Vesicular glutamate transporter 2-immunoreactive afferent nerve terminals in rat carotid sinus baroreceptors

Sensory nerve endings respond to various stimuli and subsequently transmit afferent informations to central nervous system, but their responsibility has been suggested to be modulated by glutamate. In the present study, we examined the immunohistochemical localization of vesicular glutamate transporter 1 (vGLUT1) and vGLUT2 in baroreceptor nerve endings immunoreactive for P2X2 and P2X3 purinoceptors in the rat carotid sinus by immunohistochemistry of whole-mount preparations with confocal scanning laser microscopy. P2X3-immunoreactive flat leaf-like axon terminals were immunoreactive to vGLUT2, but not to vGLUT1. Among members of the soluble N-ethylmaleimide-sensitive factor attachment protein receptor complex, immunoreactivities for synaptosomal-associated protein, 25 kDa, Syntaxin1, and vesicle-associated membrane protein 2 (VAMP2) were localized in P2X2- and P2X3-immunoreactive axon terminals. Punctate immunoreactive products for VAMP2 and vGLUT2 were co-localized in axon terminals. These results suggest that vGLUT2 is localized in P2X3-immunoreactive baroreceptor terminals in the carotid sinus, and these terminals may release glutamate by exocytosis in order to modulate baroreceptor function in the carotid sinus.

Coumestrol inhibits carotid sinus baroreceptor activity by cAMP/PKA dependent nitric oxide release in anesthetized male rats

Phytoestrogens could offer multiple beneficial effects on the cardiovascular system. Here, we have examined the effects of coumestrol (CMT) on carotid baroreceptors activity (CBA) and the possible mechanisms in male rats. The functional parameters of carotid baroreceptors were measured by recording sinus nerve afferent discharge in anesthetized male rats with perfused isolated carotid sinus. The levels of protein expression were determined by using ELISA and Western blotting. CMT (1 to 100μmolL(-1)) inhibited CBA, which shifted the functional curve of the carotid baroreceptor to the right and downward, with a marked decrease in the peak slope and the peak integral value of carotid sinus nerve discharge in a concentration dependent manner. These effects were not blocked by a specific estrogen receptor antagonist ICI 182,780, but were completely abolished by nitric oxide (NO) synthase inhibitor l-NAME (N(G)-nitro-l-arginine methyl ester). Furthermore, a NO donor, SIN-1(3-morpholion-sydnon-imine), could potentiate these inhibitory effects of CMT. CMT stimulated the phosphorylation of Ser(1176)-eNOS (endothelial nitric oxide synthase) in a dose-dependent manner in carotid bifurcation tissue over a perfusion period of 15min. The rapid activation of eNOS by CMT was blocked by a highly selective PKA (protein kinase A) inhibitor H89. In addition, inhibition of PI3K (phosphatidylinositol-3-kinase) and ERK (extracellular signal-regulated kinase) pathways had no effect on eNOS activation by CMT. CMT inhibited CBA via eNOS activation and NO synthesis. These effects were mediated by the cAMP/PKA pathway and were unrelated to the estrogenic effect.

Discharges of aortic and carotid sinus baroreceptors during spontaneous motor activity and pharmacologically evoked pressor interventions

