Connexin 26 expression and extensive gap junctional coupling in cultures of GT1-7 cells secreting gonadotropin-releasing hormone.

Gap junctions (GJs) are transmembrane channels that permit rapid intercellular transit of various small molecules including ions, second messengers and metabolites. GJs promote communication and coordinated activity between coupled neurons, and may help facilitate the synchronous release and pulsatile secretion of neurohormones. A previous study using GnRH-secreting GT1-7 cells reported that connexin 26 was the major GJ subunit present, and that about 20% of the cultured cells engaged in GJ coupling as assayed by fluorescence recovery after photobleaching of 5,6-carboxyfluorescein diacetate (MW 460 D). To reassess GJ connectivity with a more permeant probe, we grew GT1-7 cells to 70% confluency on Matrigel-coated glass coverslips and microinjected Neurobiotin(TM) (MW 322 D) into single cells. Dye was allowed to diffuse for 30 min before cultures were fixed, and subsequently immunostained for Neurobiotin with 3,3'-diaminobenzidine HCl and examined by light microscopy. Dye coupling between 2 or more GT1-7 cells was observed after 75% of all microinjections. Connectivity involved the somata and neurites of an average of 6.6 +/- 2.0 adjoining cells, but in one instance was seen in a group of 32 GT1-7 neighbors. Western blotting and immunofluorescence staining confirmed that connexin 26 was the predominant GJ subunit expressed by GT1-7 cultures. Our results using Neurobiotin suggest these GJ channels may be smaller than anticipated. In addition, functional GJ connectivity between subconfluent GT1-7 cells is more extensive than previously reported, occurring with higher frequency and coupling significantly greater numbers of cultured cells. Since cAMP, IP3, and Ca(2+) are able to pass through GJs and can elicit secretion of GnRH by GT1 cell cultures, GJs may play an important role in the coordination and synchronization of GnRH release.

Expression of estrogen and progesterone receptors in glutamate and GABA neurons of the pubertal female monkey hypothalamus.

We have previously reported direct glutamate (Glu) synapses upon GnRH-containing neurons in the primate hypothalamus, and extensive interactions between Glu and aminobutyric acid (GABA) neurons in areas associated with reproductive function. Both Glu and GABA are known to affect peripubertal GnRH neurohormone release, but their relative roles remain unclear. In a developmental survey, estrogen receptors (ER) and progesterone receptors (PR) were virtually undetectable after immunostaining the hypothalamus of prepubertal monkeys, but were clearly evident in neurons of adults. We hypothesized, therefore, that Glu and GABA neurons which develop ER or PR expression during puberty may participate in reactivation of the hypothalamic-pituitary-gonadal axis. To identify those neurons in midpubertal female cynomolgus monkeys, we performed immunofluorescence staining for ER or for PR in separate sets of hypothalamic sections, and then immunostained for Glu or for glutamate decarboxylase (GAD, to identify GABA neurons) using a contrasting fluorophore. ER and PR were localized in the cytoplasm and nuclei of Glu and GAD neurons in nine hypothalamic and related brain regions. Quantitation revealed intranuclear ER in an average of 80% of the Glu neurons in all regions analyzed, and an average of 84% of the GAD neurons in all regions except the supraoptic nucleus (28%). Intranuclear PR expression was more variable, occurring in an average of 93% of the Glu neurons in seven regions, but in only 41% in the medial preoptic area, and 0% in the arcuate-periventicular zone. In addition, while intranuclear PR was seen in 96% of the GAD neurons in the septum, it appeared in 67% of the GAD neurons in the paraventricular nucleus, 47% in the medial preoptic area, 40% in the periventricular zone, and was absent from neurons in the supraoptic nucleus and mammillary bodies. In summary, certain subpopulations of Glu and GABA neurons in principal hypothalamic regions of the female monkey express ER and PR at midpuberty. Taken together with previous findings, these results suggest that Glu and GABA neurons which become sensitive to steroid hormones may help regulate GnRH neurohormone release and promote the onset of puberty. Since neuronal expression of ER or PR connotes sensitivity to gonadal feedback, and intranuclear translocation signals transcriptional activation, these results provide insights into the specific neuronal events involved in the peripubertal transition in primates.

Estrogen and progesterone receptor expression in neuroendocrine and related neurons of the pubertal female monkey hypothalamus.

