Osteocalcin- and Osteopontin-Containing Neurons in the Rat Hind Brain

Immunohistochemistry for osteocalcin (OC) and osteopontin (OPN) was performed to know their distributions in the hind brain of adult rats. OC- and OPN-immunoreactivity (-ir) were detected in neuronal cell bodies, including perikarya and proximal dendrites and the neuropil. In the cranial nerve motor nuclei, numerous OC- and OPN-immunoreactive (-ir) neurons were detected. The neuropil in the cranial motor nuclei mostly showed strong OC- and OPN-staining intensity. The cranial nerve sensory nuclei and other relay and modulating structures in the lower brain stem also contained various numbers of OC- and OPN-ir neurons. The staining intensities in the neuropil were varied among these regions. In the cerebellar cortex, Purkinje cells and granule cells showed OPN-ir but not OC-ir. However, OC- and OPN-ir neurons were abundantly distributed throughout the cerebellar nuclei. The neuropil in the cerebellar nuclei showed moderate OC-ir and strong OPN-ir staining intensities. These findings indicate that the distribution patterns of OC- and OPN-ir neurons were similar in many structures within the hind brain. OC may play a role in modulating neuroprotective function of OPN.     

CHOLINE ACETYLTRANSFERASE CONTENT IN DISCRETE REGIONS OF THE RAT BRAIN STEM

—Choline acetyltransferase (ChAc) content of 50 separate rat brain stem nuclei and cerebellum removed by microdissection was determined using a sensitive radiometric assay. The distribution of ChAc activity is uneven, with extremely high levels in the cranial motor nuclei and the nucleus salivatorius. Low ChAc concentrations were observed in the cranial sensory nuclei, the nuclei of the reticular formation, the raphe nuclei and the nuclei of the acoustic system. The lowest ChAc levels were measured in the cerebellum. Comparison of the distribution of ChAc with histochemical localization of acetylcholinesterase revealed generally good agreement, and notable exceptions are discussed.     

Expression of<Emphasis Type="Italic"> neurochondrin</Emphasis> in the developing and adult mouse brain

Here we describe a detailed analysis of the expression of neurochondrin (ncdn) in the developing and adult mouse brain. Ncdn is first expressed in the hindbrain and spinal cord at embryonic day 10.5 (E10.5) followed by expression in the midbrain at E11.5. By E18 ncdn is also expressed in the diencephalon and telencephalon. However, strongest expression is still observed in the hindbrain. In adults, the expression in the forebrain is as strong as in the hindbrain. Ncdn is highly expressed in the hippocampus, piriform cortex, septum, amygdaloid complex, medial geniculate nucleus, inferior colliculus, cerebellar nuclei and the nuclei of the Vth, VIIth, and XIIth cranial nerves.Edited by B. HerrmannR. Istvánffy and D.M. Vogt Weisenhorn contributed equally to this paper     

Topico-anatomical relations among the structures of the caudal medullary region in early postnatal rats

Anatomical and topographical organization of the structures of the caudal medullary region was studied in 3- and 21-day-old rats. A system of stereotaxic coordinates was proposed, and brain maps for the animals of these age groups were plotted. Topographic characteristics were given for the nuclei forming the medullary respiratory center: the lateral reticular nucleus,n. ambiguus, and the nuclei of the solitary tract, vagus and hypoglossal cranial nerves. These structures differ from each other in their cytoarchitectonics and in the changes in number during their neurons' postnatal development. The differences are suggested to result from the differences in morphological maturation of the neurons at early ontogenic stages.Neirofiziologiya/Neurophysiology, Vol. 26, No. 4, pp. 243–250, July–August, 1994.     

Cranial capacity in hominid evolution

We present an analysis of cranial capacity of 118 hominid crania available from the literature. The crania belong to both the genusAustralopithecus andHomo and provide a clear outline of hominid cranial evolution starting at more than 3 million years ago. Beginning withA. afarensis there is a clear increase in both absolute and relative brain size with every successive time period.H.s. neandertal has an absolutely and relatively smaller brain size (1412cc, E.Q.=5.6) than fossil modernH.s. sapiens (1487cc, E.Q.=5.9). Three evolutionary models of hominid brain evolution were tested: gradualism, punctuated equilibrium, and a mixed model using both gradualism and punctuated equilibrium. Both parametric and non-parametric analyses show a clear trend toward increasing brain size withH. erectus and a possible relationship within archaicH. sapiens. An evolutionary stasis in cranial capacity could not be refuted for all other taxa. Consequently, the mixed model appears to more fully explain hominid cranial capacity evolution. However, taxonomic decisions could directly compromise the possibility of testing the evolutionary mechanisms hypothesized to be operating in hominid brain expansion.     

