Low pO2 selectively inhibits K channel activity in chemoreceptor cells of the mammalian carotid body

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.

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.

Effects of two K+ channel openers, aprikalim and pinacidil, on hypoxic pulmonary vasoconstriction

This study investigated the effects of two K+ channel openers, aprikalim and pinacidil, on hypoxic pulmonary vasoconstriction induced in isolated rat lung perfused at constant flow. In order to evaluate the mechanism of the hypoxic vasoconstriction we also studied the effects of an inhibitor of the endothelium-derived relaxing factor (EDRF), NG-nitro-L-arginine methyl ester (100 microM), an inhibitor of the guanylate cyclase, methylene blue (30 microM), two K+ channel blockers, glibenclamide (1 microM) and tetraethylammonium (20 mM). In normoxia, NG-nitro-L-arginine methyl ester, methylene blue, glibenclamide or tetraethylammonium did not enhance significantly the baseline perfusion pressure, suggesting that neither EDRF nor K+ channels are involved in the modulation of the low basal pulmonary vascular tone. In hypoxia, aprikalim and pinacidil (0.03-3 microM) induced a concentration-dependent decrease of pulmonary pressure, exhibiting their spasmolytic effects in acute hypoxia. The hypoxic pressure response was significantly increased by NG-nitro-L-arginine methyl ester, methylene blue and tetraethylammonium, but not by glibenclamide suggesting that EDRF and K+ channels other than ATP-sensitive K+ channels are involved in the modulation of the hypoxic pressure response. The spasmolytic effects of aprikalim and pinacidil (1 microM) were not modified by NG-nitro-L-arginine methyl ester, but were partially reduced by tetraethylammonium and completely abolished by glibenclamide, suggesting that these effects are mainly but not exclusively mediated through ATP-sensitive K+ channel opening.

Exploration of the pulmonary circulation. Festschrift to Professor Donald Heath

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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.

Effects of hypercapnia on membrane potential and intracellular calcium in rat carotid body type I cells

1. An acid-induced rise in the intracellular calcium concentration ([Ca2+]i) of type I cells is thought to play a vital role in pH/PCO2 chemoreception by the carotid body. In this present study we have investigated the cause of this rise in [Ca2+]i in enzymatically isolated, neonatal rat type I cells. 2. The rise in [Ca2+]i induced by a hypercapnic acidosis was inhibited in Ca(2+)-free media, and by 2 mM Ni2+. Acidosis also increased Mn2+ permeability. The rise in [Ca2+]i is dependent, therefore, upon a Ca2+ influx from the external medium. 3. The acid-induced rise in [Ca2+]i was attenuated by both nicardipine and methoxyverapamil (D600), suggesting a role for L-type Ca2+ channels. 4. Acidosis depolarized type I cells and often (approximately 50% of cells) induced action potentials. These effects coincided with a rise in [Ca2+]i. When membrane depolarization was prevented by a voltage clamp, acidosis failed to evoke a rise in [Ca2+]i. The acid-induced rise in [Ca2+]i is a consequence, therefore, of membrane depolarization. 5. Acidosis decreased the resting membrane conductance of type I cells. The reversal potential of the acid-sensitive current was about -75 mV. 6. A depolarization (30 mM [K+]o)-induced rise in [Ca2+]i was blocked by either the removal of extracellular Ca2+ or the presence of 2 mM Ni2+, and was also substantially inhibited by nicardipine. Under voltage-clamp conditions, [Ca2+]i displayed a bell-shaped dependence on membrane potential. Depolarization raises [Ca2+]i, therefore, through voltage-operated Ca2+ channels. 7. Caffeine (10 mM) induced only a small rise in [Ca2+]i (< 10% of that induced by 30 mM extracellular K+). Ca(2+)-induced Ca2+ release is unlikely, therefore, to contribute greatly to the rise in [Ca2+]i induced by depolarization. 8. Although the replacement of extracellular Na+ with N-methyl-D-glucamine (NMG), but not Li+, inhibited the acid-induced rise in [Ca2+]i, this was due to membrane hyperpolarization and not to the inhibition of Na(+)-Ca2+ exchange or Na(+)-dependent action potentials. 9. The removal of extracellular Na+ (NMG substituted) did not have a significant effect upon the resting [Ca2+]i, and only slowed [Ca2+]i recovery slightly following repolarization from 0 to -60 mV. Therefore, if present, Na(+)-Ca2+ exchange plays only a minor role in [Ca2+]i homeostasis. 10. In summary, in the neonatal rat type I cell, hypercapnic acidosis raises [Ca2+]i through membrane depolarization and voltage-gated Ca2+ entry.

