Abstract
Metabolic flux can dictate cell fate, including immune cell effector and regulatory function. The metabolic regulation of cell function is well characterized with respect to effector, memory, and regulatory T cells. This knowledge may allow for manipulation of T cell metabolic pathways that set the stage for more effective T cell therapy. Natural Killer (NK) and T-lymphocytes have complementary roles in the defense against pathogens. However, studies of NK cell metabolism are only beginning to emerge and there is comparatively little knowledge on the metabolic regulation of NK-cell activation and effector function. Given their common lymphoid lineage, effector functions and cellular memory potential our current knowledge on T cell metabolism could inform investigation of metabolic reprogramming in NK cells. In this review, we compare the current knowledge of metabolic regulation in T cell and NK cell development, activation, effector and memory function. Commonalties in glucose transport, hypoxia-inducible factors and mTOR highlight metabolic control points in both cells types. Contrasting the glycolytic and oxidative nodes of metabolic regulation in T cells versus NK cells may provide insight into the contribution of specific immune responses to disease and promote the development of immunotherapeutic approaches targeting both innate and adaptive immune responses.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
NK cells and T cells participate in innate and adaptive immunity
Natural Killer (NK) and T lymphocytes are components in the body’s defense against infections, autoimmunity, and cancer. As part of innate immunity, NK cells respond to a broad range of danger signals [1]. NK cell function is influenced by chemical messengers (including cytokines) and through signal integration from activating and inhibitory cell-surface receptors [1, 2]. Upon activation, NK cells can induce cell death directly in target cells by receptor-mediated interactions and/or by the release of cytotoxic granules [1]. NK cells further augment the innate response and initiate adaptive immunity through direct interactions and by releasing pro-inflammatory cytokines such as interferon gamma (IFN-γ) [1, 2]. Similar to T cells, NK cells can develop memory, leading to enhanced secondary responses upon re-stimulation [3]. As a critical component of adaptive immunity, T cells mount antigen-specific responses through T cell receptor (TCR) recognition combined with co-stimulation by other inflammatory signals [4]. While the activation process differs, NK cells and T cells share similarities with respect to effector functions. Both cell types can robustly proliferate when stimulated, exert cytotoxicity against target cells, and produce IFN-γ [5]. The purpose of this review is to highlight the current knowledge of similarities and differences in T cell versus NK cells regarding the role of cellular metabolism linked to effector and regulatory function. These two cell populations share characteristics relevant to immunotherapy and diseases such as autoimmunity.
There is a reciprocal relationship between NK and T cells, which should be considered when immunotherapies aim to augment NK and T cell effector functions to boost immune defenses against disease. Targeting mechanisms to enhance NK cell-mediated innate responses can improve T cell functions during infection [6]. Conversely, boosting T cell activity can support NK cell effector responses [7]. There are also analogous subsets of NK and T cells regarding cell function, which are relevant to autoimmune diseases. For example, different T cell subsets can promote or mitigate aspects of autoimmunity. Generally, Th17 effector cells promote autoimmunity while regulatory T (Treg) cells suppress these responses [8,9,10,11,12,13]. Similarly, NK cells have a dual role in autoimmune disease, where aberrant NK cell activation promoting pathogenesis, while regulatory NK subsets maintain tolerance [14, 15]. The knowledge of T cell metabolism outweighs (but may inform) how metabolism may influence NK cell function.
Immunometabolism
Cellular metabolism encompasses both the catabolic and anabolic pathways to generate and use adenosine triphosphate (ATP) molecules, respectively. Features of these metabolic pathways have been reviewed elsewhere in detail [16]. It is commonly reported that glucose is the principle fuel source used by immune cells [16]. Circulating glucose can directly fuel tissue metabolism through the tricarboxylic acid (TCA) cycle or anaerobic glycolysis, but this can also occur indirectly via circulating lactate [17]. Glucose can be catabolized to pyruvate through glycolysis, which rapidly generates ATP and nicotinamide adenine dinucleotide (NADH) molecules. Pyruvate is then converted to lactate (anaerobic glycolysis) or acetyl-CoA, which is oxidized in the mitochondria by the tricarboxylic acid (TCA) cycle (aerobic glycolysis), fueling oxidative phosphorylation (OXPHOS). The catabolism of other biomolecules, such as glutamine via glutaminolysis and fatty acids via fatty acid oxidation (FAO), can also fuel the TCA cycle and OXPHOS. The TCA cycle is a series of oxidation steps which generate redox reagents NADH and flavin adenine dinucleotide (FADH2) that provide electrons for OXPHOS. OXPHOS is a series of redox reactions that generates a proton gradient across the inner mitochondrial membrane resulting in ATP production. Depending on the metabolic needs of the cell, intermediates in the TCA cycle can participate in anabolic pathways including fatty acid (FAS) and amino acid synthesis.
Immune cells adopt a range of functional profiles depending on the environment. Both NK cells and T cells rapidly mount an effector response to inflammatory signals, curtail their response when the inflammatory signal is cleared, and retain basal functionality, longevity, and readiness to respond in the interim of inflammation. A shift in these diverse functional states requires plasticity of energetic metabolism. Therefore, it is not surprising that immune cells in different functional states adopt distinct metabolic signatures. Further, it has become clear that cell metabolism can dictate immune cell function.
NK and T cell metabolism
Metabolic flux of different substrates can regulate T cell function and characterizes different subsets including effector, memory, and Treg cells. However, less is known about how specific metabolic pathways influence NK cell function. There is some evidence that the metabolic requirements for activation and effector function in NK cells demonstrate parallels with the immunometabolism of T cells. Given the similarities between these cells including a common lymphoid lineage, shared effector functions, and ability to form memory populations, it is logical that the state of knowledge in T cell metabolism could inform on comparative knowledge gaps and new areas of research in NK cell metabolism. Much of the evidence reviewed on cellular development, activation, effector function, memory, and immune suppression is based on cell biology assessment and mouse models to understand the underlying molecular mechanisms. Nevertheless, identifying common metabolic pathways between NK and T cells would identify metabolic nodes that could be exploited to alter both innate and adaptive immunity.
Cell development
Metabolic changes during T cell development
In the thymus, T cell development begins with progenitor cells committed to the T cell lineage that becomes CD4/8 double negative (DN) thymocytes. DN thymocytes undergo rearrangement of the TCR gene forming a pre-TCR via beta selection (Fig. 1, outlined in black) [18]. DN thymocyte proliferation coincides with increased glycolytic flux, increased expression of the glucose transporter, Glut1 and activation of PI3K-AKT signal transduction [18, 19]. Subsequently, DN thymocytes transition to double positive (DP) thymocytes [18, 19], undergo maturation, coinciding with a decrease in the rate of cellular proliferation. DP thymocytes become increasingly metabolically quiescent, as genes involved in lipid biosynthesis, oxidative–reductive reactions, and carbohydrate metabolism are down-regulated [20]. This more quiescent metabolic state continues as DP thymocytes mature to single positive (SP) naïve T cells which exit the thymus. Naïve T cells rely primarily on FAO and OXPHOS to efficiently sustain basal energetic needs (Fig. 1) [21,22,23,24].
There is good evidence for the requirement of glucose metabolism in the early stages of T cell proliferation and development, particularly via glucose transport through Glut1. For example, using LckCreGlut1fl/fl mice, Glut1 deficient DN thymocytes have reduced DP thymocytes and lower levels of mature CD4 SP T cells [13]. Glut1 deficiency appears not to alter later stages of T cell development, since DN thymocytes in the initial development stages (stages DN 1–3) are unchanged in mice that lack Glut1, but there is a trend for reduced DN thymocytes in the 4th developmental stage [13]. As DN3 and DN4 thymocytes have the highest expression of Glut1 and undergo extensive proliferation, this suggests Glut1 is required to support this proliferative phase [13]. Despite a role for glucose transport, not all aspects of anaerobic glycolysis appear strictly required for thymocyte development, since deficiency of lactate dehydrogenase A (LDHA), the enzyme which converts pyruvate to lactate, did not affect the frequency of DN, DP, mature CD4 SP or CD8 SP T cells [21]. It should be carefully considered that glucose can also be used in aerobic metabolism via pyruvate entry into the TCA cycle. Altogether, these studies demonstrate that cellular glucose transport is required for normal T cell development in mice. Proliferation stages of T cell development coincide with increased rates of glycolysis, but not necessarily strictly involving or requiring all aspects of anaerobic glycolysis.
Metabolic changes during NK-cell development
Murine NK-cell maturation state is defined by the expression of the cell-surface markers CD11b and CD27. Immature CD11bloCD27hi NK cells transition to an intermediate CD11bhiCD27hi stage, and then CD27 declines resulting in the expression pattern of CD11bhiCD27lo in the mature NK-cell subset (Fig. 2, outlined in black) [25]. As immature NK proceed down the maturation process, cells progressively rely less on glycolysis and cellular glucose uptake. It is important to consider that immature NK cells have increased cell size and granularity when comparing coincident changes in cell metabolism and maturity status. Nevertheless, immature NK cells have increased glucose transporter and nutrient receptor expression compared to mature NK cells [26]. Furthermore, transcript analysis also has shown that pathways associated with cell growth were down-regulated in mature cells, whilst FAO and aerobic metabolism metabolic pathways are up-regulated as NK cell mature (Fig. 2, outlined in black) [26].
