Neurohormones in the intercellular clefts and in glia-like cells of the rat brain

Summary With the aid of electron microscopic immunocytochemistry following the application of antisera against somatostatin and luliberin (LRF), a labeling of the intercellular clefts in different areas of the brain was observed. This labeling is especially conspicuous near the basal pole of the cuboidal ependymal cells, but is also generally present in all regions containing neurohormone-producing perikarya or their processes (for example, the preoptic area, the basal ganglia and the cortex).Furthermore, in all these regions displaying labeled intercellular clefts, glialike cells and sparsely ciliated ependymal cells are found, the secondary lysosomes of which exhibit an immunoreactivity resembling that observed in the intercellular clefts.As sources of the immunoreactive material the following possibilities are discussed: (i) perikarya producing somatostatin or LRF, situated in the wall of the third ventricle and sending fibers between the cuboidal ependymal cells, (ii) hypothalamic and extrahypothalamic projections of both peptidergic systems, and (iii) in the case of somatostatin, immunoreactive perikarya in the cortex.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/3) and Stiftung VolkswagenwerkDedicated to Professor Walter Kirsche on the occasion of his 60th birthday     

Ultrastructure of the subfornical organ of the chicken (Gallus domesticus)

Summary The SFO of the chicken is divided in half by a large central blood sinus; ventrally it is covered by a thin layer of ependyma (including tanycytes, dendrites, and axons) which connects the two lateral halves and protrudes as a midsagittal crest into the lumen of the third ventricle. The ependyma consists predominantly of tanycytes with long basal processes which terminate upon perivascular spaces. These cells have an extensive Golgi apparatus and abundant lysosomes; their cellular apices containing polyribosomes and a few vesicles frequently protrude into the ventricle. In addition to astrocytes, oligodendrocytes, and microglial cells, there is another glial cell population that is distinguished by the presence of parallel stacks or spherical to ovoid conglomerates of rough ER and their unique location, i.e., limited to areas ventral and ventral-lateral to the large blood sinus. Two types of neurons are present: neurons in which there is a paucity of granulated vesicles and occasional vacuoles in both the cytoplasm and nuclei, the second type of neuron elaborates many granulated vesicles. Numerous puncta adhaerentia are observed between adjacent neuronal perikarya and between glial processes and neuronal perikarya.Diverse axon types are found within the chicken SFO. Axo-dendritic and axo-somatic axon terminals and presynaptic axon dilations contain assorted combinations of electron-lucent and granulated vesicles of different maximal diameters. Based on the morphology of these axons, cholinergic, peptidergic, and serotoninergic fibers are described. There are two additional groups of axons whose classification awaits further investigation.The chicken SFO differs from the mammalian SFO in several respects: it possesses an ependyma with secretory and/or absorptive tanycytes predominating; it is divided midsagittally by a central blood sinus; its lateral and dorsal limits are nebulous; a previously undescribed peculiar type of glial cell is found in a limited portion of the organ; supraependymal neurons are lacking.Dedicated to Prof. H. Grau at the occasion of his 80th birthdayWe gratefully acknowledge the technical help of Susan Woroch and secretarial assistance of Diana Hapes and Debbie Harrison     

Surface morphology of the subfornical organ in the rabbit's brain

Summary The ventricular surface of the subfornical organ of the rabbit's brain was studied with scanning and transmission electron microscopic techniques. The ependymal covering was found to consist of hexagonal cells with convex apical surfaces. From the center of each cellular surface a single kinocilium up to 6 m in length protrudes into the liquor. It is usually covered with secretory material having the shape of pearlstrings. The surface aspect of the subfornical organ suggests secretion into the liquor by emptying of giant vacuoles which originate below the ependyma in nerve cells, move towards the surface, develop pressure while flattening their ependymal cover and finally erupt, leaving collapsed ependyma- and/or nerve cells bag on the surface of the organ. A second mechanism of more granular secretion by ependymal cells appears possible.We are indebted to Fräulein E. Östermann, Frau L. Schulze and Frau H. Zuther-Witzsch for excellent technical assistance.     

