Identification of cells expressing Cx43, Cx30, Cx26, Cx32 and Cx36 in gap junctions of rat brain and spinal cord

We have identified cells expressing Cx26, Cx30, Cx32, Cx36 and Cx43 in gap junctions of rat central nervous system (CNS) using confocal light microscopic immunocytochemistry and freeze-fracture replica immunogold labeling (FRIL). Confocal microscopy was used to assess general distributions of connexins, whereas the 100-fold higher resolution of FRIL allowed co-localization of several different connexins within individual ultrastructurally-defined gap junction plaques in ultrastructurally and immunologically identified cell types. In >4000 labeled gap junctions found in >370 FRIL replicas of gray matter in adult rats, Cx26, Cx30 and Cx43 were found only in astrocyte gap junctions; Cx32 was only in oligodendrocytes, and Cx36 was only in neurons. Moreover, Cx26, Cx30 and Cx43 were co-localized in most astrocyte gap junctions. Oligodendrocytes shared intercellular gap junctions only with astrocytes, and these heterologous junctions had Cx32 on the oligodendrocyte side and Cx26, Cx30 and Cx43 on the astrocyte side. In 4 and 18 day postnatal rat spinal cord, neuronal gap junctions contained Cx36, whereas Cx26 was present in leptomenigeal gap junctions. Thus, in adult rat CNS, neurons and glia express different connexins, with "permissive" connexin pairing combinations apparently defining separate pathways for neuronal vs. glial gap junctional communication.     

Differential distribution of orexin-A and orexin-B immunoreactivity in the rat brain and spinal cord

The orexins are recently identified appetite-stimulating hypothalamic peptides. We used immunohistochemistry to map orexin-A and orexin-B immunoreactivity in rat brain, spinal cord, and some peripheral tissues. Orexin-A- and orexin-B-immunoreactive cell bodies were confined to the lateral hypothalamic area and perifornical nuclei. Orexin-A-immunoreactive fibers were densely distributed in the hypothalamus, septum, thalamus, locus coeruleus, spinal cord, and near the ventricles, but absent from peripheral sites investigated. In contrast, orexin-B-immunoreactive fibers were distributed sparsely in the hypothalamus. Orexin cells are strategically sited to contribute to feeding regulation, but their widespread projections suggest that orexins have other physiological roles.     

Regional distribution of neuromedin K and neuromedin L in rat brain and spinal cord

Neuromedin K and neuromedin L are novel mammalian tachykinins isolated from porcine spinal cord. We have developed a highly sensitive radioimmunoassay for neuromedin K. Since the radioimmunoassay for neuromedin K has significant crossreactivity with neuromedin L and substance P, we can simultaneously determine the tissue concentrations of neuromedin K, neuromedin L and substance P after separation of the tissue extracts by reverse phase high performance liquid chromatography. Substance P is found to be the most abundant mammalian tachykinin in every brain region. The ratio of the concentration of substance P to neuromedin K is small in cerebral cortex and large in medulla-pons, while that of substance P to neuromedin L is rather constant in a range of 2.0–2.5. In spinal cord, dorsal half contains more neuromedin K and L than ventral half as is the case with substance P. These results indicate that both neuromedin K and L are endogenous mammalian tachykinins with specific physiological functions.     

Prostaglandin D2 in rat brain,spinal cord and pituitary: Basal level and regional distribution

A highly sensitive and specific radioimmunoassay for prostaglandin D₂ has been developed and used to determine the basal level and regional distribution of this prostaglandin in rat brain, spinal cord and pituitary. The assay can detect as little as 20 pg of prostaglandin D₂, and the antiserum used shows 20% cross-reactivity to prostaglandin D₁, 0.1% cross-reactivity to 13,14-dihydro-15-ketoprostaglandin D₂ and even lower cross-reactivity to other prostaglandins. Prostaglandin D₂-like immunoreactivity was extracted with ethanol from the rat tissues. The immunoreactivity comigrated with authentic prostaglandin D₂ on silica gel thin layer chromatography, showed the dilution curve parallel to that of the authentic compound, and decreased in amounts by the pretreatment of animals with indomethacin, suggesting that it was prostaglandin D₂ itself. To avoid a postmortem formation of prostaglandins, we sacrificed animals by microwave irradiation at 4.5 kW for 1.2 sec under which conditions both prostaglandin D synthetase and prostaglandin D dehydrogenase were completely inactivated. The amount of prostaglandin D₂ in whole brain measured under these conditions was 3.42±0.59 ng (mean+S.E.M.), and those of prostaglandin E₂ and F_2α measured by the respective radioimmunoassays were 1.32±0.24 and 0.96±0.20 ng, respectively. Prostaglandin D₂ was widely distributed in rat brain, spinal cord and pituitary. The highest concentrations were seen in pineal gland and neurointermediate pituitary followed by anterior pituitary. Lower but significant concentrations were observed in other parts of brain, among which hypothalamus and septum showed the relatively high concentrations.     