Our laboratory has demonstrated that the cardiomotor component of aortic baroreflex is temporarily inhibited at the onset of spontaneous motor activity in decerebrate cats, without altering carotid sinus baroreflex. A reason for this dissociation may be attributed to a difference in the responses between aortic nerve activity (AoNA) and carotid sinus nerve activity (CsNA) during spontaneous motor activity. The stimulus-response curves of AoNA and CsNA against mean arterial blood pressure (MAP) were compared between the pressor interventions evoked by spontaneous motor activity and by intravenous administration of phenylephrine or norepinephrine, in which the responses in heart rate (HR) were opposite (i.e., tachycardia vs. baroreflex bradycardia), despite the identical increase in MAP of 34-40 mmHg. In parallel to the pressor response, mean AoNA and CsNA increased similarly by 78-81 and by 88 % of the baseline control, respectively, irrespective of whether the pressor response was evoked by spontaneous motor activity or by a pharmacological intervention. The slope of the stimulus-response curve of the mean AoNA became greater (P < 0.05) during spontaneous motor activity as compared to the pharmacological intervention. On the other hand, the stimulus-response curve of the mean CsNA and its slope were equal (P > 0.05) between the two pressor interventions. Furthermore, the slopes of the stimulus-response curves of both diastolic AoNA and CsNA (defined as the minimal value within a beat) exhibited a greater increase during spontaneous motor activity. All differences in the slopes of the stimulus-response curves were abolished by restraining HR at the intrinsic cardiac frequency. In conclusion, mean mass activities of both aortic and carotid sinus baroreceptors are able to encode the beat-by-beat changes in MAP not only at rest but also during spontaneous motor activity and spontaneous motor activity-related reduction of aortic baroreceptor activity is denied accordingly.

Elastin and mechanoreceptor mechanisms with special reference to the mammalian carotid sinus

Light microscopic studies reveal that the carotid baroreceptor region in mammals, located at the origin of the internal carotid artery, has a preponderantly elastic structure and a thick tunica adventitia. Electron microscopy discloses the presence of sensory nerve endings within the parts of the tunica adventitia adjoining the preponderantly elastic zone of the internal carotid artery. Bundles of collagen fibres in the tunica adventitia form convolutions or whorls around the nerve terminals and often terminate on the surface of the elastic fibres or into the basement membranes of the neuronal profiles. It is concluded that the large content of elastic tissue in the tunica media of the baroreceptor region renders the vessel wall highly distensible to intraluminal pressure changes, and thereby facilitates transmission of the stimulus intensity to sensory nerve terminals. However, a change in the geometrical configuration of the bundles of collagen under the influence of elastic fibres may provide a better insight into the mechanisms of distortion of the baroreceptors related to and/or in contact with collagen fibres. In support of this is the demonstration of contact sites between collagen and elastic fibres.

Cyclic phosphatidic acid stimulates respiration without producing vasopressor or tachycardiac effects in rats

The effects of a novel lipid mediator, cyclic phosphatidic acid (cPA), on respiratory and cardiovascular functions were examined in anesthetized rats. Intravenous (i.v.) administration of 3-O-carba-oleoyl-cPA at doses of 130 and 390 microg/kg produced dose-dependent increases in tidal volume and respiratory frequency, resulting in an increase in total ventilation. Heart rate was slightly decreased at a dose of 390 microg/kg, while systemic arterial pressure was not affected. Bilateral section of vagi and carotid sinus nerves designed to eliminate major regulatory inputs from the peripheral afferents to the respiratory center reduced these responses, but did not abolish them. These results indicate that cPA stimulates respiration, via central and peripheral mechanisms acting on the central respiratory rhythm generator in the brain stem. Administration of cPA may be of therapeutic value as a respiratory stimulant without producing vasopressor or tachycardiac effects, for treatment of respiratory disorders.

Oxygen Mass Transport in a Compliant Carotid Bifurcation Model

The purpose of the present study was to investigate oxygen mass transfer in the human carotid bifurcation, focusing on the effects of the wall compliance and flow field on the temporal variation and spatial distribution of the oxygen wall flux. Details of unsteady convective-diffusive oxygen transport were examined numerically using a compliant model of the human carotid bifurcation and realistic blood flow waveforms. Results reveal that axial flow separation at the outer common-internal carotid wall can significantly alter the flow field, oxygen tension field, and oxygen wall flux distribution. At the outer wall of the sinus, the Sherwood number, Sh (non-dimensional oxygen wall flux), takes on significantly lower values than at other sites due to the attenuation of transport rates by convective flow away from wall. More specifically, the lowest value of Sh was Sh approximately 6 (in the sinus), which is much lower than the value of the non-dimensional oxygen consumption rate (Damkohler number, Da) in the reactive wall tissue (Da=29-39). At the inner wall of the sinus, Sh approximately 170 is far above the expected value of Da. This implies that flow separation on the outer wall of the sinus provides a very strong fluid mechanical barrier to oxygen transport; whereas at the inner wall of the sinus, the mechanism of transport is controlled by the wall consumption rate.

