Synaptic morphology of the carotid body of the domestic fowl

Efferent and reciprocal synapses have been demonstrated in the carotid body of the domestic fowl (Gallus gallus domesticus). Synapses were also found with purely afferent morphology, but were probably components of reciprocal synapses. The general morphology of the endings suggested the presence of two types of axon, afferent axons making reciprocal and perhaps afferent synapses with Type I cells, and efferent axons making efferent synapses with Type I cells. A few axo-dendritic synapses were also found. The dense-cored vesicles associated with the afferent components of reciprocal synapses and with the possible true afferent synapses varied in diameter and core but could belong to one population of pre-synaptic vesicles. These observations are consistent wtih a new theory for the carotid body receptor mechanism. This proposes a spontaneously discharging afferent axon inhibited by an inhibitory transmitter substance released by the Type I cell via the "afferent" component of its reciprocal synapse, the "efferent" component inhibiting this release. Besides this chemoreceptor modulation of its afferent axon, the Type I cell may also have a general secretory function.     

Structural and functional characteristics of the special regulatory devices in the peripheral pulmonary circulation in rabbits

The present study intended to describe in detail the several blood vessels harboring special regulatory devices in rabbit’s pulmonary tissue using light and electron microscopy and immuno-histochemistry. Numerous throttle arteries were recorded within the adventitia of the segmental and sub-segmental bronchi and within pulmonary pleura. These arteries showed characteristic narrow or obliterated lumens and some of them bear longitudinal muscular intimal bolsters. For the first time, TEM revealed some structural modifications of the vascular endothelial cells of these arteries indicating that they become more activated to perform some additional functions. Arteriovenous anastomoses (AVAs) including direct shunt vessels and glomus organs were also recognized. Direct arteriovenous shunts appeared as small connecting devices communicating between small arteries and small veins while glomus organs consisted of the tortuous glomus vessels and the related afferent and efferent vessels. Several arteries and veins showing unique unusual structural characteristics were also described. For the first time, serotonin (5-HT) was strongly expressed in the vascular endothelium and muscle fibers of throttle arteries, in glomus cells of the glomus vessels, and in vascular endothelium of some veins and venules of special structure. The exact role of 5-HT is still unknown and further investigations are required to determine the types and distribution of 5-HT receptors present in these vascular devices. We concluded that these special vascular devices can play a critical role in controlling blood flow and pressure in the peripheral pulmonary circulation; however, the exact physiological mechanisms by which they work or are controlled remain unknown providing a ripe area for further investigation.     

Developmental aspects of oxygen sensing by the carotid body.

The carotid body chemoreceptors, the major hypoxia sensory organs for the respiratory system, undergo a significant increase in their hypoxia responsiveness in the postnatal period. This is manifest by a higher level of afferent nerve activity for a given level of arterial oxygen tension. The mechanism for the enhanced sensitivity is unresolved, but most work has focused on the glomus cell, a secretory cell apposed to the afferent nerve ending and believed to be the site of hypoxia transduction. The glomus cell secretory response to hypoxia increases postnatally, and this is correlated with an enhanced calcium rise in response to hypoxia and an increase in oxygen-sensitive potassium currents. These changes are sensitive to the level of hypoxia in the postnatal period, and significant impairment of organ function is observed with postnatal hypoxia as well as postnatal hyperoxia. Although many questions remain, especially with regard to the coupling of glomus cells to nerve endings, the use of cellular and molecular techniques should offer resolution in the near future.     

Expression of tandem P domain K+ channel, TREK-1, in the rat carotid body.

TREK-1 is one of the important potassium channels for regulating membrane excitability. To examine the distribution of TREK-1 in the rat carotid body, we performed RT-PCR for mRNA expression and in situ hybridization and immunohistochemistry for tissue distribution of TREK-1. RT-PCR detected mRNA expression of TREK-1 in the carotid body. Furthermore, in situ hybridization revealed the localization of TREK-1 mRNA in the glomus cells. TREK-1 immunoreactivity was mainly distributed in the glomus cells and nerve fibers in the carotid body. TREK-1 may modulate potassium current of glomus cells and/or afferent nerve endings in the rat carotid body.     