Neuritic growth cone and ependymal gap junctions in the feline subfornical organ during early development

Summary Intercellular contacts in the subfornical organ (SFO) of kittens 3, 16, and 29 days old were studied in thin sections and by the freeze-etch method. Gap junctions appeared between growing nerve processes and target cells. The junctions were interspersed between immature synapses lacking mitochondria as well as full preand postsynaptic membrane specializations. Gap junctions were seen on filopodia as well as on more mature processes. The morphology of these junctions was typical of those described earlier but they were of small size (0.2–0.3 m).Gap junctions of peculiar form were also seen between ependymal elements in the SFO at 16 days. These were of large size (0.5–0.8 m) and were often of segmented character. This segmentation consisted of bands 3–4 particles in width with a center-to-center spacing of 90 nm with particle free corridors between corresponding to the width of about two rows of particles. The margin of the group might be circumscribed by a row of particles. Although gap junctions of large size were seen between ependymal cells in thin section, features corresponding to the particle free corridors have not been observed to date.On leave of absence from the National Institute of Neurological and Communicative Disorders and Stroke, Section of Functional Neurosurgery, Branch of Clinical Neuroscience, Bethesda, Maryland 20014, USAThis work was supported by grants from the Swiss National Foundation for Scientific Research Nos. 3.636.76 and 3.611.0.75, the EMDO Stiftung and the Dr. Eric Slack-Gyr Stiftung     

Excitatory action of the bird antidiuretic hormone vasotocin on neurons in the subfornical organ

The responsiveness of spontaneously active neurons in the subfornical organ (SFO) of adult ducks to angiotensin II (ANGII) and the bird specific anti-diuretic hormone, arginine vasotocin (AVT), the analog of the mammalian arginine vasopressin (AVP), were investigated in brain slices with extracellular recording technique. 65% (n = 66) of the neurons increased their activity after superfusion with ANGII, the rest were unresponsive. Application of AVT activated 52% (n = 68) of the investigated neurons and like ANGII never caused an inhibition of the spontaneously active SFO neurons. A close correlation exists between the ANGII and AVT sensitivity of duck SFO neurons, because 29 out of 33 neurons were excited by AVT as well as ANGII. The relatively weak antagonistic effect of the V₁-type receptor antagonist Pmp-Tyr (Me)-Arg⁸-vasopressin on the AVT induced excitation suggests a different pharmacology of the bird AVT receptor as compared to the mammalian AVP receptor. The excitatory response of ANGII and AVT on the very same neurons suggest a similar function of both peptides on SFO mediated effects in vivo, such as an increase in water intake. However, peripheral AVT concentrations, unlike ANGII concentrations in the blood are not high enough to activate SFO neurons from the blood side of the blood brain barrier. Therefore AVT is presumably released from synapses of neurons originating within or projecting to the SFO. The identity of the ANGII and AVT reactive neurons suggests that synaptically released AVT should facilitate SFO mediated drinking.Abbreviations _a CSF artificial cerebrospinal fluid - ANGII angiotensin II - AVT arginine vasotocin - AVP arginine vasopressin - ADH antidiuretic hormone - SFO subfornical organ - AVP _4–9 arginine-vasopressin fragment 4–9 - BBB blood-brain barrier     

The role of the subfornical organ in drinking induced by angiotensin in the Japanese quail,Coturnix coturnix japonica

Summary Synthetic 5-valine angiotensin II (AII) induced copious drinking when applied directly to the subfornical organ (SFO) in the Japanese quail. Reliable response was obtained with as little as 1 ng of AII. The amount of water intake increased dose-dependently from 5 ng to 1 ng. A latent period of 73.0 ± 11.0 seconds at 100 ng was noted. The electrical destruction of the SFO significantly reduced the amount of water intake induced by both intravenous and intracranial AII injections. The decrease was proportional to the extent of the SFO lesion. It is conceivable, therefore, that the SFO plays an important role in elicitation of drinking by AII in birds as suggested in mammals.     

