C, Wijeyekoon B, Nuyts J, Jordan B, Silasi-Mansat R, Lupu F, Dewerchin M, Pugh C, Salmon P, Mortelmans L, Gallez B, Gorus F, Buyse J, Sluse F, Harris RA, Gnaiger E, Hespel P, Van Hecke P, Schuit F, Van Veldhoven P, Ratcliffe P, Baes M, Maxwell P, Carmeliet P (2008) Deficiency or inhibition of oxygen sensor Phd1 induces hypoxia tolerance by reprogramming basal metabolism. Nat Genet 40:170–180. https://doi.org/10.1038/ng.2007.62
Arsenault PR, Pei F, Lee R, Kerestes H, Percy MJ, Keith B, Simon MC, Lappin TRJ, Khurana TS, Lee FS (2013) A knock-in mouse model of human PHD2 gene-associated erythrocytosis establishes a haploinsufficiency mechanism. J Biol Chem 288:33571–33584. https://doi.org/10.1074/jbc.M113.482364
Beneke A, Guentsch A, Hillemann A, Zieseniss A, Swain L, Katschinski DM (2017) Loss of PHD3 in myeloid cells dampens the inflammatory response and fibrosis after hind-limb ischemia. Cell Death Dis 8:e2976. https://doi.org/10.1038/cddis.2017.375
Bersten DC, Peet DJ (2019) When is a target not a target? Elife 8. https://doi.org/10.7554/eLife.50585
Bishop T, Gallagher D, Pascual A, Lygate CA, de Bono JP, Nicholls LG, Ortega-Saenz P, Oster H, Wijeyekoon B, Sutherland AI, Grosfeld A, Aragones J, Schneider M, van Geyte K, Teixeira D, Diez-Juan A, Lopez-Barneo J, Channon KM, Maxwell PH, Pugh CW, Davies AM, Carmeliet P, Ratcliffe PJ (2008) Abnormal sympathoadrenal development and systemic hypotension in PHD3-/- mice. Mol Cell Biol 28:3386–3400. https://doi.org/10.1128/MCB.02041-07
Bishop T, Talbot NP, Turner PJ, Nicholls LG, Pascual A, Hodson EJ, Douglas G, Fielding JW, Smith TG, Demetriades M, Schofield CJ, Robbins PA, Pugh CW, Buckler KJ, Ratcliffe PJ (2013) Carotid body hyperplasia and enhanced ventilatory responses to hypoxia in mice with heterozygous deficiency of PHD2. J Physiol 591:3565–3577. https://doi.org/10.1113/jphysiol.2012.247254
Bogaerts E, Paridaens A, Verhelst X, Carmeliet P, Geerts A, Van Vlierberghe H, Devisscher L (2016) Effect of prolyl hydroxylase domain 2 haplodeficiency on liver progenitor cell characteristics in early mouse hepatocarcinogenesis. EXCLI J 15:687–698. https://doi.org/10.17179/excli2016-607
Broeker KAE, Fuchs MAA, Schrankl J, Lehrmann C, Schley G, Todorov VT, Hugo C, Wagner C, Kurtz A (2022) Prolyl-4-hydroxylases 2 and 3 control erythropoietin production in renin-expressing cells of mouse kidneys. J Physiol 600:671–694. https://doi.org/10.1113/JP282615
Bruick RK, McKnight SL (2001) A conserved family of prolyl-4-hydroxylases that modify HIF. Science 294:1337–1340. https://doi.org/10.1126/science.1066373
Chan DA, Sutphin PD, Yen SE, Giaccia AJ (2005) Coordinate regulation of the oxygen-dependent degradation domains of hypoxia-inducible factor 1 alpha. Mol Cell Biol 25:6415–6426. https://doi.org/10.1128/MCB.25.15.6415-6426.2005
Chen RL, Nagel S, Papadakis M, Bishop T, Pollard P, Ratcliffe PJ, Pugh CW, Buchan AM (2012) Roles of individual prolyl-4-hydroxylase isoforms in the first 24 hours following transient focal cerebral ischaemia: insights from genetically modified mice. J Physiol 590:4079–4091. https://doi.org/10.1113/jphysiol.2012.232884
Chen T, Zhou Q, Tang H, Bozkanat M, Yuan JX, Raj JU, Zhou G (2016) miR-17/20 controls prolyl hydroxylase 2 (PHD2)/hypoxia-inducible factor 1 (HIF1) to regulate pulmonary artery smooth muscle cell proliferation. J Am Heart Assoc 5. https://doi.org/10.1161/JAHA.116.004510
Chen Y, Zhang HS, Fong GH, Xi QL, Wu GH, Bai CG, Ling ZQ, Fan L, Xu YM, Qin YQ, Yuan TL, Sun H, Fang J (2015) PHD3 stabilizes the tight junction protein occludin and protects intestinal epithelial barrier function. J Biol Chem 290:20580–20589. https://doi.org/10.1074/jbc.M115.653584
Cheng S, Aghajanian P, Pourteymoor S, Alarcon C, Mohan S (2016) Prolyl hydroxylase domain-containing protein 2 (Phd2) regulates chondrocyte differentiation and secondary ossification in mice. Sci Rep 6:35748. https://doi.org/10.1038/srep35748
Cheng S, Pourteymoor S, Alarcon C, Mohan S (2017) Conditional deletion of the Phd2 gene in articular chondrocytes accelerates differentiation and reduces articular cartilage thickness. Sci Rep 7:45408. https://doi.org/10.1038/srep45408
Cheng S, Xing W, Pourteymoor S, Mohan S (2014) Conditional disruption of the prolyl hydroxylase domain-containing protein 2 (Phd2) gene defines its key role in skeletal development. J Bone Miner Res 29:2276–2286. https://doi.org/10.1002/jbmr.2258
Cheng S, Xing W, Pourteymoor S, Schulte J, Mohan S (2016) Conditional deletion of prolyl hydroxylase domain-containing protein 2 (Phd2) gene reveals its essential role in chondrocyte function and endochondral bone formation. Endocrinology 157:127–140. https://doi.org/10.1210/en.2015-1473
Christoph M, Pfluecke C, Mensch M, Augstein A, Jellinghaus S, Ende G, Mierke J, Franke K, Wielockx B, Ibrahim K, Poitz DM (2022) Myeloid PHD2 deficiency accelerates neointima formation via Hif-1alpha. Mol Immunol 149:48–58. https://doi.org/10.1016/j.molimm.2022.06.003
Cockman ME, Lippl K, Tian YM, Pegg HB, Figg WDJ, Abboud MI, Heilig R, Fischer R, Myllyharju J, Schofield CJ, Ratcliffe PJ (2019) Lack of activity of recombinant HIF prolyl hydroxylases (PHDs) on reported non-HIF substrates. Elife 8. https://doi.org/10.7554/eLife.46490
Corcoran A, Kunze R, Harney SC, Breier G, Marti HH, O’Connor JJ (2013) A role for prolyl hydroxylase domain proteins in hippocampal synaptic plasticity. Hippocampus 23:861–872. https://doi.org/10.1002/hipo.22142
Cutz E, Yeger H, Pan J (2007) Pulmonary neuroendocrine cell system in pediatric lung disease-recent advances. Pediatr Dev Pathol 10:419–435. https://doi.org/10.2350/07-04-0267.1
Dahl SL, Bapst AM, Khodo SN, Scholz CC, Wenger RH (2022) Fount, fate, features, and function of renal erythropoietin-producing cells. Pflugers Arch 474:783–797. https://doi.org/10.1007/s00424-022-02714-7
Dai Z, Cheng J, Liu B, Yi D, Feng A, Wang T, An L, Gao C, Wang Y, Zhu MM, Zhang X, Zhao YY (2021) Loss of endothelial hypoxia inducible factor-prolyl hydroxylase 2 induces cardiac hypertrophy and fibrosis. J Am Heart Assoc 10:e022077. https://doi.org/10.1161/JAHA.121.022077
Dai Z, Li M, Wharton J, Zhu MM, Zhao YY (2016) Prolyl-4 hydroxylase 2 (PHD2) deficiency in endothelial cells and hematopoietic cells induces obliterative vascular remodeling and severe pulmonary arterial hypertension in mice and humans through hypoxia-inducible factor-2alpha. Circulation 133:2447–2458. https://doi.org/10.1161/CIRCULATIONAHA.116.021494
De Galan C, De Vos M, Hindryckx P, Laukens D, Van Welden S (2021) Long-term environmental hypoxia exposure and haematopoietic prolyl hydroxylase-1 deletion do not impact experimental Crohn’s like ileitis. Biology (Basel) 10. https://doi.org/10.3390/biology10090887