Catecholamine release from isolated sensory neurons of cat petrosal ganglia in tissue culture

The petrosal ganglion (PG) is entirely constituted by the perikarya of primary sensory neurons, part of which innervates the carotid body via the carotid sinus nerve (CSN). Application of acetylcholine (ACh) or nicotine (Nic) as well as adenosine 5'-triphosphate (ATP) to the PG in vitro increases the frequency of CSN discharges, an effect that is modified by the concomitant application of dopamine (DA). Since a population of PG neurons expresses tyrosine hydroxylase, and DA is released from the cat carotid body in response to electrical stimulation of C-fibers in the CSN, it is possible that DA may be released from the perikarya of PG neurons. Therefore, we studied whether ACh or Nic, ATP and high KCl could induce DA release from PG neurons in culture. Petrosal ganglia were excised from pentobarbitone-anesthetized adult cats, dissociated and their neurons maintained in culture for 7-21 days. Catecholamine release was measured by amperometry via carbon-fiber microelectrodes. In response to KCl, Nic, ACh or ATP application, about 25% of neurons exhibited electrochemical signals compatible with DA release. This percentage increased to 41% after loading the neurons with exogenous DA. The present results suggest that DA release may be induced from the perikarya of a population of PG neurons.

[Angiotensin II contents in plasma, and cardiac and renal tissues of sinoaortic denervated rats]

Our previous data demonstrate that impairment of arterial baroreceptor reflex (ABR) plays an independent role in hypertension target organ damage. To elucidate the mechanisms responsible for the dysfunction of ABR associated organ damage, sinoaortic denervated (SAD) rats were used as an animal model of ABR dysfunction. Twenty-four-hour continuous blood pressure (SBP and DBP), blood pressure variability (BPV), heart rate (HR) and HR variability (HRV) were measured in conscious and unrestrained rats. Angiotensin II (Ang II) in plasma, heart and kidney was assayed by raio-immunological assay (RIA) 1 or 18 weeks after denervation. In short-term SAD rats, twenty-four-hour mean SBP and DBP increased compared with that of sham-operated rats and long-term SAD rats. No significant difference in SBP, DBP or HR was found between long-term SAD rats and sham-operated ones. Compared with the sham-operated rats, long-term SAD rats had elevated BPV. No significant change in Ang II levels of caridiac and renal tissues was found in short-term SAD rats. In long-term SAD rats, Ang II level of plasma was not increased while the Ang II content in the heart and kidney increased. Ang II contents of plasma and tissues in long-term SAD rats exposed to chronic stress were higher than those in the control rats. These results show (1) in short-term SAD rats blood pressure increased, while in long-term SAD rats 24 h mean blood pressure did not increase, although BPV elevated in long-term SAD rats; (2) in long-term SAD rats, secretion of Ang II in cardiac and renal tissues was enhanced and more Ang II released when the animals were exposed to chronic stress. These results suggest that elevated BPV and secretion of Ang II may be related to the development of organ damage induced by ABR dysfunction.

Carotid sinus nerve chemosensory response to dopamine and acetylcholine in catecholamine depleted cats

The aim of this study was to determine the role of endogenous dopamine (DA) and the combined effect of DA and acetylcholine (ACh) on the carotid sinus nerve chemosensory discharge (CSND). CSND was measured in vivo in 6 control cats and 6 cats pre-treated with reserpine and alpha-methyl-paratyrosine [catecholamine depleted group: CAD] during infusions of DA and DA+ACh. In normoxia, CSND was similar between CAD's and controls. DA induced CSND depression was transient in controls but sustained in CAD's. Addition of ACh increased CSND in both groups. In hypoxia (8% O(2) in N(2)), the dynamic CSND response was slowed by DA in CAD's but not controls. Addition of ACh increased this response in both groups. Neither DA nor DA+ACh altered the steady state hypoxic CSND in either group. It is concluded that endogenous DA is important in expressing the dynamic characteristics of both the response to exogenous DA and the response to hypoxia under constant DA infusion. The study also confirms the opposing effects of exogenous DA and ACh on the normoxic CSND.

