Autoradiographic localization of angiotensin II receptors in developing rat cerebellum and brainstem

The role of Angiotensin II (Ang II) as a growth promoting or modulating factor has recently become a field of intensive research. A central issue in developmental neurobiology is the understanding of mechanisms governing the formation of spatially ordered connections. In this study, we show the localization of Ang II receptor subtypes by autoradiography in 2-week-old rat hindbrains confronting these data with membrane binding assays. Competition studies done on membrane preparations evidence no major changes on the relative affinities for both receptor subtypes between 2-week-old and adult rat tissues. By autoradiography, we found that all the areas (1-10) of the 2-week-old cerebellum showed both receptor subtypes present in complementary adjacent layers. Areas expressing a high level of AT2 receptors follow: inferior colicullus (IC), dorso tegmental nucleus, central (DTgC), subcoeruleus, alpha, sensory root of the trigeminal nerve, principal sensory root trigeminal nucleus (Pr5, Pr5VL) supragenual nucleus, genu facial nerve, facial nucleus, cerebellar peduncles, vestibular and lateral nuclei. Spinal trigeminal, (oral) and Raphe nuclei express AT1 receptor subtype. The high level of Ang II AT2 receptors present in the cerebellar peduncles might have a meaning on the establishment of the olivo-cerebellar connection. The high expression of Ang II AT2 receptors on 2-week-old rat hindbrains, a critical age on development, as well as its disappearance in the adult, strongly suggests a probable role of these receptors in cell migration and neuronal synaptogenesis.     

65Zn uptake in the rat cerebellum and brainstem

We have studied the autoradiographic uptake of 65Zn in the cerebellum and brainstem of the rat, contrasting these results with Timm's positivity in these structures. Both, autoradiographic uptake and histochemical positivity, have demonstrated Zinc in a location that could be accepted as in climbing fibres and glomeruli of the cerebellum cortex, and also in brainstem neurons that project their axons to the cerebellum cortex, suggesting a circuit where zinc may act as a neuromodulator.     

Expression of dystrophin mRNA and the protein in the developing rat heart.

We examined the expression of dystrophin mRNA and the protein in the developing rat heart with polymerase chain reaction, immunoblotting and immunohistochemical analyses. Dystrophin mRNA was detectable on and after the 10th embryonic day, while the protein became detectable during the perinatal period.     

Lead-induced alterations of apoptosis and neurotrophic factor mRNA in the developing rat cortex, hippocampus, and cerebellum

Previous reports have recently shown the prototypic neurotoxicant, lead, to induce apoptosis in the brains of developing organisms. In the current study, timed-pregnant rats were exposed to lead acetate (0.2% in the drinking water) 24 h following birth at postnatal day 1 (PND 1). Dams and pups were continuously exposed to lead through the drinking water of the dam until PND 20. Postnatal exposure in the pups resulted in altered mRNA levels of the following apoptotic and neurotrophic factors: caspase 2 and 3, bax, bcl-x, brain-derived neurotrophic factor (BDNF). Ribonuclease protection assays were conducted to measure the factors simultaneously at the following postnatal time points: 9, 12, 15, 20, 25, days. Our results suggest a brain region- and time-specific response following lead acetate exposure. The region most vulnerable to alterations occurs in the hippocampus with alterations beginning at PND 12, in which caspase 3, bcl-x, BDNF increase with lead exposure. Significant treatment effects were not observed for both the cortex and cerebellum.     

Postnatal expression of glutamate decarboxylases in developing rat cerebellum

The recent identification of two genes encoding distinct forms of the GABA synthetic enzyme, glutamate decarboxylase (GAD), raises the possibility that varying expression of the two genes may contribute to the regulation of GABA production in individual neurons. We investigated the postnatal development the two forms of GAD in the rat cerebellum. The mRNA for GAD₆₇, the form which is less dependent on the presence of the cofactor, pyridoxal phosphate (PLP), is present at birth in presumptive Purkinje cells and increases during postnatal development. GAD₆₇ mRNA predominates in the cerebellum. The mRNA for GAD₆₅, which displays marked PLP-dependence for enzyme activity, cannot be detected in cerebellar cortex by in situ hybridization until P7 in Purkinje cells, and later in other GABA neurons. In deep cerebellar nuclei, which mature prenatally, both forms of GAD mRNA can be detected at birth. The amounts of immunoreactice GAD and GAD enzyme activity parallel changes in mRNA levels. We suggest that the delayed appearance of GAD₆₅ is coincident with synapse formation between GABA neurons and their targets during the second postnatal week. GAD₆₇ mRNA may be present prior to synaptogenesis to produce GABA for trophic and metabolic functions.Special issue dedicated to Dr. Eugene Roberts.     