Expression of hypothalamic estrogen receptors (ER) and progesterone receptors (PR) is barely evident in prepubertal monkeys but is prominent in adults. To investigate whether adult patterns of ER and PR expression are established in mid-pubertal female cynomolgus monkeys, we labeled neuroendocrine (NEU) neurons by microinjection of retrograde tracer into the median eminence, and then identified ER and PR by specific immunostaining in separate sets of hypothalamic sections. ER and PR appeared in the cytoplasm and nuclei of cells identified exclusively as neurons, and retrograde tracer remained clearly visible in the cytoplasm of NEU neurons after immunostaining. Numbers of NEU and related neurons expressing ER or PR were quantified in principal hypothalamic regions. In the supraoptic nucleus, almost all neurons analyzed (n = 580) contained ER (94%) with many also NEU (73% ER + NEU), while lesser amounts of the neurons examined (n = 214) expressed PR (75%) and were NEU (53% PR + NEU). In the paraventricular nucleus, most of the neurons analyzed (n = 302) contained ER (90% ER; 54% ER + NEU), but few of the neurons studied (n = 269) contained PR (34% PR; 19% PR + NEU). In the periventricular zone, nearly all neurons examined (n = 795) contained ER (95% ER; 48% ER + NEU), but fewer of those studied (n = 298) exhibited PR (79% PR; 47% PR + NEU). In the arcuate-periventricular zone, all neurons examined (n = 542) contained ER (100%) but few were NEU (4% ER + NEU), while nearly all neurons studied (n = 418) contained PR (95%), some of which were NEU (21% PR + NEU). Neurons expressing ER were also prevalent in areas without NEU labeling, including the diagonal band of Broca, medial preoptic area, and mammillary bodies, but were less common in the septum and dorsomedial hypothalamus. Likewise, neuronal PR expression was seen frequently in the mammillary bodies, but occurred less often in the diagonal band of Broca, medial preoptic area, and dorsomedial hypothalamus. Neurons in the suprachiasmatic nucleus and lateral hypothalamic area lacked retrograde labeling. These results identify the principal sites and subsets of NEU and related neurons which express ER and PR in the mid-pubertal female monkey hypothalamus. They appear to correlate well with known populations of steroid-sensitive NEU neurons present in these areas in adults. The data also suggest that functional patterns of ER and PR expression arise upon reactivation of the hypothalamic-pituitary-gonadal axis at puberty. The degrees of receptor expression and of nuclear translocation most likely reflect peripubertal changes in the levels of gonadal steroids. Taken together, these results provide important insights into the mechanisms and development of neuroendocrine control during the pubertal period in primates.

Reinnervation of the rat bladder with a somatic nerve and a striated muscle flap.

PURPOSE: Current techniques of ventral sacral root stimulation to regain voluntary motor control of the decentralized urinary bladder depend upon intact parasympathetic innervation of the detrusor. We investigated techniques that might allow restoration of motor control of the bladder after efferent parasympathetic impairment. MATERIALS AND METHODS: In a chronic rat model, we evaluated whether motor control of a peripherally denervated bladder could be restored by transplantation of autologous excitable tissues and subsequent electrostimulation. Either a somatic nerve or a striated muscle flap was used as the transplant. RESULTS: Four months after the initial surgery, electrostimulation of the somatic nerve implant provoked bladder contractions--a response that was blocked by atropine. Stimulation of the nerve innervating the striated muscle flap also provoked bladder contractions; these were not affected by atropine and were slightly reduced by hexamethonium. CONCLUSION: Reinnervation of the bladder with somatic nerves or striated muscles is possible in principle. Future experiments will clarify the clinical significance of electrostimulation of such implants.

Glutamate and GABAergic neurointeractions in the monkey hypothalamus: a quantitative immunomorphological study.