Arterial baroreflex deficit induced organ damage in sinoaortic denervated rats

To verify the independent role of the arterial baroreceptor dysfunction involved in target-organ damage in hypertension, sinoaortic denervated (SAD) rats were used as a model of arterial baroreflex (ABR) deficit. SAD, isolated aortic-denervated (AD), and isolated sinus-denervated (SD) rats were instrumented to record blood pressure (BP), heart rate (HR), BP variability (BPV), HR variability (HRV), ABR function control of heart period (ABR-HP), and BP (ABR-BP). Vascular maximum contractile/relaxant function was determined and organ damage was estimated by observation of morphologic changes. Short-term (postoperative 1 week) SAD caused hypertension and tachycardia in rats. Eighteen weeks after operation, BP and HR values in SAD and SD rats were not different from those in sham-operated rats, but AD rats were hypertensive compared with control group. Although 24-h mean BP values of long-term SAD rats were not different from those of sham-operated rats, 24-h BPV of SAD rats was significantly higher than that of sham-operated rats. Arterial baroreflex function in short-term SAD rats was significantly less than in sham-operated rats, whereas in long-term SAD rats, ABR-HP and ABR-BP were higher than those in short-term SAD rats, but were still significantly lower than those in control groups. At postoperative 18 weeks, baroreflex function in SAD and AD rats was significantly less than function in SD and control groups. SBPmax after phenylephrine and DBPmin after nitroprusside were significantly higher in SAD, AD, and SD rats than in control rats. Baroreflex function was negatively correlated to DBPmin and SBPmax in all denervated rats (n = 44). Some morphologic changes were found 18 weeks after denervation in heart, kidney, and small artery in SAD, AD, and SD rats. Baroreflex function in all denervated rats was negatively related to 24-h BPV values. In contrast, 24-h BPV values in SAD, AD, and SD rats were positively related to organ-damage score. A negative correlation between ABR function and end-organ damage score was found. Arterial baroreflex deficit played an independent and important role in organ-damage in SAD rats with significantly elevated 24-h BPV.

Effects of selective sinoaortic denervations on phenylephrine-induced activational responses in the nucleus of the solitary tract

Intravenous administration of phenylephrine provokes a pattern of cellular activation in the nucleus of the solitary tract that resembles the central distributions of primary baroreceptor afferents supplied by the carotid sinus and aortic depressor nerves. Transganglionic transport and denervation methods were used in an experimental setting to test the dependence of phenylephrine-induced Fos immunoreactivity on the integrity of buffer nerve afferents, and to identify the subregions of the nucleus of the solitary tract supplied by each. Cholera toxin B-horseradish peroxidase injections into either or both nerves revealed terminal labeling concentrated in, but not restricted to, the dorsal commissural part of the nucleus of the solitary tract at the level of the apex of calamus scriptorius, and extending into the dorsal subnucleus at the level of the area postrema. Preferential ramifications of carotid sinus and aortic depressor nerve afferents at the levels of the commissural part of the nucleus and the area postrema, respectively, were reflected in the extent to which labeled fibers comingled with neurons exhibiting phenylephrine-induced Fos in dual labeling experiments. Complete sinoaortic denervation reduced by 90% the number of neurons exhibiting drug-induced Fos expression. Selective carotid and aortic sinus denervations effected partial reductions manifest preferentially in the caudal and rostral foci of the distribution, respectively. Reduced activational responses at the level of the area postrema of aortic sinus-denervated rats were accompanied by a reduction in cellular nicotinamide adenine dinucleotide phosphate-diaphorase activity in this region. Animals killed 30 days after complete sinoaortic denervation displayed no evidence of recovery of phenylephrine-induced Fos, while the strength and distribution of the response in rats that received selective carotid sinus denervation were indistinguishable from those seen in controls. These findings (i) support the dependence of phenylephrine-induced Fos expression on the integrity of carotid sinus and aortic depressor nerve afferents, (ii) provide anatomical and functional evidence that the two buffer nerves distribute differentially within the nucleus of the solitary tract, and (iii) implicate central reorganization as a likely basis for functional recovery of baroreflex mechanisms following partial sinoaortic denervation.