Effects of hypoxia on membrane potential and intracellular calcium in rat neonatal carotid body type I cells

1. We have studied the effects of hypoxia on membrane potential and [Ca2+]i in enzymically isolated type I cells of the neonatal rat carotid body (the principal respiratory O2 chemosensor). Isolated cells were maintained in short term culture (3-36 h) before use. [Ca2+]i was measured using the Ca(2+)-sensitive fluoroprobe indo-1. Indo-1 was loaded into cells using the esterified form indo-1 AM. Membrane potential was measured (and clamped) in single isolated type I cells using the perforated-patch (amphotericin B) whole-cell recording technique. 2. Graded reductions in PO2 from 160 Torr to 38, 19, 8, 5 and 0 Torr induced a graded rise of [Ca2+]i in both single and clumps of type I cells. 3. The rise of [Ca2+]i in response to anoxia was 98% inhibited by removal of external Ca2+ (+1 mM EGTA), indicating the probable involvement of Ca2+ influx from the external medium in mediating the anoxic [Ca2+]i response. 4. The L-type Ca2+ channel antagonist nicardipine (10 microM) inhibited the anoxic [Ca2+]i response by 67%, and the non-selective Ca2+ channel antagonist Ni2+ (2 mM) inhibited the response by 77%. 5. Under voltage recording conditions, anoxia induced a reversible membrane depolarization (or receptor potential) accompanied, in many cases, by trains of action potentials. These electrical events were coincident with a rapid rise of [Ca2+]i. When cells were voltage clamped close to their resting potential (-40 to -60 mV), the [Ca2+]i response to anoxia was greatly reduced and its onset was much slower.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanisms and meaning of cellular oxygen sensing in the organism

Oxygen sensors in the body induce various cell activities to avoid any mismatch between oxygen demand and oxygen supply and to maintain an optimal level of oxygen partial pressure (PO2) in various organs. Oxygen sensing seems to be a well conserved process among procaryontic and eucaryontic cells. The molecular mechanism of oxygen sensing is unknown, but it has been suggested that a hemeprotein is involved that does not participate in the mitochondrial energy production. As examplified on the carotid body and on erythropoietin producing HepG2 cells, a cytochrome b was described for the NAD(P)H oxidase of neutrophiles might be an attractive candidate for this hemeprotein. It is hypothesised that hydrogen peroxide (H2O2) produced by this cytochrome b in direct correlation with cellular PO2, serves as a second messenger to regulate potassium channels or gene expression. One might forsee, that this new concept of oxygen sensing could have an impact on all processes in physiology and pathophysiology which are dealing with reactive oxygen intermediates.

Response to cyanide of two types of glomoid cells in mature rat carotid body

Cells belonging to glomoids of mature rat carotid bodies were studied using the whole-cell patch clamp technique following acute dissociation. The recorded population encompassed two subtypes: one type (n = 202), termed G(out), was characterized by a small voltage-dependent inward current (43 +/- 9 pA, mean +/- S.E.M.), large outward current (671 +/- 31 pA @ +40 mV), high membrane resistance (1910 +/- 110 M omega) and low capacitance (5.1 +/- 0.1 pF). A second subtype (n = 56), termed G(in), had significantly lower membrane resistance (177 +/- 35 M omega), higher membrane capacitance (15.0 +/- 1.0 pF) and little voltage-dependent current. Neither subtype supported generation of multiple action potentials during depolarization in the current clamp mode. Intracellular staining of the recorded cells by Lucifer yellow showed co-localization of both subtypes to clusters of cells which stained positively for catecholamines. Somal diameter was slightly, but significantly, larger for G(in) cells (8.7 +/- 0.4 microM, n = 7) compared to G(out) cells (7.8 +/- 0.2 microM, n = 31) and all cells had fine cytoplasmic processes extending around neighboring cells. During recordings using the perforated patch technique, histotoxic hypoxia significantly decreased a voltage-dependent outward current in G(out) cells by 113 +/- 60 pA (n = 13), and decreased the holding current by 10 +/- 4 pA (n = 13) from a control value of -32 +/- 6 pA. In G(in) cells, cyanide significant decreased membrane resistance and decreased holding current by 55 +/- 28 pA from a control value of +120 +/- 42 pA (n = 7), but caused no significant change in outward current. These results show that glomoids of mature rat carotid bodies contain at least two types of cells which differ in their morphologic and electrophysiologic characteristics. The subtypes rapidly respond to histotoxic hypoxia and thus may mediate separate roles in the organ response to chemostimuli.

Hyperosmolality alters the ventilatory response to acute hypercapnia and hypoxia

Acute hyperosmolality in the Pekin duck results in an extracellular acidosis and hypercarbia without any stimulation of ventilation. The development of the extracellular acidosis is accompanied by the concurrent development of an intracellular alkalosis systemically which has been hypothesized to depress ventilation (Kasserra et al., J. Appl. Physiol., 1993). In order to investigate this apparent suppression of ventilation, the ventilatory response to various respiratory challenges (CO2, O2, K+) was studied both before (normosmotic) and after (hyperosmotic) hypertonic sucrose infusion. Increased plasma osmolality caused a significant drop in arterial pH of 0.06 +/- 0.01 units and a 4 Torr increase in PaCO2, yet did not stimulate any significant increase in ventilation despite a significant increase in oxygen consumption. Acute hyperosmolality increased the PaCO2 associated with resting ventilation, and decreased the magnitude of the ventilatory response to a given increase in PaCO2, compared with the response to the same ventilatory challenge in normosmotic animals. Acute hyperosmolality increased the ventilatory response to hypoxia and K+ compared with normosmotic animals. The opposite effect of hyperosmolality on the ventilatory responses to hypercapnia compared with hypoxia suggests that the mechanisms of chemoreception for hypercapnia and hypoxia are different. The depressed ventilatory response curve to increased PaCO2 and decreased arterial pH during hyperosmolality, both alone and during the hypercapnic challenge, suggests that the peripheral chemoreceptor response to pH and CO2 is suppressed. It is hypothesized that the suppression results from the intracellular alkalosis occurring during acute hyperosmolality.

