Oxygen chemoreception by carotid body cells in culture

Physiology of the Carotid Body: From Molecules to Disease

The carotid body (CB) is an arterial chemoreceptor organ located in the carotid bifurcation and has a well-recognized role in cardiorespiratory regulation. The CB contains neurosecretory sensory cells (glomus cells), which release transmitters in response to hypoxia, hypercapnia, and acidemia to activate afferent sensory fibers terminating in the respiratory and autonomic brainstem centers. Knowledge of the physiology of the CB has progressed enormously in recent years. Herein we review advances concerning the organization and function of the cellular elements of the CB, with emphasis on the molecular mechanisms of acute oxygen sensing by glomus cells. We introduce the modern view of the CB as a multimodal integrated metabolic sensor and describe the properties of the CB stem cell niche, which support CB growth during acclimatization to chronic hypoxia. Finally, we discuss the increasing medical relevance of CB dysfunction and its potential impact on the mechanisms of disease.

Mechanisms and Consequences of Oxygen and Carbon Dioxide Sensing in Mammals

Molecular oxygen (O₂) and carbon dioxide (CO₂) are the primary gaseous substrate and product of oxidative phosphorylation in respiring organisms, respectively. Variance in the levels of either of these gasses outside of the physiological range presents a serious threat to cell, tissue, and organism survival. Therefore, it is essential that endogenous levels are monitored and kept at appropriate concentrations to maintain a state of homeostasis. Higher organisms such as mammals have evolved mechanisms to sense O₂ and CO₂ both in the circulation and in individual cells and elicit appropriate corrective responses to promote adaptation to commonly encountered conditions such as hypoxia and hypercapnia. These can be acute and transient nontranscriptional responses, which typically occur at the level of whole animal physiology or more sustained transcriptional responses, which promote chronic adaptation. In this review, we discuss the mechanisms by which mammals sense changes in O₂ and CO₂ and elicit adaptive responses to maintain homeostasis. We also discuss crosstalk between these pathways and how they may represent targets for therapeutic intervention in a range of pathological states.

Voltage- and receptor-mediated activation of a non-selective cation channel in rat carotid body glomus cells

A recent study showed that hypoxia activates a Ca²⁺-sensitive, Na⁺-permeable non-selective cation channel (NSC) in carotid body glomus cells. We studied the effects of mitochondrial inhibitors that increase Ca²⁺ influx via Ca²⁺ channel (Ca_v), and receptor agonists that release Ca²⁺ from endoplasmic reticulum (ER) on NSC. Mitochondrial inhibitors (NaCN, FCCP, H₂S, NO) elevated [Ca²⁺]_i and activated NSC. Angiotensin II and acetylcholine that elevate [Ca²⁺]_i via the Gq-IP₃ pathway activated NSC. However, endothelin-1 (Gq) and 5-HT (Gq) showed little or no effect on [Ca²⁺]_i and did not activate NSC. Adenosine (Gs) caused a weak rise in [Ca²⁺]_i but did not activate NSC. Dopamine (Gs) and γ-aminobytyric acid (Gi) were ineffective in raising [Ca²⁺]_i and failed to activate NSC. Store-operated Ca²⁺ entry (SOCE) produced by depletion of Ca²⁺ stores with cyclopiazonic acid activated NSC. Our results show that Ca²⁺ entry via Ca_v, ER Ca²⁺ release and SOCE can activate NSC. Thus, NSC contributes to both voltage- and receptor-mediated excitation of glomus cells.

Oxygen sensing by the carotid body: mechanisms and role in adaptation to hypoxia

Oxygen (O2) is fundamental for cell and whole-body homeostasis. Our understanding of the adaptive processes that take place in response to a lack of O2(hypoxia) has progressed significantly in recent years. The carotid body (CB) is the main arterial chemoreceptor that mediates the acute cardiorespiratory reflexes (hyperventilation and sympathetic activation) triggered by hypoxia. The CB is composed of clusters of cells (glomeruli) in close contact with blood vessels and nerve fibers. Glomus cells, the O2-sensitive elements in the CB, are neuron-like cells that contain O2-sensitive K(+)channels, which are inhibited by hypoxia. This leads to cell depolarization, Ca(2+)entry, and the release of transmitters to activate sensory fibers terminating at the respiratory center. The mechanism whereby O2modulates K(+)channels has remained elusive, although several appealing hypotheses have been postulated. Recent data suggest that mitochondria complex I signaling to membrane K(+)channels plays a fundamental role in acute O2sensing. CB activation during exposure to low Po2is also necessary for acclimatization to chronic hypoxia. CB growth during sustained hypoxia depends on the activation of a resident population of stem cells, which are also activated by transmitters released from the O2-sensitive glomus cells. These advances should foster further studies on the role of CB dysfunction in the pathogenesis of highly prevalent human diseases.

Where there is smoke…there is sleep apnea: exploring the relationship between smoking and sleep apnea

Smoking and OSA are widely prevalent and are associated with significant morbidity and mortality. It has been hypothesized that each of these conditions adversely affects the other, leading to increased comorbidity while altering the efficacy of existing therapies. However, while the association between smoking and OSA is plausible, the evidence is less than conclusive. Cigarette smoking may increase the severity of OSA through alterations in sleep architecture, upper airway neuromuscular function, arousal mechanisms, and upper airway inflammation. Conversely, some evidence links untreated OSA with smoking addiction. Smoking cessation should improve OSA, but the evidence to support this is also limited. This article reviews the current evidence linking both conditions and the efficacy of various treatments. Limitations of the current evidence and areas in need of future investigation are also addressed.

Endogenous H2S is required for hypoxic sensing by carotid body glomus cells

H(2)S generated by the enzyme cystathionine-γ-lyase (CSE) has been implicated in O(2) sensing by the carotid body. The objectives of the present study were to determine whether glomus cells, the primary site of hypoxic sensing in the carotid body, generate H(2)S in an O(2)-sensitive manner and whether endogenous H(2)S is required for O(2) sensing by glomus cells. Experiments were performed on glomus cells harvested from anesthetized adult rats as well as age and sex-matched CSE(+/+) and CSE(-/-) mice. Physiological levels of hypoxia (Po(2) ∼30 mmHg) increased H(2)S levels in glomus cells, and dl-propargylglycine (PAG), a CSE inhibitor, prevented this response in a dose-dependent manner. Catecholamine (CA) secretion from glomus cells was monitored by carbon-fiber amperometry. Hypoxia increased CA secretion from rat and mouse glomus cells, and this response was markedly attenuated by PAG and in cells from CSE(-/-) mice. CA secretion evoked by 40 mM KCl, however, was unaffected by PAG or CSE deletion. Exogenous application of a H(2)S donor (50 μM NaHS) increased cytosolic Ca(2+) concentration ([Ca(2+)](i)) in glomus cells, with a time course and magnitude that are similar to that produced by hypoxia. [Ca(2+)](i) responses to NaHS and hypoxia were markedly attenuated in the presence of Ca(2+)-free medium or cadmium chloride, a pan voltage-gated Ca(2+) channel blocker, or nifedipine, an L-type Ca(2+) channel inhibitor, suggesting that both hypoxia and H(2)S share common Ca(2+)-activating mechanisms. These results demonstrate that H(2)S generated by CSE is a physiologic mediator of the glomus cell's response to hypoxia.