Vasotocin acts as a dipsogen in ducks at concentrations stimulating subfornical organ neurons in vitro

The effects of systemic infusions of the avian antidiuretic hormone arginine vasotocin on water intake of domestic ducks were investigated under steady conditions of water balance in which angiotensin II was effective as a dipsogen. The study proceeded from the consistent stimulatory effect of arginine vasotocin on angiotensin II-responsive neurons found in the subfornical organ of ducks, suggesting brain-intrinsic vasotocinergic control of these neurons which are also accessible to circulating agents because of the lacking blood-brain barrier. Levels of circulating arginine vasotocin of about 2700 pg·ml^-1 which were close to the threshold for activation of subfornical organ neurons in vitro, induced weak but significant drinking responses. Even at this high arginine vasotocin level circulatory effects were absent, thereby excluding their interference with water intake. Arginine vasotocin plasma levels of about 60 pg·ml^-1 significantly attenuated the dipsogenic action of angiotensin. While drinking in response to high pharmacological levels of arginine vasotocin is assumed to mimic a stimulatory innervation of angiotensin-responsive subfornical organ neurons by brain-intrinsic vasotocinergic axons, attenuation of angiotensin-induced drinking by high physiological arginine vasotocin levels cannot be explained by its action on central neurons, but may be secondary to body fluid retention caused by the antidiuretic action of arginine vasotocin.Abbreviations ADH antidiuretic hormone - ANGII angiotensin II - AVP arginine vasopressin - AVT arginine vasotocin - BBB blood-brain barrier - HR heart rate - ICV intracerebroventricular - IV intravenous - MAP mean arterial pressure - SFO subfornical organ     

Parenchymal fine structure of the subfornical organ in the Japanese quail,Coturnix coturnix japonica

Summary The parenchyma of the subfornical organ (SFO) of the Japanese quail was studied by light and electron microscopy. The SFO consists of ependymal, intermediate, and basal (perimeningeal) layers. In the intermediate layer, neurons, glial cells, and their processes are found. Axons containing dense core granules approximately 80 nm in diameter are numerous, some of which make synaptic contact with the neuronal perikarya or dendrites. Synaptic vesicles in some axons contain a dense dot in the interior after treatment with 5-hydroxydopamine. The activity of the SFO, which is probably concerned with elicitation of drinking by angiotensin II, may be regulated at least partly by afferent monoaminergic axons. Capillaries with a non-fenestrated endothelium are occasionally found in the parenchyma. The basal layer is occupied by glial processes abutting on the digitating layer of perivascular connective tissue of meningeal vessels. The endothelium of these vessels is occasionally fenestrated. Trypan blue injected systemically accumulated in the SFO, but not in the deeper areas of the brain. The absence of a blood-brain barrier is suggested in the SFO.     

Surface fine structure of the subfornical organ in the Japanese quail,Coturnix coturnix japonica

The surface ultrastructure of the subfornical organ (SFO) was investigated in the Japanese quail. The SFO consists of a body and a stalk. The body of the SFO can be divided into rostral and caudal parts. On the rostral part, each ependymal cell possesses a short central solitary cilium; clustered cilia are also occasionally seen. Microvilli are abundant. On the caudal part, cells with a solitary cilium are fewer in number, and clustered cilia are rarely found. Microvilli are not as abundant as on the rostral part. In addition, large bulbous protrusions, tufts of small protrusions, deep funnel-shaped hollows, small pinocytotic invaginations and possible cerebrospinal fluid-contacting axons are sporadically observed on the surface of various regions of the body. Each ependymal cell of the stalk has a wide apical surface. A central solitary cilium, microvilli and other structures are observed more rarely on the stalk than on the body, while clustered cilia are not seen on the stalk. These structures are compared with those of the mammalian SFO and further discussed in relation to the possible dipsogenic receptor function for angiotensin II.     