Oxygen sensing in airway chemoreceptors

Pulmonary neuroepithelial bodies, composed of innervated clusters of amine- and peptide-containing cells, are widely distributed throughout the airway mucosa of human and animal lungs. Structurally, neuroepithelial bodies resemble chemoreceptors (such as carotid body, taste buds) and are thought to function as hypoxia sensitive airway sensors. Evidence for this is indirect, however, and the mechanism of oxygen sensing by these cells is unknown. Here we culture neuroepithelial bodies isolated from rabbit fetal lungs and identify voltage-activated potassium, calcium and sodium currents using the whole-cell patch clamp technique. Upon exposure to hypoxia there is a reversible reduction (25-30%) in the outward potassium current, with no change in inward currents. In addition, we demonstrate the expression of an oxygen-binding protein (b-cytochrome, NADPH oxidase) on the plasma membrane of these cells. The identification of an oxygen-sensing mechanism (namely the presence of an O2-sensitive potassium channel coupled to an O2 sensor protein) in the cells of pulmonary neuroepithelial bodies indicates that they are transducers of the hypoxia stimulus and hence may function as airway chemoreceptors in the regulation of respiration.

Opioid peptides in the rabbit carotid body: identification and evidence for co-utilization and interactions with dopamine

The rabbit carotid body is a catecholaminergic organ that contains dopamine and norepinephrine in a proportion of nearly 5:1. Chronic (15 days) carotid sinus nerve denervation or superior cervical ganglionectomy did not modify the carotid body dopamine content (5-6 nmol/mg of protein, equivalent to 250 pmol per carotid body), but sympathectomy reduced by approximately 50% the norepinephrine content. The carotid body has also a very high content of opioid activity (250 equivalent pmol of Leu-enkephalin/mg of protein) as measured by a radioreceptor assay that detects preferentially delta-opioid activity. In the carotid body the degree of opioid posttranslational processing to low-molecular-weight peptides (mostly Leu- and Met-enkephalin) is nearly 80%. HPLC identification of opioid peptides revealed that the sequences of Met- and Leu-enkephalin were in a proportion of nearly 6:1, indicating that the main opioid precursor in the carotid body is proenkephalin A. Chronic denervations of the carotid body did not modify the levels or the degree of opioid precursor processing. Acute hypoxic exposure of the animals (8% O2 in N2; 3 h) resulted in a parallel decrease of dopamine and opioid activity, without any change in the degree of opioid processing. Norepinephrine levels were not affected by hypoxia. These findings suggest corelease of dopamine and opioids during natural hypoxic stimulation. In agreement with the analytical data, [D-Ala2, D-Leu5]enkephalin, but not [D-Ala2,N-Me-Phe4,Gly5-ol]-enkephalin, reduced the in vitro release of dopamine induced by low PO2, a high external K+ concentration, and dinitrophenol. Naloxone augmented the release response elicited by low PO2 stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Dependence of carotid chemosensory responses on metabolic substrates

The dependence of the carotid chemosensory response to hypoxia on metabolic substrate and the hypothesis that lactic acidosis is essential for O2 chemoreception were tested. Effects of 3 types of substrate (glucose, glutamate and a mixture of amino acids) on the response to hypoxia (perfusate flow interruption) were measured (n = 33 carotid bodies). The response to nicotine (n = 25) was used to determine whether these effects were exclusive to the hypoxic response. The cat carotid body was perfused and superfused in vitro with modified Tyrode solution (pO2 > 400 Torr, pCO2 < 1 Torr, pH = 7.4) at 36 degrees C containing a given substrate for at least 15 min prior to flow interruption or nicotine injection. Without substrate, responses to flow interruption (n = 4) and nicotine (n = 2) were irreversibly depressed. With glucose, responses to flow interruption (n = 13) and nicotine (n = 8) increased in a concentration-dependent fashion. Glutamate (42 mM) alone (n = 11) or a mixture of amino acids (4.2 mM) plus 5.5 mM glucose (n = 12) substituted for 11 mM glucose (n = 10). Thus, glutamate (42 mM), or a mixture of amino acids (4.2 mM) or a high concentration of glucose (11 mM) can support chemosensory responses to flow interruption and nicotine. Since glutamate undergoes oxidative deamination to alpha-ketoglutarate without lactic acid production, O2 chemoreception does not depend on lactic acidosis.

Properties of a transient K+ current in chemoreceptor cells of rabbit carotid body