The metabolic regulator mTOR is a key node integrating cell NK metabolism and development. mTOR can integrate cell growth signals to cellular metabolism by promoting cell proliferation, anabolic responses, and anaerobic glycolysis [27]. Activation of mTOR signaling is progressively down-regulated as NK cells mature, consistent with reduced glucose uptake during maturation [26]. Mice with an NK cell-specific mTOR deletion (NK-mTOR−/−) have compromised NK cell development due to impaired transition from immature to intermediate subsets. Consequently, NK-mTOR−/− mice have lower mature NK cells in peripheral organs [26]. The involvement of mTOR in NK cell maturation, together with changes in metabolism during maturation, indicates one way that cell metabolism is linked to development. However, a comprehensive, functional assessment of metabolic pathways during NK cell maturation has not been reported.
Comparison of NK cell and T cell metabolism during development
Many parallels exist between the metabolic signatures of developing lymphocytes. Both immature NK and T cells have higher reliance on glucose metabolism compared to their mature counterparts, which likely supports more rapid cell proliferation. Both cell types become metabolically quiescent as they acquire a mature phenotype, relying mainly on FAO and OXPHOS to support a change in energetic needs. There is evidence that glucose transport via Glut1 expression is critical for T cell development. There is evidence that mTOR can regulate NK cell development, but the direct role of glycolysis and Glut1 in regulating NK cell development requires further clarification.
Cell activation
Metabolic regulation of T cell activation (T effector cells)
While mature naïve cells are skewed towards a more metabolically quiescent status, T cells can undergo profound metabolic reprogramming upon activation to support proliferation and effector functions (Fig. 1, intracellular). Effector T cells have augmented glycolysis and OXPHOS, indicating greater cellular metabolism than naïve T cells. During this overall increase in cellular metabolism, effector T cells have a greater reliance on aerobic and anaerobic glycolysis at the relative expense of energy derived from OXPHOS upon activation [21,22,23,24]. The importance of extracellular glucose transport and subsequent utilization is evident in Glut1-deficient mature T cells which have reduced proliferation upon activation [13]. However, T effector cells are not entirely dependent on glucose to fuel ATP production. In vitro experiments culturing murine CD4 T cells in galactose instead of glucose, which limits glycolysis, only partially reduced proliferation. These results indicate that other compounds contribute to OXPHOS-derived ATP to support proliferation [22]. In addition, there is evidence that T effector cells do not rely solely on glucose catabolism to fuel aerobic glycolysis as substrates beyond glucose (and lipids) have been shown to fuel OXPHOS. One study demonstrated that murine effector T cells utilize glutamine to maintain intracellular ATP levels in glucose-limiting conditions [28]. This increase in glutamine oxidation is facilitated by increased expression of glutamine transporters such as CD98, which is analogous to increased glucose use facilitated by increased Glut1 levels [13, 23, 29].
Up-regulation of glucose and glutamine transport and catabolism produces intermediates that can fuel anabolic pathways involved in cell growth, proliferation, and effector functions. Effector T cells up-regulate numerous anabolic pathways to help achieve theses cellular responses, including augmented fatty acid synthesis (FAS) [11, 23, 30]. Increased glucose catabolism supplies short-chain carbon molecules that can be shunted through the TCA cycle and citrate pyruvate shuttle system, promoting FAS [11]. To demonstrate that lipid synthesis is critical in effector cell differentiation, one group showed that inhibiting the FAS rate-limiting enzyme acetyl-CoA carboxylase 1 (ACC1), impaired Th17 differentiation in both murine and human T cells [11]. Furthermore, T cell-specific ACC1-knockout mice were protected against Th17-mediated autoimmune encephalomyelitis. Thus, upon activation, T effector cells increase overall metabolic activity, with enhanced glucose and glutamine catabolism to rapidly generate energy and feed anabolic pathways.
Numerous studies have highlighted key metabolic regulators of T cell activation-induced metabolic reprogramming (Fig. 1, intracellular). Up-regulating Glut1 and glucose uptake is an important hallmark of T effector cell differentiation. One study demonstrated that Glut1 deficiency in both murine and human T cells impaired anaerobic glycolysis and glycolytic capacity upon activation [13]. Unlike naïve T cells, Glut1 expression promotes T effector survival. Another study showed Glut1 expression and glycolysis enhanced T effector cell differentiation, since aged Glut1 transgenic mice had enriched CD4 T effector cell subsets [29]. Furthermore, they demonstrated that T effector cell differentiation in vitro was impaired in the absence of glucose.
As a key regulator of glycolysis, mTOR plays a critical role in T effector cell metabolism. mTOR activity is up-regulated upon T cell activation and exerts numerous functions to promote glycolysis. mTOR up-regulates hypoxia-inducible factor 1-alpha (HIF1α), which stimulates glycolysis, resulting in Th17 differentiation (Fig. 1, highlighted in green on left) [31]. mTOR also activates the transcription factor Myc which promotes glycolysis, glutamine oxidation, and CD98 expression (Fig. 1, highlighted in green bottom right) [23]. In line with these roles, mTOR activation is critical for T effector cell differentiation as treatment with the mTOR inhibitor rapamycin inhibited this process [29]. In addition to mTOR integration of cellular nutrient/energy status and even cellular oxygen sensing by mTOR, transcription factors can influence metabolic control of T cell activation. For example, interferon regulatory factor 4 (IRF4) can act T effector cell glycolytic switch point. IRF4 knockout CD4 T cells have reduced glucose uptake, and impaired glycolysis and OXPHOS upon activation [32]. IRF4 appears to be an important immunometabolism relay that can help integrate the metabolic status of immune cells to activation status (and effector function), but IRF4 also can propagate immune responses into whole body and tissue metabolic outcomes such as lipid storage versus oxidation and insulin sensitivity [33,34,35]. Altogether, these studies highlight the critical role of metabolic reprogramming for T effector cell differentiation.
Metabolic regulation of T effector cell function
Cellular metabolic status also impacts T cell effector function (Fig. 1). T cell activation is characterized by a shift in relative energy reliance from OXPHOS to aerobic glycolysis [22]. Changes in the cellular metabolism upon activation of T effector cells are not entirely dependent on glucose to fuel ATP production from aerobic glycolysis. However, limiting supply or catabolism of either glucose or glutamine reduces proliferation of T effector cells in vitro and in vivo [23]. This suggests that both glucose and glutamine are essential for T effector cell growth and proliferation. In addition, the transcription factor Myc supports glucose and glutamine catabolism upon cellular activation. Genetic deletion of Myc impaired in vitro and in vivo T cell proliferation, suggesting its role in driving catabolism and proliferation [23]. Up-regulation of anabolic pathways is also critical for supporting T effector cell proliferation. Indeed, ACC1-knockout T cells had impaired proliferation in vivo in response to antigen stimulation, suggesting ACC provision of malonyl CoA for FAS is required for CD8 T cell proliferation during an activating stimulus [30]. In addition to glucose flux, amino acid metabolism is essential for T cell activation. In activated T cells, TCR:antigen engagement increases the expression of amino acid SLC7 transporters and cellular uptake of leucine and glutamine, where ERK/MAPK signaling has been implicated [36,37,38]. Inhibiting amino acid uptake and subsequent metabolism can alter T cell function. For example, blocking l-leucine uptake in human primary T cells using the inhibitor JPH203 or siRNA-mediated reduction in SLC7a5 ex vivo reduced production of cytokines such as IFN-γ, IL-4, and IL-17 [37]. CD8 T cells deficient in SLC7a5 have impaired antigen responses and do not undergo proliferative expansion [38]. Glutamine deficiency also impairs secretion of cytokines such as IL-2, IFN-γ and also impairs T cell proliferation [36]. Ma et al. recently showed serine uptake is required for optimal CD4 and CD8 T cell expansion in vivo and in vitro [39]. Altogether, these studies demonstrate that amino acid uptake and utilization is required for optimal effector T cell proliferation and function.
Amino acid metabolism also plays a role in Th1 and Th17 cellular differentiation. Elevated levels of glutamine and its metabolite alpha-ketoglutarate promote Th1 and Th17 differentiation, where mTORC1 signaling has been implicated [40]. Th1 and Th17 differentiation, but not Th2 or T-reg, is impaired in SLC1a5 and SLC7a5 deficient CD4 T cells, which transport glutamine and l-leucine, respectively [38, 41]. Interestingly, T-reg differentiation is promoted during glutamine deficiency [40]. Therefore, these results suggest that amino acid metabolism is required for proper CD4 T cell differentiation, and Th1 and Th17 subsets may depend on mTOR signaling.
Augmented IFN-γ production is a critical effector function of activated T cells. Numerous studies have examined the roles of glycolytic enzymes and intermediates in regulating cytokine expression. A seminal study by Chang et al. revealed that IFN-γ production is regulated by glycolysis, independent of cellular metabolism via OXPHOS. Culturing T cells in galactose, which limits glycolysis, impaired IFN-γ secretion while inhibiting OXPHOS did not [22]. This study found that glycolysis regulated IFN-γ post-transcriptionally, since increased translation occurred when cells were cultured in glucose rather than galactose. Furthermore, it was revealed that glycolysis controlled IFN-γ production through the glycolytic enzyme glyceraldehyde-3 phosphate dehydrogenase (GAPDH). GAPDH inhibits IFN-γ translation by binding to the 3′UTR mRNA region. During glycolysis, GAPDH is diverted from IFN-γ mRNA binding, enabling its translation [22].