白藜芦醇抑制大鼠穹隆下器神经元放电

应用细胞外记录单位放电技术,在大鼠穹隆下器脑片上观察了白藜芦醇(resveratrol)对穹隆下器神经元放电的影响。实验结果如下:(1)给予白藜芦醇(1、5、10μmol/L)2min后,大多数穹隆下器神经元(60/65,92.3%)的自发性放电频率呈剂量依赖性降低;(2)预先用0.3mmol/L的L-glutamate灌流穹隆下器脑片,全部放电单位(12/12,100%)放电频率明显增加,表现为癫痫样放电,在此基础上灌流白藜芦醇(5μmol/L)2min,大多数脑片(10/12,83.3%)的癫痫样放电被抑制;(3)预先用L型钙通道开放剂BayK8644灌流,全部(8/8,100%)放电增加,在此基础上灌流白藜芦醇(5μmol/L)2min,其放电全部被抑制;(4)灌流一氧化氮合酶抑制剂NG-nitro-L-argininemethylester(L-NAME)50μmol/L,多数脑片(11/14,78.6%)放电明显增加,在此基础上灌流白藜芦醇(5μmol/L)2min,大部分神经元(9/11,81.8%)放电被抑制;(5)灌流大电导钙激活性钾通道阻断剂tetraethylammoniumchloride(TEA)1mmol/L后,大多数神经元(10/12,83.3%)放电增加,在此基础上灌流白藜芦醇(5μmol/L)2min,(9/10,90%)放电频率明显减低。以上结果提示:白藜芦醇能抑制大鼠穹隆下器神经元自发放电以及由L-glutamate、L-NAME、BayK8644和TEA诱发的放电,可能与白藜芦醇抑制L型钙通道以及促进一氧化氮的释放有关;似乎与大电导钙激活性钾通道无关。     

Transplantation of the rat pineal organ to the brain: pinealocyte differentiation and innervation

Summary The pineal organ of neonatal rats was transplanted to the frontal part of the cerebral cortex or the cerebral interhemispheric fissure of an isogenic adult rat to determine whether pineal differentiation and pinealopetal innervation are affected by aberrant neuronal influences. Transplants were fixed for immunohistochemistry at 1, 2 and 6 months after transplantation. When treated with an anti-serotonin antibody, cells in transplants from both locations showed intense immunoreactivity and a morphology comparable to intact pinealocytes, indicating that the transplanted pinealocytes had differentiated normally. Tyrosine hydroxylase immunohistochemistry revealed that new catecholamine fibers of central nervous origin extended only into the periphery and not into the core of transplants grafted within the cortex. However, numerous catecholamine fibers were found in transplants placed in the interhemispheric fissure. These fibers were often accompanied by blood vessels, suggesting that they derived from sympathetic ganglia. Serotonin fibers, which are densely distributed in the cerebral cortex, were seldom found to enter transplants from both locations. These observations indicate that pineal cells express their characteristic properties even when transferred to a foreign milieu and that they do not receive novel innervation from the central nerves that normally do not innervate the intact pineal body; the transplant thereby retains the property of selective pinealopetal innervation.     

Scanning and transmission electron microscopy of the subfornical organ of the grass frog (Rana pipiens)

Summary The ventricular surface of the subfornical organ of the frog is made up of ependymal cells with numerous apical microvilli, occasional cytoplasmic protrusions and many vacuoles projecting into the lumen of the third ventricle. Between these cells dendrites of cerebrospinal fluid-contacting neurons reach the ventricle to terminate in bulbous enlargements. In addition, flask-shaped encephalo-chromaffin cells, containing granulated vesicles and aggregates of filaments in their cytoplasm, project into the cerebrospinal fluid. Surrounding the centrally located capillaries are enlarged dendrites and axons of heterogeneous morphology, some of which appear to originate within the subfornical organ, intermingled with dendrites and axons of normal structure. The glial cells in this region, especially the microglial cells, often contain large lipofuscin inclusions, suggestive of degeneration and subsequent phagocytosis of some of the enlarged dendrites and axons. The normally scarce neurosecretory peptidergic axons become more evident and form typical Herring bodies in stalk-transected animals. Neuronal perikarya of varying morphology are predominantly located peripheral to the region of enlarged dendrites and axons. Supraependymal macrophages are particularly numerous on the subfornical organ.Abbreviations used CSF cerebrospinal fluid - SEM scanning electron microscope, scanning electron microscopy - SFO subfornical organ - TEM transmission electron microscope, transmission electron microscopy Supported, in part, by NIH grant NB 07492The skillful technical assistance of J.G. Linner and the secretarial assistance of Ann Gerdom are gratefully acknowledged. The SEM studies were made possible through a grant from the Graduate College of Iowa State University and the use of the SEM facility in the Department of Botany     