Distribution of simple esterase in the nuclei and fiber tracts of the medulla oblongata of squirrel (Funambulus palmarum)

The distribution of simple esterase has been studied in the nuclei and fiber tracts of the medulla oblongata. The simple esterase activity has mainly been observed in the grey matter. The white matter did not reveal enzymatic activity. In the grey matter also the cranial nerve nuclei are intensely stained as compared to intrinsic and reticular nuclei. The distributive pattern of simple esterase in the nuclei has been discussed in relation to its metabolic involvement in brain.     

Biosynthesis of serotonin in Raphé nuclei of rat brain: effect of p-chlorophenylalanine

The activity of tryptophan hydroxylase (EC 1.99.1.4) in the region of the raphé nuclei of rat brain was higher than that of any other brain area. The content of serotonin and the rate of serotonin synthesis were also highest in the raphé nuclei. Following the administration of p-chlorophenylalanine the injection of tryptophan and pargyline increased the content of serotonin in the region of the raphé nuclei of rat brain. The results suggest that the raphé nuclei retained the capacity to hydroxyl-late tryptophan to some extent after the injection of p-chlorophenylalanine.     

Systematic implications of brain morphology in potamotrygonidae (Chondrichthyes: Myliobatiformes)

The gross brain morphology, brain proportions, and position of cranial nerves in all four genera (Potamotrygon, Plesiotrygon, Paratrygon, and Heliotrygon) and 11 of the species of the Neotropical stingray family Potamotrygonidae were studied to provide new characters that may have a bearing on internal potamotrygonid systematics. The brain was also studied in four other stingray (Myliobatiformes) genera (Hexatrygon, Taeniura, Dasyatis, and Gymnura) to provide a more inclusive phylogenetic context for the interpretation of features of the brain in potamotrygonids. Our results indicate, based on neuroanatomical characters, that the genera Paratrygon and Heliotrygon are sister groups, as are the genera Potamotrygon and Plesiotrygon, agreeing with previous morphological and molecular phylogenetic studies. Both groups of genera share distinct conditions of the olfactory tracts, telencephalon and its central nuclei, hypophysis and infundibulum, morphology and orientation of the metencephalic corpus cerebelli, orientation of the glossopharyngeal nerve, and overall encephalic proportions. The corpus cerebelli of Paratrygon and Heliotrygon is interpreted as being more similar to the general batoid condition and, given their phylogenetic position highly nested within stingrays, is considered secondarily derived, not plesiomorphically retained. Our observations of the corpus cerebelli of stingrays, including Hexatrygon, corroborate that the general stingray pattern previously advanced by Northcutt is derived among batoids. The morphology of the brain is shown to be a useful source of phylogenetically informative characters at lower hierarchical levels, such as between genera and species, and thus, has significant potential in phylogenetic studies of elasmobranchs. J. Morphol. 277:252–263, 2016. © 2015 Wiley Periodicals, Inc.     

Androgen receptor mRNA expression in Xenopus laevis CNS: Sexual dimorphism and regulation in laryngeal motor nucleus

Using Northern analysis, in situ hybridization, and nuclease protection assays, the expression and regulation of androgen receptor messenger RNA (AR mRNA) was examined in the CNS of juvenile Xenopus laevis. Only one of the AR mRNA isoforms expressed in X. laevis is transcribed in the CNS as shown by Northern blot analysis. Nuclease protection assays demonstrate that the expression of AR mRNA is higher in the brain stem than in the telencephalon and diencephalon. Although expression of AR mRNA is widespread throughout the CNS, cells of cranial nerve nucleus IX-X (N. IX-X) and spinal cord display the highest in situ hybridization signals in their cytoplasm. Double labeling using horseradish peroxidase and digoxigenin labeled AR probes reveals that laryngeal and anterior spinal cord motor neurons express AR mRNA. More cells express AR mRNA in N. IX-X of males than of females. The number of AR expressing cells in N. IX-X decreases following gonadectomy in both sexes, and dihydrotestosterone (DHT) treatment for 1 month reverses this effect. Increased expression of AR mRNA in the brain of DHT treated animals is also apparent in nuclease protection assays. Sex differences in number of AR expressing cells and hormone regulation of AR mRNA expression in motor nuclei may influence neuromuscular systems devoted to sexually differentiated behaviors. © 1996 John Wiley & Sons, Inc.     