Thromboxane A2 does not act at the carotid sinus to mediate cardiovascular, adrenocorticotropin, cortisol, or blood gas responses

Thromboxane A2 (TxA2), well known as a vasoconstrictor and activator of platelets, also stimulates reflex cardiovascular, pituitary, adrenocortical, and blood gas responses, although the site of action is unknown. Previously we determined that the site of these actions is perfused by the carotid vasculature. The purpose of the present study was to test the hypothesis that TxA2 stimulates these responses by acting at the carotid sinus. The TxA2 mimetic U46619 (1 microgram.kg-1.min-1) or saline was infused into the carotid artery (CA) or vena cava in conscious, chronically instrumented carotid sinus denervated (CSD) or sham-operated sheep. Mean arterial pressure increased in all groups receiving U46619. Heart rate increased only in the CSD group receiving CA infusions of U46619. Adrenocorticotropic hormone (ACTH) and cortisol increased in the sham and CSD groups receiving CA U46619, and responses were not different between sham and CSD groups. PaCO2 values were higher in all CSD treatment groups compared with sham treatment groups. Arterial pH increased and PaCO2 decreased in both the sham and CSD groups in response to CA U46619. Although PaCO2 values were higher overall in the CSD group, the magnitude of change in response to U46619 infusions was similar in sham and CSD animals. There was no difference in pHa between CSD and sham groups. Hematocrit and PaO2 did not change. We conclude that TxA2 does not act at the carotid sinus, as responses to U46619 infusions in CSD animals were not different in the cases of ACTH, cortisol, and blood gases, or were enhanced rather than diminished in the case of heart rate. These findings support a hypothesis that TxA2 acts at the brain to mediate cardiovascular, pituitary, adrenocortical, and blood gas responses.

Gene transfer to carotid sinus in vivo: a novel approach to investigation of baroreceptors

Baroreceptor nerve endings are located in the adventitia of the carotid sinuses and aortic arch. The goal of the present study was to develop a method for gene transfer to the carotid sinus adventitia. Replication-deficient adenovirus containing the gene for Escherichia coli beta-galactosidase (beta-Gal) was applied topically to the carotid sinuses of anesthetized rabbits. Transgene expression was localized by histochemical staining and quantified by chemiluminescence assay (Galacto-Light). Possible effects of adenovirus on baroreceptor sensitivity were investigated by recording baroreceptor activity from the vascularly isolated carotid sinus over a pressure range of 0 to 160 mm Hg. Beta-Gal expression in carotid sinus was evident 1 day after virus application, was dose dependent, and was markedly enhanced after 4 days. Expression was restricted to the adventitia of the vessel wall and was not present in vehicle-treated carotid sinuses. Baroreceptor sensitivity measured from carotid sinuses exposed to adenovirus 4 to 5 days beforehand was not altered compared with that measured from control carotid sinuses. In summary, topical application of adenoviral vectors to the carotid sinus provides transgene expression restricted to the region of baroreceptor innervation. The technique provides a novel approach to delineate mechanisms involved in baroreceptor activation and to deliver neuroactive gene products to the baroreceptors.

Precise coexistence of regulatory peptides in the nerve fibers of the amphibian carotid labyrinth demonstrated by a combination of double immunofluorescence labelling and a multiple dye filter

An application of double-immunolabelling in combination with a multiple dye filter system demonstrated new findings regarding the distribution pattern of peptidergic fibers in the carotid labyrinth to addition to our previous findings shown by the individual filter system. In high magnification images of about 10% of the yellowish fibers which represent the coexistence of two neuropeptides, there was a definite difference in localization between the fluorescence originating from rhodamine (substance P fibers) and from FITC (vasoactive intestinal polypeptide and neuropeptide Y fibers), but it was clear that they are intertwined within a single nerve bundle. This combination method was able to discriminate two different peptidergic fibers which run side by side. The coexistence suggested previously by the individual filter system may actually be due to the phenomenon described above. This means that it is necessary to apply the multiple dye filter system for reliable evidence of coexistence of different two substances in a single nerve fiber.

