Effect of chronic hypoxia on purinergic synaptic transmission in rat carotid body.

Recent studies indicate that chemoafferent nerve fiber excitation in the rat carotid body is mediated by acetylcholine and ATP, acting at nicotinic cholinergic receptors and P2X2 purinoceptors, respectively. We previously demonstrated that, after a 10- to 14-day exposure to chronic hypoxia (CH), the nicotinic cholinergic receptor blocker mecamylamine no longer inhibits rat carotid sinus nerve (CSN) activity evoked by an acute hypoxic challenge. The present experiments examined the effects of CH (9-16 days at 380 Torr) on the expression of P2X2 purinoceptors in carotid body and chemoafferent neurons, as well as the effectiveness of P2X2 receptor blocking drugs on CSN activity evoked by hypoxia. In the normal carotid body, immunocytochemical studies demonstrated a dense plexus of P2X2-positive nerve fibers penetrating lobules of type I cells. In addition, type I cells were lightly stained, indicating P2X2 receptor expression. After CH, the intensity of P2X2 receptor immunostaining was maintained in chemosensory type I cells and in the soma of chemoafferent neurons. P2 receptor expression on type I cells was confirmed by demonstrations of ATP-evoked increased intracellular Ca2+; this response was modulated by simultaneous exposure to hypoxia. In normal preparations, CSN activity evoked by hypoxia in vitro was 65% inhibited in the presence of specific P2X2 receptor antagonists. However, unlike the absence of mecamylamine action after CH, P2X2 antagonists remained effective against hypoxia-evoked activity after CH. Our findings indicate that ATP acting at P2X2 receptors contributes to adjusted chemoreceptor activity after CH, indicating a possible role for purinergic mechanisms in the adaptation of the carotid body in a chronic low-O2 environment.     

Upregulation of gap junction protein connexin43 in alveolar epithelial cells of rats with radiation-induced pulmonary fibrosis

 The degree of immunoreactive connexin43 (Cx43) in rat lung was evaluated during the development of radiation-induced pulmonary fibrosis in rat by a double immunofluorescence technique using polyclonal antisera to Cx43 and monoclonal antibodies to cytokeratins on cryostat sections. In normal rat lungs, Cx43 was detected in pneumocytes type II and I, in large blood vessel endothelia, in peribronchial smooth muscle cells, and in some peribronchial and perivascular interstitial cells. As early as 1 week after irradiation, enhanced immunoreactivity for Cx43 in the epithelial cells was detected. In severely injured lungs (about 3 months after irradiation), Cx43 was found also in the cytoplasm of type II pneumocytes. These findings were confirmed by western blot data. Western blot analysis also revealed increased phosphorylation of Cx43. It remains to be investigated whether the increased content of Cx43 in irradiated rat lung may be due to an enhanced number of gap junctions between type I and II alveolar epithelial cells. Accepted: 20 May 1996     

Protein phosphorylation signaling mechanisms in carotid body chemoreception

Chemotransduction in the carotid body occurs in specialized type I cells and likely involves a complex series of regulated events which culminates in the release of neurotransmitter agents and the excitation of afferent nerve fibers. Previous studies have shown that multiple factors, including the levels of calcium and cyclic nucleotide second messengers, are important regulators of the chemoreceptor transduction cascade in type I cells. In addition, increases in electrical excitability induced in type I cells by chronic exposure to hypoxia are mimicked by agents which elevate intracellular cyclic AMP levels [Stea et al., J Neurosci 1995;15:2192-2202]. These and other findings suggest that protein kinases, and the phosphorylation of specific protein targets are important components of the hypoxic transduction machinery. Moreover, protein kinase-mediated cascades may participate in the well-known physiological adjustments which occur in the carotid body during prolonged stimulation. In the current study, our data demonstrate (1) the presence of specific protein kinases and target phosphoproteins in the carotid body, and also in the morphologically similar small intensely fluorescent cells of the superior cervical sympathetic ganglia. (2) Nitric oxide production and efferent inhibition in the chemosensory tissue is reduced in the presence of the specific tyrosine kinase inhibitor, lavendustin A. (3) Hypoxia-induced catecholamine release from type I cells is inhibited by the protein kinase A antagonist, Rp-cAMPs. And finally (4), exposure to chronic hypoxia up-regulates the expression of the tyrosine kinase, fyn, and an important growth regulatory phosphoprotein, growth associated protein-43 (GAP-43). These findings suggest that second messenger-mediated phosphorylation and dephosphorylation of specific protein targets is a mechanism capable of regulating diverse cellular functions in the carotid body during acute and chronic stimulation. Copyright Copyright 1999 S. Karger AG, Basel     