In addition, a GAPDH-independent mechanism of IFN-γ regulation by anaerobic glycolysis has been uncovered [21]. LDHA regulates T cell IFN-γ production in a 3′UTR-independent mechanism. By sustaining high rates of pyruvate conversion to lactate, the cell’s reliance on OXPHOS and TCA cycle for energy is reduced, facilitating mitochondrial export of citrate for conversion to acetyl-CoA (Fig. 1, center). Cytosolic acetyl-CoA leads to histone acetylation and consequently IFN-γ transcription. An additional regulator of T cell IFN-γ production is the glycolytic intermediate phosphoenolpyruvate (PEP). PEP promotes effector T cell IFN-γ expression by inhibiting the endoplasmic reticulum calcium transporter SERCA [42]. Inhibition of SERCA sustained cytosolic calcium levels, promoting nuclear factor of activated T cells (NFAT) signaling, resulting in IFN-γ transcription. Altogether, these studies reveal that enzyme and intermediates of glycolysis can control T cell IFN-γ production via multiple and redundant mechanisms.
Numerous TCR-independent methods of stimulation have also been used implicate glycolysis as a critical regulator of T cell IFN-γ production, including IL-18/IL-12 cytokine administration or IL-2/IL-36 stimulation of dual-costimulated T-cells. However, the method of stimulation may determine the relative importance of glycolysis in T cell effector function. One study described a glycolytic-independent mechanism for IFN-γ production following TLR2 stimulation of antigen-experienced CD8 T cells [43]. Interestingly, IFN-γ production was unaffected by glycolysis inhibition via 2-deoxyglucose (2DG), but dependent on OXPHOS. More information is required to understand how T cell metabolism influences effector function from diverse ligands and how metabolic flux can influence effector functions beyond IFN-γ.
Metabolic regulation of NK cell activation
NK cell activation induces metabolic changes reminiscent to T effector cells. Similar to T cells, NK cell activation prompts cellular proliferation and effector functions, which necessitate profound metabolic demands. As a result, activated NK cells increase metabolic flux through both glycolysis and OXPHOS, with a proportionally increased reliance on glycolysis relative to OXPHOS (Fig. 2) [26, 44, 45]. Elevated glycolysis upon activation is supported by enhanced glucose uptake and Glut1 expression [44, 45]. The evidence to date suggests that NK cell activation is fueled by glucose as a substrate. However, the reliance on glucose flux through aerobic and anaerobic fates may be different in NK cells compared to T cells. For example, one study showed that glucose-derived OXPHOS was required for NK receptor-mediated activation and that inhibiting glycolysis via 2DG or OXPHOS reduced intracellular levels of ATP to comparable levels in NK cells [46]. This is contrasted by T cells, where glutamine oxidization supplements ATP levels in glucose-deficient conditions [28]. Nevertheless, glucose catabolism in NK cells feeds anabolic pathways similar to T cells. One study shows that murine NK cells up-regulate genes involved in protein and lipid biosynthesis in response to IL-15 stimulation or mouse cytomegalovirus (MCMV) infection [26]. In addition, upon IL-2/IL-12 stimulation, 13C-glucose-tracing demonstrated that NK cells up-regulate glucose-fueled FAS and amino acid synthesis [47]. An important future area of research will be determining how different activating ligands such as IL-15, IL-12/18 or IL-2/36 alter effector function in NK cells versus T cells.
Two critical nodes have been shown to regulate NK cell metabolic reprogramming upon activation. NK cell up-regulation of both glycolysis and OXPHOS is regulated by a Srebp-mediated transcriptional program that up-regulates glucose metabolism through increased activity of a citrate–malate shuttle [47]. In addition, mTOR regulates NK cell metabolic reprogramming upon activation. mTOR activity is up-regulated in both mouse and human NK cells following various methods of stimulation, including Poly(I:C), IL-15, IL-2/IL-12, and IL-2 [26, 44, 45, 48] (Fig. 2, highlighted in green on right). Genetic or chemical inhibition (via rapamycin) of mTOR impairs activation-induced increase in NK cell size, glucose uptake, and nutrient uptake receptor expression [26, 44, 45]. Furthermore, mTOR activation in IL-15-stimulated NK cells correlated with increased expression of genes related to cell metabolism [48]. Inhibiting mTOR also directly suppressed murine NK cell activation-induced anaerobic glycolysis and the up-regulation of rate-limiting glycolytic enzymes, hexokinase 2 and LDHA, and Glut1 following IL-2/IL-12 stimulation [44]. While mTOR is a critical regulator of glycolysis, NK cells can up-regulate anaerobic glycolysis using an mTOR-independent mechanism following IL-12/IL-15 stimulation [45]. One important consideration is the dose and duration of ligand exposure. For example, prolonged treatment with a high dose of IL-15 eliminated the reliance on changes in metabolic flux for NK-cell receptor stimulation [46]. Thus, NK cell activation induces metabolic changes, but their regulation may depend on how they are activated.
Metabolic regulation of NK cell effector functions
Since metabolism underpins aspects of NK cell activation, it is logical to elucidate whether these metabolic changes directly regulate NK cell effector functions. Similar to T cells, activation induces NK cell proliferation, which requires profound bioenergetic demands. Thus, it is likely that an increase in energy production via glycolysis and OXPHOS, along with production of biomolecules through anabolic pathways sustain NK cell proliferation. There is still a dearth of information on metabolic control points of NK cell proliferation. Nevertheless, in support of this concept, deletion of mTOR or inhibition of Srebp impairs NK cell proliferation [26, 47].
NK cells are potent IFN-γ producers following activation. There is evidence implicating mTOR, Srebp, and both glycolysis and OXPHOS in NK cell IFN-γ production following stimulation (Fig. 2). For example, mTOR deletion in NK cells impaired IFN-γ secretion in response to Poly(I:C) stimulation [26]. Blocking mTOR also prevented NK cell IFN-γ production following Poly(I:C) and IL-2/IL-12 stimulation [44]. Likewise, inhibition of Srebp impaired IL-2/IL-12-induced IFN-γ production [47]. Blocking glycolysis using 2DG or galactose in culture also impaired NK cell IFN-γ secretion upon IL-2/IL-12 stimulation [44]. Furthermore, culturing NK cells in either glucose-free media or with 2DG inhibited cytokine production following activation receptor stimulation [46]. Despite these similar nodes of immunometabolism, the evidence to date suggests that NK cells have a differential reliance on OXPHOS compared to T cells. NK cells rely on OXPHOS for IFN-γ production following activation with IL-2, or IL-12/IL-15 stimulation [45, 46]. It is not yet clear if this is a cell intrinsic or ligand-derived difference in metabolic control of effector function compared to T cells.
While mTOR, Srebp, glycolysis, and OXPHOS are critical for NK cell IFN-γ production following stimulation, the metabolic control of cytokine production depends on the method of activation. Human NK cells produced IFN-γ independent of mTOR following in vitro IL-12/IL-15 activation, but was mTOR dependent following IL-2 stimulation [45]. However, limiting glycolysis by culturing cells in galactose reduced IFN-γ expression in CD56bright NK cells following IL-12/IL-15 stimulation. This indicates an mTOR-independent mechanism of glycolytic control in IFN-γ production [45]. One study reported that NK cells produced IFN-γ following short term stimulation with IL-12/IL-18 independent of both OXPHOS and glycolysis [26, 46]. These findings demonstrate that NK cells differ from T cells, which are dependent on glycolysis for IL-12/IL-18-induced IFN-γ secretion [49]. However, both studies assessed short term (1–6 h) IL-18/IL-12 NK cell stimulation and the metabolic requirements may change with extended (18–24 h) stimulation. Duration is important in determining the metabolic requirements for NK cell IFN-γ secretion. For example, treatment with IL-15 for 72 h eliminated cellular reliance on glycolysis and OXPHOS for receptor-mediated IFN-γ production [46]. While glycolytic intermediates and enzymes are critical for T cell secretion, these findings indicate they are not necessarily involved in the NK cell IFN-γ response.
A multitude of activation, inhibitory, and cytokine receptors enable NK cells to integrate a range of non-specific inflammatory signals that regulate activation and IFN-γ production as an early innate response. Distinct molecular mechanisms are responsible for IFN-γ secretion by NK cells, depending on the mechanism of activation [50]. Furthermore, different combinations of activation signals synergize to induce enhanced NK cell IFN-γ production compared to a single activation signal [51]. The specific metabolic requirements of NK cells to produce IFN-γ based on activation method further demonstrates the complexity in examining mechanisms underlying this effector function. Nevertheless, targeting conserved changes in energy flux may simplify strategies aimed at purposefully modifying NK cell effector function.
Comparing the metabolic regulation of NK cell and T cell activation and effector functions
Both T cells and NK cells require more energy upon activation and undergo fundamental metabolic reprogramming. Although there are different metabolic needs and responses induced by the plethora of potential activating ligands, one commonality appears to be use of glucose to fuel augmented glycolysis and OXPHOS, including a relative shift toward glycolysis in both cell types upon activation (Tables 1, 2). This metabolic shift is likely in response to increased energy demands for ATP and anabolic responses within a short period of time. Similar anabolic pathways are up-regulated by activated T cells and NK cells. However, while FAS is critical for differentiation and proliferation of T effector cells, it was surprisingly not required for NK cell growth and proliferation [47]. While many similar metabolic pathways are up-regulated upon T cell and NK cell activation, there appears to be cell intrinsic discrepancies in metabolic control points, particularly in response to diverse activating signals. mTOR up-regulates T cell glycolysis through HIF1α and Myc activation, but it is not yet clear how mTOR up-regulates glycolysis in NK cells and it is not known if HIF1α and Myc are common nodes of metabolic control in both NK and T cells.