Glutamate (Glu) and gamma-aminobutyric acid (GABA) are the most abundant excitatory and inhibitory neurotransmitters in the mammalian hypothalamus. Glu and GABA-containing neurons have both been shown to synapse with gonadotropin-releasing hormone (GnRH) and other neuroendocrine systems in the hypothalamus of several species. Since their direct interactions could play a pivotal role in governing neuroendocrine function, we performed double-label immunostaining for Glu and for glutamic acid decarboxylase (GAD) as a marker for GABAergic neurons in hypothalamic sections from adult female cynomolgus monkeys. Ultrastructural analysis of 785 Glu-immunoreactive (-ir) and GAD-ir elements in the medial septum (MS), arcuate nucleus-ventral hypothalamic tract (VHT1), supraoptic nucleus (SON), paraventricular nucleus (PVN), and median eminence (ME) revealed that 63% were Glu-ir, 28% were GAD-ir, and 9% were Glu + GAD-ir. In addition, we observed surprisingly consistent labeling of 2-4% somata (SOM), 65-80% dendrites (DEN), and 15-30% axons and terminals (AXO) in all of these areas. Characterization of 177 interactions (36% synapses, 64% contacts) by pre/post-transmitter content indicated that 29% contained Glu/GAD, 15% Glu/Glu, and 15% Glu/Glu + GAD, while 16% were unlabeled/Glu, 9% were unlabeled/GAD, and 16% expressed other transmitter combinations. Regional analysis of these interactions showed that 43% occurred in the MS, 22% in VHT1, 14% in SON, 9% in PVN, and 12% in the ME. AXO/DEN interactions made up 51% of all labeled interactions characterized, and were comprised 29% of Glu/GAD, 22% of Glu/Glu, and 18% of the Glu/Glu, and 18% of the Glu/Glu + GAD type. AXO/DEN synapses were more prevalent than contacts in all areas except the PVN and of course the ME, where anatomical synapses do not occur. AXO/SOM interactions represented approximately 15% of all those identified, and were predominantly unlabeled/Glu (71%) and unlabeled/GAD (18%) synapses. Almost all (95%) AXO/SOM synapses and 75% of the contacts occurred in the MS. DEN/DEN interactions, 28% of the total, were composed 50% of Glu/GAD, 12% of Glu/Glu, and 18% of the Glu/Glu+GAD type. The relatively few DEN/DEN synapses all appeared in the MS, whereas much more abundant DEN/DEN contacts were more widely distributed. DEN/SOM interactions, 6% of the total, appeared only as contacts, with the majority (60%) again located in the MS. In addition, the MS contained 48% of all asymmetrical synapses (vs. 35% in VHT1 and 17% in SON), 62% of all symmetrical synapses (vs. 19% in VHT1 and 14% in SON), and 35% of all contacts (vs. 21% in VHT1 and 12% in SON) identified.(ABSTRACT TRUNCATED AT 400 WORDS)

Glutamate-immunoreactive neurons and their gonadotropin-releasing hormone-neuronal interactions in the monkey hypothalamus.

Glutamate (Glu) is the most prevalent excitatory neurotransmitter in the brain and has been implicated in the regulation of GnRH secretion in several mammalian species, including the monkey. To investigate the neuroanatomical basis for Glu-GnRH interactions, we performed an immunocytochemical study at both the light and electron microscopic levels on the brains of four female and five male macaques. Initially, we determined the location of Glu-immunoreactive (-ir) elements using a monoclonal antibody specific for glutaraldehyde-fixed Glu (Glu-2) and 3,3'-diaminobenzidine-4-HCl (DAB). Glu-ir was observed in the cytoplasm and to a variable degree in the nuclei of neurons in the diencephalon. Cytoplasmic staining was particularly intense in numerous neurons in the arcuate nucleus, supraoptic nucleus, and many paraventricular nucleus neurons. Short Glu-ir processes were evident in these and other hypothalamic regions and were extremely dense in the infundibular stalk and median eminence. Prior absorption of the Glu-2 antibody with a Glu-glutaraldehyde-BSA conjugate completely abolished all immunostaining in both neuronal nuclei and cytoplasm. Double label Glu-GnRH immunostaining for light microscopy was performed using Glu-2 and DAB without enhancement, and a polyclonal antibody (LR1 or LR2) with silver-enhanced DAB for Glu and GnRH, respectively. Glu-ir interactions with GnRH-ir cell bodies were not apparent, but a few Glu-ir axons seemed to contact GnRH-ir dendrites in the organum vasculosum of the lamina terminalis, medial septum, and arcuate nucleus regions. Reciprocal interactions occurred more frequently, however, in which GnRH-ir axons and dendritic fibers engaged Glu-ir cell bodies en passant, particularly toward the medial and posterior hypothalamus. For ultrastructural analyses, Glu-ir elements were stained with the Glu-2 antibody and 15 nm immunogold or DAB. Electron microscopy demonstrated that Glu-ir was associated with clear microvesicles within the neuronal cytoplasm. Glu-ir processes made classical asymmetrical synapses with one another and received asymmetrical synapses from unlabeled afferents. In sections double labeled for Glu with immunogold and for GnRH with DAB, axo-somatic interactions were not observed. However, axo-dendritic Glu-GnRH synapses were seen, which usually exhibited Glu-ir labeling of terminal vesicles and inconsistent postsynaptic densities, with GnRH-ir neurosecretory granules sometimes congregated in the apposing dendrite or spine. Surprisingly, reverse GnRH-Glu interactions were observed more frequently.(ABSTRACT TRUNCATED AT 400 WORDS)

