Abstract
The carotid body (CB) is the major arterial chemoreceptor responsible for the detection of acute decreases in O2 tension (hypoxia) in arterial blood that trigger hyperventilation and sympathetic activation. The CB contains O2-sensitive glomus (chief) cells, which respond to hypoxia with the release of transmitters to activate sensory nerve fibers impinging upon the brain respiratory and autonomic centers. During exposure to sustained hypoxia (for weeks or months), the CB grows several-fold in size, a response associated with acclimatization to high altitude or to medical conditions presenting hypoxemia. Here, I briefly present recent advances on the mechanisms underlying glomus cell sensitivity to hypoxia, in particular the role of mitochondrial complex I in acute oxygen sensing. I also summarize the properties of adult CB stem cells and of glomus cell–stem cell synapses, which contribute to CB hypertrophy in chronic hypoxia. A note on the relationship between hypoxic CB growth and tumorigenesis is included. Finally, the medical implications of CB pathophysiology are discussed.
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Introduction
Oxygen (O2) sensing is fundamental for life of aerobic organisms and particularly for mammals, as it is necessary for their adaptation to environments with changing O2 tension (PO2) or pathophysiological conditions presenting a decrease in blood PO2 (hypoxemia). Acute changes in PO2 are detected by chemoreceptor, O2-sensitive, cells in organs of the homeostatic O2-sensing system (Weir et al. 2005). Among these organs, the carotid body (CB) has a special significance, as it is strategically located at the bifurcation of the carotid artery (Fig. 1a) and functions as the main arterial chemoreceptor activated by hypoxemia, hypercapnia (rise of blood PCO2), acidic pH, hypoglycemia and other stimuli (see Lopez-Barneo et al. 2016a). The CB is composed of clusters of cells (glomeruli) in close contact with capillaries and nerve fibers. Neuron-like glomus or type I cells (most frequently named in the medical literature as “chief” cells), the most abundant in the glomeruli, are highly dopaminergic (can be stained with antibodies against tyrosine hydroxylase; TH) and also contain ATP, neuropeptides and several other neurotransmitters (Fig. 1b). Upon activation, glomus cells release transmitters, which activate afferent fibers terminating at the respiratory and autonomic centers of the brainstem, thereby eliciting hyperventilation and sympathetic activation (Fig. 1c). Glomus cells are enveloped by glia-like type II, or sustentacular, cells (Fig. 1b), which have classically been ascribed a supportive role, although recent studies have unraveled their function as quiescent stem cells (Pardal et al. 2007; Macias et al. 2014; Navarro-Guerrero et al. 2016). CB glomeruli are highly complex structures with sophisticated autocrine and paracrine interactions among the different cell classes (see Nurse 2014).
In the last decade, the CB, with a well-established role in the regulation of respiration, has also drawn special medical attention due to its possible contribution to the pathogenesis of highly prevalent human diseases. Alterations of CB development have been associated with respiratory disturbances (congenital central hypoventilation or sudden infant death syndromes) in the newborn (Cutz et al. 1997; Gauda et al. 2004; Perez and Keens 2013) and, more recently, CB over-activation has been suggested to contribute to the exaggerated sympathetic outflow existing in sleep apnea (Del Rio et al. 2016), cardiac failure (Marcus et al. 2014) and metabolic (Ribeiro et al. 2013) syndromes. Indeed, CB resection has been proposed for the treatment of refractory neurogenic hypertension (McBryde et al. 2013), although this procedure does not seem to be exempt from adverse effects (Limberg et al. 2015). In addition to dopamine, CB glomus (chief) cells contain high levels of glial cell line-derived neurotrophic factor (GDNF), an agent that promotes survival of central dopaminergic neurons (Lin et al. 1993; Hidalgo-Figueroa et al. 2012), hence CB transplantation has been suggested as a potential therapeutic approach to Parkinson’s disease (Minguez-Castellanos et al. 2007).
In this article, I will briefly summarize our current understanding of the mechanisms underlying acute O2 sensing by CB glomus (chief) cells and their responsiveness to hypoxia. I will also discuss the process of CB growth during sustained hypoxia, an intriguing property that is not normally seen in other structures of the peripheral nervous system (see, however, Pan et al. 2016). I will describe the properties of adult CB stem cells and the mechanisms whereby, during exposure to hypoxia, mature O2-sensitive glomus cells induce stem cells to proliferate and differentiate to generate new glomus cells.