Control of metabolic pathways and effector functions in NK cells depends on the stimulation method and there are a multitude of ligands to consider. While mTOR promotes NK cell glycolysis following numerous activation methods, IL-12/IL-15 activation up-regulates glycolysis in an mTOR-independent mechanism. Since mTOR and glycolysis can regulate NK and T cell IFN-γ production, the mechanism of action for this effector may be comparable between both cell types. Glycolytic transcriptional regulation of IFN-γ is mediated in T cells by LDHA. However, whether this occurs in NK cells is unknown. The role of GAPDH in post-translational regulation of IFN-γ is well established in T cells, but is likely not imperative for NK cells [21, 44]. Therefore, further research outlining mechanistically how mTOR and glycolysis regulate NK cell IFN-γ transcription is needed.
Similarities in T cell and NK cell metabolism upon activation reflect comparable energetic requirements of both cell types to support proliferation and effector function. The variability in metabolic regulation of NK cell IFN-γ production is likely attributed to the various stimuli to which NK cells respond when mounting an innate response. The evidence to date suggests that adaptive immune responses by T cells rely heavily on glycolysis to produce IFN-γ. Glycolytic intermediates and enzymes are directly involved in controlling T cell IFN-γ production. The metabolic mechanisms underpinning innate NK cell IFN-γ production are poorly characterized and appear to engage both glycolysis and OXPHOS, but this is likely dependent on the method of activation. Nevertheless, metabolic pathways play a fundamental role in controlling both T cell and NK cell activation and effector functions.
Memory
Metabolic regulation of memory T cells
During an inflammatory response, T effector cells are highly energetic to support their proliferation and effector functions. At the peak of an immune response, nutrient competition and absence of stimulatory signals occur when resolution of inflammation is initiated. During this time, the T cell population contracts and generates a memory subset [60]. A landmark study by Pearce et al. identified that the transition to memory T cells is metabolically regulated. A metabolic switch from anoxic glycolysis in T effector cells to FAO is required to generate a memory population (Fig. 3) [55]. To augment FAO, memory T cells increase the expression of the rate-limiting enzyme carnitine palmitoyl transferase 1 (CPT1) [56]. CPT1 inhibition by etomoxir in memory cells reduced rates of OXPHOS, suggesting FAO primarily drives OXPHOS-derived ATP [56].
With enhanced reliance on FAO to meet metabolic demands, memory T cells have increased mitochondrial mass, copy numbers, and spare respiratory capacity (SRC) [56]. These dynamic mitochondrial changes are associated with the metabolic effects of the cytokine IL-15, which also promotes memory cell survival. Buck et al. showed that effector T cells have punctate mitochondria, while memory T cells have fused mitochondria networks, which is associated with improved OXPHOS efficiency [54]. These mitochondrial and metabolic differences in memory T-cells are mediated by enhanced expression of mitochondrial dynamin-related protein (Drp)-1 and optic atrophy (Opa)-1 fusion protein, respectively. Mitochondrial fission in effector T cells results in reduced OXPHOS efficiency and reliance on anoxic glycolysis, while fused mitochondria in memory T cells improves OXPHOS efficiency [54].
Inhibiting FAO reduced SRC in both in vitro cytokine-generated and in vivo virus-induced memory T cells, suggesting FAO augments SRC [56]. Furthermore, FAO and SRC promoted memory T cell survival both in vitro and in vivo [56]. This efficient energy-producing metabolic signature is advantageous during the contraction phase, when nutrients and inflammatory signals are limited [56]. Therefore, SRC enables memory cells to generate more ATP, increase mitochondrial membrane potential, and promote survival upon re-stimulation compared to activated naïve T cells [56]. Lastly, FAO and changes to mitochondrial dynamics are critical for the development, longevity, and secondary response of memory T cells.
Memory T cells do not consume large amounts of exogenous lipids, indicating these fatty acids are not primarily utilized for FAO. Culturing memory T cells in lipid-depleted media did not affect rates of FAO, OXPHOS, nor SRC [53], further suggesting endogenous fatty acids may fuel FAO in these cells (Fig. 3). In addition, inhibiting FAS impaired memory T cell survival. In vitro experiments using 13C-labeled glucose revealed that glucose-derived carbon from catabolic events is synthesized into fatty acids to fuel FAO by memory T cells [53]. Furthermore, culturing memory T cells in low glucose conditions reduced OXPHOS and SRC [53]. Glutamine supplementation did not restore OXPHOS or SRC in low glucose conditions, indicating that glucose primarily fuels FAS in memory T cells [53].
Storage and release of fatty acids from triacylglycerols is imperative for memory T cells. Inhibition of the triacylglycerol synthesis enzyme diacylglycerol acyltransferase reduced SRC [53]. Additionally, silencing the lysosomal acid lipase enzyme, which hydrolyzes lipids to fatty acids, impaired memory T cell development and survival [53]. Overall, these studies demonstrate that memory T cells utilize glucose transport and catabolism to fuel lipid synthesis and, in turn, oxidize de novo synthesized lipids to fuel OXPHOS.
Several key regulators are involved in the metabolic reprogramming of memory T cells (Fig. 3). The adaptor protein tumor necrosis factor receptor-associated factor 6 (TRAF6), which inhibits antigen-specific T cell activation [61], regulates memory T cell development by activating adenosine monophosphate-activated protein kinase (AMPK). AMPK is an intracellular nutrient sensor that can increase FAO [55]. Mice with TRAF6 deficient T-cells mount a robust primary T cell response, but had impaired memory generation. Increasing AMPK-mediated FAO restored memory T cell generation in mice with TRAF6-deficient T cells. AMPK and mTOR are both intracellular nutrient sensors, with opposing roles in metabolic regulation [27]. AMPK up-regulates FAO and OXPHOS to efficiently generate ATP during low nutrient conditions, while mTOR promotes growth and proliferation through enhanced glycolysis and anabolic pathways [27]. Interestingly, mTOR may negatively regulate CD8 memory T cell development. Inhibiting mTOR augmented levels of antigen-specific CD8 memory T cells, in mice following lymphocyte choriomeningitis infection, and in non-human primates vaccinated with modified vaccinia virus [62]. IL-15 also provides a metabolic node that is critical for memory T cell generation. IL-15 increased mitochondrial biogenesis and CPT1 expression, resulting in enhanced memory T cell FAO, SRC, and OXPHOS [56]. Thus, certain cytokines (IL-15) and drugs (metformin or rapamycin) can tip the balance of catabolic and anabolic signals that regulate memory T-cells.
Metabolic regulation of memory NK cells
While classically characterized as innate immune cells, studies show that NK cells can develop memory, enabling enhanced responsiveness upon re-stimulation. Memory NK cells are induced by infection (i.e., cytomegalovirus (CMV) [63]), or by cytokine stimulation (i.e., IL-12/IL-15/IL-18 [3]). Memory development has fundamental implications in the immune response to infections. More importantly, memory NK cells also have translational implications, as improved longevity and potent secondary response can be exploited for NK cell immunotherapies to enhance persistence and function [64].
There is a dearth of information that describes key metabolic regulators involved in generating NK cell memory. The evidence to date links defective mitochondria, autophagy and key metabolic nodes in NK cell memory. It is thought to engage protective mitophagy responses in a subset of cells that become long-lived (i.e., memory). It has been shown that activation of AMPK or inhibition of mTOR promotes mitophagy-dependent NK memory cells as NK cells transition from contraction to the memory phase [65]. It is not yet clear which metabolic pathways or intermediates are involved, but given that AMPK and mTOR are key nodes of cell catabolism and anabolism, it is likely that glucose and/or OXPHOS flux regulates NK cell memory formation through control of mitophagy. Since autophagy/mitophagy can regulate lipid metabolism in other cell types, FAO may also be integral in memory development [66]. Since metabolic pathways contribute to T cell memory, characterizing metabolic pathways in NK cells transitioning to memory cells and determining their role in regulating development and enhanced secondary response should be assessed. Uncovering underlying metabolic mechanisms in NK cell memory would determine how memory is regulated and lead to strategies improving persistence and activation potential for vaccine or adoptive NK cell therapies.
Limiting inflammation
Metabolic regulation of regulatory T cells and regulatory NK cells
The role of regulatory T cells (Tregs) is to limit inflammatory responses and maintain tolerance to self-antigens. To support these functions, Tregs have opposing metabolic needs from effector cells (Fig. 4). Treg generation is highly dependent on mitochondrial FAO, but hindered by enhanced glycolysis. For example, inhibiting FAO impaired Treg differentiation, but not T effector cells [29]. Tregs also rely more on OXPHOS and have greater mitochondrial mass and ROS production than T effector cells [58]. In contrast to T effector cells, Treg differentiation is enhanced by restricting glycolysis or its precursors such as using low glucose including 2DG in cell culture [29, 31]. While Tregs and memory cells both rely on FAO and increased mitochondrial mass, Tregs primarily use exogenous fatty acids for FAO and have low levels of FAS compared to memory subsets. In fact, blocking FAS by inhibiting ACC1 favors Treg differentiation [11].