The distribution of progestin receptor mRNA in rat brainstem

Hypothalamic sites wherein P4, through progestin receptor, (Pgr; commonly abbreviated PR), maximizes the expression of female sexual behaviors and gonadotropin surge release have been studied intensively. However, little is known regarding PR expression in brainstem regions likely to regulate changes in autonomic functions observed when P4 levels are elevated (i.e. pregnancy). Using in situ hybridization, we found PR mRNA-containing cells widely distributed throughout the brainstem of ovariectomized, estradiol-treated Sprague-Dawley rats, with high expression in regions including the medial vestibular nucleus, nucleus of the solitary tract, substantia nigra (compact part), ventral tegmental area, hypoglossal nucleus, locus coeruleus, Purkinje cell layer of the cerebellum and inferior olivary complex. We also detected moderate to high levels of PR gene expression in several regions, such as the trapezoid nucleus, facial nucleus, periaqueductal gray regions, and rostral ventrolateral medulla. These results demonstrate that PR expression is widespread in the brainstem and identify nuclei wherein P4 may act to influence a number of physiological functions during pregnancy.     

Expression of isotocin-neurophysin mRNA in developing zebrafish

Neurohypophysial peptides are important regulators of homeostasis, reproduction and behavior. We have sequenced a zebrafish cDNA representing isotocin-neurophysin (IT-NP) mRNA. The developmental expression pattern of zebrafish IT-NP mRNA was determined by whole-mount in situ hybridization histochemistry. At 32 h post fertilization (hpf) no IT-NP mRNA is detected. However, by 36 hpf, staining for IT-NP mRNA is detected in a tight bilateral cluster of cells located in the anterior hypothalamus. The IT-NP mRNA expression pattern remains remarkably stable throughout further development at least until 120 hpf.     

Hydroxyurea inhibits thymidine kinase activity in developing rat cerebellum

Hydroxyurea when injected intraperitoneally into rats either as a single dose or as three consecutive daily doses, markedly inhibited thymidine kinase activity in cerebellum on 7th day. The inhibitory effect of the drug was found to be both dose and time dependent. The drug has however, failed to exert any inhibitory action when added to the reaction mixture in vitro. It is concluded that the well established inhibition on DNA synthesis by hydroxyurea may not be solely due to its action on ribonucleotide reductase (EC 1.17.4.1) but probably due to its interference at several other sites including thymidine kinase.     

Expression of acidic fibroblast growth factor mRNA in the developing and adult rat brain.

We have localized acidic fibroblast growth factor (aFGF) mRNA in the developing and adult rat brain using in situ hybridization histochemistry. Prenatally, hybridization to aFGF mRNA was observed throughout the brain, with the strongest signal associated with cells of the developing cortical plate. Postnatally, labeling was localized to specific neuronal populations. In the hippocampus, labeling of the pyramidal cell layer and dentate granule cells was observed and became progressively more intense with maturation. Labeling was also observed in both the external and internal granule cell layers of the developing cerebellum. Pyramidal cells of the neocortex as well as neurons of the substantia nigra and locus ceruleus also express aFGF. This pattern persists into adulthood, although the intensity of the labeling is significantly reduced in the adult brain. These patterns of hybridization correlate with specific developmental events and suggest that aFGF plays a significant role in both central nervous system development and neuronal viability in the adult brain.     

Characterization of separated cell types from developing rat cerebellum

The characteristics of [³H]GABA transport were investigated in preparations greatly enriched in different classes of cerebellar cells. In contrast to observations in situ, isolated Purkinje cells readily accumulated [³H]GABA. In comparison with astrocytes, theV _max of the high-affinity uptake process was sixfold higher (0.31 vs. 0.05 nmol/min/10⁶ cells) and the apparentK _t twofold greater (2 vs. 1 M). In contrast to these cell types, uptake was very low in granule cell-enriched preparations.cis-1,3-Aminocyclohexane carboxylic acid was a potent inhibitor of [³H]GABA uptake by the Purkinje cells and a weak blocker in astrocytes, while the converse was the case for -alanine. Diaminobutyric acid strongly inhibited uptake in both cell types. [³H]GABA transport was Na⁺ dependent in both cell classes. However, veratridine and ouabain selectively blocked [³H]GABA accumulation in the Purkinje cells, which were also more sensitive than the astrocytes to the glycolysis inhibitor, NaF. The results indicated, therefore, marked differences between Purkinje cells and astrocytes in the properties of both the [³H]GABA transport systems and the underlying metabolic processes.     