Autonomic microganglion cells: a source of acetylcholine in the rat carotid body.

Hypoxic chemosensitivity of peripheral arterial chemoreceptors and the ventilatory response to O2 deprivation increases with postnatal development. Multiple putative neurotransmitters, which are synthesized in the carotid body (CB), are thought to mediate signals generated by hypoxia. Acetylcholine (ACh) is believed to be a major excitatory neurotransmitter participating in hypoxic chemosensitivity. However, it is not known whether ACh originates from type I cells in the CB. In these studies, we tested the hypothesis that choline acetyltransferase (ChAT) and vesicular ACh transporter (VAChT) mRNAs are expressed in the CB and that mRNA levels would increase with postnatal maturation or exposure to hypoxia. Semiquantitative in situ hybridization histochemistry and immunohistochemistry were used to localize cholinergic markers within neurons and cells of the rat CB, the nodose-petrosal-jugular ganglion complex, and the superior cervical ganglion up to postnatal day 28. We show that the pattern of distribution, in tissue sections, is similar for both ACh markers; however, the level of VAChT mRNA is uniformly greater than that of ChAT. VAChT mRNA and immunoreactivity are detected abundantly in the nodose-petrosal-jugular ganglion complex in a number of microganglion cells embedded in nerve fibers innervating the CB for all postnatal groups, whereas ChAT mRNA is detected in only a few of these cells. Contrary to our hypothesis, postnatal maturation caused a reduction in ACh trait expression, whereas hypoxic exposure did not induce the upregulation of VAChT and ChAT mRNA levels in the CB, microganglion, or within the ganglion complex. The present findings indicate that the source of ACh in the CB is likely within autonomic microganglion cells and cholinergic nerve terminals.     

Signal processing at mammalian carotid body chemoreceptors

Mammalian carotid bodies are richly vascularized chemosensory organs that sense blood levels of O₂, CO₂/H⁺, and glucose and maintain homeostatic regulation of these levels via the reflex control of ventilation. Carotid bodies consist of innervated clusters of type I (or glomus) cells in intimate association with glial-like type II cells. Carotid bodies make afferent connections with fibers from sensory neurons in the petrosal ganglia and receive efferent inhibitory innervation from parasympathetic neurons located in the carotid sinus and glossopharyngeal nerves. There are synapses between type I (chemosensory) cells and petrosal afferent terminals, as well as between neighboring type I cells. There is a broad array of neurotransmitters and neuromodulators and their ionotropic and metabotropic receptors in the carotid body. This allows for complex processing of sensory stimuli (e.g., hypoxia and acid hypercapnia) involving both autocrine and paracrine signaling pathways. This review summarizes and evaluates current knowledge of these pathways and presents an integrated working model on information processing in carotid bodies. Included in this model is a novel hypothesis for a potential role of type II cells as an amplifier for the release of a key excitatory carotid body neurotransmitter, ATP, via P2Y purinoceptors and pannexin-1 channels.     