Cells of the sympathoadrenal lineage: Biological properties as donor tissue for cell-replacement therapies for Parkinson's disease

Sympathoadrenal (SA) cell lineage encompasses neural crest derivatives such as sympathetic neurons, small intensely fluorescent (SIF) cells of sympathetic ganglia and adrenal medulla, and chromaffin cells of adrenal medulla and extra-adrenal paraganglia. SA autografts have been used for transplantation in Parkinson's disease (PD) for three reasons: (i) as autologous donor tissue avoids graft rejection and the need for immunosuppressant therapy, (ii) SA cells express dopaminotrophic factors such as GNDF and TGFbetas, and (iii) although most of SA cells release noradrenaline, some of them are able to produce and release dopamine. Adrenal chromaffin cells were the first SA transplanted cells in both animal models of PD and PD patients. However, these autografts have met limited success because long-term cell survival is very poor, and this approach is no longer pursued clinically. Sympathetic neurons from the superior cervical ganglion have been also grafted in PD animal models and PD patients. Poor survival into brain parenchyma of grafted tissue is a serious disadvantage for its clinical application. However, cultured sympathetic cell grafts present a better survival rate, and they reduce the need for levodopa medication in PD patients by facilitating the conversion of exogenous levodopa. SA extra-adrenal chromaffin cells are located on paraganglia (i.e., the Zuckerkandl's organ), and have been used for grafting in a rodent model of PD. Preliminary results indicate that long-term survival of these cells is better than for other SA cells, exerting a more prolonged restorative neurotrophic action on denervated host striatum. The ability of SA extra-adrenal cells to respond to hypoxia, differently to SA sympathetic neurons or adrenal medulla cells, could explain their good survival rate after brain transplantation.

The role of calcium in hypoxia-induced signal transduction and gene expression

Mammalian cells require a constant supply of oxygen in order to maintain adequate energy production, which is essential for maintaining normal function and for ensuring cell survival. Sustained hypoxia can result in cell death. Sophisticated mechanisms have therefore evolved which allow cells to respond and adapt to hypoxia. Specialized oxygen-sensing cells have the ability to detect changes in oxygen tension and transduce this signal into organ system functions that enhance the delivery of oxygen to tissue in a wide variety of different organisms. An increase in intracellular calcium levels is a primary response of many cell types to hypoxia/ischemia. The response to hypoxia is complex and involves the regulation of multiple signaling pathways and coordinated expression of perhaps hundreds of genes. This review discusses the role of calcium in hypoxia-induced regulation of signal transduction pathways and gene expression. An understanding of the molecular events initiated by changes in intracellular calcium will lead to the development of therapeutic approaches toward the treatment of hypoxic/ischemic diseases and tumors.

Functional genomics approach to hypoxia signaling

Mammalian cells require a constant supply of oxygen to maintain energy balance, and sustained hypoxia can result in cell death. It is therefore not surprising that sophisticated adaptive mechanisms have evolved that enhance cell survival during hypoxia. During the past few years, there have been a growing number of reports on hypoxia-induced transcription of specific genes. In this review, we describe a unique experimental approach that utilizes focused cDNA libraries coupled to microarray analyses to identify hypoxia-responsive signal transduction pathways and genes that confer the hypoxia-tolerant phenotype. We have used the subtractive suppression hybridization (SSH) method to create a cDNA library enriched in hypoxia-regulated genes in oxygen-sensing pheochromocytoma cells and have used this library to create microarrays that allow us to examine hundreds of genes at a time. This library contains over 300 genes and expressed sequence tags upregulated by hypoxia, including tyrosine hydroxylase, vascular endothelial growth factor, and junB. Hypoxic regulation of these and other genes in the library has been confirmed by microarray, Northern blot, and real-time PCR analyses. Coupling focused SSH libraries with microarray analyses allows one to specifically study genes relevant to a phenotype of interest while reducing much of the biological noise associated with these types of studies. When used in conjunction with high-throughput, dye-based assays for cell survival and apoptosis, this approach offers a rapid method for discovering validated therapeutic targets for the treatment of cardiovascular disease, stroke, and tumors.

Presynaptic modulation of rat arterial chemoreceptor function by 5-HT: role of K+ channel inhibition via protein kinase C

The peripheral control of breathing is mediated by O2-sensitive carotid body (CB) type 1 cells, which express multiple neurotransmitters including the monoamines, dopamine and serotonin (5-HT). Whereas dopamine has been extensively studied, 5-HT has received little attention. Here, to elucidate the role of 5-HT in CB chemotransmission, we used perforated-patch recording from rat type 1 cell clusters and co-cultured petrosal (afferent) neurones. 5-HT induced action potentials and/or membrane depolarization associated with a conductance decrease in approximately 40% of recordings from type 1 cells (n = 78/192). These responses were markedly inhibited by the 5-HT2 receptor antagonist ketanserin (10-50 microM) and by the protein kinase C (PKC) inhibitor chelerythrine (50 microM). The PKC activator 1-oleoyl-2-acetylglycerol (OAG; 50 microM) mimicked the 5-HT-induced depolarization, and the combined effects of 5-HT and OAG were non-additive. The 5-HT-induced responses reversed near the potassium (K+) equilibrium potential (at approximately -82 mV; EK = -83 mV), suggesting inhibition of a resting K+ conductance. In type 1 cells (n = 7), voltage-activated outward K+ current was also inhibited by 1-50 microM 5-HT, an effect that was prevented by PKC inhibitors (chelerythrine and NPC 15437) and mimicked by OAG; the outward K+ current inhibited by 5-HT appeared to be predominantly a Ca(2+)-dependent K+ current. The 5-HT2 receptor blockers ketanserin and ritanserin reversibly inhibited spontaneous action potentials and the hypoxia-induced receptor potential recorded from clustered type 1 cells. Moreover, these blockers reversibly inhibited the hypoxic chemosensory response recorded postsynaptically in petrosal neurones that functionally innervated type 1 clusters in co-culture. RT-PCR and confocal immunofluorescence techniques revealed 5-HT2a receptor expression in rat CB type 1 cells. These results suggest that release of endogenous 5-HT regulates CB chemoreceptor function presynaptically, by a positive feedback mechanism involving autocrine-paracrine stimulation of 5-HT2a receptors and PKC modulation of resting and Ca(2+)-dependent K+ conductances.

Oxygen sensing in neuroendocrine cells and other cell types: pheochromocytoma (PC12) cells as an experimental model

A steady supply of oxygen is an absolute requirement for mammalian cells to maintain normal cellular functions. To answer the challenge that oxygen deprivation represents, mammals have evolved specialized cell types that can sense changes in oxygen tension and alter gene expression to enhance oxygen delivery to hypoxic areas. These oxygensensing cells are rare and difficult to study in vivo. As a result, pheochromocytoma (PC12) cells have become a vital in vitro model system for deciphering the molecular events that confer the hypoxia-resistant and oxygen-sensing phenotypes. Research over the last few years has revealed that the hypoxia response in PC12 cells involves the interactions of several signal transduction pathways (Ca2+/calmodulin-dependent kinases, Akt, SAPKs, and MAPKs) and transcription factors (HIFs, CREB, and c-fos/junB). This review summarizes the current understanding of the role these signal transduction pathways and transcription factors play in determining the hypoxic response.