A freeze-fracture study of exocytosis and reflexive gap junctions in human ovarian decidual cells

Fine-structural features of ovarian decidual cells and their mode of secretion were examined by means of freeze-fracture microscopy. Unique cortical peduncular processes contained secretory vesicles within the expanded peduncle tip, the membrane-leaflets of which exhibited a particle-poor E face adjacent to the vesicle lumen and a P face containing a greater particle number. Exocytosis from attached peduncles involved release of vesicular profiles 40-55 nm in diameter; small particles 8.5-11.5 nm in diameter were also observed at degranulation sites. In fractures revealing the E face of the plasmalemma, cytoplasmic portals at the bases of peduncular stalks were distinguishable from endocytic vesicles. The frequent occurrence of reflexive gap junctions associated with peduncles was shown by freeze-fracture. However, there appeared to be no consistent spatial relationship between gap junctions, secretory peduncles, or sites of exocytosis. Freeze-fracture analysis of the topography of reflexive gap junctional profiles revealed that such gap junctions share basic similarities with intercellular gap jum particle-free aisles. The finding in the present study of reflexive gap junctions occurring between peduncles and the cell soma, as well as between peduncles, suggests that the original definitiof the same cell should be broadened to include any gap junctional specialization formed between portions of the plasma membrane of one cell.     

Neuromedin B is a major bombesin-like peptide in rat brain: regional distribution of neuromedin B and neuromedin C in rat brain, pituitary and spinal cord

Neuromedin B and neuromedin C are the novel mammalian bombesin-like peptides isolated from porcine spinal cord. We have developed highly specific and sensitive radioimmunoassays for neuromedin B and neuromedin C, and determined their regional distribution in rat central nervous system. Prior to measurements of the tissue contents, immunoreactive neuromedin B and C were characterized by gel-filtration and high performance liquid chromatography. Neuromedin B and C immunoreactivities have similar regional distribution in rat brain, but the content of immunoreactive neuromedin B is 2-6 times higher than that of immunoreactive neuromedin C in every region. These results indicate that neuromedin B is a major endogenous bombesin-like peptide in rat brain and has specific functions of physiological importance.     

The distribution and turnover of tryptamine in the brain and spinal cord

Tryptamine levels have been determined in mouse brain regions and spinal cord and in rat spinal cord. They were; caudate nucleus 2.5 ng·g^–1, hypothalamus <0.5 ng·g^–1, hippocampus <0.7 ng·g^–1, olfactory bulb <0.7 ng·g^–1, olfactory tubercles <0.6 ng·g^–1, brain stem <0.4 ng·g^–1, cerebellum <1.0 ng·g^–1, and the rest 0.9 ng·g^–1. The mouse whole brain was found to have 0.5 ng·g^–1, the mouse spinal cord 0.3 ng·g^–1, and the rat spinal cord 0.3 ng·g^–1. These concentrations increased rapidly to 22.8 ng·g^–1, 14.2 ng·g^–1, and 6.6 ng·g^–1 respectively at 1 hr after 200 mg·kg^–1 pargyline. The turnover rates and half lives of tryptamine in the mouse brain and spinal cord and rat spinal cord were estimated to be 0.14 nmol·g^–1·h^–1 and 0.9 min; 0.054 nmol·g^–1·h^–1 and 1.5 min and 0.04 nmol·g^–1·h^–1 and 1.6 min respectively. The aromaticl-aminoacid decarboxylase inhibitors NSD 1034 and NSD 1055 reduced synthesis of tryptamine in controls and pargyline pretreated animals. Tryptophan increased the concentrations of mouse striatal tryptamine and 5-hydroxytryptamine and brain stem 5-hydroxyindole acetic acid.p-Chlorophenylalanine reduced formation of 5-hydroxytryptamine and 5-hydroxyindoleacetic acid but did not change that of tryptamine.     