Localization of tissue plasminogen activator mRNA in the developing rat cerebellum and effects of inhibiting tissue plasminogen activator on granule cell migration

Tissue plasminogen activator (tPA) mRNA was localized in the developing cerebellum and the potentials role of tPA in migration of cerebellar granule cells was investigated. Proteolytic assays and Northern blots showed little variation in levels of tPA proteolytic activity or tPA mRNA expression in the developing cerebellum. The distribution of cerebellar tPA mRNA at different ages was visualized by in situ hybridization histochemistry. At postnatal day 7 (P7), most labeled cells were in the internal granule layer or developing white matter, and very few if any premigratory granule cells contained tPA mRNA. Although the molecular layer contained labeled cells at all ages, cell counts indicated that a greater percentage of cells in the molecular layer contained tPA mRNA during adulthood than during the period of granule cell migration. The most striking change in tPA mRNA expression was in Purkinje neurons, most of which began to express tPA mRNA between P7 and P14. The potential role of tPA in granule cell migration was investigated by performing migration assays in cerebellar slice explants in the presence or absence of protease inhibitors. The presence of inhibitors did not affect the distance that granule cells migrated. Data in the present study do not support a role for tPA in granule neuron migration; however, they do indicate that tPA is both spatially and temporally regulated during cerebellar development. Possible functions of tPA in the cerebellum are discussed. © 1995 John Wiley & Sons, Inc.     

Myelination in developing cultured newborn rat cerebellum inhibited by 5-bromodeoxyuridine

Incorporation of 5-bromodeoxyuridine (BUdR) into developing newborn rat cerebellum organ cultures inhibited formation of myelin without apparent effect on morphological maturation. Inhibition of the appearance of myelin, which usually begins on 10–11 days in vitro (DIV), occurred only when BUdR was present during 6 and 7 DIV, thus suggesting a ‘critical’ cell division on those days for the differentiating oligodendrocytes that will produce myelin.     

Cholecystokinin mRNA in porcine cerebellum

Using previously cloned cDNAs to pig brain prepro-cholecystokinin mRNA and slot blot and S1 nuclease protection assays, the relative cholecystokinin mRNA levels in different regions of the pig brain were measured. The relative amounts of cholecystokinin mRNA generally correlated well with the levels of cholecystokinin-immunoreactive peptides in the various regions tested. One clear exception was noted in the cerebellum; in this region, levels of cholecystokinin mRNA were about 20% of the levels in brain cortex (or second highest level in all areas tested) whereas the mature forms of cholecystokinin peptides (cholecystokinin 58, cholecystokinin 8) were undetectable (less than 3 pmol/g). In vitro translation of cerebellar and cortical cholecystokinin mRNA indicated that there was no difference in the efficiency with which these two RNAs were translated into immunoreactive prepro-cholecystokinin. DNA sequence analysis confirmed that a cloned full-length cerebellar cholecystokinin cDNA was indistinguishable from its cortical counterpart and, therefore, must encode an identical prepro-cholecystokinin. We conclude that there are pronounced regional differences in cholecystokinin expression in pig brain. The apparent discrepancy between levels of immunoreactive cholecystokinin peptides and cholecystokinin mRNA in the cerebellum could be explained by a high turnover rate for the peptides, differential processing of the peptides, or tissue-specific inhibition of cholecystokinin mRNA translation.     

Glutaminase in the postnatally developing rat cerebellum: Comparison of staining and immunocytochemistry activity

Distribution patterns and developmental profiles of phosphate activated glutaminase (PAG) in the cerebellar cortex of the rat were demonstrated by enzyme activity staining (tetrazolium salt technique) and immunolabeling. Histochemical evaluation of enzyme activity stained sections revealed in the molecular and granular layer (i.e. premigratory zone and external germinal zone in neonate rats) an increase from postnatal day 2 to day 50 by 350 and 400%, respectively. The smallest elevation was found in Purkinje cell bodies (140%). Maximum rise of PAG-activity was observed for all of the areas examined between day 12 and 15. The immunocytochemical visualisation of PAG-like immunoreactivity resulted in spatial and developmental patterns which differed from those of PAG-activity staining and displayed, to some extent, dependency on the way of tissue preparation, especially the fixation procedure.     

Carbonic anhydrase and oligodendroglia in developing rat cerebellum: A biochemical and immunohistological study

In the cerebellum, the isoenzyme II of carbonic anhydrase (CAII) appears to be a specific oligodendrocyte marker. Formation and maturation of oligodendrocytes during the postnatal development of rat cerebellum were followed by using specific immune serum directed against CAII for immunohistofluorescence and radioimmunoassay. Few oligodendrocytes are present in the cerebellum of the newborn rat. Their number increases rapidly between the fourth and the tenth days after birth and then more slowly until the end of the third week. Sequential changes in oligodendrocyte morphology have been observed. Determinations of CAII in cerebellar homogenate by radioimmunoassay show that the CAII level is low from birth to the end of the second week, the increase in the number of oligodendrocytes being accompanied by a small increase in the CAII level. Subsequent cell maturation is accompanied by significant accumulation of CAII.