Carotid body chemoreceptors in dissociated cell culture

Carotid body (CB) glomus or type 1 cells act as peripheral chemoreceptors which detect changes in arterial PO(2), PCO(2), and pH and help maintain homeostasis via the reflex control of ventilation. Over the last approximately 12 years significant progress has been made towards understanding chemotransduction mechanisms using freshly isolated or cultured type 1 cells. The latter preparation allows several powerful experimental manipulations (e.g., co-culture with sensory neurons) resulting in significant advances in our understanding of CB chemoreception. Here, we review several properties of type 1 cells after several days to weeks in culture. Typically, cultured type 1 cells grow in monolayer clusters enveloped by glial-like, type II, or sustentacular cells, which are immunopositive for the glial marker, glial fibrillary acid protein (GFAP). These cells can undergo DNA synthesis, evidenced by uptake of bromodeoxyuridine (BrdU), and show a limited capacity for cell division. Mitosis and survival of type 1 cells can be regulated by oxygen tension and/or growth factors (e.g., bFGF, insulin). In the rat, type 1 cells are immunopositive for several monoaminergic markers, including tyrosine hydroxylase (TH), dopamine transporter (DAT), and 5-HT. They also express cholinergic markers (e.g., vesicular acetylcholine transporter; VAChT), the highly conserved synaptic vesicle protein (SV2), and gap junctional proteins including Connexin 32 (Cx32). Moreover, in long-term culture ( approximately 2 weeks) they retain expression of O(2)-sensitive, TASK-1-like, and Ca(2+)-dependent (BK), K(+) channels as revealed by immunocytochemistry or RT-PCR analysis of mRNA extracted from type 1 clusters after removal from the culture surface.

Responding to hypoxia: lessons from a model cell line

Mammalian cells require a constant supply of oxygen to maintain adequate energy production, which is essential for maintaining normal function and for ensuring cell survival. Sustained hypoxia can result in cell death. It is, therefore, not surprising that sophisticated mechanisms have evolved that allow cells to adapt to hypoxia. "Oxygen-sensing" is a special phenotype that functions to detect changes in oxygen tension and to transduce this signal into organ system functions that enhance the delivery of oxygen to tissue in various organisms. Oxygen-sensing cells can be segregated into two distinct cell types: those that functionally depolarize (excitable) and those that do not functionally depolarize (nonexcitable) in response to reduced oxygen. Theoretically, excitable cells have all the same signaling capabilities as the nonexcitable cells, but the nonexcitable cells cannot have all the signaling capabilities as excitable cells. A number of signaling pathways have been identified that regulate gene expression during hypoxia. These include the Ca2+-calmodulin pathway, the 3'-5' adenosine monophosphate (cAMP)-protein kinase A (PKA) pathway, the p42 and p44 mitogen-activated protein kinase [(MAPK); also known as the extracellular signal-related kinase (ERK) for ERK1 and ERK2] pathway, the stress-activated protein kinase (SAPK; also known as p38 kinase) pathway, and the phosphatidylinositol 3-kinase (PI3K)-Akt pathway. In this review, we describe hypoxia-induced signaling in the model O2-sensing rat pheochromocytoma (PC12) cell line, the current level of understanding of the major signaling events that are activated by reduced O2, and how these signaling events lead to altered gene expression in both excitable and nonexcitable oxygen-sensing cells.

Dopaminergic cells of the carotid body: physiological significance and possible therapeutic applications in Parkinson's disease

Parkinson's disease is a neurodegenerative disorder characterized by the progressive loss of dopaminergic neurons in the substantia nigra projecting to the striatum. One therapeutic approach to this disease has been the intrastriatal transplantation of dopamine-secreting cells. We have investigated the suitability of glomus cells of the carotid body for dopamine-cell replacement in animal models of Parkinson's disease. Carotid body glomus cells are physiologic arterial oxygen sensors that release large amounts of dopamine in response to hypoxia. We have used hemi-Parkinsonian rats, induced by injection of 6-hydroxydopamine into the substantia nigra, and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine treated monkeys with chronic Parkinsonism. In both cases we made transplants of carotid body cell aggregates into the putamen. Functional recovery of the grafted animals was observed after the surgery and was stable for several months. Although the study was more detailed in the rat, in the two animal models the amelioration of the motor deficits was paralleled by striatal dopaminergic reinnervation and survival of grafted glomus cells. Our results suggest that intrastriatal autotransplants of carotid body tissue could be a feasible technique to treat some cases of Parkinson's disease in humans.

Recovery of chronic parkinsonian monkeys by autotransplants of carotid body cell aggregates into putamen

We have studied the effect of unilateral autografts of carotid body cell aggregates into the putamen of MPTP-treated monkeys with chronic parkinsonism. Two to four weeks after transplantation, the monkeys initiated a progressive recovery of mobility with reduction of tremor and bradykinesia and restoration of fine motor abilities on the contralateral side. Apomorphine injections induced rotations toward the side of the transplant. Functional recovery was accompanied by the survival of tyrosine hydroxylase-positive (TH-positive) grafted glomus cells. A high density of TH-immunoreactive fibers was seen reinnervating broad regions of the ipsilateral putamen and caudate nucleus. The nongrafted, contralateral striatum remained deafferented. Intrastriatal autografting of carotid body tissue is a feasible technique with beneficial effects on parkinsonian monkeys; thus, this therapeutic approach could also be applied to treat patients with Parkinson's disease.

Electrophysiological characterization of 5-HT receptors on rat petrosal neurons in dissociated cell culture

The petrosal ganglion supplies chemoafferent pathways via the glossopharyngeal (IXth) nerve to peripheral targets which release various neurotransmitters including serotonin (5-HT). Here, we combined rapid 5-HT application with patch clamp, whole-cell recording to investigate whether 5-HT receptors are expressed on isolated petrosal neurons (PN), cultured from 7-12 day-old rat pups. In responsive cells, the dominant effect of 5-HT was a rapid depolarization associated with a conductance increase in approximately 43% of the neurons (53/123); however, in a minority population ( approximately 6%; 8/123), 5-HT caused membrane depolarization associated with a conductance decrease. In the former group, 5-HT produced a transient inward current (I5-HT) in neurons voltage-clamped near the resting potential ( approximately -60 mV); the effect was mimicked by the 5-HT3 receptor-specific agonist, 2-methyl-5-HT, suggesting it was mediated by 5-HT3 receptors. Further, I5-HT was selectively inhibited by the 5-HT3 receptor-specific antagonist MDL72222 (1-10 microM), but was unaffected by either 5-HT1/5-HT2 receptor antagonist, spiperone, or by 5-HT2 receptor-specific antagonist, ketanserin (50-100 microM). I5-HT displayed moderate inward rectification and had a mean reversal potential (+/-S.E.M.) of -4.3+/-6.6 mV (n=6). Application of 5-HT (dose range: 0.1-100 microM) produced a dose-response curve that was fitted by the Hill equation with EC50= approximately 3.4 microM and Hill coefficient= approximately 1.6 (n=8). The activation phase of I5-HT (10 microM 5-HT at -60 mV) was well fitted by a single exponential with mean (+/-S.E.M.) time constant of 45+/-30 ms (n=6). The desensitization phase of I5-HT was best fitted by a single exponential with mean (+/-S.E.M.) time constant of 660+/-167 ms (n=6). Fluctuation analysis yielded an apparent mean single-channel conductance (+/-S.E.M) of 2.7+/-1.5 pS (n=4) at -60 mV. In the minority ( approximately 6%) population of neurons which responded to 5-HT with a conductance decrease, the depolarization was blocked by the 5-HT2 receptor antagonist, ketanserin (50 microM). Taken together, these results suggest that 5-HT3 receptors are the major subtype expressed by rat petrosal neurons, and therefore are candidates for facilitating chemoafferent excitation in response to 5-HT released from peripheral targets.