Ultracytochemistry of the synaptic ribbons in the rat pineal organ

Summary The synaptic complexes of the rat pinealocytes are neither cholinergic nor adrenergic. In the synaptic vesicles, a neurotransmitter carrier substance of lipid nature reacting with OsO₄-Zn I₂ mixture (similar to that present in both cholinergic and adrenergic vesicles) was not found.In addition, there were no indications of glucose-6-phosphatase or thiamine-pyrophosphatase activity in the synaptic vesicles. Thus, it appears that the synaptic vesicles do not originate from the rough or smooth endoplasmic reticulum.The synaptic ribbons do not contain carbohydrates, are of protein nature and possess some chemical resemblance to microtubules and microtubular bouquets.Appropriate ultracytochemical reactions have not shown detectable quantities of sodium and calcium ions in pinealocyte synaptic complexes.Grateful acknowledgment is made to Mr. P.-A. Milliquet for technical assistance and to Dr. T. Jalanti (C.M.E., Lausanne) for his help in the use of the X-ray microanalyser.Dedicated to Professor Dr. med. G. Töndury on the occasion of his 70th birthday.     

Vasopressin- and oxytocin-containing fibres in the pineal gland and subcommissural organ of the rat

Summary Vasopressin and oxytocin were specifically demonstrated in the rat brain using the unlabelled antibody-enzyme method and purification of the first antiserum. Vasopressin and oxytocin fibres extend via the subcommissural organ or habenular commissure into the pineal stalk and terminate in the anterior part of the pineal organ. In addition, immediately adjacent to the subsommissural organ many vasopressin-containing fibres run caudally toward the central grey. These results are discussed in relation to the proposed presence of vasotocin in the pineal gland.This study was supported by the Foundation for Medical Research, FUNGOThe authors wish to thank Dr. D.F. Swaab and Prof. J. Ariëns Kappers for their suggestions and critical remarks     

Identification of neutrophils in the nonsensory epithelium of the vomeronasal organ in virus-antibody-free rats

Cells infiltrating the nonsensory epithelium of the vomeronasal organ of virus-antibody-free rats exhibited surface immunoreactivity for ₂-microglobulin and immunoglobulin (Ig) E. They were further characterized by using immunohistochemical techniques with antibodies to cell-specific markers or histochemical techniques for immunocytes with surface receptors for IgE. Localization of intracellular granules immunoreactive for lactoferrin and CD18, a leukocyte adhesion molecule, unequivocally identified these cells as neutrophils. The low number of IgA-and IgG-immunoreactive B lymphocytes, T lymphocytes, and accessory immunocytes in the vomeronasal organ as well as the rest of the nasal cavity confirmed the absence of infection. We hypothesize that the operation of the vomeronasal pump induces repeated episodes of transient focal ischemia followed by reperfusion, which results in release of neutrophil chemoattractants and modulation of adhesion factors that regulate the extravasation and migration of neutrophils into the nonsensory epithelium. The distribution of immunoreactivity for interleukin 8 suggests that it is not the primary neutrophil chemoattractant in this system while that of CD18 suggests its active involvement in neutrophil extravasation. In addition to their role in immune surveillance, neutrophils may stimulate ion/water secretion into the vomeronasal lumen, affecting the perireceptor processes regulating stimulus access and clearance from the sensory epithelium.     