Structural changes in cardiac gap junctions after hypoxia and reoxygenation: a quantitative freeze-fracture analysis

Summary Isolated rat hearts were subjected to increasing periods of hypoxia with or without subsequent reoxygenation and the gap-junctional particle configuration was followed quantitatively. Irregular contractions were prevented by K⁺-arrest; glucose, counteracting the effects of hypoxia, was omitted. Hyperkalemia alone and a maximum of 20 min of hypoxia do not produce reorganization of the gap-junctional particles normally forming multiple hexagonally packed arrays separated by smooth aisles. After 30 min of hypoxia, the aisles disappear in a proportion of the junctions, thereby increasing the particle density from 9400±800/m² to 10200±900/m². After 40 min of hypoxia, the normal configuration is no longer found and numerous junctions are arranged as uninterrupted hexagonal lattices. The particles are further condensed to 11600±900/m². Following reoxygenation after both 30 and 40 min of hypoxia, the proportion of crystalline gap junctions dramatically augments and the mean particle density has further increased significantly. Corresponding thin sections show irreversible cell damage. When reoxygenation is performed with a control solution containing normal levels of K⁺ and glucose, the particle density does not increase substantially in comparison to the respective 30- and 40-min hypoxic periods. In both groups, the gap junctions display either a normal, a crystalline or an intermediate configuration with crystalline margins and loose centers. The gap-junctional reorganization during hypoxia essentially represents a particle condensation, while the mean center-to-center distances between the particles and pits remain constant. Furthermore, the reappearance of normal gap junctions after reoxygenation appears to depend on glucose availability.     

Histochemical demonstration of copper in normal rat brain and spinal cord

Summary The high sensitivity of the magnesium-dithizonate silver-dithizonate (MDSD) staining procedure makes this method very suitable for the histochemical localization of copper in different regions of the central nervous system of adult rats. In the telencephalon (bulbus olfactorius, nucleus caudatus-putamen, septum pellucidum and are dentata), diencephalon (nucleus habenulae medialis, nuclei of the hypothalamus in the vicinity of the third ventricle, and corpus mamillare), mesencephalon (substantia nigra), cerebellum (mainly in the nodulus), pons (locus coeruleus, nucleus vestibularis), medulla oblongata (nucleus tractus solitarii) and spinal cord, the glial cells exhibit specific copper staining. The glial cells of some circumventricular organs (e.g. the subfornical organ) are also stained using the MDSD method. The significant staining observed in whitematter glial cells (e.g. in the corpus callosum, cerebellum and spinal cord) further indicates the very high sensitivity of this method. In glial cells of the same regions, the presence of copper can likewise be demonstrated using the modified sulphide silver method. On the basis of the present histochemical results, it is suggested that copper may play an important role in the normal physiological functioning of glial cells and also, via glia-neuron interactions, in neuronal processes.     

Regional distribution of pyroglutamyl peptidase II in rabbit brain, spinal cord, and organs.

Pyroglutamyl peptidase II (PPII) is a narrow specificity ectoenzyme that degrades thyrotropin-releasing hormone (TRH). We detected the enzyme in the brain of various mammals, with highest specific activity in rabbit brain. In this species, activity was heterogeneously distributed in the central nervous system. There was a 28-fold difference between regions of highest and lowest PPII activity. Enzyme activity was highest in the olfactory bulb and posterior cortex. In the spinal cord, activity was low but unevenly distributed, with highest values detected in the thoracic (T) region. Segments T1 and T2 activities were particularly high. Other organs contained low or undetectable levels of activity. The levels of TRH-like immunoreactivity (TRH-LI) in spinal cord segments were greatest in T3-T4 and lumbar L2-L6. Low concentrations were found in T1 and T9-T12. There was a partial correlation between the distribution of PPII activity and TRH receptors but not with TRH-LI levels. These results demonstrate that PPII is predominantly a central nervous system enzyme, and they support the hypothesis that PPII is responsible for degrading TRH released into the synaptic cleft.     