Histochemical distribution of alkaline and acid phosphatase and adenosine triphosphatase in the brain of squirrel monkey (Saimiri sciureus)

Summary The distribution of some phosphatases (alkaline and acid phosphatase and ATPase) have been studied on 15 thick fresh frozen serial sections in the various regions and nuclei of the squirrel monkey brain. The alkaline phosphatase activity is concentrated in the blood vessels and the peripheral part of the neurons of some nuclei (e.g., nucleus supraoptic hypothalami) and the lining cells of choroid plexus. Acid phosphatase (AC) is a cellular enzyme and is concentrated in the large neurons of nuclei basalis Meynert, diagonalis band of Broca, magnocellular hypothalamic nuclei, corpus mammillaris, large sized neurons of the thalamus (e.g., nuclei paracentralis, ventralis lateralis, ventralis posterior thalami, magnocellular part of corpus geniculatum laterale), motor neurons of cranial nerve nuclei, large neurons of the reticular formation, giant pyramidal cells of cerebral cortex and the Purkinje cells of cerebellar cortex. The AC activity does not show as much variation in the different areas of the brain as the oxidative enzymes, which may mean that AC is more related to static maintenance metabolism of cells than to dynamic functional metabolism. The ATPase activity is more pronounced in the neuropil and the blood vessels compared to the neurons. In the perikarya, ATPase is concentrated close to the cell membrane, which may be significant in molecular transport across the membrane as well as in impulse conduction and synaptic transmission. Significant ATPase activity has been observed in the nucleus caudatus and putamen, magnocellular hypothalamic nuclei, nuclei parataenialis, paraventricularis, paracentralis, ventralis anterior thalami, habenular complex and cranial nerve nuclei.This work has been carried out with the aid of Grant No. 00165 from The Animal Resources Branch, National Institute of Health and a grant (NGR-11-001-016) from The National Aeronautics and Space Administration. Thanks are due to Mrs. M. J. Nimnicht and Miss M. E. Rogero for their technical help.     

Diencephalic and brainstem mechanisms in migraine

Migraine is a common and complex brain disorder. Although it is clear that head pain is a key manifestation of the disorder for most patients, what drives the activation of neuronal pain pathways in susceptible patients is less obvious. There is growing evidence that migraine pathophysiology may, in part, include dysfunction of subcortical structures. These include diencephalic and brainstem nuclei that can modulate the perception of activation of the trigeminovascular system, which carries sensory information from the cranial vasculature to the brain. Dysfunction of these nuclei, and their connections to other key brain centres, may contribute to the cascade of events that results in other symptoms of migraine - such as light and sound sensitivity - thus providing a comprehensive explanation of the neurobiology of the disorder.     

Paleoclimatic Variation and Brain Expansion during Human Evolution

One of the major adaptations during the evolution of Homo sapiens was an increase in brain size. Here we present evidence that a significant and substantial proportion of variation in brain size may be related to changes in temperature. Based on a sample of 109 fossilized hominid skulls, we found that cranial capacities were highly correlated with paleoclimatic changes in temperature, as indexed by oxygen isotope data and sea-surface temperature. Indeed, as much as 52% of the variance in the cranial capacity of these skulls could be accounted for by temperature variation at 100 ka intervals. As an index of more short-term seasonal fluctuations in temperature, we examined the latitude of the sites from which the crania originated. More than 22% of the variance in cranial capacity of these skulls could be accounted for by variation in equatorial distance.     

Comparison of changes in AChE activity in the brain of the laboratory rat after soman and tabun intoxication

The aim of this study was to compare changes in activity of acetylcholinesterase (AChE) in the brain and motor endplates of rat after administration of soman and tabun. We took brain and diaphragm from laboratory rats administered a median lethal dose (LD(50)) of soman or tabun. Enzyme activity of AChE was studied in selected structures of brain and in motor endplates in the diaphragm. Histochemical detection of AChE by Karnovski and Roots with simultaneous histochemical detection of alkaline phosphatase in case of brain sections was used. The highest activity of AChE in the control group was found in the striatum, amygdaloid nuclei, substantia nigra, superior colliculi, and motor nuclei of cranial nerves V, X a XII. LD(50) of both nerve agents dramatically decreased the activity of AChE in the structures studied--both brain and diaphragm. After intoxication by either agent, activity in above mentioned nuclei was characterized as low or focally moderate. Very low activity was seen in some structures (CA3 field of hippocampus, some nuclei of the tegmentum and cerebellar cortex). We found minimal differences in the histochemical picture of soman or tabun intoxication, apart from the striatum and the superior colliculi which showed stronger inhibition by tabun.     

