Postnatal changes of morphology of nerve and glial cells in neocortex of mice developing on the background of serotonin deficit

It has been shown that deficit of serotonin during embryogenesis in rodents is accompanied by changes of morphological characteristics of neurons and glial cells at the period of postnatal development. A characteristic peculiarity of these changes is cell vacuolization that is of different expression in various cortical layers. In the experimental animals as compared with control ones, neurons of all neocortex layers have changed nuclei and a reduced volume of the cytoplasm. In neurons of upper layers, nuclei and cytoplasm contain occasional small vacuoles. In deep layers, vacuolization both of nuclei and of the cytoplasm is expressed to the much greater degree and vacuoles of large size are predominant. Results of immunocytochemical study have shown that in animals developing on the background of serotonin deficit there takes place a delay of the rates of formation and differentiation of astrocytic glia.     

Distribution of GAD67-expressing neurons and morphological changes in hippocampal structures during pubertal period after acute perinatal hypoxia in rats

We investigated structural changes in the Wistar rat hippocampal CA1 field and fascia dentate during the pubertal period (on P60) after perinatal hypoxic exposure as well as the distribution of GAD67-expressing neurons in these structures. It was established that in the granular layer of the fascia dentata and in the CA1 field acute perinatal hypoxia leads to irreversible homotypic abnormalities as expressed in the reduced number of neurons and their rows as well as injury of a considerable portion of cells, which exhibit the signs of chromatolysis and vacuolization of the cytoplasm. Both in experimental and control animals, GAD67-expressing neurons in the fascia dentata are scattered diffusely and share approximately the same size of their populations. In the CA1 field, immunoreactive neurons lie in the lower rows of the pyramidal layer, while neurons in the upper layers exhibit no immunolabeling and have less synaptic structures in experimental animals than in control. We suggest that neurons in the hippocampal structures are involved in the regulation of functions and formation of prenatal pathology.     

Antagonism of kainic acid lesions in the mouse hippocampus by U-54494A and U-50488H.

A morphometric study of kainic acid- (KA) induced lesions was designed for the study of the interaction of the diamines U-5449A and U-50488H with excitatory amino acids, and the dose-response relationship thereof. IC50S determined for binding at the kappa receptor and other opioid receptors demonstrated the lack of kappa activity of U-54494A, a structurally related analog of U-50488H. Both opiate kappa receptor related anticonvulsant diamines were tested for their ability to protect the mouse hippocampus from the cytopathological changes induced by KA in neurons and glia. The damage observed with i.c.v. KA in mouse was restricted to neurons of the CA3 pyramidal region and glia of the hippocampus. It involved massive cell loss and shrunken neurons with dark cytoplasm and nuclei. Groups treated with combinations of KA and U-54494A or U-50488H showed scarce damage, but patches of necrotic changes were still observed. Control animals treated with saline (i.c.v.) and U-54494A (s.c.) or U-50488H (s.c.) did not suffer any noticeable alterations of the polymorphic layers of the hippocampal formation. Image analysis of the CA3 area of the hippocampus was used to quantitate the vacuolization induced by KA lesions in the control and treated groups. By this method, both U-54494A and U-50488H were shown to protect this area in a dose-related fashion as evidenced by reduced vacuolization. The anticonvulsant properties of these compounds may result in the antagonism of the excitotoxic lesions. More specifically, the ability of these diamines to block depolarization-induced influxes of Ca++ may protect the CA3 cells from the cytotoxic effects of persistent depolarization.     

Alcohol-induced vacuolization in bone marrow cells: ultrastructure and mechanism of formation

Vacuolization has been known for two decades to occur in the cytoplasm and over the nuclei of the erythroid and myeloid precursors in bone marrows of patients with acute alcoholism. Electron microscopic examination of the marrows from four acute alcohol-intoxicated subjects disclosed that the vacuoles are present only in the cytoplasm and free of organized structure. Surface invagination of the cell membrane of erythroblasts leads to endocytosis and consequent vacuole formation. Cytoplasmic vacuolization of bone marrow cells was reproduced in vitro in 8 of 12 bone marrows from normal individuals when incubated for 6 hours or more in nutrient medium containing alcohol. The critical alcohol concentration for vacuolization was 62.5 mg/dl. The proportion of cells developing vacuoles appeared to correlate with the concentration of alcohol particularly above levels of 250 mg/dl.     