Demandt JAF, van Kuijk K, Theelen TL, Marsch E, Heffron SP, Fisher EA, Carmeliet P, Biessen EAL, Sluimer JC (2021) Whole-body prolyl hydroxylase domain (PHD) 3 deficiency increased plasma lipids and hematocrit without impacting plaque size in low-density lipoprotein receptor knockout mice. Front Cell Dev Biol 9:664258. https://doi.org/10.3389/fcell.2021.664258
Duan LJ, Fong GH (2019) Developmental vascular pruning in neonatal mouse retinas is programmed by the astrocytic oxygen-sensing mechanism. Development 146. https://doi.org/10.1242/dev.175117
Duan LJ, Takeda K, Fong GH (2011) Prolyl hydroxylase domain protein 2 (PHD2) mediates oxygen-induced retinopathy in neonatal mice. Am J Pathol 178:1881–1890. https://doi.org/10.1016/j.ajpath.2010.12.016
Duan LJ, Takeda K, Fong GH (2014) Hematological, hepatic, and retinal phenotypes in mice deficient for prolyl hydroxylase domain proteins in the liver. Am J Pathol 184:1240–1250. https://doi.org/10.1016/j.ajpath.2013.12.014
Eckardt L, Prange-Barczynska M, Hodson EJ, Fielding JW, Cheng X, Lima J, Kurlekar S, Douglas G, Ratcliffe PJ, Bishop T (2021) Developmental role of PHD2 in the pathogenesis of pseudohypoxic pheochromocytoma. Endocr Relat Cancer 28:757–772. https://doi.org/10.1530/ERC-21-0211
Eckle T, Kohler D, Lehmann R, El Kasmi K, Eltzschig HK (2008) Hypoxia-inducible factor-1 is central to cardioprotection: a new paradigm for ischemic preconditioning. Circulation 118:166–175. https://doi.org/10.1161/CIRCULATIONAHA.107.758516
Elamaa H, Kaakinen M, Natynki M, Szabo Z, Ronkainen VP, Aijala V, Maki JM, Kerkela R, Myllyharju J, Eklund L (2022) PHD2 deletion in endothelial or arterial smooth muscle cells reveals vascular cell type-specific responses in pulmonary hypertension and fibrosis. Angiogenesis 25:259–274. https://doi.org/10.1007/s10456-021-09828-z
Epstein AC, Gleadle JM, McNeill LA, Hewitson KS, O’Rourke J, Mole DR, Mukherji M, Metzen E, Wilson MI, Dhanda A, Tian YM, Masson N, Hamilton DL, Jaakkola P, Barstead R, Hodgkin J, Maxwell PH, Pugh CW, Schofield CJ, Ratcliffe PJ (2001) C. elegans EGL-9 and mammalian homologs define a family of dioxygenases that regulate HIF by prolyl hydroxylation. Cell 107:43–54. https://doi.org/10.1016/s0092-8674(01)00507-4
Faivre A, Scholz CC, de Seigneux S (2021) Hypoxia in chronic kidney disease: towards a paradigm shift? Nephrol Dial Transplant 36:1782–1790. https://doi.org/10.1093/ndt/gfaa091
Fan Q, Mao H, Xie L, Pi X (2019) Prolyl hydroxylase domain-2 protein regulates lipopolysaccharide-induced vascular inflammation. Am J Pathol 189:200–213. https://doi.org/10.1016/j.ajpath.2018.09.012
Fandrey J, Schodel J, Eckardt KU, Katschinski DM, Wenger RH (2019) Now a Nobel gas: oxygen. Pflugers Arch 471:1343–1358. https://doi.org/10.1007/s00424-019-02334-8
Fielding JW, Hodson EJ, Cheng X, Ferguson DJP, Eckardt L, Adam J, Lip P, Maton-Howarth M, Ratnayaka I, Pugh CW, Buckler KJ, Ratcliffe PJ, Bishop T (2018) PHD2 inactivation in Type I cells drives HIF-2alpha-dependent multilineage hyperplasia and the formation of paraganglioma-like carotid bodies. J Physiol 596:4393–4412. https://doi.org/10.1113/JP275996
Franke K, Kalucka J, Mamlouk S, Singh RP, Muschter A, Weidemann A, Iyengar V, Jahn S, Wieczorek K, Geiger K, Muders M, Sykes AM, Poitz DM, Ripich T, Otto T, Bergmann S, Breier G, Baretton G, Fong GH, Greaves DR, Bornstein S, Chavakis T, Fandrey J, Gassmann M, Wielockx B (2013) HIF-1alpha is a protective factor in conditional PHD2-deficient mice suffering from severe HIF-2alpha-induced excessive erythropoiesis. Blood 121:1436–1445. https://doi.org/10.1182/blood-2012-08-449181
Futatsugi K, Tokuyama H, Shibata S, Naitoh M, Kanda T, Minakuchi H, Yamaguchi S, Hayashi K, Minamishima YA, Yanagita M, Wakino S, Itoh H (2016) Obesity-induced kidney injury is attenuated by amelioration of aberrant PHD2 activation in proximal tubules. Sci Rep 6:36533. https://doi.org/10.1038/srep36533
Gaete D, Rodriguez D, Watts D, Sormendi S, Chavakis T, Wielockx B (2021) HIF-prolyl hydroxylase domain proteins (PHDs) in cancer-potential targets for anti-tumor therapy? Cancers (Basel) 13. https://doi.org/10.3390/cancers13050988
Grover SP, Saha P, Humphries J, Lyons OT, Patel AS, Serneels J, Modarai B, Mazzone M, Smith A (2018) Inhibition of prolyl hydroxylase domain proteins selectively enhances venous thrombus neovascularisation. Thromb Res 169:105–112. https://doi.org/10.1016/j.thromres.2018.07.015
Gruneberg D, Montellano FA, Plaschke K, Li L, Marti HH, Kunze R (2016) Neuronal prolyl-4-hydroxylase 2 deficiency improves cognitive abilities in a murine model of cerebral hypoperfusion. Exp Neurol 286:93–106. https://doi.org/10.1016/j.expneurol.2016.10.001
Guentsch A, Beneke A, Swain L, Farhat K, Nagarajan S, Wielockx B, Raithatha K, Dudek J, Rehling P, Zieseniss A, Jatho A, Chong M, Santos CXC, Shah AM, Katschinski DM (2017) PHD2 is a regulator for glycolytic reprogramming in macrophages. Mol Cell Biol 37. https://doi.org/10.1128/MCB.00236-16
Gunter J, Ruiz-Serrano A, Pickel C, Wenger RH, Scholz CC (2017) The functional interplay between the HIF pathway and the ubiquitin system - more than a one-way road. Exp Cell Res 356:152–159. https://doi.org/10.1016/j.yexcr.2017.03.027
Haase VH (2010) Hypoxic regulation of erythropoiesis and iron metabolism. Am J Physiol Renal Physiol 299:F1-13. https://doi.org/10.1152/ajprenal.00174.2010
Heindryckx F, Kuchnio A, Casteleyn C, Coulon S, Olievier K, Colle I, Geerts A, Libbrecht L, Carmeliet P, Van Vlierberghe H (2012) Effect of prolyl hydroxylase domain-2 haplodeficiency on the hepatocarcinogenesis in mice. J Hepatol 57:61–68. https://doi.org/10.1016/j.jhep.2012.02.021
Hirsila M, Koivunen P, Gunzler V, Kivirikko KI, Myllyharju J (2003) Characterization of the human prolyl 4-hydroxylases that modify the hypoxia-inducible factor. J Biol Chem 278:30772–30780. https://doi.org/10.1074/jbc.M304982200
Hoang M, Jentz E, Janssen SM, Nasteska D, Cuozzo F, Hodson DJ, Tupling AR, Fong GH, Joseph JW (2022) Isoform-specific roles of prolyl hydroxylases in the regulation of pancreatic beta-cell function. Endocrinology 163. https://doi.org/10.1210/endocr/bqab226
Hodson EJ, Nicholls LG, Turner PJ, Llyr R, Fielding JW, Douglas G, Ratnayaka I, Robbins PA, Pugh CW, Buckler KJ, Ratcliffe PJ, Bishop T (2016) Regulation of ventilatory sensitivity and carotid body proliferation in hypoxia by the PHD2/HIF-2 pathway. J Physiol 594:1179–1195. https://doi.org/10.1113/JP271050
Holscher M, Silter M, Krull S, von Ahlen M, Hesse A, Schwartz P, Wielockx B, Breier G, Katschinski DM, Zieseniss A (2011) Cardiomyocyte-specific prolyl-4-hydroxylase domain 2 knock out protects from acute myocardial ischemic injury. J Biol Chem 286:11185–11194. https://doi.org/10.1074/jbc.M110.186809
Huang M, Chan DA, Jia F, Xie X, Li Z, Hoyt G, Robbins RC, Chen X, Giaccia AJ, Wu JC (2008) Short hairpin RNA interference therapy for ischemic heart disease. Circulation 118:S226-233. https://doi.org/10.1161/CIRCULATIONAHA.107.760785