Interestingly, Treg proliferation and its suppressive function have distinct metabolic needs [12]. In response to TLR signals, Tregs up-regulate Glut1 expression and anaerobic glycolysis to support proliferation and inhibit suppressive functions. In turn, suppressive Tregs utilize lipid oxidation coincident with reduced glycolysis. Together, these studies demonstrate a critical role for FAO and OXPHOS in Treg generation and suppressive function.
Numerous regulators of Treg function also modulate cell metabolism. AMPK plays an integral role in integrating nutrient status and Treg metabolism by increasing FAO, where AMPK activation promotes Treg differentiation both in vivo and in vitro (Fig. 4) [29]. Likewise, mTOR inhibition promotes Treg differentiation [29], whereas its activation through TLR signaling inhibits its suppressive function [12]. The transcription factor FOXP3 is influenced by cell metabolism and is a master regulator of Treg development and function [67]. FOXP3 transcriptional controls are linked to reduced expression of glycolytic enzymes and increased expression of FAO enzymes. FOXP3 activation coincides with reduced mTOR activity, glucose uptake, anaerobic glycolysis, and promotes mitochondrial lipid oxidation and rate of oxygen consumption. In essence, FOXP3 is a node in Treg development and function by tipping the metabolic balance toward FAO.
PTEN is an intracellular phosphatase that supports Treg function and confers protection from autoimmunity. Mice with a Treg-specific PTEN deletion have impaired function, resulting in systemic autoimmunity and lymphoproliferative disease [59]. PTEN supports suppressive function by inhibiting mTOR signaling, stabilizing FOXP3 expression, and promoting FAO. PTEN deficient Tregs have impaired mitochondrial function, characterized by reduced mitochondrial mass, and membrane potential (Fig. 4). Furthermore, PTEN−/− Tregs up-regulated glycolysis following TCR stimulation. PP2A is another intracellular phosphatase that is important for Treg function by suppressing mTOR activity [68]. Treg-specific PP2A−/− cells have increased basal and maximal anaerobic glycolytic rates comparable to WT cells, mediated by mTOR.
Very little is known about regulatory NK cells. Regulatory NK cells have a role in limiting autoimmune disease, whereas aberrant NK cell activation can contribute to its pathogenesis [14, 15] However, the underlying metabolic regulation of these distinct functional NK cell subsets and whether metabolic manipulation of these NK cell subsets can affect the course of autoimmune diseases, as it does in T cells, are important unanswered questions.
Inhibitory signals alter T cell metabolism
In addition to specialized regulatory cells, signals that help resolve T cell effector function counterbalance prolonged or excessive inflammation. Changes in cellular metabolic flux can integrate inhibitory T cell signals. For example, nutrient availability (at the peak of T cell activation) may promote inflammatory resolution, where AMPK is activated in a low glucose local environment [69].
Numerous inhibitory compounds alter T cell metabolism, including indoleamine 2,3-dioxygenase (IDO), an enzyme involved in tryptophan catabolism [70, 71]. IDO inhibits T cell Glut1 expression and glucose uptake [72]. Furthermore, IDO down-regulated FAS enzymes ATP-citrate lyase and ACC1, which are critical for T effector function [71]. Programmed death-1 (PD1) is a checkpoint receptor expressed by T cells that inhibits effector function, maintains tolerance, and limits the inflammatory response [73]. The pathological up-regulation of PD1 occurs within a tumor or during chronic viral infection, resulting in impaired T effector functions [74, 75]. PD1 ligation promotes conversion of T cell metabolism from an anaerobic glycolytic state toward a more oxidative state upon activation [76]. Additionally, PD1 ligation inhibited glucose and glutamine uptake, and subsequent catabolism, while up-regulating lipolysis and FAO. Similarly cytotoxic T-lymphocyte-associated antigen 4 (CTLA4), another checkpoint receptor, also inhibits glycolytic metabolism, but without up-regulating FAO [76]. Therefore, inhibitory signals suppress T effector function by suppressing T cell glycolytic and anabolic pathways.
Limiting NK cell effector functions
Metabolic flux can also inhibit NK cell function. The evidence to date supports a role for AMPK and mTOR pathways in limiting NK cell function. One study reported that AMPK activity correlates with impaired function in senescent NK cells with high inhibitory receptor KLRG1 expression [77]. Not only do KLRG1bright NK cells have spontaneous AMPK activation, but KLRG1 ligation activates AMPK which negatively regulates NK cell IFN-γ production, cytotoxicity, and proliferation [78]. Immunosuppressive cytokines, such as transforming growth factor-beta (TGF-β) can inhibit NK cell function. Deletion and TGF-β signaling reduced NK cell cytotoxicity and IFN-γ production both in vitro and in vivo [79]. TGF-β signaling inhibited IL-15-induced up-regulation of both anaerobic glycolysis and OXPHOS, an effect that occurs via mTOR inhibition [79]. Taken together, these results suggest that TGF-β inhibits IL-15-induced NK cell effector functions through mTOR inhibition, demonstrating that metabolic pathways can mediate inhibitory NK cell signals.
Comparison of NK cell and T cell inhibition
Similar metabolic by-products, inhibitory signals, and intracellular regulators known to promote Treg suppressive function or inhibit T effector functions also suppress NK cell effector functions. For instance, lactic acid secreted by tumor cells impaired both NK and T cell anti-tumor responses, including IFN-γ production, promoting tumor growth. Furthermore, elevated levels of lactic acid inhibit intracellular ATP levels in both cell types upon activation [80]. In addition, IDO and PD1, which mediate inhibitory signals that coincide with changes in metabolic flux in T cells function, also impair NK cell effector functions [81, 82]. However, the effects of IDO and checkpoint inhibitor pathways on NK cell metabolism are ill-defined. Similar to T cells, the intracellular phosphatase PTEN negatively regulates NK cell cytotoxicity. Overexpression of PTEN reduced murine and human NK cell cytotoxicity by suppressing the PI3K/AKT pathway, a known mTOR activator. Inhibition of PTEN enhances NK cell cytotoxicity against tumor targets [83, 84]. PP2A activity also affects NK cell function. Promoting PP2A activation in NK cells suppressed cytotoxicity, granzyme B expression, and IFN-γ production [85, 86]. Inhibiting PP2A increased NK cell cytotoxicity of metastasis in a B16 melanoma model [87]. Since both PTEN and PP2A enhanced T cell mitochondrial oxidation and mitigate anaerobic glycolysis to sustain Treg function, it is plausible that similar metabolic processes are engaged to alter NK cell cytotoxic function.
T effector cell inhibition or enhanced Treg suppressive function is associated with a metabolic conversion from glycolytic and anabolic pathways to lipid oxidation. NK cell inhibition is regulated by inhibiting mTOR or activating AMPK, indicating similar metabolic reprogramming in T cells may regulate NK cell inhibition. While energy-sensing molecules inhibit NK cell function, it is not yet clear if distinct metabolic pathways are altered in response to specific inhibitory signals. Additionally, determining the metabolic state and regulation of NK cell subsets in immunosuppressive states, including senescence and tumor microenvironments is positioned to advance cell-based therapeutic strategies.
Endocrine and pharmacological modifiers of T and NK cell metabolism
Endocrine factors such as insulin play a critical role in glucose uptake and glucose flux in many cell types, including, lymphocytes [88]. The metabolic consequences of insulin are facilitated by the insulin receptor-dependent signaling and glucose transporters [89]. Induction of the insulin signaling cascade in activated T cells occurs following CD28 signaling upon antigen presentation, leading to PI3K-dependent Akt phosphorylation, up-regulation of GLUT1 and subsequent increase in glucose uptake, glycolysis and lactate production [24]. Using an inducible insulin receptor-knockdown and adoptive transfer approach, Fischer et al. demonstrated that silencing the insulin receptor reduced glucose transport, glycolysis, migration, and IFN-γ expression, and enhanced apoptosis in activated CD4 T cells [88]. Insulin receptor deficiency also reduced proliferation rates in both activated CD4 and CD8 T lymphocytes when compared to controls. In CD8 T-cells, knockdown of the insulin receptor also reduced cytotoxic alloantigen responses. Furthermore, insulin receptor deficiency did not impair thymocyte development, nor Treg number and suppressive capacity [88]. Therefore, insulin does not equally affect all T cell subsets. Overall, these findings suggest that the insulin signaling cascade contributes to effector T cell glucose flux. Similar to effector T cells, NK cells express the insulin receptor, but little is known regarding its role in NK cell physiology [90]. Further work is needed to determine whether NK and T cells share physiological commonalities regarding the role of insulin.
Rapamycin and metformin are two compounds that have profound metabolic effects and can influence immune cell metabolism. Rapamycin was discovered as an antifungal metabolite with immunosuppressive and anti-proliferative effects in mammalian cells and is a well-known inhibitor of mTOR [91]. In CD8 T cells, inhibiting mTOR with rapamycin transcriptionally regulates T cell fate by promoting memory cell formation [92]. Enhanced mTOR kinase activity with IL-12 treatment and antigen stimulation in naïve CD8 T cells induced the expression of the transcription factor T-bet, which leads to short-lived effector cell formation. Conversely, inhibiting mTOR with rapamycin treatment dampened T-bet expression, while enhancing eomesodermin expression, a transcription factor known to promote memory cell precursors. Rapamycin has historically been considered an immunosuppressive drug, but its immunostimulatory effects on memory CD8 cells were revealed upon adoptive transfer of rapamycin treated CD8 T cells, which had enhanced antigen-recall responses [62]. Enhanced memory cell formation due to rapamycin treatment was also shown in both murine and primate models virally infected with acute lymphocytic choriomeningitis and vaccinia, respectively [62]. These results demonstrate that mTOR is involved in determining CD8 T cell fate, whereby rapamycin treatment favors a memory phenotype.