Mechanisms of acute O2 sensing by carotid body chemoreceptor cells
A principal characteristic of CB chemoreceptor cells is that they contain several classes of K+ channels, the open probability of which is inhibited during hypoxia, thereby leading to cell depolarization, Ca2+ influx and transmitter release. These “O2-sensitive” K+ channels, initially identified in glomus (chief) cells, have also been described in other preparations such as pulmonary arterial myocytes (see Lopez-Barneo et al. 1999; Weir et al. 2005) or adrenal medulla (AM) chromaffin cells (Thompson et al. 1997; Keating et al. 2005). In rodent glomus cells, background K+ channels (most likely Task1/Task3 heteromers) seem to be the most important for the initiation of the hypoxic depolarization (Buckler et al. 2000; Kim et al. 2009), which may be potentiated by inhibition of O2-sensitive voltage-gated K+ channels (see Ortega-Saenz et al. 2010). Activation of Ca2+ permeable cationic channels has also been suggested to contribute to the hypoxic response in glomus (Kang et al. 2014) and chromaffin (Inoue et al. 1998) cells.
Although the “membrane model” of chemosensory transduction is generally accepted, the mechanisms whereby decreases in PO2 result in altered ion channel activity have been a matter of much debate and discussion (see Peers 2015; Nurse 2017). Several molecules that directly or indirectly modify ion channel function have been proposed to function as O2 sensors; however, none of them has received robust experimental support (see Lopez-Barneo et al. 2016b). On the other hand, as CB cells are strongly activated by cyanide and other electron transport chain (ETC) inhibitors, a classical view is that mitochondria have an important role in hypoxic CB activation (Mills and Jobsis 1972; Mulligan and Lahiri 1982; Duchen and Biscoe 1992). Rotenone, a mitochondrial complex (MC) I blocker, can selectively occlude sensitivity to hypoxia in glomus cells without affecting responsiveness to hypoglycemia (Garcia-Fernandez et al. 2007); therefore, a rotenone binding molecule has been suggested to be essential for acute O2 sensing (Ortega-Saenz et al. 2003; Keating et al. 2005; Thompson et al. 2007). To test this hypothesis, we generated genetically modified mice with ablation of the Ndufs2 gene, which encodes the 49-kD subunit of the ubiquinone (CoQ)/rotenone binding site at the catalytic core of MCI. Mice with Ndufs2 deficiency restricted to catecholaminergic cells (TH-NDUFS2 mice) can survive 3–4 months but show a complete abolition of the hypoxic ventilatory response with normal responsiveness to hypercapnia (Fernandez-Aguera et al. 2015). In agreement with this systemic phenotype, Ndufs2-null glomus cells are insensitive to hypoxia, although they respond normally to hypercapnia, hypoglycemia and direct depolarization with high extracellular K+ (Fig. 1d, d’). CBs from Ndufs2-deficient mice are histologically normal, which suggests that glomus cells survive without a functional MCI and rely on the MCII–MCIV pathway for oxidative phosphorylation. This idea is supported by the high levels of succinate found in the CB, in comparison with other central and peripheral neural organs (Fernandez-Aguera et al. 2015) and the marked cell loss in CB from MCII-deficient mice (Diaz-Castro et al. 2012). Recently, a “signature gene expression profile”, characterized by high levels of pyruvate carboxylase (Pcx) and of three atypical mitochondrial subunits (Ndufa4l2, Cox4i2 and Cox8b) as well as down-regulation of Phd3 and up-regulation of Hif2α, has been reported for acute O2-sensing chemoreceptor cells (Gao et al. 2017). CB cells also contain unusually high levels of biotin, the essential cofactor of carboxylases (Ortega-Saenz et al. 2016). Taken together, these findings suggest that specific metabolic specializations confer CB glomus cells with their special sensitivity to hypoxia. The overexpression of Pcx is probably required for TCA cycle anaplerosis and the accumulation of high levels of reduced ubiquinone (CoQH2). The presence of the three atypical mitochondrial subunits could make cytochrome c oxidase activity highly sensitive to decreases in PO2, such that even relatively mild hypoxia would cause backup of electrons in the ETC and a further increase in the CoQH2/CoQ ratio, thereby leading to reactive oxygen species (ROS) and NADH production in MCI. This comprehensive model of acute O2 sensing fits well with recent experiments showing reversible increases in mitochondrial ROS and NADH, which can modulate membrane ion channels-, during hypoxia and the disappearance of both signals in Ndufs2-deficient glomus cells (Fig. 1e, e’, f, f’) (Fernandez-Aguera et al. 2015). In addition, responsiveness to acute hypoxia in glomus cells is abolished by pharmacological and genetic inhibition of succinate dehydrogenase (Gao et al. 2017). Moreover, increases in mitochondrial ROS have also been associated with acute hypoxic pulmonary vasoconstriction (HPV) (Waypa et al. 2001) and ablation of the Cox4i2 subunit inhibits acute HPV and activation by hypoxia of single pulmonary artery smooth muscle cells (Sommer et al. 2017).