Hulley PA, Bishop T, Vernet A, Schneider JE, Edwards JR, Athanasou NA, Knowles HJ (2017) Hypoxia-inducible factor 1-alpha does not regulate osteoclastogenesis but enhances bone resorption activity via prolyl-4-hydroxylase 2. J Pathol 242:322–333. https://doi.org/10.1002/path.4906
Hyvärinen J, Hassinen IE, Sormunen R, Mäki JM, Kivirikko KI, Koivunen P, Myllyharju J (2010) Hearts of hypoxia-inducible factor prolyl 4-hydroxylase-2 hypomorphic mice show protection against acute ischemia-reperfusion injury. J Biol Chem 285:13646–13657. https://doi.org/10.1074/jbc.M109.084855
Ikeda J, Ichiki T, Matsuura H, Inoue E, Kishimoto J, Watanabe A, Sankoda C, Kitamoto S, Tokunou T, Takeda K, Fong GH, Sunagawa K (2013) Deletion of phd2 in myeloid lineage attenuates hypertensive cardiovascular remodeling. J Am Heart Assoc 2:e000178. https://doi.org/10.1161/JAHA.113.000178
Ivan M, Haberberger T, Gervasi DC, Michelson KS, Gunzler V, Kondo K, Yang H, Sorokina I, Conaway RC, Conaway JW, Kaelin WG Jr (2002) Biochemical purification and pharmacological inhibition of a mammalian prolyl hydroxylase acting on hypoxia-inducible factor. Proc Natl Acad Sci U S A 99:13459–13464. https://doi.org/10.1073/pnas.192342099
Ivan M, Kondo K, Yang H, Kim W, Valiando J, Ohh M, Salic A, Asara JM, Lane WS, Kaelin WG Jr (2001) HIFalpha targeted for VHL-mediated destruction by proline hydroxylation: implications for O2 sensing. Science 292:464–468. https://doi.org/10.1126/science.1059817
Jaakkola P, Mole DR, Tian YM, Wilson MI, Gielbert J, Gaskell SJ, von Kriegsheim A, Hebestreit HF, Mukherji M, Schofield CJ, Maxwell PH, Pugh CW, Ratcliffe PJ (2001) Targeting of HIF-alpha to the von Hippel-Lindau ubiquitylation complex by O2-regulated prolyl hydroxylation. Science 292:468–472. https://doi.org/10.1126/science.1059796
Jatho A, Zieseniss A, Brechtel-Curth K, Yamamoto A, Coleman ML, Vergel Leon AM, Biggs D, Davies B, Pugh CW, Ratcliffe PJ, Katschinski DM (2021) Precisely tuned inhibition of HIF prolyl hydroxylases is key for cardioprotection after ischemia. Circ Res 128:1208–1210. https://doi.org/10.1161/CIRCRESAHA.120.318216
Jin Y, Pan Y, Zheng S, Liu Y, Xu J, Peng Y, Zhang Z, Wang Y, Xiong Y, Xu L, Mu K, Chen S, Zheng F, Yuan Y, Fu J (2022) Inactivation of EGLN3 hydroxylase facilitates Erk3 degradation via autophagy and impedes lung cancer growth. Oncogene 41:1752–1766. https://doi.org/10.1038/s41388-022-02203-2
Kaelin WG Jr, Ratcliffe PJ (2008) Oxygen sensing by metazoans: the central role of the HIF hydroxylase pathway. Mol Cell 30:393–402. https://doi.org/10.1016/j.molcel.2008.04.009
Kalucka J, Ettinger A, Franke K, Mamlouk S, Singh RP, Farhat K, Muschter A, Olbrich S, Breier G, Katschinski DM, Huttner W, Weidemann A, Wielockx B (2013) Loss of epithelial hypoxia-inducible factor prolyl hydroxylase 2 accelerates skin wound healing in mice. Mol Cell Biol 33:3426–3438. https://doi.org/10.1128/MCB.00609-13
Kapitsinou PP, Rajendran G, Astleford L, Michael M, Schonfeld MP, Fields T, Shay S, French JL, West J, Haase VH (2016) The endothelial prolyl-4-hydroxylase domain 2/hypoxia-inducible factor 2 axis regulates pulmonary artery pressure in mice. Mol Cell Biol 36:1584–1594. https://doi.org/10.1128/MCB.01055-15
Karsikas S, Myllymäki M, Heikkilä M, Sormunen R, Kivirikko KI, Myllyharju J, Serpi R, Koivunen P (2016) HIF-P4H-2 deficiency protects against skeletal muscle ischemia-reperfusion injury. J Mol Med (Berl) 94:301–310. https://doi.org/10.1007/s00109-015-1349-0
Kennel KB, Burmeister J, Radhakrishnan P, Giese NA, Giese T, Salfenmoser M, Gebhardt JM, Strowitzki MJ, Taylor CT, Wielockx B, Schneider M, Harnoss JM (2022) The HIF-prolyl hydroxylases have distinct and nonredundant roles in colitis-associated cancer. JCI Insight 7. https://doi.org/10.1172/jci.insight.153337
Kerkelä R, Karsikas S, Szabo Z, Serpi R, Magga J, Gao E, Alitalo K, Anisimov A, Sormunen R, Pietila I, Vainio L, Koch WJ, Kivirikko KI, Myllyharju J, Koivunen P (2013) Activation of hypoxia response in endothelial cells contributes to ischemic cardioprotection. Mol Cell Biol 33:3321–3329. https://doi.org/10.1128/MCB.00432-13
Kiss J, Mollenhauer M, Walmsley SR, Kirchberg J, Radhakrishnan P, Niemietz T, Dudda J, Steinert G, Whyte MK, Carmeliet P, Mazzone M, Weitz J, Schneider M (2012) Loss of the oxygen sensor PHD3 enhances the innate immune response to abdominal sepsis. J Immunol (Baltimore, Md : 1950) 189:1955–1965. https://doi.org/10.4049/jimmunol.1103471
Ko SH, Nauta AC, Morrison SD, Hu MS, Zimmermann AS, Chung MT, Glotzbach JP, Wong VW, Walmsley GG, Peter Lorenz H, Chan DA, Gurtner GC, Giaccia AJ, Longaker MT (2018) PHD-2 suppression in mesenchymal stromal cells enhances wound healing. Plast Reconstr Surg 141:55e–67e. https://doi.org/10.1097/PRS.0000000000003959
Kobayashi H, Davidoff O, Pujari-Palmer S, Drevin M, Haase VH (2022) EPO synthesis induced by HIF-PHD inhibition is dependent on myofibroblast transdifferentiation and colocalizes with non-injured nephron segments in murine kidney fibrosis. Acta Physiol (Oxf) 235:e13826. https://doi.org/10.1111/apha.13826
Kobayashi H, Liu J, Urrutia AA, Burmakin M, Ishii K, Rajan M, Davidoff O, Saifudeen Z, Haase VH (2017) Hypoxia-inducible factor prolyl-4-hydroxylation in FOXD1 lineage cells is essential for normal kidney development. Kidney Int 92:1370–1383. https://doi.org/10.1016/j.kint.2017.06.015
Kobayashi H, Liu Q, Binns TC, Urrutia AA, Davidoff O, Kapitsinou PP, Pfaff AS, Olauson H, Wernerson A, Fogo AB, Fong GH, Gross KW, Haase VH (2016) Distinct subpopulations of FOXD1 stroma-derived cells regulate renal erythropoietin. J Clin Invest 126:1926–1938. https://doi.org/10.1172/JCI83551
Ku E, Del Vecchio L, Eckardt KU, Haase VH, Johansen KL, Nangaku M, Tangri N, Waikar SS, Wiecek A, Cheung M, Jadoul M, Winkelmayer WC, Wheeler DC, for Conference P (2023) Novel anemia therapies in chronic kidney disease: conclusions from a Kidney Disease: Improving Global Outcomes (KDIGO) Controversies Conference. Kidney Int 104:655–680. https://doi.org/10.1016/j.kint.2023.05.009
Kuchnio A, Dewerchin M, Carmeliet P (2015) The PHD2 oxygen sensor paves the way to metastasis. Oncotarget 6:35149–35150. https://doi.org/10.18632/oncotarget.6216
Kuchnio A, Moens S, Bruning U, Kuchnio K, Cruys B, Thienpont B, Broux M, Ungureanu AA, Leite de Oliveira R, Bruyere F, Cuervo H, Manderveld A, Carton A, Hernandez-Fernaud JR, Zanivan S, Bartic C, Foidart JM, Noel A, Vinckier S, Lambrechts D, Dewerchin M, Mazzone M, Carmeliet P (2015) The cancer cell oxygen sensor PHD2 promotes metastasis via activation of cancer-associated fibroblasts. Cell Rep 12:992–1005. https://doi.org/10.1016/j.celrep.2015.07.010