Different effects of prolonged isocapnic hypoxia on the carotid body and the glomus cells in the wall of the common carotid artery of the chicken

In the chicken, glomus cells are widely distributed not only in the carotid body but also in the wall of the common carotid artery and around each artery arising from the common carotid artery. Effects of chronic isocapnic hypoxia on the chicken carotid body and the glomus cells in and around the arteries were examined by immunohistochemistry and electron microscopy. In chickens exposed to isocapnic hypoxia for 35 days, three- to four-fold increase of the carotid body volume was induced. Immunoreactivity for tyrosine hydroxylase of glomus cells almost completely disappeared. Dense networks of TuJ1-immunoreactive nerve fibers were unchanged, whereas peptidergic nerve fibers, i.e., substance P-, calcitonin gene-related peptide-, vasoactive intestinal peptide-, galanin- and neuropeptide Y-immunoreactive fibers, were decreased in and around the carotid body. At the electron microscopic level, increased secretory activity of the glomus cells was verified. Mature dense-cored vesicles were markedly decreased, although prosecretory granules were numerous around Golgi complexes. Many immature glomus cells filled with rough endoplasmic reticulum and free ribosomes, also appeared in the carotid bodies of hypoxic chickens. In contrast to the carotid body, the glomus cells located in the wall of the common carotid artery revealed no changes after long-term hypoxia. The cells in the hypoxic chickens, as well as normal controls, expressed intense immunoreactivity for neuropeptide Y, serotonin and chromogranin A. Furthermore, a large number of dense-cored vesicles were distributed throughout the cytoplasm. The glomus cells around each artery arising from the common carotid artery were affected by hypoxia, although the degree of their response to hypoxia varied depending on the locations.

Release of dopamine and norepinephrine by hypoxia from PC-12 cells

We examined the effects of hypoxia on the release of dopamine (DA) and norepinephrine (NE) from rat pheochromocytoma 12 (PC-12) cells and assessed the involvement of Ca2+ and protein kinases in stimulus-secretion coupling. Catecholamine release was monitored by microvoltammetry using a carbon fiber electrode as well as by HPLC coupled with electrochemical detection (ECD). Microvoltammetric analysis showed that hypoxia-induced catecholamine secretion (PO2 of medium approximately 40 mmHg) occurred within 1 min after the onset of the stimulus and reached a plateau between 10 and 15 min. HPLC-ECD analysis revealed that, at any level of PO2, the release of NE was greater than the release of DA. In contrast, in response to K+ (80 mM), DA release was approximately 11-fold greater than NE release. The magnitude of hypoxia-induced NE and DA releases depended on the passage, source, and culture conditions of the PC-12 cells. Omission of extracellular Ca2+ or addition of voltage-gated Ca2+ channel blockers attenuated hypoxia-induced release of both DA and NE to a similar extent. Protein kinase inhibitors, staurosporine (200 nM) and bisindolylmaleimide I (2 microM), on the other hand, attenuated hypoxia-induced NE release more than DA release. However, protein kinase inhibitors had no significant effect on K+-induced NE and DA releases. These results demonstrate that hypoxia releases catecholamines from PC-12 cells and that, for a given change in PO2, NE release is greater than DA release. It is suggested that protein kinases are involved in the enhanced release of NE during hypoxia.

Hypoxia and cyanide induce depolarization and catecholamine release in dispersed guinea-pig chromaffin cells

1. The perforated patch method and amperometry were used to determine whether the adrenal medullary cell itself is capable of sensing hypoxia and, if so, how such sensation is transduced to secretion of catecholamines (CA). 2. Exposure to hypoxia, cyanide (CN), or muscarine facilitated CA secretion from dissociated chromaffin cells. The CN-induced secretion was not affected by removal of glucose, indicating that the CN release is due to chemical hypoxia. 3. The secretions induced by CN and muscarine were markedly diminished by removal of Ca2+ ions or by application of Cd2+ or methoxyverapamil (D-600). 4. Cyanide and muscarine produced depolarizations with generation of action potentials and increased intracellular Ca2+ concentrations determined using the acetoxymethyl (AM) ester form of fluo-3 in the presence of external Ca2+ ions, but not in their absence. 5. Hypoxia and CN produced inward currents at an equilibrium potential for Cl- ions, irrespective of whether or not Na+ ions were present in the cells, and substitution of N-methyl-D-glucamine for 134 mM Na+ ions in the perfusate inhibited the CN current by 71 %. The reversal potential for the CN current was -24 mV in the standard perfusate. 6. The hypoxia-, CN- and muscarine-induced currents decreased in parallel with hyperpolarizations, and exposure to CN prevented muscarine, but not nicotine, from inducing a further inward current. 7. We conclude that hypoxia and CN induce CA secretion through depolarization and the subsequent activation of voltage-dependent Ca2+ channels and that this depolarization is due to opening of cation channels, which are possibly identical to muscarinic cation channels.

Cellular and functional recovery of Parkinsonian rats after intrastriatal transplantation of carotid body cell aggregates

We have tested the suitability of chromaffin-like carotid body glomus cells for dopamine cell replacement in Parkinsonian rats. Intrastriatal grafting of cell aggregates resulted in almost optimal abolishment of motor asymmetries and deficits of sensorimotor orientation. Recovery of transplanted animals was apparent 10 days after surgery and progressed throughout the 3 months of the study. The behavioral effects were correlated with the long survival of glomus cells in the host brain. In host tissue, glomus cells were organized into glomerulus-like structures and retained the ability to secrete dopamine. Several weeks after transplantation, dopaminergic fibers emerged from the graft, reinnervating the striatal gray matter. The special durability of grafted glomus cells in the conditions of brain parenchyma could be related to their sensitivity to hypoxia, which is known to induce cell growth, excitability, and dopamine synthesis. This work should stimulate research on the clinical applicability of carotid body autotransplants in Parkinson's disease.

