Early morphological and functional changes in the GABAergic system of hippocampus in the rat lithium-pilocarpine model of epilepsy.

We studied early alterations in the GABAergic system of the rat hippocampus in the lithium-pilocarpine model of epilepsy. Twenty-four hours after the pilocarpine treatment, a decrease in the number of calretinin-positive interneurons was observed in the CA1 field of the hippocampus, whereas the number of parvalbumin-positive interneurons remained unchanged. The decreased levels of the GABA-synthesizing enzyme glutamic acid decarboxylase (GAD67) and the membrane GABA transporter GAT1 were revealed using Western blot analysis. These data indicate an altered excitation/inhibition balance in the hippocampus with excitation dominance.

[Effects of repeated short-term immobilization stress on plastisity of brain cortical division and cognition in adult rats with normal and disturbed embryogenesis].

The aim of the work was the analysis of the changes in a number of labile synaptopodin-positi- ve dendritic spines in parietal cortex and the CA1 field of the hippocampus, which characterize plasticity of intracellular interaction, and of the memorization after short-term repeated immobili- zation stress (daily for 5 minutes, 10 days), both in control rats and in rats subjected to prenatal hypoxia (E14, 7% of O2, 3 hours). There were observed deterioration of short-term and long-term memory, decrease in number labile spines in the CA1 field of the hippocampus (for 17.3 ± 10.4%; p ≤ 0.05) and their increase in a molecular layer of brain parietal cortex (for 36.9 ± 9.2%) at the adult rats with normal embryogenesis after immobilization stress in comparison with control intact animals. At the rats subjected to a prenatal hypoxia, regardless of that, they were ex- posed to an immobilized stress at an adult stage or not, was noted both violation of short-term and long-term memory, and decrease in number labile spines in the CA1 field of the hippocampus (for 22.9 ± 10.5%) and parietal cortex (for 28.1 ± 9.3%). The obtained data allow to conclude that the increase of plasticity providing adaptive behavior of animals, takes place in neocortical neuronal networks as a reply to a short-term repeating stress only at normal brain formation during embryo- genesis, while, violation of embryogenesis leads to decrease in plasticity and adaptive opportuni- ties of the nervous system during further ontogenesis.

[The ability of NMDA glutamate receptor blockers to prevent a pentylenetetrazole kindling in mice and morphological changes in the hippocampus].

We investigated in mice the relationship between convulsions and morphological changes of hippocampal neurons that arise in the development of pentylentetrazol (PTZ)-induced kindling. The kindling was caused by of 35 mg/kg PTZ i.p. 3 times a week for a month. By the end of this period, 70% of the mice responded to the injections of PTZ with pronounced clonic or tonic-clonic seizures. The hippocampal slices (layer stratum pyramidale, CA1, Nissl's stain) obtained from mice exhibiting seizures revealed a large number of modified cells (24.7 +/- 2.1%). These hyperchromic neurons have been characterized by a decrease of the size cell body, there was a loss of turgor, the body cells shrink, and dendritic spines curl. Part of the cells took the shape of elongated neck. Such modified the dark type of neurons contained only 2.3 +/- 2.3% in the hippocampus of intact mice, and 30% of the mice resistant to the convulsive action ofPTZ during the period of observation. The expression of protein NeuN (Fox3) in hippocamal neuron including the hyperchromic once suggests that neurons on the whole did not die and were relatively viable. Preventive administration of NMDA receptor blockers (0.5 mg/kg, memantine 0.1 mg/kg or IEM-1958 1 mg/kg, s.c.) 30 minutes prior to PTZ reduced the proportion of mice which exhibited PTZ kindling from 70% to 40%. The modified neurons were observed in which the PTZ kindling due to the blocker presence did not develop, i.e., the same as in intact mice. Contrary, 24.0 +/- 5.6% of hyperchromic neurons were found in the hippocampal slices from mice manifested seizures, despite the co-administration of NMDA blockers. The data obtained indicate that modified neurons are the result of seizures suffered by the animals in the course of PTZ kindling, and that the blockade of NMDA glutamate receptors can suppress manifestations of seizures and the accompanying morphological changes of hippocampal neurons.

[Study of distribution of protein of the spine apparatus synaptopodin in cortical brain parts of rats submitted to hypoxia at different periods of embryogenesis].

A comparative study of the nervous tissue and distribution of the spine apparatus protein synaptopodin was performed in all layers of the brain sensorymotor cortex and hippocampal CA1 area in control rats and in the rats submitted to hypoxia at E14 and E18. It was found that beginning from the 20th day of postnatal development, in rats submitted to hypoxia both at E14 and E18 there was observed a statistically significant decrease of the mean number of labile synaptopodin-positive spines in the stratum radiatum molecular of the hippocampus area CA1. The decrease of the number of labile spines in the sensorymotor brain cortex was revealed only in the I layer beginning from the 20th day after birth in the rats submitted to hypoxia at E14. Maximal differences in the studied brain areas were observed in adult rats (exposed to hypoxia at E14: in the neocortex--a decrease by 23 +/- 10%, in hippocampus--by 24 +/- 8%, respectively). In adult animals, the increased degeneration of neuzons was not detected. It is suggested that disturbances in cognitive functions and in the capability for learning observed in rats after prenatal hypoxia can be due to a decrease of the amount of the labile synaptopodin-positive spines, which leads to a change of the structural-functional properties of neuronal networks and to a decrease of their plasticity.