Peptidergic innervation in the amphibian carotid labyrinth

The amphibian carotid labyrinth, which corresponds to the mammalian carotid body and carotid sinus, is innervated by nerve fibers containing substance P (SP), calcitonin gene-related peptide (CGRP), vasoactive intestinal polypeptide (VIP), neuropeptide Y (NPY), FMRFamide (FMRF), and somatostatin (SOM). SP, CGRP, VIP, and NPY immunoreactive varicose fibers are more densely distributed in the peripheral portion of the carotid labyrinth than FMRF and SOM fibers. The time of appearance of SP, CGRP, and VIP is different for each. First CGRP fibers, then SP fibers appear at an early stage of larval development, and finally VIP fibres are detected at a later stage of larval development. Most SP fibres show coexistence with CGRP, and some SP fibres which show coexistence with NPY immunoreactivity are assumed to be continuous with those demonstrating VIP immunoreactivity. This indicates the possibility of coexistence of four different peptides in the same nerve fibers within the labyrinth. In various vasculatures of mammals, it has been shown that SP, CGRP, VIP, and NPY have a vasoactive nature in relation to the vascular smooth muscle cells. On this basis, it seems that the target of the peptidergic innervation in the amphibian carotid labyrinth is the smooth muscle cells which are abundantly distributed in the intervascular stroma. Accordingly, the peptidergic innervation may be involved in the vascular regulatory function of the labyrinth, although the possibility that these peptides participate in the chemoreception cannot be ruled out. In addition, the vascular regulatory function of the labyrinth may be modulated by the interaction of multiple neuropeptides.

NMDA receptor-mediated sympathetic chemoreflex excitation of RVL-spinal vasomotor neurones in rats

1. We investigated the role of N-methyl-D-aspartic acid (NMDA) receptors in mediating hypoxic excitation of the reticulospinal vasomotor neurones of the rostroventrolateral reticular nucleus (RVL) of the medulla oblongata in paralysed ventilated rats. 2. Unilateral close arterial injection of sodium cyanide (100 nmol) into the carotid sinus region or ventilation with 100% N2 for 12 s rapidly, reversibly and reproducibly excited the RVL-spinal vasomotor neurones, followed about 1-2 s later by increases in sympathetic nerve activity and arterial pressure, effects abolished by denervation of the ipsilateral carotid sinus nerve. 3. Ionophoresis onto the RVL-spinal vasomotor neurones of kynurenate (a wide-spectrum antagonist of the excitatory amino acid receptors) or of 2-amino-5-monophosphovaleric acid (APV; a selective NMDA receptor antagonist), but not of xanthurenate (an inactive analogue of kynurenate), blocked the excitation elicited by intracarotid cyanide or 12 s of hypoxia. Kynurenate completely and APV partially blocked the excitatory responses to ionophoretically applied L-glutamate. APV, however, did not alter the excitatory responses of the vasomotor neurones to ionophoreses of kainate and quisqualate. 4. Bilateral microinjection of kynurenate (10 nmol, 50 nl per site) or APV (5 nmol, 50 nl per site) into the RVL blocked the increases in arterial pressure elicited by intracarotid cyanide or 12 s of 100% N2 ventilation. 5. Twenty seconds of intratracheal administration of 100% N2 resulted in complex and prolonged elevations of arterial pressure, the late component of which was affected neither by sinus denervation nor by microinjections of kynurenate or APV into the RVL. 6. We conclude that the sympathetic and cardiovascular responses to stimulation of arterial chemoreceptors result from excitation of RVL-spinal vasomotor neurones via activation of the NMDA subtypes of the excitatory amino acid receptors of the neurones. In contrast, the failure of these antagonists to influence the delayed excitation of the RVL-spinal vasomotor neurons by more prolonged exposure to N2 inhalation further supports the view that these neurones are directly stimulated by hypoxia.