Kunze R, Zhou W, Veltkamp R, Wielockx B, Breier G, Marti HH (2012) Neuron-specific prolyl-4-hydroxylase domain 2 knockout reduces brain injury after transient cerebral ischemia. Stroke 43:2748–2756. https://doi.org/10.1161/STROKEAHA.112.669598
Laitakari A, Huttunen R, Kuvaja P, Hannuksela P, Szabo Z, Heikkilä M, Kerkelä R, Myllyharju J, Dimova EY, Serpi R, Koivunen P (2020) Systemic long-term inactivation of hypoxia-inducible factor prolyl 4-hydroxylase 2 ameliorates aging-induced changes in mice without affecting their life span. Faseb j 34:5590–5609. https://doi.org/10.1096/fj.201902331R
Laitakari A, Ollonen T, Kietzmann T, Walkinshaw G, Mennerich D, Izzi V, Haapasaari KM, Myllyharju J, Serpi R, Dimova EY, Koivunen P (2019) Systemic inactivation of hypoxia-inducible factor prolyl 4-hydroxylase 2 in mice protects from alcohol-induced fatty liver disease. Redox Biol 22:101145. https://doi.org/10.1016/j.redox.2019.101145
Lee FS (2019) Substrates of PHD. Cell Metab 30:626–627. https://doi.org/10.1016/j.cmet.2019.08.008
Leite de Oliveira R, Deschoemaeker S, Henze AT, Debackere K, Finisguerra V, Takeda Y, Roncal C, Dettori D, Tack E, Jonsson Y, Veschini L, Peeters A, Anisimov A, Hofmann M, Alitalo K, Baes M, D’Hooge J, Carmeliet P, Mazzone M (2012) Gene-targeting of Phd2 improves tumor response to chemotherapy and prevents side-toxicity. Cancer Cell 22:263–277. https://doi.org/10.1016/j.ccr.2012.06.028
Li F, Yin C, Ma Z, Yang K, Sun L, Duan C, Wang T, Hussein A, Wang L, Zhu X, Gao P, Xi Q, Zhang Y, Shu G, Wang S, Jiang Q (2021) PHD3 mediates denervation skeletal muscle atrophy through Nf-kappaB signal pathway. FASEB J 35:e21444. https://doi.org/10.1096/fj.202002049R
Li F, Zhang F, Yi X, Quan LL, Yang X, Yin C, Ma Z, Wu R, Zhao W, Ling M, Lang L, Hussein A, Feng S, Fu Y, Wang J, Liang S, Zhu C, Wang L, Zhu X, Gao P, Xi Q, Zhang Y, Zhang L, Shu G, Jiang Q, Wang S (2023) Proline hydroxylase 2 (PHD2) promotes brown adipose thermogenesis by enhancing the hydroxylation of UCP1. Mol Metab 73:101747. https://doi.org/10.1016/j.molmet.2023.101747
Li L, Saliba P, Reischl S, Marti HH, Kunze R (2016) Neuronal deficiency of HIF prolyl 4-hydroxylase 2 in mice improves ischemic stroke recovery in an HIF dependent manner. Neurobiol Dis 91:221–235. https://doi.org/10.1016/j.nbd.2016.03.018
Li S, Fu J, Wang Y, Hu C, Xu F (2021) LncRNA MIAT enhances cerebral ischaemia/reperfusion injury in rat model via interacting with EGLN2 and reduces its ubiquitin-mediated degradation. J Cell Mol Med 25:10140–10151. https://doi.org/10.1111/jcmm.16950
Li X, Sutherland S, Takeda K, Fong GH, Lee FS (2010) Integrity of the prolyl hydroxylase domain protein 2:erythropoietin pathway in aging mice. Blood Cells Mol Dis 45:9–19. https://doi.org/10.1016/j.bcmd.2010.03.003
Lieb ME, Menzies K, Moschella MC, Ni R, Taubman MB (2002) Mammalian EGLN genes have distinct patterns of mRNA expression and regulation. Biochem Cell Biol 80:421–426. https://doi.org/10.1139/o02-115
Lisy K, Peet DJ (2008) Turn me on: regulating HIF transcriptional activity. Cell Death Differ 15:642–649. https://doi.org/10.1038/sj.cdd.4402315
Liu B, Yi D, Pan J, Dai J, Zhu MM, Zhao YY, Oh SP, Fallon MB, Dai Z (2022) Suppression of BMP signaling by PHD2 deficiency in pulmonary arterial hypertension. Pulm Circ 12:e12056. https://doi.org/10.1002/pul2.12056
Liu H, Xia Y, Li B, Pan J, Lv M, Wang X, An F (2016) Prolyl hydroxylase 3 overexpression accelerates the progression of atherosclerosis in ApoE-/- mice. Biochem Biophys Res Commun 473:99–106. https://doi.org/10.1016/j.bbrc.2016.03.058
Liu J, Li W, Limbu MH, Li Y, Wang Z, Cheng Z, Zhang X, Chen P (2018) Effects of simultaneous downregulation of PHD1 and Keap1 on prevention and reversal of liver fibrosis in mice. Front Pharmacol 9:555. https://doi.org/10.3389/fphar.2018.00555
Liu S, Zhang G, Guo J, Chen X, Lei J, Ze K, Dong L, Dai X, Gao Y, Song D, Ecker BL, Yang R, Feltcher C, Peng K, Feng C, Chen H, Lee RX, Kerestes H, Niu J, Kumar S, Xu W, Zhang J, Wei Z, Martin JS, Liu X, Mills G, Lu Y, Guo W, Sun L, Zhang L, Weeraratna A, Herlyn M, Wei W, Lee FS, Xu X (2018) Loss of Phd2 cooperates with BRAF(V600E) to drive melanomagenesis. Nat Commun 9:5426. https://doi.org/10.1038/s41467-018-07126-9
Livermore S, Pan J, Yeger H, Ratcliffe P, Bishop T, Cutz E (2015) Augmented 5-HT secretion in pulmonary neuroepithelial bodies from PHD1 null mice. Adv Exp Med Biol 860:309–313. https://doi.org/10.1007/978-3-319-18440-1_35
Loinard C, Ginouves A, Vilar J, Cochain C, Zouggari Y, Recalde A, Duriez M, Levy BI, Pouyssegur J, Berra E, Silvestre JS (2009) Inhibition of prolyl hydroxylase domain proteins promotes therapeutic revascularization. Circulation 120:50–59. https://doi.org/10.1161/CIRCULATIONAHA.108.813303
Luo B, Xiang D, Wu D, Liu C, Fang Y, Chen P, Hu YP (2018) Hepatic PHD2/HIF-1alpha axis is involved in postexercise systemic energy homeostasis. FASEB J 32:4670–4680. https://doi.org/10.1096/fj.201701139R
Mamlouk S, Kalucka J, Singh RP, Franke K, Muschter A, Langer A, Jakob C, Gassmann M, Baretton GB, Wielockx B (2014) Loss of prolyl hydroxylase-2 in myeloid cells and T-lymphocytes impairs tumor development. Int J Cancer 134:849–858. https://doi.org/10.1002/ijc.28409
Marsch E, Demandt JA, Theelen TL, Tullemans BM, Wouters K, Boon MR, van Dijk TH, Gijbels MJ, Dubois LJ, Meex SJ, Mazzone M, Hung G, Fisher EA, Biessen EA, Daemen MJ, Rensen PC, Carmeliet P, Groen AK, Sluimer JC (2016) Deficiency of the oxygen sensor prolyl hydroxylase 1 attenuates hypercholesterolaemia, atherosclerosis, and hyperglycaemia. Eur Heart J 37:2993–2997. https://doi.org/10.1093/eurheartj/ehw156
Marxsen JH, Stengel P, Doege K, Heikkinen P, Jokilehto T, Wagner T, Jelkmann W, Jaakkola P, Metzen E (2004) Hypoxia-inducible factor-1 (HIF-1) promotes its degradation by induction of HIF-alpha-prolyl-4-hydroxylases. Biochem J 381:761–767. https://doi.org/10.1042/BJ20040620
Matsuura H, Ichiki T, Inoue E, Nomura M, Miyazaki R, Hashimoto T, Ikeda J, Takayanagi R, Fong GH, Sunagawa K (2013) Prolyl hydroxylase domain protein 2 plays a critical role in diet-induced obesity and glucose intolerance. Circulation 127:2078–2087. https://doi.org/10.1161/CIRCULATIONAHA.113.001742
Mazzone M, Dettori D, de Oliveira RL, Loges S, Schmidt T, Jonckx B, Tian YM, Lanahan AA, Pollard P, de Almodovar CR, De Smet F, Vinckier S, Aragones J, Debackere K, Luttun A, Wyns S, Jordan B, Pisacane A, Gallez B, Lampugnani MG, Dejana E, Simons M, Ratcliffe P, Maxwell P, Carmeliet P (2009) Heterozygous deficiency of PHD2 restores tumor oxygenation and inhibits metastasis via endothelial normalization. Cell 136:839–851. https://doi.org/10.1016/j.cell.2009.01.020
Miao M, Wu M, Li Y, Zhang L, Jin Q, Fan J, Xu X, Gu R, Hao H, Zhang A, Jia Z (2022) Clinical potential of hypoxia inducible factors prolyl hydroxylase inhibitors in treating nonanemic diseases. Front Pharmacol 13:837249. https://doi.org/10.3389/fphar.2022.837249