Neuropeptide Y system of the female monkey hypothalamus: retrograde tracing and immunostaining.

Neuropeptide Y (NPY) stimulates the release of hypothalamic gonadotropin-releasing hormone (GnRH) as well as pituitary gonadotropins in the presence of ovarian steroids, but inhibits release in their absence. In primates, however, the effects of NPY depend largely upon the site and method of administration. In ovariectomized monkeys, NPY infusion into the stalk-median eminence reportedly causes a dose-response increase in GnRH secretion in the absence of gonadal steroids. To help elucidate these findings, we investigated the NPY system and its neuroendocrine (NEU) component in the primate brain by retrograde tracing and immunostaining. One adult female and 1 juvenile female cynomolgus monkey were given microinjections of retrograde tracer into the median eminence (ME). Two weeks later, they were perfused with fixative, and series of 40-microns frontal vibratome sections were collected at 500-microns intervals through 4 mm of the forebrain. Injection sites were not visible in the juvenile female monkey ME, so this animal served as a neurosurgical and injection control. Sections were immunostained using a polyclonal NPY antiserum and the peroxidase antiperoxidase (PAP) technique. NPY immunostaining in another adult female cynomolgus monkey and in a late fetal female and a neonatally castrated adult male rhesus monkey gave essentially similar results. NPY-immunoreactive (NPY-IR) neurons were widely distributed throughout the caudate nucleus, but appeared concentrated within specific hypothalamic areas. Their number, as well as the number of NEU neurons, was nearly equal in bilaterally paired areas and on both sides of the hypothalamus overall. Ratios of retrogradely labeled NPY-IR neurons to the number of NPY-IR somata were expressed as percentages of NEU NPY-IR neurons for each side and in each area. These averaged 65% in the supraoptic nucleus (SON), 41% in the paraventricular nucleus (PVN), 32% in the medial preoptic area (MPOA), which has only one quarter of their number of NPY-IR cells, and 11% in the medial basal hypothalamus (MBH). NPY-IR fiber densities were highest in the area olfactoria, medial septal and ventromedial nuclei. They were high in the tuberculum olfactorium, lateral septum, nucleus accumbens, MPOA, PVN, dorsomedial nucleus and regions of the MBH including the arcuate nucleus, tuber cinereum and ventral hypothalamic tract (VHT). NPY fiber densities were moderate in the vertical portion of the diagonal band of Broca, the ventral part of the caudate nucleus, the anterior commissural nucleus and the lateral preoptic area, as well as the anterior and lateral hypothalamic areas, the anterior ventral periventricular area, the suprachiasmatic nucleus and the dorsolateral SON.(ABSTRACT TRUNCATED AT 400 WORDS)

Immortalized hypothalamic gonadotropin-releasing hormone neurons.

The neuroendocrine hypothalamus has been intensively studied using whole animals and tissue slices. However, it has been difficult to approach questions at the molecular and cellular level. By targeting expression of the oncogene product, simian virus 40 T antigen, in transgenic mice using the regulatory domain of the rat gonadotropin-releasing hormone (GnRH) gene, we have produced specific hypothalamic tumours. These tumours have been cultured to produce clonal cell lines (GT-1 cells) that express T antigen, GnRH and many other neuronal markers, but do not express other hypothalamic hormones. These immortal cell lines have a distinctive neuronal phenotype, process the GnRH peptide accurately and secrete GnRH in a pulsatile pattern. Thus, by targeting oncogenesis to a defined population of neurons using the regulatory region of a gene that is expressed late in differentiation of that cell lineage, we have succeeded in immortalizing hypothalamic GnRH neurons. The GT-1 cell lines are an excellent model for future molecular, cell biological, physiological and biochemical investigations into the mechanisms involved in regulation of GnRH and the characteristics of an isolated central nervous system neuron. Their derivation demonstrates the utility of targeting tumorigenesis to specific differentiated neurons of the central nervous system in transgenic mice.