Postnatal maturation of carotid chemoreceptor responses to O2 and CO2 in the cat

This study aimed to characterize neural responses of the carotid chemoreceptors of the maturing cat to natural stimuli and to determine the time course of carotid chemoreceptor development from the neonatal period to adulthood. Carotid sinus nerve (CNS) responses to O2 and CO2 were studied in cats at 1, 4, and 8 wk of age and in adult cats (n = 6 at each age). Pentobarbital sodium-anesthetized cats were exposed to three levels of O2 (arterial PO2 = 40-45, 80-90, and > 300 Torr) at five levels of arterial PCO2 (22, 35, 48, 63, and 75 Torr) while the moving average of whole nerve output from the CSN was recorded. Ganglioglomerular nerves were sectioned. All cats at every age increased CSN activity during hypoxia. However, the CSN response to hypoxia was not sustained in some immature cats. Of the cats that sustained CSN activity during hypoxia, four of the six 1-wk-old cats showed a biphasic pattern of response, with an initial overshoot followed by a steady level of discharge. Older cats did not exhibit this pattern. CNS sensitivity to hypoxia was weakest in 1-wk-old kittens but increased to nearly adult levels by 4 wk of age. Carotid chemoreceptor responses to CO2 were also smallest in 1-wk-old kittens and increased with maturation. However, unlike hypoxia responses, CO2 sensitivity during hypoxia continued to develop between 8 wk and adulthood. O2-CO2 interaction did not become significant until after 4 wk of age. Thus, carotid chemoreceptor responses to both O2 and CO2 are weak in newborn cats and increase during postnatal development.(ABSTRACT TRUNCATED AT 250 WORDS)

Release of dopamine from carotid sinus nerve fibers innervating type I cells in the cat carotid body

This study presents evidence that dopaminergic neurons innervate the cat carotid body. Immunocytochemical studies revealed many tyrosine hydroxylase (TH)-positive nerve fibers in the carotid body which establish extensive contacts with type I cells. All TH-positive intralobular profiles disappeared with chronic carotid sinus nerve (CSN) section, but survived sympathectomy following removal of the superior cervical ganglion. The level of endogenous dopamine (DA) in the CSN was higher than that for norepinephrine (NE). While both catecholamines were synthesized by the nerve at similar rates, NE synthesis was abolished by chronic sympathectomy, but DA synthesis remained largely unchanged following this procedure. Our data indicate that DA is not present in the CSN as a mere precursor of NE. Following a 3-hour incubation of carotid bodies with their attached nerves in media containing 20 microM 3H-tyrosine, electrical stimulation of CSN C-fibers in chronically sympathectomized preparations provoked the release of 3H-DA, but not 3H-NE.

Changes in heart rate by verapamil during carotid sinus stimulation in patients with hyperparathyroidism, pre- and postoperatively

It has been investigated whether calcium- and verapamil-dependent sensitivities of carotis baroreceptors also exist in man. To answer this question, we pre- and postoperatively measured changes in heart rate during carotid sinus stimulation before and after intravenous administration of 5 mg verapamil in 23 patients with primary hyperparathyroidism. Findings during hypercalcemia were as expected: a more pronounced reduction of heart rate at comparatively low calcium levels. During normocalcemia, we found an opposite effect: a more pronounced reduction at relatively high calcium levels, which was statistically significant. This fact could be explained according to our interpretation. In previous reports, local effects on baroreceptors were examined, whereas we measured the combined effect of several calcium actions. As expected, verapamil attenuated the decrease in heart rate which, however, was not statistically significant.