Nuclear receptor sites for vitamin D-soltriol in midbrain and hindbrain of Siberian hamster (Phodopus sungorus) assessed by autoradiography

Summary Autoradiograms were prepared from midbrains and hindbrains of male and female Siberian hamsters (Phodopus sungorus), kept under short-day or long-day illumination, after injection of tritium-labeled 1,25-dihydroxycholecalciferol (vitamin D, soltriol). Concentration and retention of radioactivity was noted in nuclei of certain neurons, glial cells, and ependymal cells, and in choroid epithelium. Labeled neurons of varying intensity were found throughout the brainstem in distinct populations at characteristic topographical sites, which include cranial nerve motor nuclei, the nucleus (n.) reticularis tegmenti pontis, the caudoventral region of the n. raphe dorsalis, the n. trapezoides, the n. vestibularis lateralis and n. vestibularis superior, neurons in the various nuclei of the sensory trigeminus, accessory optic nuclei, scattered neurons in nuclei of the reticular formation, the n. ambiguus, certain cells in the area postrema, and many others. Glial cells with nuclear labeling, probably microglia, were scattered predominantly in or near myelinated nerve fascicles. The choroid epithelium showed strong nuclear labeling throughout the ventricle. Nuclear labeling of ependyma was variable and weak, mainly at ventral and lateral extensions (recesses) of the ventricle. The extensive presence of nuclear binding in select neural structures indicates that vitamin D exerts specific genomic effects on cell populations that are known to be involved in the regulation of motor, sensory, autonomic, neuroendocrine, metabolic, and immune functions. The results of these studies, in conjunction with those from other brain and peripheral tissues, recognize vitamin D-soltriol as a steroid hormone with a wide scope of hormone-specific target cells, similar to estrogen, androgen, and adrenal steroids, and which are topographically distinct and characteristic for its functions as the steroid hormone of sunlight.     

Histochemical studies of monoamine oxidase of the brain of rodents

Summary MAO of the brain was investigated histochemically in mice, rats, guinea pigs and rabbits. Fresh frozen sections were subjected to the tryptamine-tetrazolium method by Glenner, Burtner and Brown (1957).MAO activity of the brain of 4 animal species is generally similar with respect to its pattern of distribution. However, the intensity of enzyme action of the brain as a whole differs somewhat in animal species, being highest in guinea pigs, intermediate in rats and lowest in mice and rabbits. The enzyme action occurs mainly in the neuropil of the cerebral grey matter, while weak or negative activity is generally observed in the white matter excepting the tractus retroflexus of Meynert.The marked activity is encountered in the interpeduncular nucleus, locus coeruleus, area postrema, dorsal nucleus of the vagus nerve, hypothalamus, habenular nuclei and midline nuclear group of the thalamus, nucleus of the brachium conjunctivum, and central grey matter. The enzyme activity is weak or negative in the neocortex, striatum, mamillary body, thalamic nuclei (excepting the habenula and midline nuclear group), subthalamic nucleus, substantia nigra, red nucleus and nuclei of the somatic cranial nerves.The possible function and significance of MAO in the brain were discussed particularly by comparing the sites of this enzyme with those of succinic dehydrogenase and cytochrome oxidase, and the inverse relation between these enzymes was suggested.     