Immortalization of hypothalamic GnRH neurons by genetically targeted tumorigenesis.

By genetically targeting tumorigenesis to specific hypothalamic neurons in transgenic mice using the promoter region of the gonadotropin-releasing hormone (GnRH) gene to express the SV40 T-antigen oncogene, we have produced neuronal tumors and developed clonal, differentiated, neurosecretory cell lines. These cells extend neurites, express the endogenous mouse GnRH mRNA, release GnRH in response to depolarization, have regulatable fast Na+ channels found in neurons, and express neuronal, but not glial, cell markers. These immortalized cells will provide an invaluable model system for study of hypothalamic neurosecretory neurons that regulate reproduction. Significantly, their derivation demonstrates the feasibility of immortalizing differentiated neurons by targeting tumorigenesis in transgenic mice to specific neurons of the CNS.

Corticotropin-releasing factor neurons innervate dopamine neurons in the periventricular hypothalamus of juvenile macaques. Synaptic evidence for a possible companion neurotransmitter.

Corticotropin-releasing factor (CRF) and dopamine (DA) are important integrators of the endocrine and autonomic response to stress. CRF neurons in the anterior portions of the periventricular nucleus (PV) and parvocellular paraventricular nucleus (pvPVN) occur close to A14 DA neurons in these same locations. Since CRF has been shown to act as an excitatory neurotransmitter, possible CRF interactions with the DA system were investigated using double-label immunocytochemistry. Coronal vibratome sections through the PV and pvPVN were obtained from colchicine-treated and nontreated juvenile female cynomolgus macaques. They were sequentially immunostained for tyrosine hydroxylase (TH) (to identify DA neurons) with PAP and DAB, and for CRF using 15 nm colloidal gold. By light microscopy, areas of coincidence of TH- and CRF-immunoreactive cell bodies in the PV and pvPVN were obvious, but double-stained elements were not observed. By electron microscopy, asymmetrical synapses frequently occurred between CRF axons and TH dendrites or somata. Symmetrical axosomatic synapses sometimes appeared adjacent to these CRF/TH synapses, while symmetrical axoaxonic synapses were rare. We conclude that CRF neuronal efferents synaptically activate A14 DA neurons in the primate PV and pvPVN. Parallel CRF/DA symmetrical synapses also suggest coexistence of a companion transmitter within some of these same CRF neurons. Our own previous work and recent independent studies indicate that this transmitter is probably GABA. Thus the CRF neuronal system, which is known to alter secretion of several pituitary hormones, may also act through hypothalamic periventricular DA neurons to mediate other responses to stress.

The gonadotropin-releasing hormone containing ventral hypothalamic tract in the fetal rhesus monkey (Macaca mulatta).