1. Adult rabbit carotid body chemoreceptor cells, enzymatically dispersed and short-term cultured, exhibit an inactivating outward K+ current that is reversibly inhibited by low PO2. In the present work we have characterized the biophysical and pharmacological properties of this current using the whole-cell voltage clamp recording technique. 2. Inactivating current was recorded after blockage of Ca2+ currents with extracellular Co2+, Cd2+, or after complete washing out of Ca2+ channels. 3. The threshold of activation of this inactivating current was about -40 mV. Current activated very quickly (mean rise time 4.8 +/- 0.42 ms at +60 mV) but inactivated more slowly. Inactivation was well fitted by two exponentials with time constants of 79.7 +/- 6.6 and 824 +/- 42.8 ms (at +40 mV). The inactivation process showed a little voltage dependence. 4. The steady-state inactivation was well fitted by a Boltzman function. Inactivation was fully removed at potentials negative to -80 mV and was complete at voltages near -10 mV; 50% inactivation occurred at -41 mV. 5. Recovery from inactivation had several components and was voltage dependent. Initial recovery was fast, but full recovery, even at -100 mV, required more than 30 s. 6. Inactivating current was selectively blocked by 4-aminopyridine (4-AP), in a dose-dependent manner (IC50, 0.2 mM). The duration of chemoreceptor cells action potentials was augmented by 1 mM 4-AP from 2.3 +/- 0.36 to 7.0 +/- 0.25 ms at 0 mV. Tetraethylamonium (TEA), at concentrations above 5 mM, blocked inactivating and non-inactivating components of the whole K+ current. 7. Inactivating current was modulated by cyclic AMP (cAMP). Bath application of 2 mM dibutyryl cAMP reduced peak amplitude by 18.7 +/- 2.9% (at +30 mV) and slowed down the rise time of the current. The effect was not voltage dependent. Forskolin (10-20 microM) also affected inactivating current, by accelerating the inactivation process. In the same preparations neither dibutyryl cAMP nor forskolin affected Ca2+ currents. 8. It is concluded that modulation of K+ channels by cAMP might play a physiological role potentiating the low PO2 inhibition of K+ channels.

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.

The meaning of H2O2 generation in carotid body cells for PO2 chemoreception

The rat carotid body is able to generate H2O2 in type-I cells with the aid of an electron-transferring chain with cytochrome b as the major component as it can be detected by spectrophotometry as well as confocal laser-microscopy. This cytochrome b is reducible by hypoxia, but not by cyanide, indicating that it does not participate in the energy production by the respiratory chain. The carotid body possesses a glutathione peroxidase (GPO) which scavenges H2O2 and other organic hydroperoxides. The nervous chemoreceptor discharge can be inhibited by external application of hydroperoxides with a similar half maximal value (60-80 microM) as used to stimulate GPO. A hypothetical signal chain is described which suggests the involvement of cytochrome b as an O2 sensor in PO2 chemoreception of the carotid body and the degradation of H2O2 by glutathione to control the K(+)-conductivity of carotid body cells.

Modulation of K+ channels by hydrogen peroxide

External application of hydrogen peroxide (H2O2) was found to inhibit the time-dependent fast inactivation process of three cloned voltage-gated K+ channels expressed in Xenopus oocytes: KShIIIC, KShIIID and HukII. As expected from kinetic models where some channels are still opening while a significant fraction of channels is already inactivated there was a large increase in current magnitude concomitant to inactivation block. The channels otherwise functioned normally. The effects of H2O2 were specific (other cloned voltage-gated K+ channels were not affected), and reversible, the currents returned to normal upon removal of the H2O2. H2O2 is produced during normal metabolism; it could act as a modulator of excitability through effects on K+ channels if effective local concentrations are reached in neuronal regions close to the channel. KShIIIC and KShIIID currents are very similar to an O2-sensitive K+ current present in type I cells of the carotid body which is believed to underlie the modulation of excitability of these cells by changes in arterial O2 pressure. H2O2 has been proposed as an intermediary between O2 and cellular response in the carotid body; our results provide support for this model.

Effects of almitrine on the release of catecholamines from the rabbit carotid body in vitro

1. Almitrine increases ventilation by stimulating the carotid body (CB) arterial chemoreceptors but neither its intraglomic target nor its mechanism of action have been elucidated. 2. We have tested the hypothesis that chemoreceptor cells are targets for almitrine by studying its effects on the release of 3H-catecholamines in an in vitro rabbit CB preparation. 3. It was found that almitrine (0.3 and 1.5 x 10(-6) M; i.e. 0.2 and 1 mg ml-1) increases the resting release of 3H-catecholamines from CBs (previously loaded with [3H]-tyrosine) incubated in a balanced 95% O2/5% CO2-equilibrated solution. 4. Almitrine at a concentration of 3 x 10(-6) M (2 mg l-1) also augmented the release of 3H-catecholamines elicited by incubating the CBs in a hypoxic solution (equilibrated with 7% O2/5% CO2 in N2), by high external K+ (35 mM) and by veratridine (2 x 10(-5) M), but did not modify release induced by dinitrophenol (7.5 x 10(-5) M). 5. At the same concentration (3 x 10(-6) M), almitrine increased the rate of dopamine synthesis and was ineffective in modifying the cyclic AMP levels in either normoxic or hypoxic CBs. 6. It is concluded that chemoreceptor cells are the intraglomic targets for almitrine. The mechanisms of action of almitrine on chemoreceptor cells are discussed.