Structure of the cumulus oophorus at the time of fertilization

Summary The paired external glomus of the fully developed pronephros has been studied in early larvae (ammocoetes) of 2 lamprey species, Lampetra fluviatilis and Petromyzon marinus, several weeks after hatching and newly hatched, by use of light-, scanning (SEM) and transmission (TEM) electron microscopy. Three weeks after hatching the glomus is a complex of capillary loops supplied by a single arteriole branching from the aorta. The glomus consists of 3 cell types: podocytes, fenestrated endothelium, and mesangial cells. A basement membrane, which has a close contact to the podocytes, is the only continuous barrier between blood and the coelomic cavity. The glomus exhibits all fine-structural elements known to be essential for function in the glomeruli of other vertebrates. We therefore assume the pronephric glomus of lampreys to be functional in ultrafiltration, with the ultrafiltrate released into the coelomic cavity. In newly hatched larvae, the structure of the glomus is not fully developed. In this earlier stage several afferent arterioles supply each glomus. The endothelial cells in the glomar capillaries still lack regular epithelial organization and resemble mesenchymal cells. However, the presence of typical podocytes stretching over a continuous basement membrane suggests that the tissue is already capable of ultrafiltration.This paper is dedicated to the memory of Professor W. Bargmann, long-time editor of Cell and Tissue Research, the author of a splendid review on the structure of the vertebrate kidney and a master of German scientific writing     

An ultrastructural study of the carotid body of horse and dog

Summary Carotid body tissue from horse and dog has been investigated ultrastructurally. Several cell types are recognized: glomus cells which are regarded as chemoreceptors, sustentacular cells which enclose the glomus cells, and nerve fibers.The glomus cells contain electron dense granules which are interpreted as packages of biogenic monoamines. There are both dark and light glomus cells, the former containing more granules and ribosomes. Invaginations of the plasma membranes as well as free coated vesicles are often seen in the cytoplasm of glomus cells. Nerves within the glomus lobules are generally wrapped by sustentacular cells, but nerve endings are also seen in close contact with the glomus cells. Some endings contain synaptic vesicles as well as a great concentration of mitochondria. The corresponding fibers are thought to be efferent. Another type of contact is interpreted as en passant synapses of afferent fibers.The author wishes to express his gratitude to Professor L. Nicander who initiated this project and took most of the micrographs and to Professor Nils Obel and associate Professor Gustav Björk at the Royal Veterinary College for their valuable help with the surgical procedure and to Dr. Martin Ritzén of the Royal Medical College for making the tests for biogenic monoamines.     

Vesicular glutamate transporter 2-immunoreactive afferent nerve terminals in the carotid body of the rat

The carotid body is a peripheral chemoreceptor that detects decreases in arterial pO₂ and subsequently activates the carotid sinus nerve. The hypoxia-evoked activity of the carotid sinus nerve has been suggested to be modulated by glutamate. In the present study, we investigate the immunohistochemical localization of vesicular glutamate transporters in the carotid body of the rat. Vesicular glutamate transporter 2 (VGLUT2) labeling was closely associated with glomus cells immunoreactive to tyrosine hydroxylase but was not in the cytoplasm of these cells. The VGLUT2 immunoreactivity was observed within nerve endings that were immunoreactive to P2X3 and densely localized inside P2X3-immunoreactive axon terminals. These results suggest that VGLUT2 is localized in the afferent nerve terminals of the carotid body. Glutamate may be released from afferent nerve terminals to modulate the chemosensory activity of the carotid body.     

Hypoxia transduction by carotid body chemoreceptors in mice lacking dopamine D(2) receptors.