Role of basic FGF and oxygen in control of proliferation, survival, and neuronal differentiation in carotid body chromaffin cells

Crest-derived glomus cells of the carotid body (CB) are O(2)-sensitive chemoreceptors, which resemble sympathoadrenal (SA) chromaffin cells. In this study, we tested whether perinatal rat glomus cells are sensitive to basic fibroblast growth factor (bFGF) in vitro and whether their sensitivity is regulated by oxygen. In chemically defined medium, bFGF (1-100 ng/ml) caused a significant, dose-dependent increase in the number of surviving tyrosine hydroxylase-positive (TH+) glomus cells in embryonic (E17-E19) CB cultures, following a 48-hr exposure. Though basic FGF (10 ng/ml) appeared mitogenic for these cells, based on stimulation of bromodeoxyuridine (BrdU) uptake, it supported survival of only approximately 60% of the initial TH+ population, suggesting that significant cell death was occurring. This apparent cell loss in E17 cultures could be largely prevented by combined treatment with bFGF and low oxygen (6% O(2)). In contrast, in early postnatal (P1) cultures, glomus cell number was relatively unchanged over 48 hr under control conditions or in presence of mitogenic activity from either bFGF or low oxygen. However, combined treatment with both bFGF and low oxygen stimulated proliferation of P1 glomus cells such that by 48 hr the TH+ population had increased to approximately 1.5x the initial density. Basic FGF (10 ng/ ml) also stimulated neurite outgrowth and neurofilament expression in E18-E19, but not P1-P3, glomus cells. In contrast to bFGF, treatment with nerve growth factor was ineffective. Taken together, these results suggest that bFGF and low oxygen are mitogens for perinatal CB chromaffin cells and interact cooperatively as survival factors. It is plausible that these mechanisms may operate to regulate chemoreceptor cell density, during the animal's transition from in utero (hypoxic) to ex utero (normoxic)life.

Post-transcriptional regulation of tyrosine hydroxylase gene expression by oxygen in PC12 cells

Reduced oxygen tension (hypoxia) leads to increased stability of mRNA for tyrosine hydroxylase (TH), the rate limiting enzyme in biosynthesis of catecholamine neurotransmitters. Hypoxia increases the half life of TH mRNA from 10 to 30 hours. The increased stability of TH mRNA during hypoxia results from fast enhanced binding of a cytoplasmic protein (hypoxia inducible protein, HIP) to a pyrimidine-rich sequence within the 3' untranslated region (3'UTR) of TH mRNA. This novel cis-element is referred to as hypoxia-inducible protein binding site (HIPBS) and is located between bases 1551 and 1578 of the 3' UTR of TH mRNA. We identified that the (U/C)(C/U)CCCU motif within the HIPBS represents the optimum protein-binding site. Mutations within this region that abolish protein binding prevent also regulation of TH mRNA stability during hypoxia. UV-crosslinking and SDS-PAGE analysis of the HIPBS-protein complexes showed the presence of a major 50 kDa complex. The formation of the complex was augmented when protein extracts were obtained from PC12 cells exposed to 5% O2. Importantly, formation of the 50 kDa complex was also increased when protein extracts were obtained from carotid bodies or superior cervical ganglia from rats exposed to 10% hypoxia for twenty-four hours.

Is sleep apnea a predisposing factor for tobacco use?

We present a plausible and powerful explanation for nicotine addiction that is consistent with recent findings. Sleep apnea, the periodic cessation of breathing during sleep, may be responsible for the addictive nature of nicotine. The main symptoms of sleep apnea are somnolence and obesity. Nicotine has been shown to decrease these two symptoms as well as reduce the frequency and duration of apneas. When an apneic youth uses tobacco, the nicotine may begin to treat the apnea and reduce the symptoms. The response of the human system is, naturally, to continue that which improves life, assuring addiction of the apnea to the nicotine. Many of the illnesses attributed to tobacco use and passive parental smoking may actually be confounded by the inherited influence of sleep apnea. Treating the apnea may be a necessary precondition for a successful tobacco cessation program. Understanding the apnea-tobacco relationship may be an important step in the development of a tobacco prevention program for youth.

Ca2+ channel currents in type I carotid body cells of normoxic and chronically hypoxic neonatal rats

Whole-cell patch-clamp recordings were used to study voltage-gated Ca2+ channel currents in type I carotid body cells of young rats born and reared in normoxia or in a chronically hypoxic (CH) environment (10% O2). Currents activated at potentials of -40 mV and more positive, and typically peaked at 0 mV in both groups of cells. Steady-state inactivation curves were similar in the two populations. Ca2+ currents were significantly larger in CH type I cells, but this was accounted for by the increased size of CH cells: current density was similar in both cell types. Nifedipine (5 microM) always partially inhibited currents and Bay K 8644 (2-5 microM) always enhanced currents, indicating the presence of L-type channels. In a small number of cells from each group, the N-type channel blocker omega-conotoxin GVIA caused partial, irreversible inhibition, but in most cells was without discernible effect. These results indicate that type I cells possess L-type Ca2+ channels, that N-type are expressed in some cells and that non-L, non-N-type channels are also present. Furthermore, chronic hypoxia does not appear to cause specific adaptive changes in the properties of Ca2+ channels in type I cells.

Oxygen sensing by ion channels and chemotransduction in single glomus cells

We have monitored cytosolic [Ca2+] and dopamine release in intact fura-2-loaded glomus cells with microfluoroimetry and a polarized carbon fiber electrode. Exposure to low PO2 produced a rise of cytosolic [Ca2+] with two distinguishable phases: an initial period (with PO2 values between 150 and approximately 70 mm Hg) during which the increase of [Ca2+] is very small and never exceeds 150-200 nM, and a second phase (with PO2 below approximately 70 mm Hg) characterized by a sharp rise of cytosolic [Ca2+]. Secretion occurs once cytosolic [Ca2+] reaches a threshold value of 180 +/- 43 nM. The results demonstrate a characteristic relationship between PO2 and transmitter secretion at the cellular level that is comparable with the relation described for the input (O2 tension)output (afferent neural discharges) variables in the carotid body. Thus, the properties of single glomus cells can explain the sensory functions of the entire organ. In whole-cell, patch-clamped cells, we have found that in addition to O2-sensitive K+ channels, there are Ca2+ channels whose activity is also regulated by PO2. Ca2+ channel activity is inhibited by hpoxia, although in a strongly voltage-dependent manner. The average hypoxic inhibition of the calcium current in 30% +/- 10% at -20 mV but only 2% +/- 2% at +30 mV. The differential inhibition of K+ and Ca2+ channels by hypoxia helps to explain why the secretory response of the cells is displaced toward PO2 values (below approximately 70 mm Hg) within the range of those normally existing in arterial blood. These data provide a conceptual framework for understanding the cellular mechanisms of O2 chemotransduction in the carotid body.

Plasticity in cultured carotid body chemoreceptors: environmental modulation of GAP-43 and neurofilament

In this study we use dissociated cell cultures of the rat carotid body to investigate the adaptive capabilities of endogenous oxygen chemoreceptors, following chronic stimulation by various environmental factors. These oxygen chemoreceptors are catecholamine-containing glomus cells, which derive from the neural crest and resemble adrenal medullary chromaffin cells. Using double-label immunofluorescence, we found that chronic exposure of carotid body cultures to hypoxia (2% to 10% oxygen) caused a significant fraction of tyrosine hydroxylase-positive (TH+) glomus cells to acquire detectable immunoreactivity for growth-associated protein GAP-43. The effect was dose-dependent and peaked around an oxygen tension of 6%, where approximately 30% of glomus cells were GAP-43 positive. Treatment with agents that elevate intracellular cyclic adenosine monophosphate (cAMP) (i.e., dibutyryl cAMP or forskolin) also markedly stimulated GAP-43 expression. Since hypoxia is known to increase cAMP levels in glomus cells, it is possible that the effect of hypoxia on GAP-43 expression was mediated, at least in part, by a cAMP-dependent pathway. Unlike hypoxia, however, cAMP analogs also stimulated neurofilament (NF 68 or NF 160 kD) expression and neurite outgrowth in glomus cells, and these properties were enhanced by retinoic acid. Nerve growth factor, which promotes neuronal differentiation in related crest-derived endocrine cells, and dibutyryl cGMP were ineffective. Thus, it appears that postnatal glomus cells are plastic and can express neuronal traits in vitro. However, since hypoxia stimulated GAP-43 expression, without promoting neurite outgrowth, it appears that the two processes can be uncoupled. We suggest that stimulation of GAP-43 by hypoxia may be important for other physiological processes, e.g., enhancing neurotransmitter release or sensitization of G-protein-coupled receptor transduction.