Characteristics of weak base-induced vacuoles formed around individual acidic organelles

We have previously found that the weak base 4-aminopyridine induces Brownian motion of acidic organelles around which vacuoles are formed, causing organelle traffic disorder in neurons. Our present study investigated the characteristics of vacuoles induced by weak bases (NH(4)Cl, aminopyridines, and chloroquine) using mouse cells. Individual vacuoles included acidic organelles identified by fluorescent protein expression. Mitochondria and actin filaments were extruded outside the vacuoles, composing the vacuole rim. Staining with amine-reactive fluorescence showed no protein/amino acid content in vacuoles. Thus, serous vacuolar contents are probably partitioned by viscous cytosol, other organelles, and cytoskeletons, but not membrane. The weak base (chloroquine) was immunochemically detected in intravacuolar organelles, but not in vacuoles. Early vacuolization was reversible, but long-term vacuolization caused cell death. The vacuolization and cell death were blocked by the vacuolar H(+)-ATPase inhibitor and Cl--free medium. Staining with LysoTracker or LysoSensor indicated that intravacuolar organelles were strongly acidic and vacuoles were slightly acidic. This suggests that vacuolization is caused by accumulation of weak base and H(+) in acidic organelles, driven by vacuolar H(+)-ATPase associated with Cl(-) entering, and probably by subsequent extrusion of H(+) and water from organelles to the surrounding cytoplasm.     

Ultrastructure of neurons manifested by hyperchromia and vacuolization observed in nerve tissue following hypoxia

100 days after the exposure of the rat sensorimotor cortex to hypoxic hypoxia two types of hyperchromic neurons with vacuolization of the cytoplasm were described. Using electron cytochemical method for the differential staining of ribonucleoproteins, it has been shown that the first type of hyperchromic neurons were cells with irreversible dystrophic changes and the second type were cells without irreversible dystrophy but with changes in the DNA-RNA-protein synthesizing system.     

Changes in the dendritic organization of the neurons of the isolated visual cortex of the cat]

The cortex of one hemisphere in cats was isolated according to M.M. Khananashwili method by means of surgical section of its projection fibres which connect it with subcortical structures. In five cats of means of Nissl's method the neuronal status of different cortical layers in the field 17 was studied during long postoperative terms (from 9 months up to 2 years). In 9 cats the neurons of the same field were impregnated after Golgi-Bubenett method and studied during the same postoperative terms. Cytological investigation in the majority of neurons did not reveal any pathologic changes during different postoperative terms up to one year. In two years, slight neuronal changes were noted presented in poor staining and vacuolization of cytoplasm. As a result of deafferentation performed shortening and thickness of dendritic branching was noted, as well as decrease in the number of thorns of large pyramids in layers III, IV, and V of the isolated cortex. Dendrites and thorns in small and medium-sized pyramids in layers II, III, IV, V, and VI were preserved to a great extent. It is possible to conclude, on the fact of thorns preserving in the major number of the neurons, that the neocortex possesses an enormous intracortical connective system that is responsible for the high degree of functional neuronal activity in the isolated cortex.     

Programmed cell death during development of cowpea (Vigna unguiculata (L.) Walp.) seed coat

The seed coat develops primarily from maternal tissues and comprises multiple cell layers at maturity, providing a metabolically dynamic interface between the developing embryo and the environment during embryogenesis, dormancy and germination of seeds. Seed coat development involves dramatic cellular changes, and the aim of this research was to investigate the role of programmed cell death (PCD) events during the development of seed coats of cowpea [Vigna unguiculata (L.) Walp.]. We demonstrate that cells of the developing cowpea seed coats undergo a programme of autolytic cell death, detected as cellular morphological changes in nuclei, mitochondria, chloroplasts and vacuoles, DNA fragmentation and oligonucleosome accumulation in the cytoplasm, and loss of membrane viability. We show for the first time that classes 6 and 8 caspase‐like enzymes are active during seed coat development, and that these activities may be compartmentalized by translocation between vacuoles and cytoplasm during PCD events.     

The role of the thymus medulla of newborn rats in lymphocytopoiesis

By means of 3H-thymidine, radioautographic investigation of lymphocytopoiesis has been performed in the cortex and medulla of the rat thymus for 2 weeks after birth. In the newborn animals the index of labelled nuclei (ILN) in the medulla is higher than in the cortex. By the 14th day after birth a progressive drop of lymphocytes including the isotope takes place in the medulla. The decrease of ILN in the medulla occurs against the background of increasing amount of epithelioreticulocytes with vacuoles and dystrophic changes in the nucleus and cytoplasm, that make groups of Hassal's bodies.     