Few studies have examined the effects of rapamycin on NK cell function. Splenic NK cells treated with rapamycin significantly decreased IFN-γ production, glucose uptake, and inhibited IL-2/IL-12-mediated up-regulation of granzyme B expression [44]. Similarly, rapamycin treated human NK cells had decreased glucose uptake and IFN-γ production, along with impaired CD98 expression, which is a subunit of the neutral amino acid transporter LAT-1 [45]. Rapamycin-induced mTOR inhibition has also been shown to inhibit NK cell proliferation, degranulation, and cytotoxicity [79]. Overall, these studies demonstrate that rapamycin treatment may not only affect NK cell metabolism by inhibiting glucose uptake and possibly affect amino acid transport but can impair NK cell cytotoxic function.
Metformin is commonly prescribed during prediabetes and type 2 diabetics since can alter lipid and glucose metabolism and acts as an insulin sensitizer by reducing hepatic glucose production and promoting glucose uptake in skeletal muscle [93]. The insulin-sensitizing effects of metformin are linked to AMP-activated protein kinase-acetyl-CoA carboxylase-mediated changes in lipid metabolism and the balance between lipogenesis and FAO in metabolic tissues such as the liver [94, 95]. Since AMPK activation and increased FAO also promote Treg differentiation, it is not surprising that metformin treatment of naïve T cells impairs Th17 differentiation [96]. In a murine model of asthma, in vivo treatment with metformin decreased Glut1 expression and increased the number and percentage of Tregs [29]. Similarly, mice treated with metformin had significant improvements in clinical severity and mortality during acute graft versus host disease, which was associated with metformin-mediated reductions in Th1/Th17 and increased Th2 and Treg populations [96]. In vitro experiments also showed that Th17 cells treated with metformin can skew towards characteristics of Treg cells, demonstrating its therapeutic potential in modulating CD4 T cell differentiation relevant to autoimmune diseases. The effects of metformin treatment on NK cell metabolism and function is currently unknown. Therefore, further work is needed to determine if metformin alters NK cell function and whether these effects are mediated through changes in cellular metabolism.
Conclusion
T cells and NK cells share common metabolic nodes that influence cell development, activation, effector, memory and regulatory function. Coaxing changes in cell metabolism may have consequences that span innate and adaptive immune responses. Cell intrinsic or ligand specific differences in how metabolic flux controls cell fate in NK and T cell subsets should be considered.
References
Bodduluru LN, Kasala ER, Madhana RM, Sriram CS. Natural killer cells: the journey from puzzles in biology to treatment of cancer. Cancer Lett. 2015;357(2):454–67. https://doi.org/10.1016/j.canlet.2014.12.020.
Vivier E, Tomasello E, Baratin T, Walzer T, Ugolini S. Functions of natural killer cells. Nat Immunol. 2008;9:503–10.
Cooper MA, Elliott JM, Keyel PA, Yang L, Carrero JA, Yokoyama WM. Cytokine-induced memory-like natural killer cells. Proc Natl Acad Sci USA. 2009;106(6):1915–9.
Chen L, Flies DB. Molecular mechanisms of T cell co-stimulation and co-inhibition. Nat Rev Immunol. 2013;13(4):227–42. https://doi.org/10.1038/nri3405.
Pearce EL, Mullen AC, Matins GA, Krawczyk CM, Hutchins AS, Zediak VP, et al. Control of effector CD8+ T cell function by the transcription factor eomesodermin. Science. 2003;302(5647):1041–3.
Jiao L, Gao X, Joyee AG, Zhao L, Qiu H, Yang M, et al. NK cells promote type 1 T cell immunity through modulating the function of dendritic cells during intracellular bacterial infection. J Immunol. 2011;187(1):401–11. https://doi.org/10.4049/jimmunol.1002519.
Cook KD, Waggoner SN, Whitmire JK. NK cells and their ability to modulate T cells during virus infections. Crit Rev Immunol. 2014;34(5):359–88.
Ye L, Jiang B, Deng J, Du J, Xiong W, Guan Y, et al. IL-37 alleviates rheumatoid arthritis by suppressing IL-17 and IL-17-triggering cytokine production and limiting Th17 cell proliferation. J Immunol. 2015;194(11):5110–9. https://doi.org/10.4049/jimmunol.1401810.
Langrish CL, Chen Y, Blumenschein WM, Mattson J, Basham B, Sedgwick JD, et al. IL-23 drives a pathogenic T cell population that induces autoimmune inflammation. J Exp Med. 2005;201(2):233–40.
Venkatesha SH, Dudics S, Weingartner E, So EC, Pedra J, Moudgil KD. Altered Th17/Treg balance and dysregulated IL-1β response influence susceptibility/resistance to experimental autoimmune arthritis. Int J Immunopathol Pharmacol. 2015;28(3):318–28. https://doi.org/10.1177/0394632015595757.
Berod L, Friedrich C, Nandan A, Freitag J, Hagemann S, Harmrolfs K, et al. De novo fatty acid synthesis controls the fate between regulatory T and T helper 17 cells. Nat Med. 2014;20(11):1327–33.
Gerriets VA, Kishton RJ, Johnson MO, Cohen S, Siska PJ, Nichols AG, et al. Foxp3 and Toll-like receptor signaling balance Treg cell anabolic metabolism for suppression. Nat Immunol. 2016;17(12):1459–66.
Macintyre AN, Gerriets VA, Nichols AG, Michalek RD, Rudolph MC, Deoliveira D, et al. The glucose transporter Glut1 is selectively essential for CD4 T cell activation and effector function. Cell Metab. 2014;20(1):61–72.
Dungan LS, McGuinness NC, Boon L, Lynch MA, Mills KH. Innate IFN-γ promotes development of experimental autoimmune encephalomyelitis: a role for NK cells and M1 macrophages. Eur J Immunol. 2014;44(10):2903–17.
Lu L, Ikizawa K, Hu D, Werneck MB, Wucherpfennig KW, Cantor H. Regulation of activated CD4+ T cells by NK cells via the Qa-1-NKG2A inhibitory pathway. Immunity. 2007;26(5):593–604.
O’Neill LA, Kishton RJ, Rathmell J. A guide to immunometabolism for immunologists. Nat Rev Immunol. 2016;16(9):553–65. https://doi.org/10.1038/nri.2016.70.
Hui S, Ghergurovich JM, Morscher RJ, Jang C, Teng X, Lu W, et al. Glucose feeds the TCA cycle via circulating lactate. Nature. 2017;551(7678):115–8. https://doi.org/10.1038/nature24057.
Ciofani M, Zuniga-Pflucker JC. Notch promotes survival of pre—T cells at the beta-selection checkpoint by regulating cellular metabolism. Nat Immunol. 2005;6(9):881–8.
Swainson L, Kinet S, Manel N, Battini JL, Sitbon M, Taylor N. Glucose transporter 1 expression identifies a population of cycling CD4+ CD8+ human thymocytes with high CXCR4-induced chemotaxis. Proc Natl Acad Sci USA. 2005;102(36):12867–72.
Vigano MA, Ivanek R, Balwierz P, Berninger P, van Nimwegen E, Karjalainen K, et al. An epigenetic profile of early T-cell development from multipotent progenitors to committed T-cell descendants. Eur J Immunol. 2014;44(4):1181–93.
Peng M, Yin N, Chhangawala S, Xu K, Leslie CS, Li MO. Aerobic glycolysis promotes T helper 1 cell differentiation through an epigenetic mechanism. Science. 2016;354(6311):481–4.
Chang CH, Curtis JD, Maggi LBJ, Faubert B, Villarino AV, O’Sullivan D, et al. Posttranscriptional control of T cell effector function by aerobic glycolysis. Cell. 2013;153(6):1239–51. https://doi.org/10.1016/j.cell.2013.05.016.
Wang R, Dillon CP, Shi LZ, Milasta S, Carter R, Finkelstein D, et al. The transcription factor Myc controls metabolic reprogramming upon T lymphocyte activation. Immunity. 2011;35(6):871–2.
Frauwirth KA, Riley JL, Harris MH, Parry RV, Rathmell JC, Plas DR, et al. The CD28 signaling pathway regulates glucose metabolism. Immunity. 2002;16(6):769–77.
Chiossone L, Chaix J, Fuseri N, Roth C, Vivier E, Walzer T. Maturation of mouse NK cells is a 4-stage developmental program. Blood. 2009;113(22):5488–96. https://doi.org/10.1182/blood-2008-10-187179.
Marcais A, Cherfils-Vicini J, Viant C, Degouve S, Viel S, Fenis A, et al. The metabolic checkpoint kinase mTOR is essential for interleukin-15 signaling during NK cell development and activation. Nat Immunol. 2014;15(8):749–57.
Shaw RJ. LKB1 and AMP-activated protein kinase control of mTOR signalling and growth. Acta Physiol (Oxf). 2009;196(1):65–80. https://doi.org/10.1111/j.1748-1716.2009.01972.x.
Blagih J, Coulombe F, Vincent EE, Dupuy F, Galicia-Vazquez G, Yurchenko E, et al. The energy sensor AMPK regulates T cell metabolic adaptation and effector responses in vivo. Immunity. 2015;42(1):41–54.