A histochemical study of the regional distribution in the rat brain of enzymatic activity hydrolyzing glucose- and 2-deoxyglucose-6-phosphate

Summary A modified Wachstein-Meisel lead salt method using glucose-6-phosphate or 2-deoxyglucose-6-phosphate as substrates was employed at the light microscopic level to map the rat brain for glucose-6-phosphatase (G-6-Pase). As has been described, most of the activity of the enzyme resided in neuronal cell bodies and dendritic stems. No differences were found between the results obtained with the two substrates. Two categories of brain structures with heavy and with moderate staining could be distinguished while the majority of brain regions contained only barely discernible neurons. Structures displaying very high enzyme activity included nuclei of cranial nerves, nuclei of the reticular formation, Purkinje cells, and some parts of the limbic system, e.g., CA 3 and CA 4 pyramidal fields of the hippocampus. It is pointed out that accurate biochemical determinations of G-6-Pase activity will critically depend on pains-taking microdissection of nuclei and cell layers. The histochemical results may be pertinent to the interpretation of the 2-deoxyglucose method for assessment of regional glucose utilization rates in brain. The present observations make it unlikely that regional variations in G-6-Pase activity account for differences in uptake and retention of radioactivity from (1-¹⁴C)glucose and (¹⁴C)2-deoxyglucose reported previously by our group.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday     

The dopamine beta-hydroxylase gene promoter directs expression of E. coli lacZ to sympathetic and other neurons in adult transgenic mice.

Dopamine beta-hydroxylase (DBH) catalyzes the final step in the biosynthesis of norepinephrine, the principal classic neurotransmitter of peripheral sympathetic neurons. We have shown that 5.8 kb of 5' upstream region from a cloned human DBH gene promoter is sufficient to direct expression of the E. coli lacZ gene in transgenic mice to neurons of the locus ceruleus and other classic noradrenergic brain stem nuclei, sympathetic ganglion neurons, and adrenal chromaffin cells. lacZ expression was also observed in neurons of the enteric system, the retina, some sensory and all cranial parasympathetic ganglia, and some diencephalic and telencephalic brain nuclei. The expression pattern of the transgene in DBH-immunonegative sites overlapped with many sites where expression of tyrosine hydroxylase or phenylethanolamine N-methyltransferase, two other catecholamine biosynthetic enzymes, has been reported.     

Autoradiographic studies with 3H dihydrotestosterone in the brain of sex reversed mice, heterozygous for androgen insensitive testicular feminization (Tfm). A comparison with normal female mice and sex reversed male mice

Specific binding sites for 3H dihydrotestosterone are demonstrated by autoradiography in brain nuclei of sex reversed mice heterozygous for testicular feminization (Tfm) which are phenotypically intersexes with testes and accessory sex glands that consist of a mosaic of androgen insensitive Tfm cells which lack specific dihydrotestosterone binding and androgen sensitive normal cells. The nuclear group evaluated include: nucleus (n.) septi lateralis, n. interstitialis striae terminalis, n. medialis amygdalae, the hypothalamic n. arcuatus, n. ventromedialis lateralis, n. pre-mammillaris ventralis, n. preopticus medialis, and nuclei of the cranial nerves VII, X, and XII. In the sex reversed males and the female, used as controls, the frequency of neurons with specific DHT binding show a distinct male-female difference in the caudal part of the arcuate nucleus. In the sex reversed Tfm heterozygotes, in all brain nuclei studied, the frequency of labeled neurons is reduced. The extent of reduction of androgen binding in the different brain nuclei varies among as well as within individual sex reversed Tfm heterozygotes, suggesting variations of the ratio of normal to Tfm neurons in sex reversed Tfm heterozygotes. The differentially reduced androgen binding of different brain systems corresponds to a differentially reduced androgen dependent behaviour reported in the literature.     

Distribution of cholineacetyltransferase histochemistry in isthmus and medulla of Onchorynchus masu. Tract-tracing observation on the ascending meso-pontine cholinergic system

The distribution of cholinergic neurons was studies in the brain steam, medulla and rostral spinal cord of the salmon Onchorynchus masu using histochemical choline acetyltransferase (ChAT) detection. Cholinergic neurons were observed in the isthmus, cranial nerve motor nuclei and spinal cord. In order to characterize several cholinergic nuclei observed in the isthmus of O. masu, their projections were studied by application of 1,1'-dioctadecyl-3,3,3',3,'-tetramethylindocarbocyanine perchlorate (DiI) to selected structures of the brain. The secondary gustatory nucleus projected mainly to the lateral hypothalamic lobes, whereas the nucleus isthmi projected to the optic tectum and parvocellular superficial pretectal nucleus, as it was earlier described for the other teleost group. In addition, the other isthmic cholinergic nuclei in O. masu may be homologous to the meso-pontine system of mammals. We conclude that the cholinergic systems of teleosts show many primitive features that have been presented during evolution, together with exclusive to the group characteristics.