Carotid body growth in chronic hypoxia, stem cells and tumorigenesis
In addition to its function as an acute O2 sensor, the CB plays a fundamental role in acclimatization to sustained (chronic) hypoxia (see Joseph and Pequignot 2009). The CB has a high level of plasticity and in individuals living at high altitude with low atmospheric pressure or in patients suffering cardiopulmonary diseases who present with hypoxemia, it can grow to several-fold its normal size. This response, unusual for a neuronal organ, is characterized by angiogenesis and enlargement of the neural parenchyma, which leads to augmentation of the excitatory electrical signals that act on the brainstem respiratory center to produce hyperventilation. During acclimatization to hypoxia, the CB-mediated constant hyperventilation prevents an excessive fall in arterial PO2, while other mechanisms trigger angiogenesis and red blood cell proliferation to increase O2 supply to the tissues.
Although CB growth is a well-known classic response to hypoxia (Fig. 2a, a’) (Arias-Stella and Valcarcel 1976; McGregor et al. 1984) the underlying mechanisms have remained largely unstudied. Using genetic markers, we have shown that, as suggested before (Le Douarin 1986; Kameda 2005), the two main cell types in the CB (glomus, type I or chief cells and type II or sustentacular cells) derive from neural crest precursors (Pardal et al. 2007). In normoxic conditions, type II cells, which can be stained with antibodies against the glial fibrillary acidic protein (GFAP), are arranged with large processes enveloping glomus cells. However, in response to hypoxia, the GFAP staining progressively disappears in parallel with the appearance of proliferating nestin+ progenitors and new blood vessels, suggesting a change of phenotype in type II cells (Pardal et al. 2007). Although a population of TH+ CB cells can undergo mitosis (Paciga et al. 1999; Chen et al. 2007; Pardal et al. 2007), in vivo cell fate mapping experiments have shown that the nestin+-positive progenitors and many TH+ glomus cells newly generated during exposure of mice to chronic hypoxia derive from GFAP+ cells (Pardal et al. 2007). The CB contains a population of cells (~1% of the total cell number in CBs from rats or mice) that, once dispersed, behave as self-renewing multipotent stem cells able to form clonal colonies (neurospheres), composed of a core of proliferating nestin+ progenitors, which in a few days give rise to the appearance of blebs formed by differentiating TH+ cells budding out from the neurosphere (Fig. 2b–b”, c–c”). In rat preparations, the blebs (clusters of TH+ cell) can grow for several weeks in culture to reach the size of an entire CB. For unknown reasons, in preparations of mouse or human CB, this “regenerative potential” is, however, much smaller than in the rat (Ortega-Saenz et al. 2013; own unpublished observations). Newly generated glomus cells in vitro have a significant population of voltage-gated Ca2+ and K+ channels, numerous catecholaminergic secretory vesicles, which are released in response to hypoxia or hypoglycemia (Fig. 2d–e’) and high levels of GDNF (Fig. 2f). In addition to neuronal O2-sensitive glomus cells, CB stem cells can also give rise to actin-positive smooth muscle cells, a typical neural crest derivative, as well as endothelial cells (Pardal et al. 2007; Navarro-Guerrero et al. 2016; Annese et al. 2017). Therefore, the CB is a neurogenic niche in the peripheral nervous system, which shares many of the properties of neurogenic centers in the mammalian brain: the subventricular zone (SVZ) and the dentate gyrus (DG) of the hippocampus (see Kriegstein and Alvarez-Buylla 2009). In all these cases, quiescent stem cells with a glia-like phenotype can be activated to become proliferative nestin+ intermediate progenitors, which can eventually differentiate into neuroblasts and other cell types (Kokovay and Temple 2007). Multipotent glia-like stem cells have also been found in the adrenal medulla, where they seem to be able to generate new chromaffin cells and contribute to the plasticity of this organ (Rubin de Celis et al. 2015).