Ca(2+)-activated K+ channels in isolated type I cells of the neonatal rat carotid body

1. Ca(2+)-activated K+ (K+Ca) channels in neonatal rat type I carotid body cells were studied using single channel patch clamp techniques. In outside-out patches, using symmetrical 120 mM [K+] solutions, channels were observed with a slope conductance of 190 pS and a reversal potential of 0 mV. Reducing [K+]o to 5 mM shifted the reversal potential as expected for a K(+)-selective channel. 2. With 100 nM Ca2+ bathing the cytosolic aspect of patches, channel activity (number of active channels in a patch x open probability, NPo) increased with depolarization. NPo also increased with increasing 'cytosolic' [Ca2+] at a fixed membrane potential (0 mV). Using outside-out patches, bath application of 20 or 100 nM charybdotoxin reduced NPo by > 85%. These data indicate the presence of K+Ca channels in type I cells. 3. At 0 mV, using solutions of identical composition (1 microM Ca2+ bathing the cytosolic aspect of the channels), NPo was higher in outside-out patches than in inside-out patches. NPo was greatest in recordings using the perforated-vesicle technique. 4. Hypoxia and anoxia were without effect on K+Ca channels in outside-out patches, but caused significant, reversible reductions of NPo in channels recorded in perforated vesicles. 5. The whole-cell perforated-patch technique was used to record membrane potential at 35-37 degrees C. Hypoxia, anoxia and charybdotoxin all depolarized type I cells. 6. Our results suggest an important role for K+Ca channels in type I carotid body cells, and their activity in relation to a model for chemotransduction is discussed.

Transduction of chemostimuli by the type I carotid body cell

The postulated mechanisms for hypoxic and acidic chemotransduction by type I cells that we have described here are summarized in the diagrams of Fig. 4. Most if not all of these require more complete evaluation and, as we have described, there are obvious points of contention that need to be resolved. Nevertheless, it is apparent that studies of isolated type I cell preparations carried out over the last six years have provided significant advancements in our understanding of chemotransduction in the type I cell. Only when the functioning of these cells has been fully described can we hope to understand the mechanisms underlying the responses of the intact organ to chemostimuli.

Differential inhibition by iodonium compounds of induced erythropoietin expression

Diphenylene iodonium chloride suppresses the cobaltous chloride-induced expression of erythropoietin by Hep3B cells to about 50% at a concentration of 30 nM. At that concentration, it has no effect on the response to low oxygen. The related compound iodonium diphenyl chloride acts similarly but is a much less effective inhibitor. If, as reported, diphenylene iodonium chloride is a specific inhibitor of cytochrome b, it follows that the response to CoCl2 is dependent on that enzyme but the response to hypoxia is not.

Hypoxia induces voltage-dependent Ca2+ entry and quantal dopamine secretion in carotid body glomus cells

We have investigated the changes of cytosolic [Ca2+] and the secretory activity in single glomus cells dispersed from rabbit carotid bodies during exposure to solutions with variable O2 tension (Po2). In normoxic conditions (Po2 = 145 mmHg; 1 mmHg = 133 Pa), intracellular [Ca2+] was 58 +/- 29 nM, and switching to low Po2 (between 10 and 60 mmHg) led to a reversible increase of [Ca2+] up to 800 nM. The response to hypoxia completely disappeared after removal of external Ca2+ or with the addition of 0.2 mM Cd2+ to the external solution. These same solutions also abolished both the Ca2+ current of the cells and the increase of internal [Ca2+] elicited by high external K+. Elevations of cytosolic [Ca2+] in response to hypoxia or to direct membrane depolarization elicited the release of dopamine, which was detected by amperometric techniques. Dopamine secretion occurred in episodes of spike-like activity that appear to represent the release from single secretory vesicles. From the mean charge of well-resolved secretory events, we estimated the average number of dopamine molecules per vesicle to be approximately 140,000, a value about 15 times smaller than a previous estimate in chromaffin granules of adrenomedullary cells. These results directly demonstrate in a single-cell preparation the secretory response of glomus cells to hypoxia. The data indicate that the enhancement of cellular excitability upon exposure to low Po2 results in Ca2+ entry through voltage-gated channels, which leads to an increase in intracellular [Ca2+] and exocytotic transmitter release.

Culture of arterial chemoreceptor cells from adult cats in defined medium

Recently patch clamp techniques and optical fluorometric techniques have been applied to freshly dissociated or cultured carotid body. However, very few studies have shown the effects of the dissociation and/or culture conditions on the health and function of the cells. The purpose of this study was to develop a culture method which support healthy and functioning carotid body cells from adult cats. Carotid bodies were dissociated with 0.1-0.2% collagenase and gentle trituration. The cells were plated on glass wells coated with poly-D-lysin and Matrigel, and cultured in chemically defined medium. Culture was maintained for up to 37 days without overgrowth of fibroblasts. Glomus cells extended their processes within and from clusters. Single glomus cells acquired the shape of neurons. Glomus cells synthesized dopamine and its secretion increased during exposure of the cells to hypoxia. Tyrosine hydroxylase was expressed throughout the culture period. These results indicate that glomus cells cultured under conditions described here are healthy and function in a manner similar to that in vivo.

Participation of Na+ channels in the response of carotid body chemoreceptor cells to hypoxia

The role played by Na+ channels of carotid body (CB) chemoreceptor cells was investigated by studying the effects of tetrodotoxin (TTX) on the release of 3H-labeled catecholamines ([3H]CA) by adult rabbit CBs previously incubated with the precursor [3H]tyrosine. TTX inhibited partially the release of [3H]CA elicited by mild hypoxia (10 or 7% O2) or by depolarizing incubation medium containing 20 or 30 mM KCl, but the response to more intense hypoxia (5 or 2% O2) or to higher KCl concentration (40 or 50 mM) was not significantly affected. The release of [3H]CA elicited by acidic stimuli, either 20% CO2 (pH 6.6) or the protonophore dinitrophenol (100 microM), although comparable in magnitude to that elicited by mild hypoxia, was not modified by TTX. These results provide evidence for the first time that Na+ channels of chemoreceptor cells participate in the transduction of hypoxic stimuli into the neurotransmitter release response of these cells and suggest that Na+ current operates as an amplifying device that enhances the initial cell depolarization mediated by the closure of the O2-sensitive K+ channels. Sympathetic denervation of CBs was followed by a marked reduction in the release of [3H]CA elicited by veratridine or by 20 mM KCl, suggesting that the number of Na+ channels in chemoreceptor cells decreases after denervation.