Hypoxia-induced dopamine (DA) release from carotid body (CB) glomus cells and activation of postsynaptic D(2) receptors have been proposed to play an important role in the neurotransmission process between the glomus cells and afferent nerve endings. To better resolve the role of D(2) receptors, we examined afferent nerve activity, catecholamine content and release, and ventilation of genetically engineered mice lacking D(2) receptors (D(2)(-/-) mice). Single-unit afferent nerve activities of D(2)(-/-) mice in vitro were significantly reduced by 45% and 25% compared with wild-type (WT) mice during superfusion with saline equilibrated with mild hypoxia (Po(2) approximately 50 Torr) or severe hypoxia (Po(2) approximately 20 Torr), respectively. Catecholamine release in D(2)(-/-) mice was enhanced by 125% in mild hypoxia and 75% in severe hypoxia compared with WT mice, and the rate of rise was increased in D(2)(-/-) mice. We conclude that CB transduction of hypoxia is still present in D(2)(-/-) mice, but the response magnitude is reduced. However, the ventilatory response to acute hypoxia is maintained, perhaps because of an enhanced processing of chemoreceptor input by brain stem respiratory nuclei.     

Histochemical characteristics of chemoreceptor organs (Glomera)

Summary Some important histochemical characteristics of the carotid, aortic and coronary glomera have been studied in man and the rabbit.All glomera present a similar histochemical pattern. Type I glomus cells contain acetylcholinesterase, monoamine oxidase and norepinephrine. Type II glomus cells are highly positive for cholinesterase, carbonic anhydrase and nucleoside phosphatases hut they do not contain acetylcholinesterase nor catecholamines. It is postulated that the type I glomus cell is the true chemoreceptor cell. Together with the type II glomus cell, which is considered to be a special type of glial cell, a functional metabolic unit is established. Efferent nerve fibres could be adrenergic; by way of cholinergic transmission action potentials could be initiated in the afferent nerve fibres.The following Abbreviations will be used AChE acetylcholinesterase - ChE cholinesterase - iso-OMPA tetraisopropylpyrophosphoramide - DFP di-isopropylfluorophosphate - 62C47 15-bis-(4-trimethylammonium-phenyl) pentan-3-one-diiodide - CAH carbonic anhydrase - ATP-ase adenosine triphosphatase - NP-ases nucleoside phosphatases - UDP uridine diphosphate - UTP uridine triphosphate - IDP inosine diphosphate - CTP cytidine triphosphate - CaFoMa calcium-formol-macrodex - Glut glutaraldehyde - TPP-ase thiamine pyrophosphatase - MAO monoamine oxidase - CA catecholamines - NE norepinephrine     

Oxygen sensing by ion channels and chemotransduction in single glomus cells

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

Postnatal maturation of neuroepithelial bodies and carotid body innervation: A quantitative investigation in the rabbit

The intrapulmonary airways contain oxygen-sensitive chemoreceptors which may be analogous to the arterial chemoreceptors: the neuroepithelial bodies (NEB). While the NEB are prominent in the neonatal lung, physiological studies indicate that the carotid bodies are still relatively inactive at birth. This points to an unequal degree of development of both during the early neonatal period. As a reflexogenic chemoreceptor function depends on a well-developed innervation, we undertook a comparative investigation of the development of the NEB and the carotid body glomus cell innervation. Two morphological aspects of the innervation of NEB and carotid body glomus cells were quantified in rabbits of different age groups. The total sectional area of intracorpuscular and intraglomerular nerve endings per NEB or glomus cell group, respectively, was measured and the area percentage of mitochondria and synaptic vesicles was determined. In the NEB, no significant difference in total sectional area of the nerve endings between the age groups was observed, while in the carotid body there was a significant increase in the adult age group. In addition, the area percentage of mitochondria and synaptic vesicles of the nerve endings did not change significantly with age in the NEB, while in the carotid body these increased and decreased, respectively, with age. These observations point to a shift from morphologically efferent nerve endings, rich in synaptic vesicles, to morphologically afferent nerve endings, rich in mitochondria. Our interpretation of these findings is that, at birth, the NEB innervation is more mature than the carotid body glomus cell innervation and that the latter matures at a later time than the former. These findings support the theory that the NEB may act as complementary chemoreceptors to the carotid body during the early postnatal period.     