Relative mitochondrial membrane potential and [Ca2+]i in type I cells isolated from the rabbit carotid body

1. In the accompanying paper (Duchen & Biscoe, 1992) we have described graded changes in autofluorescence derived from mitochondrial NAD(P)H in type I cells of the carotid body in response to changes of PO2 over a physiologically significant range. These observations suggest that mitochondrial function in these cells is unusually sensitive to oxygen and could play a role in oxygen sensing. We have now explored further the relationships between hypoxia, mitochondrial membrane potential (delta psi m) and [Ca2+]i. 2. The fluorescence of Rhodamine 123 (Rh 123) accumulated within mitochondria is quenched by delta psi m. Mitochondrial depolarization thus increases the fluorescence signal. Blockade of electron transport (CN-, anoxia, rotenone) and uncoupling agents (e.g. carbonyl cyanide p-trifluoromethoxy-phenylhydrazone; FCCP) increased fluorescence by up to 80-120%, while fluorescence was reduced by blockade of the F0 proton channel of the mitochondrial ATP synthase complex (oligomycin). 3. delta psi m depolarized rapidly with anoxia, and was usually completely dissipated within 1-2 min. The depolarization of delta psi m with anoxia (or CN-) and repolarization on reoxygenation both followed a time course well characterized as the sum of two exponential processes. Oligomycin (0.2-2 micrograms/ml) hyperpolarized delta psi m and abolished the slower components of both the depolarization with anoxia and of the subsequent repolarization. These data (i) illustrate the role of the F1-F0 ATP synthetase in slowing the rate of dissipation of delta psi m on cessation of electron transport, (ii) confirm blockade of the ATP synthetase by oligomycin at these concentrations, and (iii) indicate significant accumulation of intramitochondrial ADP during 1-2 min of anoxia. 4. Depolarization of delta psi m was graded with graded changes in PO2 below about 60 mmHg. The stimulus-response curves thus constructed strongly resemble those for [Ca2+]i and NAD(P)H with PO2. The change in delta psi m closely followed changes in PO2 with time. 5. The rate of rise of [Ca2+]i in response to anoxia is strongly temperature sensitive. The rate of depolarization of delta psi m with anoxia similarly increased at least two- to fivefold on warming from 22 to 36 degrees C. The change with FCCP was not significantly altered by temperature. 6. These data show that the mitochondrial membrane potential changes over a physiological range of PO2 values in type I cells. This contrasts with the behaviour in dissociated chromaffin cells and sensory neurons, in which no change was measurable until the PO2 fell close to zero.(ABSTRACT TRUNCATED AT 400 WORDS)

Mitochondrial function in type I cells isolated from rabbit arterial chemoreceptors

1. In this, and the accompanying paper (Duchen & Biscoe, 1992), we test the hypothesis that the oxygen sensitivity of mitochondrial electron transport forms a basis for transduction in the carotid body, the primary peripheral arterial oxygen sensor. We here describe for isolated type I cells the changes in autofluorescence of mitochondrial NAD(P)H that accompany changes in PO2. 2. NAD(P)H autofluorescence (excitation, 340-360 nm; emission peak, 450 nm) increased with anoxia, reflecting a rise in the NAD(P)H/NAD(P) ratio. Graded increases in autofluorescence were seen in response to graded decreases in PO2, suggesting that mitochondrial function is progressively altered below a PO2 of about 60 mmHg. 3. A mitochondrial origin for the NAD(P)H autofluorescence was suggested by the mutual exclusion of the responses to anoxia and cyanide. 4. Oxidized flavoproteins fluoresce when excited at 450 nm with an emission peak at 550 nm. The small signals obtained under these conditions increased with uncoupler and showed a graded decrease with falling PO2 reflecting a rise in the FADH/FAD ratio. 5. Hypoxia raises [Ca2+]i. The hypoxia-induced changes in mitochondrial function were not secondary to this rise. A brief K(+)-induced depolarization leads to a transient increase in [Ca2+]i. At the same time there is a rapid decrease in NAD(P)H autofluorescence followed by an increase that far outlasts the rise in [Ca2+]i. This delayed increase in autofluorescence was smaller than was the increase with anoxia, even though K(+)-induced depolarization raised [Ca2+]i more than does anoxia. In Ca(2+)-free solutions the depolarization-induced changes were abolished, while those associated with hypoxia were maintained. 6. The changes of autofluorescence with K(+)-induced depolarization appear to reflect (i) oxidation of NAD(P)H by stimulation of respiration following mitochondrial Ca2+ uptake and (ii) reduction of NAD(P) by the Ca(2+)-dependent activation of mitochondrial dehydrogenases. This activation could last several minutes following only 100 ms depolarization, while the changes accompanying hypoxia closely followed the time course of the change in PO2. 7. In similarly isolated rat or mouse chromaffin cells and mouse dorsal root ganglion neurons under identical conditions, no measurable change in autofluorescence or in [Ca2+]i was seen until the PO2 fell below about 5 mmHg. 8. Carbonyl cyanide p-trifluoromethoxy-phenylhydrazone (FCCP) increases O2 consumption, oxidizing mitochondrial NADH and hence decreasing autofluorescence, (delta FFCCP). Blockade of electron transport by anoxia or CN- decreases O2 consumption, increasing mitochondrial NADH/NAD and autofluorescence (delta FCN). The fractional change in autofluorescence with FCCP, delta FFCCP/delta FFCCP+FCN), is thus a measure of resting O2 consumption.(ABSTRACT TRUNCATED AT 400 WORDS)

Oxygen and acid chemoreception in the carotid body chemoreceptors

The carotid bodies are arterial chemoreceptors that are sensitive to blood PO2, PCO2 and pH. They are the origin of reflexes that are crucial for maintaining PCO2 and pH in the internal milieu and for adjusting the O2 supply according to the metabolic needs of the organism in situations of increased demand, such as exercise and while breathing at decreased O2 partial pressures during ascent or when living at high altitude. Chemoreceptor cells of the carotid body transduce the blood-borne stimuli into a neurosecretory response that is dependent on external Ca2+. These cells have an O2-sensitive K+ current that is reversibly inhibited by low PO2. It is proposed that the depolarization produced by inhibition of this K+ current activates Ca2+ channels; Ca2+ influx and neurosecretion follow. The cells have also a potent Na(+)-Ca2+ antiporter that could be responsible for the intracellular Ca2+ rise required to trigger the release of neurotransmitters during high PCO2 or low pH stimulation.

