Heterogeneity of glial progenitor cells during the neurogenesis-to-gliogenesis switch in the developing human cerebral cortex

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Ultrastructure of putative migrating cells in the cerebral cortex of Lacerta galloti

Cells considered to be migratory in the cerebral cortex of adult lizards are ultrastructurally of two types. Nuclei in the first type have highly dispersed chromatin, creating a spongy appearance, whereas in the second type the chromatin is irregularly clumped. Both types of cells are closely associated with processes of radial ependymal glia cells, which perhaps orient their migratory pathways. Cells with spongy chromatin show an increase in cytoplasmic organelles and progressive chromatin condensation as they travel from the ependymal layer to the granular layer. Possibly these cells account for the neuronal increase that takes place in the granular layer during postnatal life. Cells with chromatin clumps are very scarce; ultrastructurally they resemble immature reptilian astroglia cells.     

Nitrogen shuttling between neurons and glial cells during glutamate synthesis

The relationship between neuronal glutamate turnover, the glutamate/glutamine cycle and de novo glutamate synthesis was examined using two different model systems, freshly dissected rat retinas ex vivo and in vivo perfused rat brains. In the ex vivo rat retina, dual kinetic control of de novo glutamate synthesis by pyruvate carboxylation and transamination of alpha-ketoglutarate to glutamate was demonstrated. Rate limitation at the transaminase step is likely imposed by the limited supply of amino acids which provide the alpha-amino group to glutamate. Measurements of synthesis of (14)C-glutamate and of (14)C-glutamine from H(14)CO(3) have shown that (14)C-amino acid synthesis increased 70% by raising medium pyruvate from 0.2 to 5 mM. The specific radioactivity of (14)C-glutamine indicated that approximately 30% of glutamine was derived from (14)CO(2) fixation. Using gabapentin, an inhibitor of the cytosolic branched-chain aminotransferase, synthesis of (14)C-glutamate and (14)C-glutamine from H(14)CO(3)(-) was inhibited by 31%. These results suggest that transamination of alpha-ketoglutarate to glutamate in Müller cells is slow, the supply of branched-chain amino acids may limit flux, and that branched-chain amino acids are an obligatory source of the nitrogen required for optimal rates of de novo glutamate synthesis. Kinetic analysis suggests that the glutamate/glutamine cycle accounts for 15% of total neuronal glutamate turnover in the ex vivo retina. To examine the contribution of the glutamate/glutamine cycle to glutamate turnover in the whole brain in vivo, rats were infused intravenously with H(14)CO(3)(-). (14)C-metabolites in brain extracts were measured to determine net incorporation of (14)CO(2) and specific radioactivity of glutamate and glutamine. The results indicate that 23% of glutamine in the brain in vivo is derived from (14)CO(2) fixation. Using published values for whole brain neuronal glutamate turnover, we calculated that the glutamate/glutamine cycle accounts for approximately 60% of total neuronal turnover. Finally, differences between glutamine/glutamate cycle rates in these two model systems suggest that the cycle is closely linked to neuronal activity.     

Ultrastructure of the synaptic apparatus of the cerebral cortex during iontophoretic application of acetylcholine

An ultrastructure comparison of presynaptic and postsynaptic components of axodendritic synapses of the fifth layer of rats neocortex sensomotor region after microionophoresis of acetylcholine and physiological solution has been carried out. The absence of true differences is considered as an adequacy indicator of application mediator regime.     

Structural and functional reorganization of neurons and glia in the sensomotor cortex of the cerebral cortex in experimental neurosis

Histological and hypoxic changes in different tissue elements (neurones and glia), testifying to active disturbances of metabolic processes, are observed in the sensorimotor cerebral cortex of rabbits with experimental neurosis. These changes indicate a complex structural-metabolic rearrangement, occuring with this form of CNS pathology. The results of the study may be used for investigation of mechanisms compensating disturbances in the higher nervous activity and for pathogenetically grounded therapy.     

Ultrastructure of sensorimotor cortex neurons in the progeny of rats receiving alcohol during pregnancy

Dynamics of ultrastructural changes in the sensomotor cortex neurons has been studied on the 21st, 30th and 60th days of life in offspring born by the rats given 20% alcohol (2 g/kg) during pregnancy. Moderate antenatal alcoholization produces certain disturbances in the ultrastructure of the cortical neurons and their dendrites. This is manifested as presence of retardation signs in maturation of nervous cell populations, as dystrophic changes in the neurons and their dendrites and display of reparative character with their own dynamics in the postnatal period of ontogenesis. The first two categories of the ultrastructural changes in the cortical neurons are more manifested at early stages of the postnatal development of the offspring, and the reparative processes--at the age of two months. Despite the presence of the reparative shifts, the dystrophic changes of the neurons of hypoxic character are present up to the period of sexual maturation. This demonstrates that the antenatal alcoholic intoxication in the offspring is manifested in the postnatal ontogenesis for a long time.     

Changes in the cortical neuronal dendrites in experimental alcoholic intoxication

The state of the cortical neuron dendrites was studied in rats at various stages of alcohol intoxication; two categories of changes occurred in dendrites--destructive and compensatory. These changes depended on the stages of alcohol intoxication and individual peculiarities of the central nervous system of the animals.     

Retrograde degeneration of the neurons of the cerebellar nuclei after partial removal of the associative cerebral cortex

Retrograde degeneration of the cerebellar nuclei cells has been studied after partial ablation of the associative parietal cerebral cortex in the cat. The material is stained after Nissl. Retrogradely degenerated and normal cells are counted. The "ghost-cells" in the cerebellar nuclei indicate that a direct axonal connection exists between some neurons and the cerebral cortex operated, while the cells that are at other stages of degeneration are, perhaps, connected with this part of the cortex by means of axonal collaterals.     

Effect of alcoholic intoxication of female mice prior to pregnancy on the ultrastructure of neurons in the sensorimotor cortex of the progeny

Sensorimotor cortex in the offspring of female rats alcoholized in the prepregnancy period revealed signs of delayed neuronal development and dystrophic changes in the neurons especially on the 14th day after birth. In 21-day-old animals the reparative changes increased, but normalization of neuronal ultrastructure was not observed. The dystrophic changes suggest that prenatal brain hypoxia plays an important role in the pathogenesis of alcohol-induced neuronal lesions in the offspring.