A question of interest is whether the proliferative potential of the CB is associated with the appearance of chemodectomas, a tumor subtype, which belongs to the group of paragangliomas affecting the peripheral nervous system. CB paragangliomas are mostly benign and have histological features that resemble those observed in the CB of individuals subjected to chronic hypoxemia (Heath et al. 1982; Arias-Stella and Valcarcel 1976; Kliewer et al. 1989). In addition, the incidence of CB tumors increases in high-altitude residents (Saldana et al. 1973; Arias-Stella and Bustos 1976; Astrom et al. 2003). There are regional variations in the prevalence of paragangliomas at high altitudes (e.g., extremely high in Mexico, probably much lower in the US Rocky Mountain states and in the Himalayas), which may result from regional differences in the prevalence of occult mutations of hereditary susceptibility genes (Cerecer-Gil et al. 2010). However, the relationship between CB tumorigenesis and the activity of the CB neurogenic niche has not been established. Mutations in the membrane anchoring subunit D of mitochondrial succinate dehydrogenase (SdhD) are the most frequent cause of congenital CB paraganglioma (Rustin et al. 2002; Baysal 2008). Affected individuals are heterozygous (contain a normal and a mutated allele) and the tumor appears after the loss of the normal allele (loss of heterozygosity) (Habano et al. 2003; Maier et al. 1999). Biallelic deletion of the succinate dehydrogenase subunits studied so far (SdhB and SdhD) are lethal at embryonic stages and heterozygous SdhD-deficient (+/−) mice up to 2 years of age do not develop tumors or any other obvious pathology, although they seem to have subtle CB alterations (Piruat et al. 2004). Moreover, conditional ablation of the Sdhd alleles in catecholaminergic cells of mice result in a marked cell loss in the CB, AM and superior cervical ganglion (SCG), as well as in mesencephalic dopaminergic neurons (Diaz-Castro et al. 2012). Therefore, it seems that SdhD ablation in mice, which can cause succinate accumulation, prolyl hydroxylase (PHD) inhibition and hypoxia inducible factor (HIF) stabilization (Selak et al. 2005; Millan-Ucles et al. 2014), is not sufficient to induce paragangliomas. A “multiple-hit” hypothesis and differential chromosomal arrangement have been suggested to explain the differences between CB tumorigenesis in humans and mice (Millan-Ucles et al. 2014). In any case, the data available do not support a direct relationship between the mechanism of hypoxic CB hypertrophy and the appearance of paragangliomas, which are tumors that can affect not only the CB but also tissues, such as the AM, without a hypertrophy response to hypoxia.
Stem cell activation in the hypoxic carotid body
A simple model of the hypoxic CB growth postulated that activation of progenitor cell proliferation by lowering PO2 was due to inhibition of PHDs and stabilization of HIF (Pardal et al. 2007; Kokovay and Temple 2007), as it is known that HIF up-regulation can induce proliferation in several cell types. However, we found that hypoxia-induced CB hypertrophy in vivo is not mimicked by the systemic administration of dimethyloxalylglycine, although this drug (a potent PHD inhibitor) is able to induce HIF-dependent responses, such as red blood cell proliferation and the up-regulation of Vegf mRNA expression in the brain. In agreement with these observations, it has also been shown that the size of the core of CB neurospheres in vitro (an indication of the proliferation of CB progenitors) is unaltered by exposure to PO2 as low as 1% (Platero-Luengo et al. 2014). These results indicated that, as it occurs in other multipotent stem cells (Ezashi et al. 2005; Mohyeldin et al. 2010) and neural progenitors (d’Anglemont de Tassigny et al. 2015), CB stem cells are not intrinsically sensitive to hypoxia as they mainly rely on a non-oxidative metabolism. Moreover, the data also suggested that activation of hypoxic CB stem cells in vivo depends on the presence of the O2-sensitive glomus cells. In support of this concept, ultrastructural studies have demonstrated the existence of numerous synaptic-like contacts between O2-sensitive glomus cells and type II (stem) cells (Fig. 3a–c). In vitro and in vivo studies have also shown that CB stem cells are induced to proliferate by endothelin 1 (ET-1) released from glomus cells and that type II cells contain ET-1 receptors (Platero-Luengo et al. 2014). Therefore, it seems that the O2-sensitive glomus cells function as presynaptic elements in two types of synapses: (1) “chemosensory synapses”, formed between glomus cells and afferent sensory fibers, involved in acute O2 sensing as well as other sensory functions of the CB and (2) “chemoproliferative synapses” formed between glomus and stem cells, which trigger CB hypertrophy during exposure to hypoxia (Fig. 3d) (Platero-Luengo et al. 2014). In the context of the current discussion, it is relevant to recall that synapses (both chemical and electrical) may also occur between pairs of adjacent glomus cells (see Nurse 2014). Although HIF induction in stem cells is not sufficient to trigger CB growth in hypoxia, the PHD–HIF pathway is necessary for normal CB plasticity. Overexpression of HIF2α induces CB hypertrophy (Macias et al. 2014) and inducible down-regulation of the HIF2α gene reduces CB cell proliferation during sustained hypoxia (Hodson et al. 2016).