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%.

The role of dihydropyridine-sensitive Ca2+ channels in stimulus-evoked catecholamine release from chemoreceptor cells of the carotid body

The present study utilized an in vitro preparation of the rabbit carotid body, with tissue catecholamine stores labeled by incubation with 3H-tyrosine. The goal was to characterize pharmacologically the voltage-dependent Ca2+ channels present in the type I (glomus) cells of this arterial chemoreceptor organ, and to elucidate their role as pathways for Ca2+ entry. We found that release of 3H-dopamine induced by high external potassium was over 95% dependent on external calcium concentration and that this release was 90-100% inhibited by the dihydropyridine antagonists, nisoldipine and nitrendipine, and was potentiated by the dihydropyridine agonist, BayK 8644. Therefore, any stimulus-induced, calcium-dependent release of 3H-dopamine that was inhibited by nisoldipine and potentiated by BayK 8644, was considered to be supported by Ca2+ entry into the cells via voltage-dependent Ca2+ channels. Significant differences were observed in the release of 3H-dopamine induced by 75 vs 25 mM K+. On prolonged stimulation, release induced by 75 mM K+ was large and transient, whilst that induced by 25 mM K+, although more moderate, was sustained. The release elicited by 75 mM K+ was inhibited approximately 90% by 1.5 mM Co2+ or 625 nM nisoldipine, while release by 25 mM K+ was completely blocked by 0.6 mM Co2+ or 125 nM nisoldipine. Low PO2-induced release of 3H-dopamine was 95% dependent on Ca2+, and was inhibited by nisoldipine (625 nM) in a manner inversely proportional to the intensity of hypoxic stimulation, i.e. 79% inhibition at a PO2 of 49 Torr, and 20% inhibition at PO2 of 0 Torr. BayK 8644 potentiated the release induced by moderate hypoxic stimuli. Release elicited by high PCO2/low pH, or by Na(+)-propionate or dinitrophenol-containing solutions, was approximately 80% Ca(2+)-dependent, and the dihydropyridines failed to modify this release. It is concluded that type I cells possess voltage-dependent Ca2+ channels sensitive to the dihydropyridines, which in agreement with previous electrophysiological data should be defined as L-type Ca2+ channels. Calcium entry which supports the release of 3H-dopamine elicited by moderate hypoxia should occur mainly through these channels while the release induced by strong hypoxic stimuli will be served by Ca2+ entry which occurs in part via voltage-dependent Ca2+ channels, and in part through an additional pathway, probably a Na+/Ca2+ exchanger.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of doxapram on ionic currents recorded in isolated type I cells of the neonatal rat carotid body

Whole-cell patch-clamp recordings were used to investigate the effects of the respiratory stimulant doxapram on K+ and Ca2+ currents in isolated type I cells of the neonatal rat carotid body. Doxapram (1-100 microM) caused rapid, reversible and dose-dependent inhibitions of K+ currents recorded in type I cells (IC50 approximately 13 microM). Inhibition was voltage-dependent, in that the effects of doxapram were maximal at test potentials where a shoulder in the current-voltage relationship was maximal. These K+ currents were composed of both Ca(2+)-activated and Ca(2+)-independent components. Using high [Mg2+], low [Ca2+] solutions to inhibit Ca(2+)-activated K+ currents, doxapram was also seen to directly inhibit Ca(2+)-independent K+ currents. This effect was voltage-independent and was less potent (IC50 approximately 20 microM) than under control conditions, suggesting that doxapram was a more potent inhibitor of the Ca(2+)-activated K+ currents recorded under control conditions. Doxapram (10 microM) was without effect on L-type Ca2+ channel currents recorded under conditions where K+ channel activity was minimized and was also without significant effect on K+ currents recorded in the neuronal cell line NG-108 15, suggesting a selective effect on carotid body type I cells. The effects of doxapram on type I cells show similarities to those of the physiological stimuli of the carotid body, suggesting that doxapram may share a similar mechanism of action in stimulating the intact organ.