Cell biology of pulmonary neuroepithelial bodies--validation of an in vitro model. I. Effects of hypoxia and Ca2+ ionophore on serotonin content and exocytosis of dense core vesicles

Pulmonary neuroendocrine (NE) cells including the innervated clusters of NE cells--neuroepithelial bodies (NEB)--are difficult to study because of their small numbers and diffuse distribution within the airway mucosa of the lung. We have previously reported a method for isolation and culture of NE cells from rabbit fetal using a combination of mechanical and enzymatic dissociation followed by gradient centrifugation. This method provides single cell suspension of mixed lung cells enriched in NE cells, particularly those originating from NEB. This study further validates our in vitro model by detailed morphologic characterization of cultured NEB cells using high resolution light microscopy, transmission and scanning electron microscopy, HPLC for detection of serotonin (5-HT), and molecular (Northern blot) analysis of mRNA encoding for 5-HT synthesizing enzymes, tryptophane hydroxylase, and aromatic L-amino acid decarboxylase. In addition the effects of hypoxia on NEB cells in vitro were investigated to define the role of these cells as possible airway chemoreceptors. Exposure of NEB cultures to hypoxia resulted in decreased intracellular content of 5-HT accompanied by increased exocytosis of dense core vesicles (DCV). The amount of 5-HT release correlated with the degree of hypoxia, suggesting modulation by ambient pO2 levels. The role of Ca2+ ions in exocytosis of DCV and 5-HT release from NEB cells was tested in experiments with Ca2+ ionophore (A23187). Exposure of cultures to 5 micrograms/ml of ionophore resulted in up to 40% reduction in 5-HT content of NEB cultures as well as increased exocytosis of DCV. Our overall findings are consistent with a view that NEB cells are chemosensory in nature and that Ca2+ signaling pathway is involved in stimulus-secretion coupling. Further refinements in cell separation and culture methodology are required before more detailed investigation of NEB cell membrane properties, signal transduction mechanisms, and intracellular signaling pathways can be carried out.

Characterization of cultured chemoreceptor cells dissociated from adult rabbit carotid body

Short-term cell cultures were obtained from enzymatically dissociated carotid bodies from adult rabbits, and morphological and functional characterization of the cultured chemoreceptor cells were carried out. Under phase contrast, freshly isolated type I cells are round, bright, and 10-14 microns in diameter and exhibit strong fluorescence when stained with the glyoxylic acid technique. The content of endogenous dopamine in the cultures increased from 80 pmol/10(5) cells 2 h after plating the cells to 200 pmol/10(5) cells on the 3rd day, and the rate of synthesis and storage of [3H]dopamine from the precursor [3H]tyrosine increased from 1.7 pmol.10(5) cells-1.h-1 in 1-day cultures to 4 pmol.10(5) cells-1.h-1 on the 3rd day; the later values represent 80-85% of the expected values for the intact carotid body. After labeling with [3H]tyrosine, cultured chemoreceptor cells release [3H]dopamine when challenged by hypoxia, high external K+, or the protonophore dinitrophenol, the pattern of response being similar to that of the intact carotid body. When studied by whole cell clamp recording, individual chemoreceptor cells exhibit a marked variability in the properties of some ionic currents; the data, however, do not support the existence of distinct subpopulations of type I cells.

Regulation of tyrosine hydroxylase gene expression in the rat carotid body by hypoxia

The activity (Vmax) of tyrosine hydroxylase (TH; EC 1.14.16.2), the rate limiting enzyme in the synthesis of catecholamines, is increased in carotid body, superior cervical ganglion, and the adrenal medulla during hypoxia (i.e., reduced PaO2). The present study was undertaken to determine if the increase in TH activity in these tissues during hypoxia is regulated at the level of TH mRNA. Adult rats were exposed to hypoxia (10% O2) or room air for periods lasting from 1 to 48 h. The carotid bodies, superior cervical ganglia, and adrenals were removed and processed for in situ hybridization using 35S-labeled oligonucleotide probes. The concentration of TH mRNA was increased by hypoxia at all time points in carotid body type I cells, but not in cells of either superior cervical ganglion or adrenal medulla. The increase in TH mRNA in carotid body during hypoxia did not require innervation of the carotid body or intact adrenal glands. In addition, hypercapnia, another physiological stimulus of carotid body activity, failed to induce an increase in TH mRNA in type I cells. Our findings suggest that hypoxia stimulates TH gene expression in the carotid body by a mechanism that is intrinsic to type I cells.

Time course of K+ current inhibition by low oxygen in chemoreceptor cells of adult rabbit carotid body. Effects of carbon monoxide

K+ currents recorded from adult rabbit chemoreceptor cells are reversibly inhibited on lowering the pO2 in the bathing solution. Bath application of a hypoxic TTX-containing solution revealed that inhibition of K+ current by low pO2 proceeds faster than TTX inhibition of Na+ currents, the apparent t1/2 being 3.68 and 7.14 s, respectively. Addition of carbon monoxide to the hypoxic gas mixture used to equilibrate the bathing solution reversed the inhibition of K+ currents by approx. 70%.

Whole-cell and perforated-patch recordings from O2-sensitive rat carotid body cells grown in short- and long-term culture

We are investigating transduction mechanisms in a major peripheral chemosensory organ, the rat carotid body, using short- and long-term dissociated cell cultures and patch-clamp, whole-cell recording. In this study membrane properties of cultured glomus or type I cells were characterized with conventional whole-cell recording and the new perforated-patch technique during control (160 Torr) and low-PO2 (20 Torr) conditions. These cells contained voltage-gated channels typical of electrically excitable cells and had large input resistances (approx. 2 G omega). Under whole-cell voltage clamp the cells produced brief inactivating inward currents, which were largely abolished by 0.2-2.0 microM tetrodotoxin, followed by prolonged outward currents, which were reduced by 5 mM tetraethylammonium or abolished by the substitution of Cs+ ions for K+ ions in the pipette. On exposure to hypoxia the outward K+ current was reduced typically by 15%-20% with both conventional whole-cell and perforated-patch recording, which minimizes washout of the cell's cytoplasm. This effect persisted in long-term culture and was specific, since the inward current was unaffected and, moreover, it did not occur in cultured small intensely fluorescent cells, which are closely related to glomus cells. These properties of cultured rat glomus cells are contrasted with those recently reported for freshly isolated rabbit glomus cells.