Severe deficits in 5-HT2A -mediated neurotransmission in BDNF conditional mutant mice

BDNF is thought to provide critical trophic support for serotonin neurons. In order to determine postnatal effects of BDNF on the serotonin system, we examined a line of conditional mutant mice that have normal brain content of BDNF during prenatal development but later depletion of this neurotrophin in the postnatal period. These mice show a behavioral phenotype that suggests serotonin dysregulation. However, as shown here, the presynaptic serotonin system in the adult conditional mutant mice appeared surprisingly normal from histological, biochemical, and electrophysiological perspectives. By contrast, a dramatic and unexpected postsynaptic 5-HT2A deficit in the mutant mice was found. Electrophysiologically, serotonin neurons appeared near normal except, most notably, for an almost complete absence of expected 5-HT2A -mediated glutamate and GABA postsynaptic potentials normally displayed by these neurons. Further analysis showed that BDNF mutants had much reduced 5-HT2A receptor protein in dorsal raphe nucleus and a similar deficit in prefrontal cortex, a region that normally shows a high level of 5-HT2A receptor expression. Recordings in prefrontal slice showed a marked deficit in 5-HT2A -mediated excitatory postsynaptic currents, similar to that seen in the dorsal raphe. These findings suggest that postnatal levels of BDNF play a relatively limited role in maintaining presynaptic aspects of the serotonin system and a much greater role in maintaining postsynaptic 5-HT2A and possibly other receptors than previously suspected.     

Seasonal changes in the structure and secretory activity of the androgenic gland of Travancoriana schirnerae

This study investigated the seasonal variation in the structure and secretory activity of the androgenic gland (AG) in the freshwater crab: Travancoriana schirnerae. The androgenic gland is an elongate structure, attached to one side on the wall of the ejaculatory duct. Histological studies showed the presence of three cell types, which differ in size, shape of nuclei, and presence or absence of secretory vesicles. Type I cells are small with large nuclei whereas type II cells are large with small nuclei. Type III cells are intermediate in size and exhibited streak-like nuclei and transparent cytoplasm. Seasonal changes were discerned in the morphology, histology and secretory activity of the gland. March-June appeared to be the active season with type II cells containing secretory vesicles. The mode of release of secretion found to be holocrine. The secretory activity almost completed by July-August (the mating season) with vacuolization of type II cells. The gland remained inactive from September-December with abundance of vacuoles, scattered pycnotic nuclei, indistinct cell membranes and total cellular degeneration. January-February was the revival period with type I cell proliferation. The present study revealed that the secretory activity of the gland is in tune with the male reproductive cycle.     

STUDIES ON CARTILAGE : II. Electron Microscope Observations on Rabbit Ear Cartilage following the Administration of Papain

Electron microscope observations on rabbit ear cartilage following the administration of papain show that both the elastic component of the matrix and the amorphous material disappear leaving a matrix which consists of delicate fibrils which are presumed to be collagen. This unmasking of fibrils coincides with the appearance of an abnormal component in the electrophoretic pattern of the rabbit's serum. The chondrocytes show vacuoles in their cytoplasm which appear at the same time that the cells appear crenated in the light microscope. A ruffly appearance of the cell surface membrane coincides with this vacuolization, and vacuoles often appear open and in continuity with the extracellular space. The resurgence of the rabbit ear is accompanied by a reconstitution of both the amorphous material and the elastic component of the matrix. During this period numerous dilated cisternae of the endoplasmic reticulum which contain a moderately dense material are present in the chondrocyte cytoplasm. We have been unable to demonstrate a direct relationship between the elastic component of the matrix and a particular component of the chondrocyte cytoplasm, but it is clear that changes occur in the cartilage cell cytoplasm during both the depletion and reconstitution of the matrix. Previous studies on the effect of papain on elastic tissue are noted and the possible relationships between changes in the cells and matrix of this elastic cartilage are discussed.     

薏苡胚乳细胞化的超微结构观察

采用透射电镜对薏苡早期的胚乳细胞化进行了研究,在胚乳游离核时期,胚乳游离核及细胞质绕中央细胞分布,游离核间没有发现胚囊壁内突、成膜体等结构。胚乳细胞化过程中初始垂周壁形成过程如下：（１）胚乳细胞质中出现液泡,使细胞质和核向中央液泡推进：（２）一对相邻细胞核间液泡成对存在,且呈垂周分布,而且两液泡间的细胞质很狭窄;（３）在这狭窄的细胞质中出现成行排列的小泡;（４）小泡融合形成细胞板,细胞板悬于两液泡     

Ultramicroscopic features of bone marrow cells in response to exposure to staphylococcal toxin during hypoxia

In rats, already on the first day of the experiment, certain signs of destruction are observed in the bone marrow cells. They are demonstrated as an intensive vacuolization of cytoplasm, its lipid infiltration, as well as presence in vacuoles the material with middle and high electron density. In cells of the erythroid line not any essential ultrastructural changes are observed. By the end of the experiment (30 days), the destructive changes are noted not in all the cells and not in all hemopoietic lines. This is evidently depended on adaptation of the organism.     