A well-defined, gonadotropin-releasing hormone (GnRH)-containing fiber pathway, the ventral hypothalamic tract (VHT), is described by immunostaining in fetal rhesus macaques (109-156 days gestation). The VHT arises above the lateral aspects of the optic chiasm near the supraoptic nucleus, and courses ventromedially close to the ventral hypothalamic surface to terminate in the infundibulum and zona externa of the median eminence. It is formed by the confluence of GnRH-immunopositive (GnRH+) axons from local neurons, from a few GnRH+ cells in the inferior thalamic peduncle, and probably from more anterior neurons in the septum and preoptic area. Bipolar GnRH+ neurons contributing directly to the VHT are grouped at its origin dorsolateral to the optic chiasm, dorsal and medial to the optic tracts, at the infundibular lip, and within the pathway between. At the infundibular lip, GnRH+ perikarya are generally lateral or ventral to the infundibular (arcuate) nucleus, and are rarely within the nucleus itself. Cell bodies here are sometimes tripolar, but GnRH+ intercellular contacts are seldom seen. A few VHT fibers extend to the ventral surface of the brain just beneath the pia mater. Abundant capillaries in the subarachnoid space suggest a possible route for delivery of GnRH to the adenohypophysis in early gestation, before maturation of the hypophysial portal system occurs. Posterior to the infundibulum, a few VHT fibers are joined by descending periventricular fibers forming a dense fiber band beneath the premammillary recess of the third ventricle. Totals of GnRH+ cell bodies in the prosencephalon of the fetal rhesus macaque are estimated to be 5,600 in females (n = 2) and 2,600 in males (n = 3). More than 60% of VHT neurons are located in the medial basal hypothalamus, and the majority of basal hypothalamic GnRH+ neurons (86%) are associated with the VHT. Furthermore, reports of the autonomy of the medial basal hypothalamic-hypophysial unit in control of gonadotropin secretion suggest that the VHT may be the most important GnRH system involved in primate reproduction. It is clear that fetal material may offer the best model to study the GnRH neuronal system in primates.

Immunostaining reveals accumulation of serotonin and coexistence with tyrosine hydroxylase in hypothalamic neurons of acutely stalk-sectioned baboons.

The distribution of serotonin (5-HT) and tyrosine hydroxylase (TH) was examined in the hypothalamus of juvenile baboons, 24 h after infundibular stalk section. Simultaneous immunostaining for 5-HT with peroxidase-antiperoxidase (PAP) and TH with 15 nm colloidal gold (IGS) was performed on Vibratome sections from 3 operated and 1 control female. Light microscopy revealed fine 5-HT immunopositive (5-HT+) fibers, presumably axons, in the suprachiasmatic nuclei and ventromedial hypothalamus (VMH) after stalk section. In addition, focal accumulations of swollen and heavily stained 5-HT+ fibers occurred on the side of the surgical approach. Enlarged fibers were densest in the medial preoptic area, lateral and VMH areas, and the median eminence. TH immunoreactivity (TH+) in VMH cell bodies and axons was only slightly increased over that in controls. Electron microscopy of areas of 5-HT+ and TH+ overlap (medial VMH and adjacent periventricular zone) showed that 5-HT+ profiles were mostly unmyelinated axons and irregular varicosities. A few myelinated 5-HT+ axons were also observed. TH+ perikarya, dendrites, axons and terminals showed gold labeling characteristic for this enzyme. However, colocalization of 5-HT (PAP) and TH (IGS) was present in a number of fiber varicosities in experimental animals only. Both single- and double-labeled profiles occurred in individual thin sections, thus arguing against antibody cross-reactivity. These results indicate that: hypothalamic 5-HT+ fibers project to the median eminence in primates; 5-HT fibers become more obvious after stalk section due to accumulation of transmitter; focal 5-HT+ immunoreactivity in the hypothalamus can increase dramatically after distant and mild surgical trauma, and coexistence of 5-HT and TH in single neurons can appear after acute stalk section and/or trauma in experimental animals. These findings might represent uptake of exogenous 5-HT or amplified expression of endogenous neurotransmitter, suggesting that plasticity of transmitter phenotype might follow acute surgical and/or endocrine intervention in mature primate brain. Neuroendocrine studies employing the stalk-sectioned primate might thus be radically affected.

GABAergic and catecholaminergic synaptic interactions in the macaque hypothalamus: double label immunostaining with peroxidase-antiperoxidase and colloidal gold.