Michalek RD, Gerriets VA, Jacobs SR, Macintyre AN, Mason NJ, Mason EF, et al. Cutting edge: distinct glycolytic and lipid oxidative metabolic programs are essential for effector and regulatory CD4+ T cell subsets. J Immunol. 2011;186(6):3299–303.
Lee JS, Walsh MC, Hoehn KL, James DE, Wherry EJ, Choi Y. Regulator of fatty acid metabolism, acetyl coenzyme a carboxylase 1, controls T cell immunity. J Immunol. 2014;192(7):3190–9.
Shi LZ, Wang R, Huang G, Vogel P, Neale G, Green DR, et al. HIF1alpha-dependent glycolytic pathway orchestrates a metabolic checkpoint for the differentiation of TH17 and Treg cells. J Exp Med. 2011;208(7):1367–76.
Mahnke J, Schumacher V, Ahrens S, Käding N, Feldhoff LM, Huber M, et al. Interferon regulatory factor 4 controls TH1 cell effector function and metabolism. Sci Rep. 2016;6:35521.
Kong X, Banks A, Liu T, Kazak L, Rao RR, Cohen P, et al. IRF4 is a key thermogenic transcriptional partner of PGC-1α. Cell. 2014;158(1):69–83. https://doi.org/10.1016/j.cell.2014.04.049.
Eguchi J, Wang X, Yu S, Kershaw EE, Chiu PC, Dushay J, et al. Transcriptional control of adipose lipid handling by IRF4. Cell Metab. 2011;13(3):249–59.
Cavallari JF, Fullerton MD, Duggan BM, Foley KP, Denou E, Smith BK, et al. Muramyl dipeptide-based postbiotics mitigate obesity-induced insulin resistance via IRF4. Cell Metab. 2017;25(5):1063–74. https://doi.org/10.1016/j.cmet.2017.03.021.
Carr EL, Kelman A, Wu GS, Gopaul R, Senkevitch E, Aghvanyan A, et al. Glutamine uptake and metabolism are coordinately regulated by ERK/MAPK during T lymphocyte activation. J Immunol. 2010;185(2):1037–44. https://doi.org/10.4049/jimmunol.0903586.
Hayashi K, Jutabha P, Endou H, Sagara H, Anzai N. LAT1 is a critical transporter of essential amino acids for immune reactions in activated human T cells. J Immunol. 2013;191(8):4080–5. https://doi.org/10.4049/jimmunol.1300923.
Sinclair LV, Rolf J, Emslie E, Shi YB, Taylor PM, Cantrell DA. Control of amino-acid transport by antigen receptors coordinates the metabolic reprogramming essential for T cell differentiation. Nat Immunol. 2013;14(5):500–8. https://doi.org/10.1038/ni.2556.
Ma EH, Bantug G, Griss T, Condotta S, Johnson RM, Samborska B, et al. Serine is an essential metabolite for effector T cell expansion. Cell Metab. 2017;25(2):345–57. https://doi.org/10.1016/j.cmet.2016.12.011.
Klysz D, Tai X, Robert PA, Craveiro M, Cretenet G, Oburoglu L, et al. Glutamine-dependent alpha-ketoglutarate production regulates the balance between T helper 1 cell and regulatory T cell generation. Sci Signal. 2015;8(396):ra97. https://doi.org/10.1126/scisignal.aab2610.
Nakaya M, Xiao Y, Zhou X, Chang JH, Chang M, Cheng X, et al. Inflammatory T cell responses rely on amino acid transporter ASCT2 facilitation of glutamine uptake and mTORC1 kinase activation. Immunity. 2014;40(5):692–705. https://doi.org/10.1016/j.immuni.2014.04.007.
Ho PC, Bihuniak JD, Macintyre AN, Staron M, Liu X, Amezquita R, et al. Phosphoenolpyruvate is a metabolic checkpoint of anti-tumour T cell responses. Cell. 2015;162(6):1217–28.
Salerno F, Guislain A, Cansever D, Wolers MC. TLR-mediated innate production of IFN-γ by CD8+ T cells is independent of glycolysis. J Immunol. 2016;196(9):3695–705.
Donnelly RP, Loftus RM, Keating SE, Liou KT, Biron CA, Gardiner CM, et al. mTORC1-dependent metabolic reprogramming is a prerequisite for NK cell effector function. J Immunol. 2014;193:4477–84.
Keating SE, Zaiatz-Bittencourt V, Loftus RM, Keane C, Brennan K, Finlay DK, et al. Metabolic reprogramming supports IFN-γ production by CD56bright NK cells. J Immunol. 2016;196(6):2552–60. https://doi.org/10.4049/jimmunol.1501783.
Keppel MP, Saucier N, Mah AY, Vogel TP, Cooper MA. Activation-specific metabolic requirements for NK cell IFN-g production. J Immunol. 2015;194(4):1954–62.
Assmann N, O’Brien KL, Donnelly RP, Dyck L, Zaiatz-Bittencourt V, Loftus RM, et al. Srebp-controlled glucose metabolism is essential for NK cell functional responses. Nat Immunol. 2017;18(11):1197–206. https://doi.org/10.1038/ni.3838.
Mao Y, van Hoef V, Zhang X, Wennerberg E, Lorent J, Witt K, et al. IL-15 activates mTOR and primes stress-activated gene-expression leading to prolonged anti-tumor capacity of NK cells. Blood. 2016;128(11):1475–89. https://doi.org/10.1182/blood-2016-02-698027.
Cham CM, Gajewski TF. Glucose availability regulates IFN-gamma production and p70S6 kinase activation in CD8+ effector T cells. J Immunol. 2005;174(8):4670–7.
Walker W, Aste-Amezaga M, Kastelein RA, Trinchieri G, Hunter CA. IL-18 and CD28 use distinct molecular mechanisms to enhance NK cell production of IL-12-induced IFN-gamma. J Immunol. 1999;162(10):5894–901.
Nielsen CM, Wolf AS, Goodier MR, Riley EM. Synergy between common γ chain family cytokines and IL-18 potentiates innate and adaptive pathways of NK cell activation. Front Immunol. 2016;7(101). https://doi.org/10.3389/fimmu.2016.00101.
Tsurutani N, Mittal P, St Rose MC, Ngoi SM, Svedova J, Menoret A, et al. Costimulation endows immunotherapeutic CD8 T cells with IL-36 responsiveness during aerobic glycolysis. J Immunol. 2016;196(1):124–34.
O’Sullivan D, van der Windt GJ, Huang SC, Curtis JD, Chang CH, Buck MD, et al. Memory CD8(+) T cells use cell-intrinsic lipolysis to support the metabolic programming necessary for development. Immunity. 2014;41(1):75–88.
Buck MD, O’Sullivan D, Klein Geltink RI, Curtis JD, Chang CH, Sanin DE, et al. Mitochondrial dynamics controls T cell fate through metabolic programming. Cell. 2016;166(1):63–76.
Pearce EL, Walsh MC, Cejas PJ, Harms GM, Shen H, Wang LS, et al. Enhancing CD8 T-cell memory by modulating fatty acid metabolism. Nature. 2009;460(7251):103–7.
van der Windt GJ, Everts B, Chang CH, Curtis JD, Freitas TC, Amiel E, et al. Mitochondrial respiratory capacity is a critical regulator of CD8+ T cell memory development. Immunity. 2012;31(1):68–78.
Gubser PM, Bantug GR, Razik L, Fischer M, Dimeloe S, Hoenger G, et al. Rapid effector function of memory CD8+ T cells requires an immediate-early glycolytic switch. Nat Immunol. 2013;14(10):1064–72.
Beier UH, Angelin A, Akimova T, Wang LS, Liu Y, Xiao H, et al. Essential role of mitochondrial energy metabolism in Foxp3+ T-regulatory cell function and allograft survival. FASEB J. 2015;29(6):2315–26.
Shrestha S, Yang K, Guy C, Vogel P, Neale G, Chi H. Treg cells require the phosphatase PTEN to restrain TH1 and TFH cell responses. Nat Immunol. 2015;16(2):178–87.
Prlic M, Williams MA, Bevan MJ. Requirements for CD8 T-cell priming, memory generation and maintenance. Curr Opin Immunol. 2007;19(3):315–9.
King CG, Kobayashi T, Cejas PJ, Kim T, Yoon K, Kim GK, et al. TRAF6 is a T cell-intrinsic negative regulator required for the maintenance of immune homeostasis. Nat Med. 2006;12(9):1088–92.
Araki K, Turner AP, Shaffer VO, Gangappa S, Keller SA, Bachmann MF, et al. mTOR regulates memory CD8 T-cell differentiation. Nature. 2009;460(7251):108–12. https://doi.org/10.1038/nature08155.
Sun JC, Beilke JN, Lanier LL. Adaptive immune features of natural killer cells. Nature. 2009;457(7229):557–61. https://doi.org/10.1038/nature07665.
Romee R, Rosario M, Berrien-Elliott MM, Wagner JA, Jewell BA, Schappe T, et al. Cytokine-induced memory-like natural killer cells exhibit enhanced responses against myeloid leukemia. Sci Transl Med. 2016;8(357):357ra123.
O’Sullivan TE, Johnson LR, Kang HH, Sun JC. BNIP3- and BNIPL-mediated mitophagy promotes the generation of natural killer cell memory. Immunity. 2015;43(2):331–42.