Michailidou Z, Morton NM, Moreno Navarrete JM, West CC, Stewart KJ, Fernandez-Real JM, Schofield CJ, Seckl JR, Ratcliffe PJ (2015) Adipocyte pseudohypoxia suppresses lipolysis and facilitates benign adipose tissue expansion. Diabetes 64:733–745. https://doi.org/10.2337/db14-0233
Minamishima YA, Kaelin WG Jr (2010) Reactivation of hepatic EPO synthesis in mice after PHD loss. Science 329:407. https://doi.org/10.1126/science.1192811
Minamishima YA, Moslehi J, Bardeesy N, Cullen D, Bronson RT, Kaelin WG Jr (2008) Somatic inactivation of the PHD2 prolyl hydroxylase causes polycythemia and congestive heart failure. Blood 111:3236–3244. https://doi.org/10.1182/blood-2007-10-117812
Minamishima YA, Moslehi J, Padera RF, Bronson RT, Liao R, Kaelin WG Jr (2009) A feedback loop involving the Phd3 prolyl hydroxylase tunes the mammalian hypoxic response in vivo. Mol Cell Biol 29:5729–5741. https://doi.org/10.1128/MCB.00331-09
Missiaen R, Lesner NP, Simon MC (2023) HIF: a master regulator of nutrient availability and metabolic cross-talk in the tumor microenvironment. EMBO J 42:e112067. https://doi.org/10.15252/embj.2022112067
Mollenhauer M, Kiss J, Dudda J, Kirchberg J, Rahbari N, Radhakrishnan P, Niemietz T, Rausch V, Weitz J, Schneider M (2012) Deficiency of the oxygen sensor PHD1 augments liver regeneration after partial hepatectomy. Langenbeck’s Arch Surg 397:1313–1322. https://doi.org/10.1007/s00423-012-0998-5
Moslehi J, Minamishima YA, Shi J, Neuberg D, Charytan DM, Padera RF, Signoretti S, Liao R, Kaelin WG Jr (2010) Loss of hypoxia-inducible factor prolyl hydroxylase activity in cardiomyocytes phenocopies ischemic cardiomyopathy. Circulation 122:1004–1016. https://doi.org/10.1161/CIRCULATIONAHA.109.922427
Nasteska D, Cuozzo F, Viloria K, Johnson EM, Thakker A, Bany Bakar R, Westbrook RL, Barlow JP, Hoang M, Joseph JW, Lavery GG, Akerman I, Cantley J, Hodson L, Tennant DA, Hodson DJ (2021) Prolyl-4-hydroxylase 3 maintains beta cell glucose metabolism during fatty acid excess in mice. JCI Insight 6. https://doi.org/10.1172/jci.insight.140288
Natarajan R, Salloum FN, Fisher BJ, Kukreja RC, Fowler AA 3rd (2006) Hypoxia inducible factor-1 activation by prolyl 4-hydroxylase-2 gene silencing attenuates myocardial ischemia reperfusion injury. Circ Res 98:133–140. https://doi.org/10.1161/01.RES.0000197816.63513.27
Natarajan R, Salloum FN, Fisher BJ, Ownby ED, Kukreja RC, Fowler AA 3rd (2007) Activation of hypoxia-inducible factor-1 via prolyl-4 hydoxylase-2 gene silencing attenuates acute inflammatory responses in postischemic myocardium. Am J Physiol Heart Circ Physiol 293:H1571-1580. https://doi.org/10.1152/ajpheart.00291.2007
Noonan ML, Ni P, Solis E, Marambio YG, Agoro R, Chu X, Wang Y, Gao H, Xuei X, Clinkenbeard EL, Jiang G, Liu S, Stegen S, Carmeliet G, Thompson WR, Liu Y, Wan J, White KE (2023) Osteocyte Egln1/Phd2 links oxygen sensing and biomineralization via FGF23. Bone Res 11:7. https://doi.org/10.1038/s41413-022-00241-w
Nunomiya A, Shin J, Kitajima Y, Dan T, Miyata T, Nagatomi R (2017) Activation of the hypoxia-inducible factor pathway induced by prolyl hydroxylase domain 2 deficiency enhances the effect of running training in mice. Acta Physiol (Oxf) 220:99–112. https://doi.org/10.1111/apha.12751
Oriowo B, Thirunavukkarasu M, Selvaraju V, Adluri RS, Zhan L, Takeda K, Fong GH, Sanchez JA, Maulik N (2014) Targeted gene deletion of prolyl hydroxylase domain protein 3 triggers angiogenesis and preserves cardiac function by stabilizing hypoxia inducible factor 1 alpha following myocardial infarction. Curr Pharm Des 20:1305–1310. https://doi.org/10.2174/13816128113199990549
Ozolins TR, Fisher TS, Nadeau DM, Stock JL, Klein AS, Milici AJ, Morton D, Wilhelms MB, Brissette WH, Li B (2009) Defects in embryonic development of EGLN1/PHD2 knockdown transgenic mice are associated with induction of Igfbp in the placenta. Biochem Biophys Res Commun 390:372–376. https://doi.org/10.1016/j.bbrc.2009.08.057
Pan J, Bishop T, Ratcliffe PJ, Yeger H, Cutz E (2016) Hyperplasia and hypertrophy of pulmonary neuroepithelial bodies, presumed airway hypoxia sensors, in hypoxia-inducible factor prolyl hydroxylase-deficient mice. Hypoxia (Auckl) 4:69–80. https://doi.org/10.2147/HP.S103957
Pan J, Yeger H, Ratcliffe P, Bishop T, Cutz E (2012) Hyperplasia of pulmonary neuroepithelial bodies (NEB) in lungs of prolyl hydroxylase -1(PHD-1) deficient mice. Adv Exp Med Biol 758:149–155. https://doi.org/10.1007/978-94-007-4584-1_21
Peng Y, Dai J, Zhao YY (2023) Egln1(Tie2Cre) mice exhibit similar therapeutic responses to sildenafil, ambrisentan, and treprostinil as pulmonary arterial hypertension (PAH) patients, supporting Egln1(Tie2Cre) mice as a useful PAH model. Int J Mol Sci 24. https://doi.org/10.3390/ijms24032391
Pradeep SR, Lim ST, Thirunavukkarasu M, Joshi M, Cernuda B, Palesty JA, Maulik N (2022) Protective effect of cardiomyocyte-specific prolyl-4-hydroxylase 2 inhibition on ischemic injury in a mouse MI model. J Am Coll Surg 235:240–254. https://doi.org/10.1097/XCS.0000000000000241
Quaegebeur A, Segura I, Schmieder R, Verdegem D, Decimo I, Bifari F, Dresselaers T, Eelen G, Ghosh D, Davidson SM, Schoors S, Broekaert D, Cruys B, Govaerts K, De Legher C, Bouche A, Schoonjans L, Ramer MS, Hung G, Bossaert G, Cleveland DW, Himmelreich U, Voets T, Lemmens R, Bennett CF, Robberecht W, De Bock K, Dewerchin M, Ghesquiere B, Fendt SM, Carmeliet P (2016) Deletion or inhibition of the oxygen sensor PHD1 protects against ischemic stroke via reprogramming of neuronal metabolism. Cell Metab 23:280–291. https://doi.org/10.1016/j.cmet.2015.12.007
Querbes W, Bogorad RL, Moslehi J, Wong J, Chan AY, Bulgakova E, Kuchimanchi S, Akinc A, Fitzgerald K, Koteliansky V, Kaelin WG Jr (2012) Treatment of erythropoietin deficiency in mice with systemically administered siRNA. Blood 120:1916–1922. https://doi.org/10.1182/blood-2012-04-423715
Rahtu-Korpela L, Karsikas S, Horkko S, Blanco Sequeiros R, Lammentausta E, Makela KA, Herzig KH, Walkinshaw G, Kivirikko KI, Myllyharju J, Serpi R, Koivunen P (2014) HIF prolyl 4-hydroxylase-2 inhibition improves glucose and lipid metabolism and protects against obesity and metabolic dysfunction. Diabetes 63:3324–3333. https://doi.org/10.2337/db14-0472
Rahtu-Korpela L, Maatta J, Dimova EY, Horkko S, Gylling H, Walkinshaw G, Hakkola J, Kivirikko KI, Myllyharju J, Serpi R, Koivunen P (2016) Hypoxia-inducible factor prolyl 4-hydroxylase-2 inhibition protects against development of atherosclerosis. Arterioscler Thromb Vasc Biol 36:608–617. https://doi.org/10.1161/ATVBAHA.115.307136
Rajendran G, Schonfeld MP, Tiwari R, Huang S, Torosyan R, Fields T, Park J, Susztak K, Kapitsinou PP (2020) Inhibition of endothelial PHD2 suppresses post-ischemic kidney inflammation through hypoxia-inducible factor-1. J Am Soc Nephrol 31:501–516. https://doi.org/10.1681/ASN.2019050523