Histochemically demonstrable increase in the catecholamine content of the carotid body in adult rats treated with methylprednisolone or hydrocortisone

Synopsis Carotid bodies of adult albino rats were examined using the formaldehyde-induced fluorescence (FIF) method for the demonstration of fluorogenic monaomines and staining with I% Toluidine Blue for morphological observations.In the carotid body of normal controls, most glomus (principal or type I) cells exhibited a FIF presumably due to catecholamines. The intensity of the fluorescence was weak in most cells, while some glomus cells were non-fluorescent and others exhibited a moderate or intense FIF. The sustentacular (satellite, supporting or type II) cells were essentially non-fluorescent.One week after the administration of a single intraperitoneal injection of the long-acting glucocorticoid 6-methylprednisolone sypionate (400 mg/kg) or after seven intraperitoneal injections of the water-soluble glucocorticoid hydrocortisone sodium succinate (40 mg/kg daily for a week), a distinct increase was observed in the FIF of the glomus cells. No non-fluorescent glomus cells were observed after treatment with either glucocorticoid, and the intensity of most fluorescent glomus cells was moderate or intense.It is concluded that glucocorticoids cause an increased storage of catecholamines in the glomus cells of the carotid body of the adult rat, an observation of interest in view of the fact that such changes due to glucocorticoids have as yet been reported only in catecholamine-storing cells of newborn rats.     

Neuromechanisms of reciprocal interrelation between jaw-opening and jaw-closing muscles in the cat (author's transl)]

Neural controlling mechanisms between the digastric (jaw-opening) and masseter (jaw-closing) muscles were studied in the cat. High threshold afferent impulses from the anterior belly of the digastric muscle to masseteric montoneurons in the trigeminal motor nucleus induced an EPSP-IPSP sequence of potentials with long latency, and high threshold afferent impulses from the masseter muscle also exerted a similar effect on digastric motoneurons in the same nucleus innervating the anterior belly of the digastric muscle. These results suggest that reciprocal inhibition via Ia interneurons as observed between the flexor and extensor muscles in the spinal cord does not exist between the digastric and masseter muscles in the cat. However, the respective motoneurons innervating the masseter and digastric muscles receive inputs of early excitation-late inhibition via high threshold afferent nerve fibers from each antagonistic muscle. As such, since EPSPs preceding IPSPs are recognized, these high threshold afferent impulses may exert not only a reciprocal inhibitory effect, but also a synchronous excitatory or inhibitory effect on the antagonistic motoneurons.     

Oxygen sensing by the carotid body chemoreceptors.

Carotid bodies are sensory organs that detect changes in arterial blood oxygen, and the ensuing reflexes are critical for maintaining homeostasis during hypoxemia. During the past decade, tremendous progress has been made toward understanding the cellular mechanisms underlying oxygen sensing at the carotid body. The purpose of this minireview is to highlight some recent concepts on sensory transduction and transmission at the carotid body. A bulk of evidence suggests that glomus (type I) cells are the initial site of transduction and that they release transmitters in response to hypoxia, which causes depolarization of nearby afferent nerve endings, leading to an increase in sensory discharge. There are two main hypotheses to explain the transduction process that triggers transmitter release. One hypothesis assumes that a biochemical event associated with a heme protein triggers the transduction cascade. The other hypothesis suggests that a K(+) channel protein is the oxygen sensor and that inhibition of this channel by hypoxia leading to depolarization is a seminal event in transduction. Although there is body of evidence supporting and questioning each of these, this review will try to point out that the truth lies somewhere in an interrelation between the two. Several transmitters have been identified in glomus cells, and they are released in response to hypoxia. However, their precise roles in sensory transmission remain uncertain. It is hoped that future studies involving transgenic animals with targeted disruption of genes encoding transmitters and their receptors may resolve some of the key issues surrounding the sensory transmission at the carotid body. Further studies are necessary to identify whether a single sensor or multiple oxygen sensors are needed for the transduction process.     