Carotid body chemoreception in the absence and presence of CO2-HCO3-

Carotid body (CB) chemosensory responses to natural and pharmacological stimuli were studied in vitro in the presence and nominal absence of CO2-HCO3- in the perfusion-superfusion media. The CBs obtained from cats (n = 10), anesthetized with sodium pentobarbitone, were simultaneously perfused and superfused with a modified Tyrode solution at 36.5 +/- 0.5 degrees C, equilibrated respectively with PO2 of 120 and less than 20 Torr. The Tyrode, nominally free of CO2-HCO3- (HEPES-NaOH, pH 7.38, 310 mOsm), was used first. Subsequently the Tyrode containing HEPES-HCO3-, equilibrated with PCO2 of 36.8 Torr (pH 7.38) was used. Chemosensory discharges were recorded from the carotid sinus nerve. Both hypoxia (PO2 = 20-25 Torr) and ischemic hypoxia stimulated the discharge in the absence and presence of CO2-HCO3-. However, the presence of CO2-HCO3- significantly raised the baseline activity, augmented the speed, sensitivity and the maximal responses to both types of hypoxia. Hypercapnic perfusate (PCO2 = 65 Torr at pH 7.17) produced a peak response equally promptly in the absence and presence of CO2-HCO3- in the ongoing perfusate but generated a larger and more sustained response. Presence of CO2-HCO3- strongly potentiated the responses to cyanide (10(-10)-10(-7) mol) but less strikingly the responses to nicotine (10(-11)-10(-8) mol). Thus, the extracellular CO2-HCO3- significantly improved the response to hypoxia but was not essential for O2 chemoreception. The underlying mechanisms of the effect of CO2-HCO3- is likely to be mediated by the Cl(-)-HCO3- anion exchanger in the pH regulation of glomus cells.

Effects of pHi and pHe on membrane currents recorded with the perforated-patch method from cultured chemoreceptors of the rat carotid body

In this study we investigated the effects of intracellular pH (pHi) and extracellular pH (pHe) on whole-cell currents in cultured glomus cells of the rat carotid body and small, intensely fluorescent (SIF) cells of sympathetic ganglia. The use of the perforated-patch recording technique along with established methods of cytoplasmic acidification allowed us to carry out this study without greatly disturbing the cell's endogenous pH regulatory mechanisms. A reversible decrease in the outward K+ current (20-30%) was observed during acid loading of glomus (and SIF cells) using the K+/H+ ionophore nigericin (3 microM) and acetate (20 mM). A reversible decrease in the inward Na+ current was also observed in both cell types during nigericin application. Application of amiloride (0.1 mM) to the bathing solution inhibited recovery of the K+ current from an acid load implicating the Na+/H+ antiporter as a mechanism involved in pH homeostasis in glomus cells. A reversible decrease in K+ and Na+ currents was also observed during changes in pHe from 7.4 to 6.5. The effects of pHi on membrane currents, Ca2+ levels, and neurotransmitter release are discussed in the context of the role of glomus cells as primary transducers of chemosensory stimuli in arterial blood.

Effects of extracellular pH, PCO2 and HCO3- on intracellular pH in isolated type-I cells of the neonatal rat carotid body

1. The effects of changing PCO2 extracellular pH (pHo) and HCO3- on intracellular pH (pHi) were studied in isolated neonatal rat type-I carotid body cells using the pH-sensitive fluoroprobe, carboxy-SNARF-1. 2. Simulated respiratory acidosis and alkalosis (i.e. changes in PCO2 at constant HCO3-) led to rapid (half-time t0.5 = 3 s) monotonic changes in pHi. The relationship between pHi and pHo under these conditions was linear, steep (0.63 pHi/pHo) and remarkably similar to the response predicted from a passive cell model (i.e. a cell lacking pHi regulation). 3. In order to model the above pHi changes (point 2), it was necessary to determine beta i (intrinsic intracellular buffering power). By using small incremental acid loads in the cell (progressive [NH4+]o removal), beta i was determined as a function of pHi to be: beta i = 127.6-16.04 pHi. 4. Changes in PCO2 at constant pHo (i.e. simultaneously changing HCO3-) caused rapid transient changes in pHi but did not significantly affect steady-state pHi over the range 1-10% CO2. 5. When PCO2 was held constant (5%), changing HCO3- and thus pHo (i.e. a simulated metabolic acidosis/alkalosis) led to much slower changes in pHi (t0.5 approximately 1 min). Steady-state pHi showed an almost identical dependence on pHo (slope 0.68) to that found for simulated respiratory acidosis/alkalosis. Therefore, over the range of pHo, PCO2 and [HCO3-]o tested, steady-state pHi appeared to be a unique function of pHo and independent of PCO2 and [HCO3-]o. 6. The effects on pHi of respiratory acidosis, metabolic acidosis and increases of PCO2 at constant pHo (present work) were compared with previously published work on the ability of similar manoeuvres to increase the carotid sinus nerve (CSN) discharge rate. The two sets of data showed several striking similarities: (i) in both cases, the response to a respiratory acidosis was rapid in onset, maintained and reversible; (ii) in both cases, the speed of response to a metabolic acidosis was significantly slower than in (i) but, again, it was maintained and reversible; (iii) in both cases, increases in PCO2 at constant pHo elicited a rapid response but one which was only transient with no change in the steady-state value. 7. The close correlation between the effects of changing pHo, PCO2 and [HCO3-]o on pHi and on CSN discharge suggests that a change in type-I cell pHi is the first step in the chemoreception of blood pH by the carotid body.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of K+ channel blockers on vascular tone in the perfused rat lung

To learn more of the role of K+ channel activity in the regulation of pulmonary vascular tone, we compared the pressor effects of the differential blockers of numerous K+ channels, tetraethylammonium chloride and 4-aminopyridine, and the inhibitor of ATP-sensitive K+ channels glibenclamide in meclofenamate-treated salt solution-perfused rat lungs. Tetraethylammonium (1 to 20 mM) and 4-aminopyridine (1 to 10 mM), but not glibenclamide (1 to 20 microM) caused vasoconstriction in the normoxic lung. The Ca++ channel blocker nifedipine (0.1 microM) and the alpha adrenoceptor antagonist phentolamine (10 microM) inhibited the 4-aminopyridine response by about 50% and reduced slightly the smaller tetraethylammonium response. 4-Aminopyridine and, to a lesser extent, tetraethylammonium, but not glibenclamide, also potentiated peak vasoconstriction to angiotensin II and airway hypoxia. Nifedipine, but not phentolamine, inhibited hypoxic vasoconstriction and prevented the potentiation by 4-aminopyridine. These results suggest that Ca(++)- and/or voltage-activated (not ATP-sensitive) K+ channels may be important in maintaining low pulmonary vascular tone.