Structural changes in the neocortex nervous tissue in rat ontogenesis after hypoxia at various terms of embryogenesis

The performed study has shown that in rats submitted to hypoxia (3 h, 7% O₂) at the 14th day of embryogenesis (E14) as compared with control animals, density of distribution of cells in the brain cortex decreased for the first month of postnatal ontogenesis (maximally by 40.8% by P20). In dying neurons, swelling of the cell body, lyses of or ganoids, and disturbance of the cytoplasm membrane intactness were observed. Two waves of neuronal death by the mechanism of capsize-dependent apoptosis were revealed; the first involved large pyramidal neurons of the layer V (P10–20), the second-small pyramidal and non-pyramidal neurons of the layers II–III (P20–30). In neurosis of molecular layer, a decrease of the mean amount of labile synaptopodin-positive dendrite spines was observed, as compared with control. In rats exposed to hypoxia at E18, no changes of cell composition and structure of the nervous tissue were found in the studied brain cortex areas. Thus, formation of the cortex nervous tissue in postnatal ontogenesis of rats submitted to hypoxia at the period of neuroblast proliferation-migration is accompanied not only by a change of the cell composition of various cortex layers in early ontogenesis, but also by a decrease of the number of the synaptopodin-positive spines in the molecular layer, the decrease being preserved in adult animals.     

Ultrastructural Modifi cations in Neurons of the Rat Frontal Cortex Induced by Intoxication by tert-Butyl Methyl Ether

We examined ultrastructural modifications in cortical neurons of the frontal part of the cerebral hemispheres of rats under conditions of chronic intoxication of the animals by tert-butyl methyl ether (TBME). Everyday doses of intrastomachic introductions of TBME in the experimental groups were 0.5, 5, 50, and 500 mg/kg. Within 60 days of the experiment, the animals preserved their viability even in the case of the highest TBME doses, but significant negative structural changes were observed in neocortical neurons under these conditions. A significant part of the mitochondria demonstrated swelling, decreases in the number of the cristae, destruction of the external membrane, and, finally, transformation into vacuoles. The endoplasmic reticulum underwent comparable modifications (dilation and destruction of the cisterns and intense vacuolization). The osmiophilia of the neuronal nuclei increased, and the latter were also deformed; the integrity of the nuclear envelope was disturbed. Other cellular organelles also underwent spatial redistribution and destruction. All these processes led to death of a considerable part of cortical neurons because of intense apoptosis followed by phagocytation of the apoptotic bodies by microgliocytes. The above-described modifications progradiently increased throughout the experiment (up to the 60th day). Their pattern was most dramatic at the highest TBME dose used (500 mg/kg), but the corresponding manifestations were quite obvious (although mild) even at the lowest doses (0.5 and 5 mg/kg). High polymorphism and variability were characteristic features of TBME-induced ultrastructural modifications in the rat frontal cortex. Therefore, TBME, an agent extensively used in industry and transport, which is believed to demonstrate relatively low integral toxicity, exerts powerful negative neurotropic effects on neuronal systems in the cerebral cortex and dramatically intensifies apoptosis in these structures.     

Effect of ionizing radiation on the protein-synthesizing system of brain neurons of ground squirrels in different functional states

Using fluorescence and electron microscopy, it is shown that the physiological state of ground squirrels exposed to ionizing radiation at different stages of the torpor-awakeness (hypothermia-normothermia) cycle is the main factor responsible for changes in the protein-synthesizing system of neurons in the hippocampus (fields CA1 and CA3) and the sensomotor cortex. The neurons of animals irradiated in the state of awakeness are less radioresistant and recover more slowly than neurons of animals irradiated in torpor, with the difference being more distinct in neurons of the CA1 field. The effect of irradiation is weak in animals entering torpor and reaches a peak in awakening animals. It is proposed that the inhibition of protein synthesis in the latter case takes place at the elongation stage, with heavy polysomes formed in the cytoplasm of neurons.     