Heterocellular gap junctional communication between alveolar epithelial cells

We analyzed the pattern of gap junction protein (connexin) expression in vivo by indirect immunofluorescence. In normal rat lung sections, connexin (Cx)32 was expressed by type II cells, whereas Cx43 was more ubiquitously expressed and Cx46 was expressed by occasional alveolar epithelial cells. In response to bleomycin-induced lung injury, Cx46 was upregulated by alveolar epithelial cells, whereas Cx32 and Cx43 expression were largely unchanged. Given that Cx46 may form gap junction channels with either Cx43 or Cx32, we examined the ability of primary alveolar epithelial cells cultured for 6 days, which express Cx43 and Cx46, to form heterocellular gap junctions with cells expressing other connexins. Day 6 alveolar epithelial cells formed functional gap junctions with other day 6 cells or with HeLa cells transfected with Cx43 (HeLa/Cx43), but they did not communicate with HeLa/Cx32 cells. Furthermore, day 6 alveolar epithelial cells formed functional gap junction channels with freshly isolated type II cells. Taken together, these data are consistent with the notion that type I and type II alveolar epithelial cells communicate through gap junctions compatible with Cx43.     

Catecholaminergic primary sensory neurons: autonomic targets and mechanisms of transmitter regulation

Contrary to traditional teaching, mammalian primary sensory neurons may express catecholaminergic (CA) neurotransmitter characteristics in vivo. Sensory neurons in the nodose, petrosal, and dorsal root ganglia of rats express tyrosine hydroxylase, the rate-limiting enzyme in CA biosynthesis, and formaldehyde-induced CA fluorescence, in addition to other CA traits. These findings suggest that catecholamines may function as sensory as well as autonomic motor (e.g., sympathetic) neurotransmitters. Most CA cells in the petrosal ganglion project peripherally to the carotid body, which indicates a striking correlation between CA expression in sensory neurons and the pattern of sensory innervation. Inasmuch as petrosal ganglion afferents make synaptic contact with chemoreceptive glomus cells in the carotid body, it is likely that CA sensory neurons in the ganglion transmit chemoreceptor information to the brain stem. Comparison with sympathetic neurons indicates that some mechanisms of CA regulation, such as altered activity of tyrosine hydroxylase in response to depolarizing stimuli, are shared among sensory and traditional CA populations. Other mechanisms, including trophic regulation, appear to be distinct. Therefore, despite expression of common phenotypic traits, CA expression in diverse populations of peripheral neurons is not necessarily associated with a common repertoire of regulatory mechanisms.     

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.     

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. © 1995 John Wiley & Sons, Inc.     

Effect of chronic hypoxia on cholinergic chemotransmission in rat carotid body.

Current views suggest that oxygen sensing in the carotid body occurs in chemosensory type I cells, which excite synaptically apposed chemoafferent nerve terminals in the carotid sinus nerve (CSN). Prolonged exposure in a low-oxygen environment [i.e., chronic hypoxia (CH)] elicits an elevated stimulus-evoked discharge in chemoreceptor CSN fibers (i.e., increased chemosensitivity). In the present study, we evaluated cholinergic chemotransmission in the rat carotid body in an effort to test the hypothesis that CH enhances ACh-mediated synaptic activity between type I cells and chemoafferent nerve terminals. Animals were exposed in a hypobaric chamber (barometric pressure = 380 Torr) for 9-22 days before evaluation of chemoreceptor activity using an in vitro carotid body/CSN preparation. Nerve activity evoked by ACh was significantly larger (P < 0.01) after CH, suggesting increased expression of cholinergic receptors. Approximately 80% of the CSN impulse activity elicited by ACh (100- or 1,000-microg bolus) in both normal and CH preparations was blocked by the specific nicotinic receptor antagonist mecamylamine (100 microM). CSN activity elicited by acute hypoxia or hypercapnia in normal preparations was likewise blocked (> or =80%) in the presence of 100 muM mecamylamine, but after CH the enhanced CSN activity elicited by acute hypoxia or hypercapnia was not reduced in the presence of 100 or 500 microM mecamylamine. A muscarinic receptor antagonist, atropine (10 microM), and a specific nicotinic receptor alpha7 subunit antagonist, methyllycaconatine (50 nM), blocked approximately 50% of the hypoxia-evoked activity in normal preparations but were ineffective after CH. Prolonged exposure to hypoxia appears to dramatically alter chemotransmission in the carotid body, and may induce alternative neurotransmitter mechanisms and/or electrical coupling between type I cells and chemoafferent nerve terminals.     