Immunogold staining (IGS) for glutamic acid decarboxylase (GAD) was combined with the peroxidase-antiperoxidase (PAP) technique for tyrosine hydroxylase (TH) to analyze gamma-aminobutyric acid-catecholaminergic neuronal interactions in the rhesus hypothalamus. At the light-microscopic level, TH-immunoreactive (-IR) perikarya and their fibers (brown) were observed in the anterior ventral periventricular area (AVPV), the arcuate nucleus (ARC) and the adjacent periventricular zone (ARC-PVZ). GAD-IR processes (light red) were also present throughout the hypothalamus and appeared to contact some TH-IR neurons. At the electron-microscopic level, PAP was present in perikarya, dendrites, axons and axon terminals of TH-IR neurons. Colloidal gold particles (15 nm) were found only in dendrites and axon terminals of GAD-IR neurons. Labeled GAD terminals typically contained small, clear synaptic vesicles, while TH terminals contained these and sometimes one or two dense-core vesicles. In the ARC and ARC-PVZ, asymmetrical (Gray I) axodendritic synapses occurred between GAD and TH-IR profiles, with TH/GAD directionality more prevalent. Symmetrical (Gray II) synapses were less common, with either TH or GAD presynaptic in axodendritic and dendrodendritic contacts. GAD/GAD interactions were not observed, but TH/TH contacts appeared to be mostly dendrodendritic. In the AVPV, only symmetrical synapses were encountered, and their directionality was difficult to determine. GAD- and TH-IR dendrites frequently established dendrodendritic synapses, but GAD/TH dendrosomatic synapses were seldom seen. These results illustrate the complex interactions of GAD- and TH-containing elements in the neuroendocrine hypothalamus.

Fixation, fine structure, and immunostaining for neuropeptides: perfusion versus immersion of the neuroendocrine hypothalamus.

The effects of various fixatives and fixation methods on ultrastructural morphology and the immunocytochemical localization of beta-endorphin were examined in rat brain. The mediobasal hypothalamus was preserved by vascular perfusion and/or immersion in nine different fixatives. We tested several combinations of paraformaldehyde, glutaraldehyde, acrolein, and picric acid in various isosmolar buffers. Vibratome sections were stained for beta-endorphin employing the peroxidase-antiperoxidase technique, or processed directly for electron microscopy. The ultrastructural quality of a given region was attributed to its location with respect to the blood-brain barrier, the method of fixation, and the concentrations of some of the fixative components. Immersion fixation gave better results and reduced extracellular space in the median eminence (outside the blood-brain barrier) and areas close to the hypothalamic surface. Positive immunostaining of beta-endorphin perikarya occurred only in tissue fixed with periodate-lysine-paraformaldehyde. Light to moderate fiber staining was also present in some paraformaldehyde-glutaraldehyde-acrolein combinations. However, a glutaraldehyde concentration of 1% or higher abolished all positive staining for beta-endorphin. These results emphasize the necessity of optimizing fixation for ultrastructure and for immunocytochemical staining of each individual antigen. The choice of the best fixation method depends not only on the intracellular location of the antigen but also on the relationship between hypothalamic tissue compartments and the blood-brain barrier.

Ultrastructural analysis of synapses involving tyrosine hydroxylase-containing neurons in the ventral periventricular hypothalamus of the macaque.

Immunocytochemical staining for tyrosine hydroxylase (TH) in the adult macaque brain revealed a network of catecholaminergic (CA) cell bodies and fibers in the arcuate (ARC), anterior ventral periventricular (APV) and lateral suprachiasmatic nuclei (SCN). Coronal Vibratome sections immunostained with PAP or colloidal gold (15 nm) were thin sectioned and examined by electron microscopy. We examined 280 TH-immunopositive processes in individual or in serial thin sections. Of these, 190 engaged in a total of 270 synapses identified as Gray Type I asymmetrical synapses (AS) with distinct postsynaptic densities or Gray Type II symmetrical synapses (SS) without such specializations. The majority (80%) of all synapses were axodendritic, 63% of which exhibited SS and 37% AS, representing almost all of the AS observed. In nearly every case, unlabeled axon terminals containing round, 45 nm, clear vesicles and occasional small dense core vesicles contacted TH-labeled dendrites. About 15% of the synapses were dendrodendritic, all of which were symmetrical. Rare contacts involving other elements (axosomatic, dendrosomatic) constituted only 5% of the total, and occurred predominantly as SS. The predominance of AS and the prevalence of SS almost exclusively on TH-containing dendrites indicates that these CA neurons receive extensive afferent input from other neurotransmitters. TH-labeling of both neural elements in most dendrodendritic, and in some axodendritic SS, also suggests that they modulate one another within the ARC, APV and SCN. The results suggest that these CA neurons perform an important role in local integration, and may act elsewhere to affect the common final pathway of the neuroendocrine system in primates.

Preembedding colloidal gold immunostaining of hypothalamic neurons: light and electron microscopic localization of beta-endorphin-immunoreactive perikarya.