Ultrastructural localization of glucocorticoid receptor (GR) in hypothalamic paraventricular neurons synthesizing corticotropin releasing factor (CRF)

Summary Corticotropin releasing factor (CRF) synthesizing neurons, located in the hypothalamic paraventricular nucleus (PVN), are the main central regulators of the pituitary-adrenal cortex endocrine axis. The hormone production and release of CRF-synthesizing neurons is regulated by neuronal messages and feedback action(s) of glucocorticoids secreted by the adrenal gland. In order to characterize the latter mechanism, glucocorticoid receptor (GR)-immunoreactive (IR) sites were studied in hypothalamic paraventricular neurons of intact, long-term adrenalectomized, and adrenalectomized plus glucocorticoid treated animals, by means of ultrastructural immunocytochemical labelling. In intact animals, glucocorticoid receptor immunoreactivity was found predominantly in the nuclei of parvocellular neurons. Following adrenalectomy GR-immunoreactivity was localized in the cytoplasm of the cells, and there was a concomitant disappearance of the label from the nuclei. After corticosterone administration to adrenalectomized animals, GR-IR sites were again concentrated within the cell nuclei. Immunocytochemical double labelling studies performed on adrenalectomized plus corticosterone-replaced animals demonstrated glucocorticoid receptor-IR sites in the cell nuclei of parvocellular paraventricular neurons that expressed CRF-immunoreactivity in their cytoplasm.These ultrastructural data indicate that the intracellular location of glucocorticoid receptor is dependent on the availability of glucocorticoids by the neurons. The simultaneous expression of GR- and CRF-immunoreactivity in parvocellular paraventricular neurons supports the concept of a direct feedback action of glucocorticoids upon CRF-synthesizing neurons.Supported by NIH Research Grants NS19266 (W.K.P. and Zs.L.), NS20832 (M.C.B.) and a joint grant (INT-8703030) awarded by the National Science Foundation and the Hungarian Academy of Sciences (Zs.L. and W.K.P.). R.M.U. is a recipient of NIMH Pre-doctoral Fellowship and M.C.B. an NIH Research Carcer Development Award     

Disturbances in Formation of the New and Old Cortex at Changes of Conditions of Embryonic Development

Using a model of acute hypoxia during pregnancy of rats, changes in the development of old (hippocampus) and new (sensorimotor) cortex associated with disturbance of neuronogenesis have been revealed in the studied brain structures at the period of action of a pathological factor. It was found that in rats submitted to hypoxia at the 13–14th days of embryogenesis, the number of degenerating neurons (including the pyramidal ones) at various levels of chromatolysis increased since the 5th day after birth; the increase was present for the entire first month of postnatal development. In the cortex of rat pups submitted to prenatal hypoxia there were observed deformation of neuronal bodies, vacuoles in the cytoplasm, shrinkage of apical dendrites of pyramidal neurons and delayed development of the structure (time of the appearance of spikes, formation of structural elements and the size of the cells) of the nervous tissue of the brain of the rat pups exposed to prenatal hypoxia. The columnar structure of the cortex was disturbed. In hippocampus, the process of degeneration of neurons started by 2–3 days later than in the cortex; by two weeks of postnatal development a massive degeneration and death of a part of neurons were also revealed. The morphometrical analysis showed a decrease in the number of neurons and their total area in the sensorimotor cortex (the layer V) and an increase in the number of glial elements at the 10–17th days after birth. In the hippocampus a decrease in the area occupied by neurons and in their size was detected in adult animals. The adult rats submitted to prenatal hypoxia were found to have disturbances of memory and learning. A correlation was shown between the disturbances of the conditions of embryonic development and the changes in the ability of learning and storage of new skills in the offspring.     

The action of salinomycin-Na and lasalocid-Na on chloroquine- and mepacrine-resistant line of Plasmodium berghei K 173-strain in Wistar rats

Salinomycin-Na and lasalocid-Na, two ionophorous antibiotics known for their anticoccidial activity, exhibit in vivo blood schizontocidal action on the Plasmodium berghei Keyberg 173 RC/M line that has a high level of resistance to chloroquine and mepacrine. Salinomycin was found to have a greater effect than lasalocid on asexual stages of this line. Trophozoites and schizonts were no longer found after a single dose of 20 mg/kg or five doses of 1.25 mg/kg of salinomycin whereas a single dose of 40 mg/kg or five doses of 20 mg/kg of lasalocid showed no marked effect on parasitaemia within 96 h of starting treatment in rats. Some toxicological data show that lasalocid, however, is better tolerated in domestic animals than salinomycin. Early morphological changes in asexual blood stages were membrane-coiling in the cytoplasm followed by vacuolization and disruption of the cell membrane or pellicle after treatment with both compounds. In particular mature schizonts were totally destroyed showing enormously large vacuoles. Toxicological data and blood schizontocidal activity indicate the narrow safety margin in P. berghei infected rats, and place salinomycin in the 'markedly toxic' group of antimalarial compounds.