Rauner M, Franke K, Murray M, Singh RP, Hiram-Bab S, Platzbecker U, Gassmann M, Socolovsky M, Neumann D, Gabet Y, Chavakis T, Hofbauer LC, Wielockx B (2016) Increased EPO levels are associated with bone loss in mice lacking PHD2 in EPO-producing cells. J Bone Miner Res 31:1877–1887. https://doi.org/10.1002/jbmr.2857
Rishi MT, Selvaraju V, Thirunavukkarasu M, Shaikh IA, Takeda K, Fong GH, Palesty JA, Sanchez JA, Maulik N (2015) Deletion of prolyl hydroxylase domain proteins (PHD1, PHD3) stabilizes hypoxia inducible factor-1 alpha, promotes neovascularization, and improves perfusion in a murine model of hind-limb ischemia. Microvasc Res 97:181–188. https://doi.org/10.1016/j.mvr.2014.10.009
Röning T, Magga J, Laitakari A, Halmetoja R, Tapio J, Dimova EY, Szabo Z, Rahtu-Korpela L, Kemppi A, Walkinshaw G, Myllyharju J, Kerkela R, Koivunen P, Serpi R (2022) Activation of the hypoxia response pathway protects against age-induced cardiac hypertrophy. J Mol Cell Cardiol 164:148–155. https://doi.org/10.1016/j.yjmcc.2021.12.003
Rosendahl AH, Monnius M, Laitala A, Railo A, Miinalainen I, Heljasvaara R, Maki JM, Myllyharju J (2022) Deletion of hypoxia-inducible factor prolyl 4-hydroxylase 2 in FoxD1-lineage mesenchymal cells leads to congenital truncal alopecia. J Biol Chem 298:101787. https://doi.org/10.1016/j.jbc.2022.101787
Sadiku P, Willson JA, Dickinson RS, Murphy F, Harris AJ, Lewis A, Sammut D, Mirchandani AS, Ryan E, Watts ER, Thompson AAR, Marriott HM, Dockrell DH, Taylor CT, Schneider M, Maxwell PH, Chilvers ER, Mazzone M, Moral V, Pugh CW, Ratcliffe PJ, Schofield CJ, Ghesquiere B, Carmeliet P, Whyte MK, Walmsley SR (2017) Prolyl hydroxylase 2 inactivation enhances glycogen storage and promotes excessive neutrophilic responses. J Clin Invest 127:3407–3420. https://doi.org/10.1172/JCI90848
Schneider M, Van Geyte K, Fraisl P, Kiss J, Aragones J, Mazzone M, Mairbaurl H, De Bock K, Jeoung NH, Mollenhauer M, Georgiadou M, Bishop T, Roncal C, Sutherland A, Jordan B, Gallez B, Weitz J, Harris RA, Maxwell P, Baes M, Ratcliffe P, Carmeliet P (2010) Loss or silencing of the PHD1 prolyl hydroxylase protects livers of mice against ischemia/reperfusion injury. Gastroenterology 138(1143–1154):e1141-1142. https://doi.org/10.1053/j.gastro.2009.09.057
Schofield CJ, Ratcliffe PJ (2004) Oxygen sensing by HIF hydroxylases. Nat Rev Mol Cell Biol 5:343–354. https://doi.org/10.1038/nrm1366
Semenza GL (2012) Hypoxia-inducible factors in physiology and medicine. Cell 148:399–408. https://doi.org/10.1016/j.cell.2012.01.021
Seth P, Krop I, Porter D, Polyak K (2002) Novel estrogen and tamoxifen induced genes identified by SAGE (Serial Analysis of Gene Expression). Oncogene 21:836–843. https://doi.org/10.1038/sj.onc.1205113
Settelmeier S, Schreiber T, Maki J, Byts N, Koivunen P, Myllyharju J, Fandrey J, Winning S (2020) Prolyl hydroxylase domain 2 reduction enhances skeletal muscle tissue regeneration after soft tissue trauma in mice. PLoS One 15:e0233261. https://doi.org/10.1371/journal.pone.0233261
Shin J, Nunomiya A, Kitajima Y, Dan T, Miyata T, Nagatomi R (2016) Prolyl hydroxylase domain 2 deficiency promotes skeletal muscle fiber-type transition via a calcineurin/NFATc1-dependent pathway. Skelet Muscle 6:5. https://doi.org/10.1186/s13395-016-0079-5
Singh RP, Franke K, Kalucka J, Mamlouk S, Muschter A, Gembarska A, Grinenko T, Willam C, Naumann R, Anastassiadis K, Stewart AF, Bornstein S, Chavakis T, Breier G, Waskow C, Wielockx B (2013) HIF prolyl hydroxylase 2 (PHD2) is a critical regulator of hematopoietic stem cell maintenance during steady-state and stress. Blood 121:5158–5166. https://doi.org/10.1182/blood-2012-12-471185
Sinha KM, Tseng C, Guo P, Lu A, Pan H, Gao X, Andrews R, Eltzschig H, Huard J (2019) Hypoxia-inducible factor 1alpha (HIF-1alpha) is a major determinant in the enhanced function of muscle-derived progenitors from MRL/MpJ mice. FASEB J 33:8321–8334. https://doi.org/10.1096/fj.201801794R
Sluiter TJ, Tillie R, de Jong A, de Bruijn JBG, Peters HAB, van de Leijgraaf R, Halawani R, Westmaas M, Starink LIW, Quax PHA, Sluimer JC, de Vries MR (2024) Myeloid PHD2 conditional knockout improves intraplaque angiogenesis and vascular remodeling in a murine model of venous bypass grafting. J Am Heart Assoc 13:e033109. https://doi.org/10.1161/JAHA.123.033109
Smaila BD, Holland SD, Babaeijandaghi F, Henderson HG, Rossi FMV, Ramer MS (2020) Systemic hypoxia mimicry enhances axonal regeneration and functional recovery following peripheral nerve injury. Exp Neurol 334:113436. https://doi.org/10.1016/j.expneurol.2020.113436
Stegen S, Stockmans I, Moermans K, Thienpont B, Maxwell PH, Carmeliet P, Carmeliet G (2018) Osteocytic oxygen sensing controls bone mass through epigenetic regulation of sclerostin. Nat Commun 9:2557. https://doi.org/10.1038/s41467-018-04679-7
Stegen S, van Gastel N, Eelen G, Ghesquiere B, D’Anna F, Thienpont B, Goveia J, Torrekens S, Van Looveren R, Luyten FP, Maxwell PH, Wielockx B, Lambrechts D, Fendt SM, Carmeliet P, Carmeliet G (2016) HIF-1alpha promotes glutamine-mediated redox homeostasis and glycogen-dependent bioenergetics to support postimplantation bone cell survival. Cell Metab 23:265–279. https://doi.org/10.1016/j.cmet.2016.01.002
Stiehl DP, Wirthner R, Koditz J, Spielmann P, Camenisch G, Wenger RH (2006) Increased prolyl 4-hydroxylase domain proteins compensate for decreased oxygen levels. Evidence for an autoregulatory oxygen-sensing system. J Biol Chem 281:23482–23491. https://doi.org/10.1074/jbc.M601719200
Strowitzki MJ, Cummins EP, Taylor CT (2019) Protein hydroxylation by hypoxia-inducible factor (HIF) hydroxylases: unique or ubiquitous? Cells 8. https://doi.org/10.3390/cells8050384
Strowitzki MJ, Kimmer G, Wehrmann J, Ritter AS, Radhakrishnan P, Opitz VM, Tuffs C, Biller M, Kugler J, Keppler U, Harnoss JM, Klose J, Schmidt T, Blanco A, Taylor CT, Schneider M (2021) Inhibition of HIF-prolyl hydroxylases improves healing of intestinal anastomoses. JCI Insight 6. https://doi.org/10.1172/jci.insight.139191
Strowitzki MJ, Kirchberg J, Tuffs C, Schiedeck M, Ritter AS, Biller M, Harnoss JM, Lasitschka F, Schmidt T, Radhakrishnan P, Ulrich A, Schneider M (2018) Loss of prolyl-hydroxylase 1 protects against biliary fibrosis via attenuated activation of hepatic stellate cells. Am J Pathol 188:2826–2838. https://doi.org/10.1016/j.ajpath.2018.08.003
Suhara T, Hishiki T, Kasahara M, Hayakawa N, Oyaizu T, Nakanishi T, Kubo A, Morisaki H, Kaelin WG Jr, Suematsu M, Minamishima YA (2015) Inhibition of the oxygen sensor PHD2 in the liver improves survival in lactic acidosis by activating the Cori cycle. Proc Natl Acad Sci U S A 112:11642–11647. https://doi.org/10.1073/pnas.1515872112