Singh R, Kaushik S, Wang Y, Xiang Y, Novak I, Komatsu M, et al. Autophagy regulates lipid metabolism. Nature. 2009;458(7242):1131–5. https://doi.org/10.1038/nature07976.
Fontenot JD, Gavin MA, Rudensky AY. Foxp3 programs the development and function of CD4+ CD25+ regulatory T cells. Nat Immunol. 2003;4(4):330–6.
Apostolidis SA, Rodriguez-Rodriguez N, Suarez-Fueyo A, Dioufa N, Ozcan E, Crispin JC, et al. Protein phosphatase 2A is requisite for the function of regulatory T cells. Nat Immunol. 2016;17(5):556–64. https://doi.org/10.1038/ni.3390.
Lanna A, Henson SM, Escors D, Akbar AN. AMPK-TAB1 activated p38 drives human T cell senescence. Nat Immunol. 2014;15(10):965–72.
Frumento G, Rotondo R, Tonetti M, Damonte G, Benatti U, Ferrara GB. Tryptophan-derived catabolites are responsible for inhibition of T and natural killer cell proliferation induced by indoleamine 2,3-dioxygenase. J Exp Med. 2002;196(4):459–68.
Eleftheriadis T, Pissas G, Antoniadi G, Liakopoulos V, Stefanidis I. Indoleamine 2,3-dioxygenase depletes tryptophan, activates general control non-derepressible 2 kinase and down-regulates key enzymes involved in fatty acid synthesis in primary human CD4+ T cells. Immunology. 2015;146(2):292–300.
Eleftheriadis T, Pissas G, Yiannaki E, Markala D, Arampatzis S, Antoniadi G, et al. Inhibition of indoleamine 2,3-dioxygenase in mixed lymphocyte reaction affects glucose influx and enzymes involved in aerobic glycolysis and glutaminolysis in alloreactive T-cells. Hum Immunol. 2013;74(12):1501–9.
Gianchecchi E, Delfino DV, Fierabracci A. Recent insights into the role of the PD-1/PD-L1 pathway in immunological tolerance and autoimmunity. Autoimmun Rev. 2013;12(11):1091–100. https://doi.org/10.1016/j.autrev.2013.05.003.
Barber DL, Wherry EJ, Masopust D, Zhu B, Allison JP, Sharpe AH, et al. Restoring function in exhausted CD8 T cells during chronic viral infection. Nature. 2006;439(7077):682–7.
Zhang L, Gajewski TF, Kline J. PD-1/PD-L1 interactions inhibit antitumor immune responses in a murine acute myeloid leukemia model. Blood. 2009;114(8):1545–52. https://doi.org/10.1182/blood-2009-03-206672.
Patsoukis N, Bardhan K, Chatterjee P, Sari D, Liu B, Bell LN, et al. PD-1 alters T-cell metabolic reprogramming by inhibiting glycolysis and promoting lipolysis and fatty acid oxidation. Nat Commun. 2015;26(6):6692.
Muller-Durovic B, Lanna A, Polaco Covre L, Mills RS, Henson SM, Akbar AN. Killer cell lectin-like receptor G1 inhibits NK cell function through activation of adenosine 5′-monophosphate-activated protein kinase. J Immunol. 2016;197(7):2891–9.
Kim KY, Kim JK, Han SH, Lim JS, Kim KI, Cho DH, et al. Adiponectin is a negative regulator of NK cell cytotoxicity. J Immunol. 2006;176(10):5958–64.
Viel S, Marçais A, Guimaraes FS, Loftus R, Rabilloud J, Grau M, et al. TGF-β inhibits the activation and functions of NK cells by repressing the mTOR pathway. Sci Signal. 2016;9(415):ra19.
Brand A, Singer K, Koehl GE, Kolitzus M, Schoenhammer G, Thiel A, et al. LDHA-associated lactic acid production blunts tumor immunosurveillance by T and NK cells. Cell Metab. 2016;24(5):657–71.
Della Chiesa M, Carlomagno S, Frumento G, Balsamo M, Cantoni C, Conte R, et al. The tryptophan catabolite L-kynurenine inhibits the surface expression of NKp46- and NKG2D-activating receptors and regulates NK-cell function. Blood. 2006;108(13):4118–25.
Beldi-Ferchiou A, Lambert M, Dogniaux S, Vély F, Vivier E, Olive D, et al. PD-1 mediates functional exhaustion of activated NK cells in patients with Kaposi sarcoma. Oncotarget. 2016;7(45):72961–77. https://doi.org/10.18632/oncotarget.12150.
Briercheck EL, Trotta R, Chen L, Hartlage AS, Cole JP, Cole TD, et al. PTEN is a negative regulator of NK cell cytolytic function. J Immunol. 2015;194(4):1832–40. https://doi.org/10.4049/jimmunol.1401224.
Ali AK, Nandagopal N, Lee SH. IL-15–PI3K–AKT–mTOR: a critical pathway in the life journey of natural killer cells. Front Immunol. 2015;6:335. https://doi.org/10.3389/fimmu.2015.00355.
Trotta R, Ciarlariello D, Dal Col J, Mao H, Chen L, Briercheck E, et al. The PP2A inhibitor SET regulates granzyme B expression in human natural killer cells. Blood. 2011;117(8):2378–84. https://doi.org/10.1182/blood-2010-05-285130.
Trotta R, Ciarlariello D, Dal Col J, Allard J, Neviani P, Santhanam R, et al. The PP2A inhibitor SET regulates natural killer cell IFN-gamma production. J Exp Med. 2007;204(10):2397–405.
Kawada M, Kawatsu M, Masuda T, Ohba S, Amemiya M, Kohama T, et al. Specific inhibitors of protein phosphatase 2A inhibit tumor metastasis through augmentation of natural killer cells. Int Immunopharmacol. 2003;3(2):179–88.
Fischer HJ, Sie C, Schumann E, Witte AK, Dressel R, van den Brandt J, et al. The insulin receptor plays a critical role in T cell function and adaptive immunity. J Immunol. 2017;198(5):1910–20. https://doi.org/10.4049/jimmunol.1601011.
Maratou E, Dimitriadis G, Kollias A, Boutati E, Lambadiari V, Mitrou P, et al. Glucose transporter expression on the plasma membrane of resting and activated white blood cells. Eur J Clin Investig. 2007;37(4):282–90. https://doi.org/10.1111/j.1365-2362.2007.01786.x.
Amer J, Salhab A, Noureddin M, Doron S, Abu-Tair L, Ghantous R, et al. Insulin signaling as a potential natural killer cell checkpoint in fatty liver disease. Hepatol Commun. 2018;2(3):285–98. https://doi.org/10.1002/hep4.1146.
Li J, Kim SG, Blenis J. Rapamycin: one drug, many effects. Cell Metab. 2014;19(3):373–9. https://doi.org/10.1016/j.cmet.2014.01.001.
Rao RR, Li Q, Odunsi K, Shrikant PA. The mTOR kinase determines effector versus memory CD8+ T cell fate by regulating the expression of transcription factors T-bet and eomesodermin. Immunity. 2010;32(1):67–78. https://doi.org/10.1016/j.immuni.2009.10.010.
Natali A, Ferrannini E. Effects of metformin and thiazolidinediones on suppression of hepatic glucose production and stimulation of glucose uptake in type 2 diabetes: a systematic review. Diabetologia. 2006;49(3):434–41. https://doi.org/10.1007/s00125-006-0141-7.
Gualdoni GA, Mayer KA, Goschl L, Boucheron N, Ellmeier W, Zlabinger GJ. The AMP analog AICAR modulates the Treg/Th17 axis through enhancement of fatty acid oxidation. FASEB J. 2016;30(11):3800–9. https://doi.org/10.1096/fj.201600522R.
Fullerton MD, Galic S, Marcinko K, Sikkema S, Pulinilkunnil T, Chen ZP, et al. Single phosphorylation sites in Acc1 and Acc2 regulate lipid homeostasis and the insulin-sensitizing effects of metformin. Nat Med. 2013;19(12):1649–54. https://doi.org/10.1038/nm.3372.
Park MJ, Lee SY, Moon SJ, Son HJ, Lee SH, Kim EK, et al. Metformin attenuates graft-versus-host disease via restricting mammalian target of rapamycin/signal transducer and activator of transcription 3 and promoting adenosine monophosphate-activated protein kinase-autophagy for the balance between T helper 17 and Tregs. Transl Res J Lab Clin Med. 2016;173:115–30. https://doi.org/10.1016/j.trsl.2016.03.006.
Acknowledgements
Supported by an operating Grant to JDS from Natural Sciences and Engineering Research Council (NSERC) (Grant no. 435474-2013). JDS holds a Canada Research Chair in Metabolic Inflammation. AAA holds a Canada Research Chair in Natural Immunity and NK Cell Function. Sophie M. Poznanski holds an Ontario Women’s Health Scholars Award funded by the Ontario Ministry of Health and Long-Term Care.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare no conflict of interest.
Additional information
Responsible Editor: John Di Battista.
Rights and permissions
About this article
Cite this article
Poznanski, S.M., Barra, N.G., Ashkar, A.A. et al. Immunometabolism of T cells and NK cells: metabolic control of effector and regulatory function. Inflamm. Res. 67, 813–828 (2018). https://doi.org/10.1007/s00011-018-1174-3
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00011-018-1174-3