A preembedding immunogold staining (IGS) procedure was developed to identify beta-endorphin/adrenocorticotropic hormone immunoreactive neurons at the light and electron microscopic levels. Colchicine-treated rats were perfused with Nakane's periodate-lysine-paraformaldehyde fixative. Vibratome sections were incubated in primary antisera followed by goat anti-rabbit immunoglobulin G coupled to 16 nm colloidal gold, and, in some cases, rabbit immunoglobulin G coupled to gold. The appearance to pink to light red perikarya, corresponding to colloidal gold deposition at antigenic sites, was monitored under the light microscope. Positive cell bodies in the arcuate region sometimes extended lateral to the nucleus. Only proximal portions of neuronal processes were stained. At the ultrastructural level, colloidal gold labeled the periphery of 90-110 nm dense neurosecretory granules in the perikaryal cytoplasm and a few proximal axons. Clusters of gold particles, appearing free in the neuroplasm, actually labeled secretory granules in adjacent thin sections. Granules associated with the Golgi apparatus were not stained. Colloidal gold labeling of mature beta-endorphin granules, but not progranules, in rat hypothalamic neurons was confirmed using the peroxidase-antiperoxidase technique. The results correlate well with data on the intracellular processing of pro-opiomelanocortin in pituitary cells and prepropressophysin in the paraventricular nucleus. These data demonstrate the first application of the preembedding colloidal gold staining method for the identification of intracellular antigens within the central nervous system. The IGS method provides a definitive marker for single or double labeling of nervous tissue at both the light and electron microscopic levels.

Mammotroph and gonadotroph volume percentage in the rat anterior pituitary after lesions of the medial basal hypothalamus.

A lesion of the medial basal hypothalamus (MBH) results in enhanced secretion of prolactin and reduced release of the other hormones from the anterior pituitary. We measured the volume percentage of the prolactin-secreting mammotrophs, stained immunocytochemically, under several experimental conditions to assess the morphological correlated of the high secretion of prolactin. In addition, gonadotrophs were stained both tinctorially with the periodic acid-Schiff reagent and immunocytochemically with antibodies to luteinizing hormone. Anterior pituitaries were studied from female rats which were: (1) cycling, (2) ovariectomized for 2 weeks, (3) ovariectomized for 2 weeks with a lesion of the MBH for 1, 14 and 21 days. The volume percentage of mammotrophs and gonadotrophs in the lateral, central and middle fields of the anterior pituitary was determined and this measurement was expressed relative to endocrine cellular area so that vascular space and necrotic regions would not be included in the assessment. Ovariectomy significantly decreased mammotroph and increased gonadotroph volume percentage when compared to the intact animals. MBH lesions had the opposite effect. At 14 and 21 days after a lesion, the volume percentage of mammotrophs was significantly greater than in the intact rat, while the volume percentage of gonadotrophs was identical to that observed in the intact rat. These data suggest that the elimination of the prolactin-inhibitory hormone(s) of the MBH result in hypertrophy and/or hyperplasia of mammotrophs. This effect occurs in the absence of ovarian and may be of importance in the induction of prolactin-secreting pituitary adenomas. The data also support the hypothesis that destruction of gonadotropin-releasing hormone neuron terminals countermands the hypertrophy of gonadotrophs induced by ovariectomy.

Neuroregulatory and neuroendocrine GnRH pathways in the hypothalamus and forebrain of the baboon.

The distribution of neurons containing gonadotropin-releasing hormone (GnRH) in the baboon hypothalamus and forebrain was studied immunocytochemically by light and electron microscopy. GnRH was present in the perikarya, axonal and dendritic processes of immunoreactive neurons. Three populations of GnRH neurons could be distinguished. Most of the GnRH neurons which are assumed to directly influence the anterior pituitary were in the medial basal hypothalamus. Other cells that projected to the median eminence were found scattered throughout the hypothalamus. A second, larger population of neurons apparently was not involved with control of the anterior pituitary. These neurons were generally found within afferent and efferent pathways of the hypothalamus and forebrain, and may receive external information affecting reproduction. A few neurons projecting to the median eminence were also observed sending collaterals to other brain areas. Thus, in addition to their neuroendocrine role, these cells possibly have neuroregulatory functions. The inference is made that these bifunctional neurons, together with the widely observed GnRH-GnRH cellular interactions may help to synchronize ovulation and sexual behavior.