The capacity of central and peripheral catecholaminergic neurons to innervate the pineal organ and cerebral cortex of the rat: in vitro immunohistochemical observations

The locus coeruleus (LC) or superior cervical ganglion (SCG) of neonatal rats were co-cultured either with the pineal organ or cerebral cortex (CX) to investigate the innervating capacity of central and peripheral catacholamine neurons under these experimental conditions. After 2 weeks of co-culturing, cultures were fixed for tyrosine hydroxylase (TH) immunohistochemistry to examine the distribution of catecholamine neurons and their fibers. Glial fibrillary acidic protein and fibronectin immunohistochemistry was performed to determine the cell types proliferating around the explants. In LC/CX co-cultures, numerous astrocytes spread between the two explants, and TH-immunoreactive neurites were generally seen to invade CX explants. In contrast, neurite extension from LC to pineal explants occurred only when a glial cell sheet grew between the two explants, and when the pineal explants were not surrounded by a tight fibronectin-positive cell layer. Neurites of the SCG usually invaded both CX and pineal explants, regardless of the existence of glial or non-glial cell layer. These results indicate that central and peripheral catecholamine neurites have the potential of invading both the cortex and pineal, although they are distributed only in particular regions of the intact brain. The distribution of LC neurites, however, seems to be profoundly affected by the cell types spreading around the explants; glial cells appear to support LC neurite extension, whereas non-glial cells appear to inhibit it.     

Nematosomes or nucleolus-like bodies in hypothalamic neurons,the subfornical organ and adenohypophysial cells of the rat

Summary Fibrillar intracytoplasmic bodies, generally referred to as nematosomes or nucleolar like bodies (NLBs), are not only observed in various types of neurons in the hypothalamus and subfornical organ but also in the glandular cells of the pars tuberalis and the pars intermedia hypophyses. According to their cytochemical properties the NLBs are probably of ribonucleoprotein nature. Within the neurons NLBs occur within perikarya and processes. Their presence within the neurosecretory nerve fibers of the neural lobe proves their ability to migrate within the axon. Morphologic modifications of NLBs are observed in stimulated neurons and after colchicine treatment. Colchicine causes a characteristic dense texture of NLBs and a peripheral agglomeration of mitochondria very similar to the rosette arrangement observed in oocytes. Our findings suggest a structural and functional similarity of NLBs in neurons and oocytes, in which their nucleolar origin appears obvious and where they seem to represent preribosomal material. It is very likely that the axonal migration of the NLBs reflects transport of ribosomal RNA for delayed utilization (as in oocytes).This paper is dedicated to Prof. F. Stutinsky for his 65th birthday.     

Developmental expression of glial markers in ependymocytes of the rat subcommissural organ: role of the environment

Summary The rat subcommissural organ (SCO), principally composed of modified ependymocytes (a type of glial cell), is a suitable model for the in vivo study of glial differentiation. An immunohistochemical study of the ontogenesis of rat SCO-ependymocytes from embryonic day 13 to postnatal day 10 shows that these cells express transitory glial fibrillary acidic protein (GFAP) from embryonic day 19 until postnatal day 3. However, S100 protein (S100) is never expressed in the SCO-cells, contrasting with the ventricle-lining cells of the third ventricle, which contain S100 as early as embryonic day 17. Environmental factors could be responsible for the repression of GFAP and S100 in adult rats, because GFAP and S100 are observed in ependymocytes of SCO 3 months after being grafted from newborn rat into the fourth ventricle of an adult rat. Neuronal factors might be involved in the control of the expression of S100, since after the destruction of serotonin innervation by neurotoxin at birth, S100 can be observed in some SCO-ependymocytes of adult rats. On the other hand, GFAP expression is apparently not affected by serotomin denervation, suggesting the existence of several factors involved in the differentiation of SCO-cells.     

Bidirectional control of parathyroid hormone and bone mass by subfornical organ

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