Inhibition of Ca(2+)-activated K+ currents by intracellular acidosis in isolated type I cells of the neonatal rat carotid body

1. K+ and Ca2+ currents were recorded from enzymatically isolated type I cells of the neonatal rat carotid body, using the whole-cell configuration of the patch-clamp technique. The effects of intracellular acidosis, caused by bath application of anions of weak acids (propionate and acetate), were tested on these currents. 2. Bath application of propionate or acetate (10 or 20 mM) caused reversible reductions in K+ current amplitudes. These effects were maximal at low, positive test potentials where a shoulder in the current-voltage relationship occurs due to the activation of Ca(2+)-activated K+ currents. 3. Time-course studies showed propionate to cause a rapid initial reduction of K+ currents which recovered partially during its continued application. Removal of propionate produced small, transient overshoots of K+ current amplitudes. In the absence of propionate or acetate, bath application of the Na(+)-H+ exchange inhibitor amiloride caused slowly developing inhibition of K+ current amplitudes. 4. Changing extracellular pH from 7.4 to 8.0 increased K+ current amplitudes, but at this pHo propionate caused smaller reductions in K+ currents than at a pHo of 7.4. 5. In the presence of 0.1 mM-Cd2+, or in high-Mg2+ (6 mM), low-Ca2+ (0.1 mM) solutions, the residual, Ca(2+)-independent K+ currents were unaffected by 20 mM-propionate or acetate. 6. Ca2+ channel currents were also recorded, using 10 mM-Ba2+ as the charge carrier. These sustained currents were completely abolished by 0.1 mM-Cd2+ and were enlarged in the presence of 5 microM-Bay K 8644, suggesting that the currents passed through L-type Ca2+ channels. 7. Ca2+ channel currents were not significantly affected by intracellular acidosis caused by bath application of 10 mM-propionate or acetate. They were also unaffected by a reduction of the extracellular pH from 7.4 to 7.0. 8. It is concluded that intracellular acidosis selectively inhibits Ca(2+)-activated K+ currents in type I carotid body cells. The possible significance of this effect on chemotransduction in the intact carotid body is discussed.

Intracellular pH and its regulation in isolated type I carotid body cells of the neonatal rat

1. The dual-emission pH-sensitive fluoroprobe carboxy-SNARF-1 (carboxy-seminaptharhodofluor) was used to measure pHi in type I cells enzymically dispersed from the neonatal rat carotid body. 2. Steady-state pHi in cells bathed in a HEPES-buffered Tyrode solution (pH 7.4) was found to be remarkably alkaline (pHi = 7.77) whereas cells bathed in a CO2-HCO3(-)-buffered Tyrode solution (pH 7.4) had a more 'normal' pHi (pHi = 7.28). These observations were further substantiated by using an independent nullpoint test method to determine pHi. 3. Intracellular intrinsic buffering (beta, determined by acidifying the cell using an NH4Cl pre-pulse) was in the range 7-20 mM per pH unit and appeared to be dependent upon pHi with beta increasing as pHi decreased. 4. In cells bathed in a HEPES-buffered Tyrode solution, pHi recovery from an induced intracellular acid load (10 mM-NH4Cl pre-pulse) was inhibited by the Na(+)-H+ exchange inhibitor ethyl isopropyl amiloride (EIPA; 150 microM) or substitution of Nao+ with N-methyl-D-glucamine (NMG). Both EIPA and Nao+ removal also caused a rapid intracellular acidification, which in the case of Nao+ removal, was readily reversible. The rate of this acidification was similar for both Nao+ removal and EIPA addition. 5. Transferring cells from a HEPES-buffered Tyrode solution to one buffered with 5% CO2-HCO3- resulted in an intracellular acidification which was partially, or wholly, sustained. The rate of acidification upon transfer to CO2-HCO3- was considerably slowed by the membrane permeant carbonic anhydrase inhibitor, acetazolamide, thus indicating the presence of the enzyme in these cells. 6. In CO2-HCO3(-)-buffered Tyrode solution, pHi recovery from an intracellular acidosis (NH4+ pre-pulse) was only partially inhibited by EIPA or amiloride whereas Nao+ removal completely inhibited the recovery. The stilbene DIDS (4,4-diisothiocyanatostilbenedisulphonic acid, 200 microM) also partially inhibited pHi recovery following an induced intracellular acidosis. Furthermore, the pre-treatment with 200 microM-DIDS of a pre-acidified cell in Na(+)-free Tyrode solution completely inhibited pHi recovery when Nao+ was reintroduced together with concomitant addition of 150 microM-EIPA. We conclude, that in the presence of CO2-HCO3-, a Na(+)- and HCO3-dependent (DIDS inhibitable) mechanism aids acid extrusion.(ABSTRACT TRUNCATED AT 400 WORDS)