[Change of 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 disposition 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, lysis of organoids, and disturbance of the cytoplasmic membrane intactness were observed. Two waved of neuronal death by the mechanism of caspase-dependent apoptosis were revealed; the first involved large pyramidal neurons of the V layer (P10-20), the second--small pyramidal and non-pyramidal neurons of the II--III layers (P20-30). In neuropil 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 molecular layer, the decrease being preserved in adult animals.

[Formation of structural and ultrastructural organization of striatum rat postnatal ontogenesis upon changes in their embryonal development].

By light microscopy (by Nissl and Golgi), electron microscopy, and immunohistochemistry methods, formation of structure of the brain striatum dorsolateral part from birth to the 3-month age was studied in rats submitted to acute hypoxia at the period of embryogenesis. It has been established that hypoxia at the 13.5th day (E13.5) leads to a delay of neuronogenesis for the first two weeks of postnatal development as compared with control animals, while the majority of large neurons at this period are degenerated by the type of chromatolysis with swelling cell body and processes and lysis of cytoplasmic organoids. By the end of the 3rd week, shrunk hyperchromic or picnomorphic neurons with the electron-dense cytoplasm and enlarged tubules of endoplasmic reticulum and Golgi complex were also observed. An increased number of swollen processes of glial cells was detected in neuropil around degenerating neurons. By the 30th day as well as in adult rats there was observed destruction of mitochondrial apparatus, an increase of the number of lysosomes, and the appearance of bladed nuclei - signs of apoptotic cell death, which was also confirmed by an increased expression of proapoptotic p53 protein and its colocalization with caspase-3 in a part of neurons. Morphometrical analysis has shown a decrease of density of striatum cell arrangement and a change of ratio of different cell types in the rats submitted to hypoxia as compared with control group. At early stages of postnatal ontogenesis there was the greatest decrease (42.3% at the 5th day, 14.2% at the 10th day, p < 0.01) of the number of large neurons with the area more than 80 microm2. After 3 weeks of postnatal development the number of middlesize neurons (30-95 microm2) decreased (by 11.8-19.2%) as compared with control. The obtained data show that a change of conditions of embryogenesis (hypoxia) at the period of the most intensive proliferation of the forebrain neuroblasts leads to disturbances of the process of formation of the striatum nervous tissue. This can be the cause of delay of development and disturbances of behavior and learning observed in rats submitted to prenatal hypoxia.

Formation of the structural and ultrastructural organization of the striatum in early postnatal ontogenesis of rats in altered conditions of embryonic development.

Light (Nissl and Golgi methods) and electron microscopy methods were used to study the formation of the structure of the striatum during the first two weeks after birth in rats subjected to acute hypoxia at different times of embryogenesis. The dynamics of the physiological development of the same population of rats were studied in parallel. Hypoxia at day 13.5 of embryogenesis was found to lead to delayed neurogenesis (delayed establishment of elements of the neuropil and differentiation of cells) and abnormalities in the structure of the striatum (degeneration, particularly chromatolysis, of neurons and the appearance of glial nodes). Morphometric analysis demonstrated a decrease in the total number of cells in the striatum; small changes in large neurons were seen. Hypoxia at day 18.5 of embryogenesis produced no significant changes. Structural abnormalities were accompanied by changes in the process of the animals' physiological development. The data obtained here show that changes in the conditions of embryogenesis (hypoxia) during the period of the most intense proliferation of neuroblasts in the forebrain lead to impairment of the process of formation of striatal nervous tissue and the body as a whole in the period of early postnatal ontogenesis.

[Formation of striatum structural and ultrastructural organization in the early postnatal ontogenesis of rats subjected to altered conditions of their embryonic development].

Formation of the structure of striatum during two postnatal weeks in rats subjected to acute hypoxia during various periods of their embryonic development was studied using light microscopic (Nissl's stain and Golgi's silver nitrate impregnation) methods and electron microscopy. This study was supplemented by a simultaneous investigation of physiological development of the same population of rats. The data obtained demonstrated that prenatal hypoxia on day 13.5 of embryonic development (E13.5) led to a delayed neurogenesis (retardation in the development of neuropil elements and cell differentiation) as well as to the malformation of the structure of striatum (degeneration, in particular, chromatolysis of neurons and glial nodule formation). Morphometric analysis demonstrated that prenatal hypoxia on E13.5 resulted in a statistically significant decrease in cell number in the striatum, these changes being especially pronounced in large neurons. Prenatal hypoxia on E18.5, however, caused no significant changes in striatum. Structural changes in the striatum were shown to be accompanied by significant changes in the physiological development of animals. The data obtained demonstrated that the alteration of the conditions of embryogenesis (hypoxia) during the period of most intensive proliferation of forebrain neuroblasts resulted in the disturbances of the formation of both striatum nervous tissue of the organism as a whole during early postnatal ontogenesis.