Hemeoxygenase-2 as an O2 sensor in K+ channel-dependent chemotransduction

The physiological response of the carotid body is critically dependent upon oxygen-sensing by potassium channels expressed in glomus cells. One such channel is the large conductance, voltage- and calcium-dependent potassium channel, BK(Ca). Although it is well known that a decrease in oxygen evokes glomus cell depolarization, voltage-gated calcium entry, and transmitter release, the molecular identity of the upstream oxygen sensor has been the subject of some controversy for decades. Recently, we have demonstrated that hemeoxygenase-2 associates tightly with recombinant BK(Ca) and that activity of this enzyme confers oxygen sensitivity to the BK(Ca) channel complex. Similar observations were also made in native channels recorded from carotid body glomus cells, suggesting that hemoxygenase-2 functions as an oxygen sensor of native and recombinant BK(Ca) channels.     

大鼠颈动脉体球细胞缺氧时膜电位变化与球细胞大小的关系

用细胞内记录法测定了８５个分离培养的大鼠颈动脉体球细胞的膜电位,并由显微照相法记录球细胞的形态进而以测微器测量球细胞的直径。由连二亚硫酸钠（Ｎａ２Ｓ２Ｏ４）造成缺氧（ＰＯ２,１．３－８．０ｋＰａ）。不同直径的球细胞对缺氧有两种不同反应：直径为８．０４±１．０９μｍ的球细胞对缺氧的反应均为去极化,直径为１４．３８±４．２１μｍ的球细胞对缺氧反应为超极化。因此似可认为,球细胞存在功能不同的亚型。缺氧程度不同对球细胞膜电位的改变也有一定影响,缺氧程度严重可使小型球细胞的去极化程度增加,但缺氧程度的高低不能改变两型球细胞对缺氧反应的固有型式。     

The effects of 6-hydroxydopamine on the appearance of granulated vesicles in glomus cells of the rat carotid body

The glomus cells of the rat carotid body reveal an intense fluorescence after exposure to paraformaldehyde vapor and contain catecholamines. After initial fixation in glutaraldehyde, many granulated vesicles are seen in the glomus cells. After initial fixation in osmium tetroxide, most of the vesicles are depleted of their dense interiors and granulated vesicles occur infrequently. Administration of 6-hydroxydopamine followed by initial fixation in osmium tetroxide leads to the reappearance of dense interiors in virtually all vesicles. 6-Hydroxydopamine apparently is taken up by the membrane pump of the glomus cell and is incorporated into the amine storage granules, thereby displacing the endogenous monoamines. Osmium tetroxide does not dissolve the 6-hydroxydopamine from the vesicles, as it apparently does for the normal vesicular contents. The 6-hydroxydopamine does not fluoresce, hence 6-hydroxydopamine administration results in a decreased intensity of formaldehyde induced fluorescence in the glomus cells. Administration of reserpine after 6-hydroxydopamine treatment (and subsequent initial fixation in osmium tetroxide) depletes the previously restored dense material from the vesicles of the glomus cells. 6-Hydroxydopamine acts like a monoamine in that it is taken up by the glomus cell, incorporated into the vesicles, and can be depleted from the vesicles by reserpine.     

Chemical and electric transmission in the carotid body chemoreceptor complex

Carotid body chemoreceptors are complex secondary receptors. There are chemical and electric connections between glomus cells (GC/GC) and between glomus cells and carotid nerve endings (GC/NE). Chemical secretion of glomus cells is accompanied by GC/GC uncoupling. Chemical GC/NE transmission is facilitated by concomitant electric coupling. Chronic hypoxia reduces GC/GC coupling but increases G/NE coupling. Therefore, carotid body chemoreceptors use chemical and electric transmission mechanisms to trigger and change the sensory discharge in the carotid nerve.