Swain L, Wottawa M, Hillemann A, Beneke A, Odagiri H, Terada K, Endo M, Oike Y, Farhat K, Katschinski DM (2014) Prolyl-4-hydroxylase domain 3 (PHD3) is a critical terminator for cell survival of macrophages under stress conditions. J Leukoc Biol 96:365–375. https://doi.org/10.1189/jlb.2HI1013-533R
Takada M, Zhuang M, Inuzuka H, Zhang J, Zurlo G, Zhang J, Zhang Q (2017) EglN2 contributes to triple negative breast tumorigenesis by functioning as a substrate for the FBW7 tumor suppressor. Oncotarget 8:6787–6795. https://doi.org/10.18632/oncotarget.14290
Takeda K, Aguila HL, Parikh NS, Li X, Lamothe K, Duan LJ, Takeda H, Lee FS, Fong GH (2008) Regulation of adult erythropoiesis by prolyl hydroxylase domain proteins. Blood 111:3229–3235. https://doi.org/10.1182/blood-2007-09-114561
Takeda K, Cowan A, Fong GH (2007) Essential role for prolyl hydroxylase domain protein 2 in oxygen homeostasis of the adult vascular system. Circulation 116:774–781. https://doi.org/10.1161/CIRCULATIONAHA.107.701516
Takeda K, Duan LJ, Takeda H, Fong GH (2014) Improved vascular survival and growth in the mouse model of hindlimb ischemia by a remote signaling mechanism. Am J Pathol 184:686–696. https://doi.org/10.1016/j.ajpath.2013.11.032
Takeda K, Ho VC, Takeda H, Duan LJ, Nagy A, Fong GH (2006) Placental but not heart defects are associated with elevated hypoxia-inducible factor alpha levels in mice lacking prolyl hydroxylase domain protein 2. Mol Cell Biol 26:8336–8346. https://doi.org/10.1128/MCB.00425-06
Takeda Y, Costa S, Delamarre E, Roncal C, Leite de Oliveira R, Squadrito ML, Finisguerra V, Deschoemaeker S, Bruyere F, Wenes M, Hamm A, Serneels J, Magat J, Bhattacharyya T, Anisimov A, Jordan BF, Alitalo K, Maxwell P, Gallez B, Zhuang ZW, Saito Y, Simons M, De Palma M, Mazzone M (2011) Macrophage skewing by Phd2 haplodeficiency prevents ischaemia by inducing arteriogenesis. Nature 479:122–126. https://doi.org/10.1038/nature10507
Tambuwala MM, Cummins EP, Lenihan CR, Kiss J, Stauch M, Scholz CC, Fraisl P, Lasitschka F, Mollenhauer M, Saunders SP, Maxwell PH, Carmeliet P, Fallon PG, Schneider M, Taylor CT (2010) Loss of prolyl hydroxylase-1 protects against colitis through reduced epithelial cell apoptosis and increased barrier function. Gastroenterology 139:2093–2101. https://doi.org/10.1053/j.gastro.2010.06.068
Tang H, Babicheva A, McDermott KM, Gu Y, Ayon RJ, Song S, Wang Z, Gupta A, Zhou T, Sun X, Dash S, Wang Z, Balistrieri A, Zheng Q, Cordery AG, Desai AA, Rischard F, Khalpey Z, Wang J, Black SM, Garcia JGN, Makino A, Yuan JX (2018) Endothelial HIF-2alpha contributes to severe pulmonary hypertension due to endothelial-to-mesenchymal transition. Am J Physiol Lung Cell Mol Physiol 314:L256–L275. https://doi.org/10.1152/ajplung.00096.2017
Taniguchi CM, Finger EC, Krieg AJ, Wu C, Diep AN, LaGory EL, Wei K, McGinnis LM, Yuan J, Kuo CJ, Giaccia AJ (2013) Cross-talk between hypoxia and insulin signaling through Phd3 regulates hepatic glucose and lipid metabolism and ameliorates diabetes. Nat Med 19:1325–1330. https://doi.org/10.1038/nm.3294
Taniguchi CM, Miao YR, Diep AN, Wu C, Rankin EB, Atwood TF, Xing L, Giaccia AJ (2014) PHD inhibition mitigates and protects against radiation-induced gastrointestinal toxicity via HIF2. Sci Transl Med 6:236ra264. https://doi.org/10.1126/scitranslmed.3008523
Tapio J, Halmetoja R, Dimova EY, Maki JM, Laitala A, Walkinshaw G, Myllyharju J, Serpi R, Koivunen P (2022) Contribution of HIF-P4H isoenzyme inhibition to metabolism indicates major beneficial effects being conveyed by HIF-P4H-2 antagonism. J Biol Chem 298:102222. https://doi.org/10.1016/j.jbc.2022.102222
Tavernier SJ, Vanlangenakker N, Vetters J, Carmeliet P, Janssens S, Lambrecht BN (2017) Opposing regulation and roles for PHD3 in lung dendritic cells and alveolar macrophages. J Leukoc Biol 102:1115–1126. https://doi.org/10.1189/jlb.3A0916-405R
Taylor CT, Colgan SP (2017) Regulation of immunity and inflammation by hypoxia in immunological niches. Nat Rev Immunol 17:774–785. https://doi.org/10.1038/nri.2017.103
Taylor CT, Scholz CC (2022) The effect of HIF on metabolism and immunity. Nat Rev Nephrol 18:573–587. https://doi.org/10.1038/s41581-022-00587-8
Thomas A, Belaidi E, Aron-Wisnewsky J, van der Zon GC, Levy P, Clement K, Pepin JL, Godin-Ribuot D, Guigas B (2016) Hypoxia-inducible factor prolyl hydroxylase 1 (PHD1) deficiency promotes hepatic steatosis and liver-specific insulin resistance in mice. Sci Rep 6:24618. https://doi.org/10.1038/srep24618
Tojo Y, Sekine H, Hirano I, Pan X, Souma T, Tsujita T, Kawaguchi S, Takeda N, Takeda K, Fong GH, Dan T, Ichinose M, Miyata T, Yamamoto M, Suzuki N (2015) Hypoxia signaling cascade for erythropoietin production in hepatocytes. Mol Cell Biol 35:2658–2672. https://doi.org/10.1128/MCB.00161-15
Ullah K, Rosendahl AH, Izzi V, Bergmann U, Pihlajaniemi T, Maki JM, Myllyharju J (2017) Hypoxia-inducible factor prolyl-4-hydroxylase-1 is a convergent point in the reciprocal negative regulation of NF-kappaB and p53 signaling pathways. Sci Rep 7:17220. https://doi.org/10.1038/s41598-017-17376-0
Urrutia AA, Guan N, Mesa-Ciller C, Afzal A, Davidoff O, Haase VH (2021) Inactivation of HIF-prolyl 4-hydroxylases 1, 2 and 3 in NG2-expressing cells induces HIF2-mediated neurovascular expansion independent of erythropoietin. Acta Physiol (Oxf) 231:e13547. https://doi.org/10.1111/apha.13547
van Kuijk K, Demandt JAF, Perales-Paton J, Theelen TL, Kuppe C, Marsch E, de Bruijn J, Jin H, Gijbels MJ, Matic L, Mees BME, Reutelingsperger CPM, Hedin U, Biessen EAL, Carmeliet P, Baker AH, Kramann RK, Schurgers LJ, Saez-Rodriguez J, Sluimer JC (2022) Deficiency of myeloid PHD proteins aggravates atherogenesis via macrophage apoptosis and paracrine fibrotic signalling. Cardiovasc Res 118:1232–1246. https://doi.org/10.1093/cvr/cvab152
Van Welden S, De Vos M, Wielockx B, Tavernier SJ, Dullaers M, Neyt S, Descamps B, Devisscher L, Devriese S, Van den Bossche L, Holvoet T, Baeyens A, Correale C, D’Alessio S, Vanhove C, De Vos F, Verhasselt B, Breier G, Lambrecht BN, Janssens S, Carmeliet P, Danese S, Elewaut D, Laukens D, Hindryckx P (2017) Haematopoietic prolyl hydroxylase-1 deficiency promotes M2 macrophage polarization and is both necessary and sufficient to protect against experimental colitis. J Pathol 241:547–558. https://doi.org/10.1002/path.4861
Volkova YL, Pickel C, Jucht AE, Wenger RH, Scholz CC (2022) The asparagine hydroxylase FIH: a unique oxygen sensor. Antioxid Redox Signal 37:913–935. https://doi.org/10.1089/ars.2022.0003
Walmsley SR, Chilvers ER, Thompson AA, Vaughan K, Marriott HM, Parker LC, Shaw G, Parmar S, Schneider M, Sabroe I, Dockrell DH, Milo M, Taylor CT, Johnson RS, Pugh CW, Ratcliffe PJ, Maxwell PH, Carmeliet P, Whyte MK (2011) Prolyl hydroxylase 3 (PHD3) is essential for hypoxic regulation of neutrophilic inflammation in humans and mice. J Clin Invest 121:1053–1063. https://doi.org/10.1172/JCI43273