Responses of type I cells dissociated from the rabbit carotid body to hypoxia

1. The carotid body chemoreceptors are stimulated in situ by hypoxia. We have studied type I cells freshly dissociated from the carotid body of the rabbit. We have used microfluorimetric and patch clamp techniques to examine the responses to hypoxia, to anoxia, and to metabolic inhibition. 2. NADH autofluorescence measured at both 400 and 500 nm increased rapidly and reversibly in response to anoxia or to cyanide (CN-), reflecting a change in mitochondrial metabolism. 3. Indo-1 was used to measure changes in intracellular calcium, [Ca2+]i. Anoxia reversibly increased [Ca2+]i from approximately 50-100 to approximately 200-450 nM in all cells tested. The response showed a striking temperature sensitivity. Responses to hypoxic stimuli were barely detectable at 17-20 degrees C, and were dramatically increased on warming to 36 degrees C. In contrast, responses to K(+)-induced depolarization were only slightly increased in rate of onset and recovery by warming. 4. The rise in [Ca2+]i originated largely from an intracellular store which was slowly depleted by exposure to nominally Ca2(+)-free solutions. Responses were unaffected by blockade of Ca2+ channels with organic (D600, verapamil) or inorganic (Co2+) blockers, by blockade of Na+ channels with tetrodotoxin (TTX), or by increasing action potential duration with tetraethylammonium (TEA). Responses to anoxia were increased by the increased [Ca2+]i loading that follows prior exposure to Ca2(+)-free solutions. 5. Responses to anoxia, to blockade of electron transport by CN-, and to the mitochondrial uncoupler, carbonyl cyanide p-trifluoromethoxy-phenylhydrazone (FCCP), were equivalent in amplitude. The response to anoxia was occluded by concurrent application of FCCP, suggesting that the Ca2+ originates from the same pool in each case. 6. At 35-36 degrees C, responses to graded levels of PO2 were also graded. Thresholds varied between cells, but were typically 30-50 mmHg. Stimulus-responses curves were essentially hyperbolic, increasing dramatically as the PO2 approached 0 mmHg. 7. The sensitivity of cells to hypoxic solutions was increased by acidification of the superfusate over the pH range from 7.3 to 6.85. 8. Cell-attached patch clamp recordings showed depression of spontaneous action potentials associated with a rise in [Ca2+]i during exposure to anoxic solutions. Whole-cell recordings showed that anoxia increased a voltage-gated gK as described previously for CN-, while producing no change in resting conductance. 9. These data suggest that the rise in [Ca2+]i originates largely from Ca2+ efflux from a mitochondrial pool.(ABSTRACT TRUNCATED AT 400 WORDS)

Carbonic anhydrase and neuronal enzymes in cultured glomus cells of the carotid body of the rat

The cellular localization of carbonic anhydrase (CAH) in the carotid body of the rat was investigated by means of Hansson's cobalt-precipitation technique in cultures of dissociated cells. In both young (2-day-old) and old (77-day-old) cultures, the parenchymal glomus (type-I) cells were selectively stained by this technique, and in addition expressed tyrosine hydroxylase and neuron-specific enolase as revealed by immunofluorescence. Enzymic reaction product of CAH appeared to be predominantly intracellular since staining was more intense and occurred more rapidly following permeabilization of the cell membranes with Triton X-100; its formation was inhibited by the CAH-inhibitor acetazolamide (1-10 microM) or by increasing the pH from 5.8 to 7.5. Cryostat sections of the carotid bifurcation revealed intense CAH-reaction product in cell clusters of the carotid body, in a few cells of the nodose ganglion, and in red blood cells. Neuronal cell bodies of the petrosal ganglion and superior cervical ganglion (SCG) were largely non-reactive. The SCG is known to contain clusters of small intensely fluorescent (SIF) cells, which were also non-reactive when grown in dissociated cell culture. Thus, although glomus and SIF cells are often considered to be similar cell types, functional CAH-activity appears unique to glomus cells, and this may be important for the physiological response of the carotid body to certain chemosensory stimuli.

Effects of Putative Neurotransmitters of the Carotid Body on its Own Glomus Cells

Carotid body glomus cells produce and release acetylcholine (ACh), catecholamines, and neuropeptides, and there is biochemical evidence that these cells possess receptors for these substances. Thus, we studied the effects of cholinergics [ACh, nicotine (Nic), bethanechol (BN)] and peptides [met-enkephalin (ME), substance P (SP)] on the membrane potential (Em), voltage noise (Erms), and input resistance (Ro) of glomus cells. Sliced carotid bodies (for cell visualization) of cats, rabbits, and mice were used. The mean Em and Ro of rabbit glomus cells were lower than those of cat and mouse. Ro of mouse cells was the largest, whereas Erms was similar in all species. The various agents had qualitatively similar effects on the cells of the three species although some quantitative differences were sometimes observed. But, for simplicity, results were pooled. ACh depolarized most cells (effect depressed by zero [Ca2+]o and Mn2+), reduced their resistance, and induced variable changes in Erms. Different ACh doses produced non-linear effects on DeltaEm. Nic and BN also depolarized most cells, reducing Ro and Erms. Atropine depressed the cell responses to BN; alpha-bungarotoxin the depolarizing response to Nic. ME and SP depolarized most cells, but only ME significantly reduced Ro. Neither peptide significantly changed voltage noise. Comparing the effects of all drugs showed that BN was the most effective depolarizing agent, producing the largest reductions in Ro. There were negative correlations between DeltaEm and DeltaRo with the cholinergics and SP; correlations between DeltaErms and DeltaRo were significant and positive only with the cholinergics. These results confirm the presence of nicotinic, muscarinic, and peptidergic receptors in glomus cells. The similar effects of cholinergics and peptides and those of flow interruption and anoxia suggest that the latter may partly act via autoreceptors for the released transmitters.

Measurements of intracellular Ca2+ in dissociated type I cells of the rabbit carotid body

1. The carotid body chemoreceptors are stimulated in situ by cyanide (CN-), which mimics the effect of hypoxia. We have shown that CN- increases a calcium-dependent potassium conductance (gK(Ca)) in single type I cells dissociated from the carotid body of the rabbit. We have now used the Ca2(+)-sensitive fluorophore, Fura-2, to measure intracellular Ca2+ directly in single type I cells. 2. CN- reversibly increased [Ca2+]i from approximately 90 nM to a mean of approximately 200 nM. Some of this Ca2+ originated from an intracellular store, which was depleted by exposure to Ca2(+)-free solutions. Prolonged application of CN- caused a sustained increase in [Ca2+]i, suggesting that CN- impairs the removal or sequestration of Ca2+. 3. pHi measured with the dye BCECF (2,7-bis(2-carboxyethyl)-5(and-6)-carboxyfluorescein) did not change consistently in response to CN-, although pHi changed predictably in response to both ammonium chloride and to acidification of the superfusate with CO2. 4. Potassium-induced depolarization (35 mM-K+) caused a large, cadmium-sensitive rise in [Ca2+]i. The K(+)-induced Ca2+ load was used to study the regulation of [Ca2+]i. 5. The clearance of a Ca2+ load was slowed either by removal of [Na+]o or by application of CN-. This shows that both a Na+-Ca2+ exchange and an energy-dependent process or processes contribute to the regulation of [Ca2+]i. 6. Carbachol (CCh, 10-100 microM), which also hyperpolarizes type I cells, caused a small transient rise in [Ca2+]i, indicating release from an exhaustible intracellular pool. The response to CN- was unaffected by prior or continued exposure to CCh, suggesting that the two stimuli operate by distinct mechanisms. 7. The increased gK(Ca) seen in type I cells in response to CN- thus reflects a change in cellular Ca2+ homeostasis. The rise in [Ca2+]i presumably underlies the documented increase in transmitter release from the carotid body in response to CN-. If chemotransduction is a consequence of the release of transmitters from the type I cell, the response of the carotid body to CN-, and possibly also to hypoxia, is thus a direct consequence of the energy dependence of Ca2+ homeostasis in the type I cell.