Regulation of neural stem cell activation by the mature cells is a phenomenon not only seen in the CB but it has also been reported to occur in the central neurogenic niches (see Pardal and Lopez-Barneo 2016). In the SVZ, there are astrocyte-like neural stem cells (NSCs) that, upon activation, are converted into rapidly proliferating intermediate progenitors, which in turn give rise to neuroblasts that migrate to the olfactory bulb (Kriegstein and Alvarez-Buylla 2009). NSCs in the SVZ can also generate oligodendrocyte precursors and striatal neurons (Nait-Oumesmar et al. 2007; Kernie and Parent 2010). The basal area of the SVZ is innervated by axonal branches of neighboring dopaminergic fibers, which release transmitters detected as spillover by NSCs (Baker et al. 2004; Hoglinger et al. 2004). Serotonergic fibers originated in the raphe nuclei also innervate the SVZ and form synaptic-like contacts with apical processes of NSCs (Tong et al. 2014). Both of these transmitters, as well as GABA released from neuroblasts, can regulate NSC quiescence. In all mammals studied, including man, there are NSCs in the DG of the hippocampus, which, like their counterpart in the SVZ, can also generate neuroblasts which mature and integrate into the granule cell layer. The innervation by glutamatergic and serotonergic fibers has been reported to modulate NSC maturation or proliferation in hippocampal DG (Deisseroth et al. 2004; Brezun and Daszuta 2000). In addition to long-distance innervation, local release of GABA by hippocampal interneurons has been shown to regulate DG NSCs’ quiescence and neural maturation (Song et al. 2012).
Concluding remarks
The molecular mechanisms underlying the detection of acute changes in O2 tension by CB glomus (chief) cells have remained elusive for decades; however, our understanding of this process has recently advanced significantly thanks to the use of gene profiling techniques and genetically modified animal models. Glomus cells do not appear to posses a specific O2 sensor but their responsiveness to acute hypoxia seems to depend on metabolic and biophysical properties, which result from the regulated expression of a mix of genes encoding mitochondrial subunits, metabolic enzymes and ion channels. On the other hand, the cellular mechanisms responsible for CB hypertrophy in chronic hypoxia, a response associated with adaptation/survival in high altitude and cardiorespiratory pathologies limiting gas exchange in the lungs, have also been identified. The CB contains a population of adult neural crest-derived multipotent stem cells, which are quiescent in normoxic conditions but are activated by hypoxia to produce new glomus cells as well as smooth muscle and endothelial cells. The CB behaves as a germinal niche in the adult peripheral nervous system, which shares many properties with neurogenic centers existing in the mammalian brain. Activation of CB stem cells during hypoxia requires stimulation of the O2-sensitive glomus cells and the release of transmitters, which induce stem cell proliferation and differentiation. Ultrastructural studies indicate that mature glomus cells and stem cells establish numerous chemical synapses (“chemoproliferative synapses”) that work in parallel with those existing between glomus cells and afferent nerve fibers (“chemosensory synapses”) (see Nurse 2014; Platero-Luengo et al. 2014). Understanding CB function in acute and chronic hypoxia has direct medical impact. It may help to combat respiratory depression, a frequent pathology generated during anesthesia or opioid overdose, as well as the CB-mediated exaggerated sympathetic outflow that exists in highly prevalent disorders, such as cardiac failure or sleep apnea.
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Acknowledgements
I am grateful to Dr. Patricia Ortega-Sáenz for her generous help in the preparation of the figures. I also thank the colleagues who have contributed to the experiments and ideas discussed in this review. The author’s laboratory is supported by grants from the Spanish Ministry of Economy and Innovation (SAF2012-39343, SAF2016-74990-R) and the European Research Council (ERC Advanced Grant PRJ201502629).
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López-Barneo, J. Oxygen sensing and stem cell activation in the hypoxic carotid body. Cell Tissue Res 372, 417–425 (2018). https://doi.org/10.1007/s00441-017-2783-9
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DOI: https://doi.org/10.1007/s00441-017-2783-9