Developmental regulation of tyrosine hydroxylase expression in primary sensory neurons of the rat

The regulation of transmitter phenotype in primary sensory neurons remains poorly understood. However, recent studies of catecholaminergic (CA) sensory neurons suggest that expression of this particular phenotype may be related to innervation of specific peripheral tissues. In the glossopharyngeal petrosal ganglion (PG) of adult rats, for example, the vast majority of CA sensory neurons innervate a single target, the carotid body. The present study was undertaken, therefore, to begin investigating factors that underlie CA differentiation in sensory neurons, using the rat PG as a model system. Immunocytochemical, biochemical, and morphometric methods were used to investigate the normal time course of CA development in the PG in vivo, employing tyrosine hydroxylase (TH) as a phenotypic marker. These studies revealed two temporally distinct waves of TH expression during embryogenesis. TH immunoreactivity was initially detectable on Embryonic Day (E) 11.5; the number of stained cells increased markedly by E12.5 and then fell off sharply to near 0 by E15.5. Simultaneous immunostaining for TH and neurofilament proteins revealed a high proportion of double-labeled perikarya on E12.5, indicating that the transiently TH-positive cells are neurons. A second, sustained phase of TH expression began on E16.5, and by Postnatal Day 1 adult numbers of TH-containing ganglion cells were present. Western blot analysis demonstrated that TH levels per cell rose 3.5-fold in the perinatal period, indicating that maturation of this particular catecholaminergic trait in PG sensory neurons is highly regulated around birth. Morphometric techniques were used to define the relationship between neurons that transiently exhibit TH immunoreactivity early in gangliogenesis and those that maintain enzyme expression in the mature PG. These studies revealed separate and distinct growth curves for the early and late TH cells, respectively, demonstrating that the appearance, disappearance, and reappearance of immunoreactive cells reflects the differentiation of two separate populations of PG neurons. Moreover, these data indicate that TH expression in the population of CA cells that persists in the mature PG begins around E16.5. This is after peripheral target innervation has begun, raising the possibility that neuron-target interactions regulate biochemical differentiation of these CA sensory neurons.     

A morphometric study of the carotid body in chronically hypoxic rats

We performed morphometric studies of carotid body in acutely and chronically hypoxic rats (inspired PO2 = 70 Torr, at sea level). Acute exposure was for the duration of about 10 min, and chronic exposure lasted for 28 days. We confirmed that the total volume of the organ increased by severalfold. At the light-microscopy level we found an enlargement of the volume density of the blood sinuses from 14 to 31% due to chronic hypoxia. The morphometric hematocrit increased from 39 to 70% paralleling changes in the conventionally measured venous hematocrit. These data do not show any specific plasma skimming in the carotid body blood vessels. With the electron microscope we found that the mean average volume of type I cells increased from 320 micron3 in controls to 1,120 micron3 in the chronically hypoxic rats without hyperplasia, whereas type II cells had increased in number without alteration in size. Qualitative observations revealed that the normal appearance of clusters of ovoid type I cells interspersed by capillaries had been transformed into a pattern of individual cells forming plates between expanded blood vessels with a large increase of contact area between the cells and vessels. Type II cells appeared to have proliferated without changes in individual size to cover the enlarged periphery of type I cells. The observed structural changes in the carotid body parenchyma and vasculature appear to be physiologically adaptive and provide further support for the idea that various elements in the organ are particularly sensitive to hypoxia.     