Wang S, Zeng H, Chen ST, Zhou L, Xie XJ, He X, Tao YK, Tuo QH, Deng C, Liao DF, Chen JX (2017) Ablation of endothelial prolyl hydroxylase domain protein-2 promotes renal vascular remodelling and fibrosis in mice. J Cell Mol Med 21:1967–1978. https://doi.org/10.1111/jcmm.13117
Wang S, Zeng H, Xie XJ, Tao YK, He X, Roman RJ, Aschner JL, Chen JX (2016) Loss of prolyl hydroxylase domain protein 2 in vascular endothelium increases pericyte coverage and promotes pulmonary arterial remodeling. Oncotarget 7:58848–58861. https://doi.org/10.18632/oncotarget.11585
Wicks EE, Semenza GL (2022) Hypoxia-inducible factors: cancer progression and clinical translation. J Clin Invest 132. https://doi.org/10.1172/JCI159839
Wu C, Rankin EB, Castellini L, Alcudia JF, LaGory EL, Andersen R, Rhodes SD, Wilson TL, Mohammad KS, Castillo AB, Guise TA, Schipani E, Giaccia AJ (2015) Oxygen-sensing PHDs regulate bone homeostasis through the modulation of osteoprotegerin. Genes Dev 29:817–831. https://doi.org/10.1101/gad.255000.114
Xia Y, Gong L, Liu H, Luo B, Li B, Li R, Li B, Lv M, Pan J, An F (2015) Inhibition of prolyl hydroxylase 3 ameliorates cardiac dysfunction in diabetic cardiomyopathy. Mol Cell Endocrinol 403:21–29. https://doi.org/10.1016/j.mce.2015.01.014
Xie L, Pi X, Mishra A, Fong G, Peng J, Patterson C (2012) PHD3-dependent hydroxylation of HCLK2 promotes the DNA damage response. J Clin Invest 122:2827–2836. https://doi.org/10.1172/JCI62374
Xie L, Pi X, Wang Z, He J, Willis MS, Patterson C (2015) Depletion of PHD3 protects heart from ischemia/reperfusion injury by inhibiting cardiomyocyte apoptosis. J Mol Cell Cardiol 80:156–165. https://doi.org/10.1016/j.yjmcc.2015.01.007
Xie Y, Yuan T, Qin Y, Weng Z, Fang J (2018) Prolyl hydroxylase 2 is dispensable for homeostasis of intestinal epithelium in mice. Acta Biochim Biophys Sin 50:540–546. https://doi.org/10.1093/abbs/gmy037
Xing W, Larkin D, Pourteymoor S, Tambunan W, Gomez GA, Liu EK, Mohan S (2022) Lack of skeletal effects in mice with targeted disruptionof prolyl hydroxylase domain 1 (Phd1) gene expressed in chondrocytes. Life (Basel) 13. https://doi.org/10.3390/life13010106
Xing W, Pourteymoor S, Gomez GA, Chen Y, Mohan S (2021) Prolyl hydroxylase domain-containing protein 3 gene expression in chondrocytes is not essential for bone development in mice. Cells 10. https://doi.org/10.3390/cells10092200
Xu X, Zhen PH, Yu FC, Wang T, Li SN, Wei Q, Tong JY (2022) Chronic intermittent hypoxia accelerates cardiac dysfunction and cardiac remodeling during cardiac pressure overload in mice and can be alleviated by PHD3 overexpression. Front Cardiovasc Med 9:974345. https://doi.org/10.3389/fcvm.2022.974345
Xu YM, Gao Q, Zhang JZ, Lu YT, Xing DM, Qin YQ, Fang J (2020) Prolyl hydroxylase 3 controls the intestine goblet cell generation through stabilizing ATOH1. Cell Death Differ 27:2131–2142. https://doi.org/10.1038/s41418-020-0490-7
Xue Y, Cui A, Wei S, Ma F, Liu Z, Fang X, Huo S, Sun X, Li W, Hu Z, Liu Y, Cai G, Su W, Zhao J, Yan X, Gao C, Wen J, Zhang H, Li H, Liu Y, Lin X, Xu Y, Fu W, Fang J, Li Y (2023) Proline hydroxylation of CREB-regulated transcriptional coactivator 2 controls hepatic glucose metabolism. Proc Natl Acad Sci U S A 120:e2219419120. https://doi.org/10.1073/pnas.2219419120
Yamamoto A, Hester J, Macklin PS, Kawai K, Uchiyama M, Biggs D, Bishop T, Bull K, Cheng X, Cawthorne E, Coleman ML, Crockford TL, Davies B, Dow LE, Goldin R, Kranc K, Kudo H, Lawson H, McAuliffe J, Milward K, Scudamore CL, Soilleux E, Issa F, Ratcliffe PJ, Pugh CW (2019) Systemic silencing of PHD2 causes reversible immune regulatory dysfunction. J Clin Invest 129:3640–3656. https://doi.org/10.1172/JCI124099
Yoon H, Spinelli JB, Zaganjor E, Wong SJ, German NJ, Randall EC, Dean A, Clermont A, Paulo JA, Garcia D, Li H, Rombold O, Agar NYR, Goodyear LJ, Shaw RJ, Gygi SP, Auwerx J, Haigis MC (2020) PHD3 loss promotes exercise capacity and fat oxidation in skeletal muscle. Cell Metab 32(215–228):e217. https://doi.org/10.1016/j.cmet.2020.06.017
Yuan X, Ruan W, Bobrow B, Carmeliet P, Eltzschig HK (2023) Targeting hypoxia-inducible factors: therapeutic opportunities and challenges. Nat Rev Drug Discov. https://doi.org/10.1038/s41573-023-00848-6
Zeng H, Chen JX (2014) Conditional knockout of prolyl hydroxylase domain protein 2 attenuates high fat-diet-induced cardiac dysfunction in mice. PLoS One 9:e115974. https://doi.org/10.1371/journal.pone.0115974
Zeng H, He X, Tuo QH, Liao DF, Zhang GQ, Chen JX (2016) LPS causes pericyte loss and microvascular dysfunction via disruption of Sirt3/angiopoietins/Tie-2 and HIF-2alpha/Notch3 pathways. Sci Rep 6:20931. https://doi.org/10.1038/srep20931
Zhang GH, Yu FC, Li Y, Wei Q, Song SS, Zhou FP, Tong JY (2017) Prolyl 4-hydroxylase domain protein 3 overexpression improved obstructive sleep apnea-induced cardiac perivascular fibrosis partially by suppressing endothelial-to-mesenchymal transition. J Am Heart Assoc 6. https://doi.org/10.1161/JAHA.117.006680
Zhao Y, Zeng H, Liu B, He X, Chen JX (2020) Endothelial prolyl hydroxylase 2 is necessary for angiotensin II-mediated renal fibrosis and injury. Am J Physiol Renal Physiol 319:F345–F357. https://doi.org/10.1152/ajprenal.00032.2020
Zhou LY, Zeng H, Wang S, Chen JX (2018) Regulatory role of endothelial PHD2 in the hepatic steatosis. Cell Physiol Biochem: international journal of experimental cellular physiology, biochemistry, and pharmacology 48:1003–1011. https://doi.org/10.1159/000491968
Zhu J, Zhao L, Hu Y, Cui G, Luo A, Bao C, Han Y, Zhou T, Lu W, Wang J, Black SM, Tang H (2021) Hypoxia-inducible factor 2-alpha mediated gene sets differentiate pulmonary arterial hypertension. Front Cell Dev Biol 9:701247. https://doi.org/10.3389/fcell.2021.701247
Zieseniss A, Hesse AR, Jatho A, Krull S, Holscher M, Vogel S, Katschinski DM (2015) Cardiomyocyte-specific transgenic expression of prolyl-4-hydroxylase domain 3 impairs the myocardial response to ischemia. Cell Physiol Biochem: international journal of experimental cellular physiology, biochemistry, and pharmacology 36:843–851. https://doi.org/10.1159/000430260
Zimmermann AS, Morrison SD, Hu MS, Li S, Nauta A, Sorkin M, Meyer NP, Walmsley GG, Maan ZN, Chan DA, Gurtner GC, Giaccia AJ, Longaker MT (2014) Epidermal or dermal specific knockout of PHD-2 enhances wound healing and minimizes ischemic injury. PLoS One 9:e93373. https://doi.org/10.1371/journal.pone.0093373
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Jucht, A.E., Scholz, C.C. PHD1-3 oxygen sensors in vivo—lessons learned from gene deletions. Pflugers Arch - Eur J Physiol 476, 1307–1337 (2024). https://doi.org/10.1007/s00424-024-02944-x
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DOI: https://doi.org/10.1007/s00424-024-02944-x