Diazepam increases 5-hydroxyindole concentrations in rat brain and spinal cord

Diazepam elevates serotonin (5HT) and 5-hydroxyindoleacetic acid (5HIAA) concentrations in rat brain and spinal cord. The maximal effect occurs 1–2 hrs after drug injection and is dose related between 5–20 mg/kg (intraperitoneal). The action of diazepam on brain 5HT and 5HIAA concentrations is modified by previous food consumption: the ingestion of a diet that raises brain 5HT and 5HIAA one hour before drug injection enhances the diazepam-induced increase in brain indoles; consumption of a diet that lowers brain 5HT and 5HIAA partially blocks the elevation in brain indoles that follows diazepam injection.     

Direct immunogold labeling of connexins and aquaporin-4 in freeze-fracture replicas of liver, brain, and spinal cord: factors limiting quantitative analysis

Direct immunogold labeling and histological mapping of membrane proteins is demonstrated in Lexan-stabilized SDS-washed freeze-fracture replicas of complex tissues. Using rat brain and spinal cord as primary model systems and liver as a "control" tissue to identify preparation and labeling artifacts, we demonstrate the presence of connexin43 in freeze-fractured gap junctions of identified and mapped astrocytes and ependymocytes, and confirm the presence of connexin32 in freeze-fractured gap junctions in liver. In addition, the simultaneous double-labeling of dissimilar proteins (connexin43 and aquaporin-4) is demonstrated in gap junctions and square arrays, respectively, in the plasma membranes of astrocytes and ependymocytes. Finally, double-side shadowing and conventional staining methods are used to reveal the extent of biological material present at the time of labeling and to investigate the dynamics of membrane solubilization, the primary artifacts that occur during labeling, and several factors limiting quantitative analysis.     

Structure and function of gap junctions in the developing brain

Gap-junction-dependent neuronal communication is widespread in the developing brain, and the prevalence of gap-junctional coupling is well correlated with specific developmental events. We summarize here our current knowledge of the contribution of gap junctions to brain development and propose that they carry out this role by taking advantage of the full complement of their functional properties. Thus, hemichannel activation may represent a key step in the initiation of Ca²⁺ waves that coordinate cell cycle events during early prenatal neurogenesis, whereas both hemichannels and/or gap junctions may control the division and migration of cohorts of precusor cells during late prenatal neurogenesis. Finally, the recent discovery that pannexins, a novel group of proteins prominently expressed in the brain, are able to form both hemichannels and gap-junction channels suggests that we need to seek more than just connexins with respect to these junctions.Work in the authors’ laboratories is supported by the Deutsche Forschungsgemeinschaft, SFB 509 (R.D.) and by the Institut Pasteur (R.B.).     

Specific processing of the thyrotropin-releasing prohormone in rat brain and spinal cord

Thyrotropin-releasing hormone (TRH) and TRH extended peptides were extracted from rat hypothalamus and spinal cord and resolved by gel exclusion chromatography under dissociating conditions. Peptides related to TRH were detected by trypsin digestion and radioimmunoassay with an antibody to TRH or an antibody raised against the pentapeptide Glp-His-Pro-Gly-Lys. In addition to the tripeptide hormone a series of C-terminally extended forms of TRH was shown to occur in both tissues; no N-terminally extended peptides were detected. The structure of the TRH-related peptides was confirmed by chromatographic identification of the N-terminal pentapeptide sequence released by trypsin. The TRH extended peptides, which accounted for 15-20% of the total TRH, were present in three groups of different molecular size corresponding to predicted fragments of the TRH prohormone. One of the peptides in the spinal cord was identified by chromatographic comparison with a synthetic 16-residue peptide representing residues 154-169 of the prohormone. In the spinal cord the TRH extended peptides differed in their relative concentrations from the corresponding peptides in the hypothalamus, possibly reflecting differences in processing. The finding of extended forms of TRH in which the extension occurs only on the C-terminal side of the hormone sequence shows that the prohormone undergoes highly specific processing.