Acute baroreflex resetting and its control of blood pressure in an open loop model

Acute baroreflex resetting has been quantitatively studied in anesthetized dogs. Carotid sinuses were isolated bilaterally and carotid sinus conditioning pressure (CPcsp) was set at nine different levels for 20 min over a range of from 40 to 200 mm Hg. Over this range of 160 mm Hg in CPcsp, the magnitude of baroreflex resetting of set point pressure (Psp), threshold pressure (Pth) and BP50 was 32.0 +/- 5, 43.3 +/- 6 and 39.6 +/- 6 mm Hg, respectively. The extent of resetting was a non-linear function of the level of CPcsp. There is less resetting at high CPcsp. The average extent of resetting is only about 25%. In contrast to this small degree of resetting, a profound inverse relationship between the baseline pressure and the conditioning pressure was observed at the end of the conditioning period for each CPcsp. In addition, we also observed an attenuation in the buffering capacity of the baroreflex at very high or very low CPcsp. Vagotomy and aortic section did not alter baroreflex resetting. This data indicates that the baroreflex is capable of monitoring the absolute level of blood pressure during acute resetting in addition to buffering transient disturbances in arterial pressure. Based upon the results of the present experiments, the concept that acute baroreflex resetting results in an inability of the baroreflex to monitor the absolute level of arterial pressure does not appear to be valid.

[Reflexogenic release of heparin after perfusion of the rabbit carotid sinus with prethrombin 1]

After perfusion of rabbit carotid sinus with prethrombin 1, hypocoagulation was found in the system circulation due to reflectory reaction of the anticoagulation system. Heparin was secreted already within the first minutes of the perfusion with prethrombin 1 (1 . 10(-6) M); maximal activity of the process was observed within 5 min. Liberation of heparin from the vessel wall of carotic artery was not caused by a mechanism of local secretion, as evidenced by absence of the phenomenon in perfusion of the carotid sinus with prothrombin at molar concentration, corresponding to the concentration of prethrombin 1. Perfusion of denervated carotid sinus by means of prethrombin 1 did not stimulate the heparin secretion. Thus, the heparin secretion was regulated by a nervous mechanism, exhibiting the reflectory nature. The data obtained suggest that perfusion of the rabbit carotid sinus with prethrombin 1 stimulates the anticoagulation system and secretion of heparin.

Role of macromolecular binding site of thrombin molecule in excitation of anticoagulation system

The reaction of anticoagulation system upon perfusion of humorally isolated (with retained innervation) carotid sinus of a rabbit by alpha-,beta/gamma-, DIP-alpha-thrombin and prethrombin I was studied. DIP-alpha-thrombin without clotting activity was shown to initiate like alpha-thrombin the reflex reaction of anticoagulation system characterized by a sharp increase in non-enzymatic fibrinolysis (by 225%) and total fibrinolytic activity of blood (by 51%). Prethrombin I (thrombin precursor) is also capable of exciting the function of anticoagulation system characterized by an increase in non-enzymatic fibrinolysis (by 82%) and total fibrinolytic activity (by 36%). Furthermore, perfusion of prethrombin I or alpha-thrombin at almost the same molar concentrations resulted in the similar degree of anticoagulation system effector reaction. Reflex response of anticoagulation system was not observed upon perfusion of carotid sinus by beta/gamma-thrombin that has high esterase but little if any clotting activity that appears to be due to molecular changes in the macromolecular binding site region. These data support the suggestion that the effect of anticoagulation system excitation is due to interaction of the macromolecular binding site in the structure of alpha-thrombin with anticoagulation system chemoreceptors.

[Activation of the anticlotting system by perfusion of the carotid sinus with prethrombin 1 in rabbits]

I.v. administration of prethrombin-1 activates the anticoagulating system but not through the thrombin generation. Perfusion of the rabbit humorally isolated carotid sinus with the prethrombin-1 increases the time of plasma recalcification, total fibrinolytic activity and nonenzymatic fibrinolysis, the effect depending on the prethrombin-1 concentration. The data obtained suggest that the prethrombin-1 is able to activate function of the anticoagulating system interacting with chemoreceptors of the isolated carotid sinus. The prethrombin-1 as well as alpha-thrombin induce similar effects in the anticoagulating system. Therefore the activation of the anticoagulating system is due to areas of chemoreceptors binding in the system and not to presence of the enzyme active center.