Satellite glial cells in the trigeminal ganglion as a determinant of orofacial neuropathic pain

Satellite glial cells (SGCs) tightly envelop the perikarya of primary sensory neurons in peripheral ganglion and are identified by their morphology and the presence of proteins not found in ganglion neurons. These SGC-unique proteins include the inwardly rectifying K(+) channel Kir4.1, the connexin-43 (Cx43) subunit of gap junctions, the purinergic receptor P2Y4 and soluble guanylate cyclase. We also present evidence that the small-conductance Ca(2+)-activated K(+) channel SK3 is present only in SGCs and that SGCs divide following nerve injury. All the above proteins are involved, either directly or indirectly, in potassium ion (K(+)) buffering and, thus, can influence the level of neuronal excitability, which, in turn, has been associated with neuropathic pain conditions. We used in vivo RNA interference to reduce the expression of Cx43 (present only in SGCs) in the rat trigeminal ganglion and show that this results in the development of spontaneous pain behavior. The pain behavior is present only when Cx43 is reduced and returns to normal when Cx43 concentrations are restored. This finding shows that perturbation of a single SGC-specific protein is sufficient to induce pain responses and demonstrates the importance of PNS glial cell activity in the pathophysiology of neuropathic pain.     

Comparative immunohistochemical distribution of connexin 37 and connexin 43 throughout folliculogenesis in the bovine ovary

Among gap junctional proteins previously identified in the mouse ovary, connexins (Cx) Cx37 and Cx43 appeared to be essential for normal follicular growth. The aim of this work was to detect Cx37 expression in the bovine ovary, then to quantify and compare its follicular distribution pattern with that of Cx43 using quantitative analysis of immunofluorescently labeled ovary sections viewed with a confocal laser scanning microscope. Cx37 immunoreactivity was detected in bovine ovarian follicles and was predominantly localized at preantral stages. Unlike follicular Cx43 expression which was restricted to granulosa cells, Cx37 staining was observed in both oocyte and granulosa cell compartments. While no changes were seen during early follicular growth, the level of Cx37 expression decreased significantly at the onset of antral cavity formation (P 相似文献   

Chronic CO exposure stimulates erythropoiesis but not glomus cell growth

The effect of chronic CO exposure, which stimulates erythropoietin production and erythropoiesis, was studied on carotid body cells in the rat. The hypothesis to be tested was that chronic CO inhalation would stimulate cellular hypertrophy and hyperplasia of carotid body if it caused local tissue hypoxia as in chronic hypoxia. The failure of an appropriate response would indicate a lack of a specific local effect on carotid body tissue PO2 presumably because of its unusually high tissue blood flow. Six young male rats were exposed to 0.4-0.5 Torr (0.05-0.07%) inspired PCO in air for 22 days. Control rats (n = 6) were maintained under similar conditions except for CO exposure. After the exposure period the rats were anesthetized, blood was collected for hematocrit, and the carotid bodies were surgically exposed and fixed for electron microscopy and morphometry of type I and type II cells and capillary endothelium. Hematocrit was significantly greater in the CO-exposed group (75 vs. 48%), whereas no significant difference was found in the carotid body parenchyma between the control and CO-exposed groups. We conclude that the lack of an effect of chronic CO exposure on the carotid bodies in contrast to the strong erythropoietic response indicates a relatively high tissue blood flow rate in the carotid body and that CO did not exert a direct cellular effect. The results also suggest that the hypertrophic response of carotid body glomus cells to chronic hypoxic hypoxia is the result of a local direct effect of low PO2 rather than secondary to systemic effects.     

Possible role of gap junction intercellular channels and connexin 43 in satellite glial cells (SGCs) for preservation of human spiral ganglion neurons

Human spiral ganglion (SG) neurons show remarkable survival properties and maintain electric excitability for a long time after complete deafness and even separation from the organ of Corti, features essential for cochlear implantation. Here, we analyze and compare the localization and distribution of gap junction (GJ) intercellular channels and connexin 43 (Cx43) in cells surrounding SG cell bodies in man and guinea pig by using transmission electron microscopy and confocal immunohistochemistry. GJs and Cx43 expression has been recognized in satellite glial cells (SGCs) in non-myelinating sensory ganglia including the human SG. In man, SG neurons can survive as mono-polar or “amputated” cells with unbroken central projections following dendrite degeneration and consolidation of the dendrite pole. Cx43-mediated GJ signaling between SGCs is believed to play a key role in this “healing” process and could explain the unique preservation of human SG neurons and the persistence of cochlear implant function.