The effects of alteration of thyroid state on neurochemical maturation have been studied in rats made hypothyroid by daily injections of methimazole or hyperthyroid by daily supplementation with thyroid hormone (T3) from postnatal days 1 to 27. Biochemical assays on seven brain regions plus the spinal cord were carried out on 14 and 28 day-old rats as well as in adult rats after at least 40 days of recovery. 2',3'cyclic nucleotide phosphohydrolase (CNPase), a specific marker for oligodendrocytes and myelination was significantly decreased in all regions except the spinal cord of hypothyroid rats. The astrocytic marker glutamine synthetase (GS) was slightly increased in the hippocampus of hypothyroid rats. Choline acetyltransferase (ChAT), a specific marker for cholinergic neurons, was decreased in the prefrontal and visual cortices, the striatum and the superior colliculus and increased in the cerebellum of hypothyroid rats; in addition, the enzyme activity was increased in the prefrontal cortex and striatum and decreased in the cerebellum of hyperthyroid rats. Acetylcholinesterase (AChE) activity was decreased in the prefrontal cortex and in the striatum of hypothyroid rats while 3H-quinuclidinyl benzilate (QNB) muscarinic binding was decreased in all cortical areas and in the hippocampus of hypothyroid rats. Glutamate decarboxylase (GAD), a specific marker for GABAergic neurons, was decreased in the cortical areas of hypothyroid rats. Aromatic amino acid decarboxylase (AAD), a general marker for monoaminergic neurons, was unaffected. Alteration of neurochemical parameters was never observed in the spinal cord. Under our experimental conditions, the effects of alteration of thyroid state appeared graded and selective with respect to temporal, regional and cellular parameters.
AF64A, a presumed selective cholinergic neurotoxin has been used to study the effect on cholinergic systems of the goldfish retina and optic tectum. Toxin injection in the vitreum and in the optic tectum caused a selective decrease of choline acetyltransferase activity in both areas, while no significant decrease of glutamate decarboxylase and D-3H aspartate uptake were observed at different times after the injections. The effect was particularly dramatic in the retina of long term-injected animals, where choline acetyltransferase dropped to practically zero level. The ultrastructural analysis showed selective degeneration of some neurons in the amacrine and ganglion cell layer of the retina as well as of synaptic terminals and neuronal cell bodies in the optic tectum. The results favour a selective cholinotoxicity of AF64A in fish nerve tissue at doses substantially higher than those found to have additional unselective effects in mammals.
By immunoblotting and immunocytochemical techniques, we characterized the cytokeratins previously localized by us in the previtellogenic ovarian follicle of Podarcis sicula. Our results show that these cytokeratins correspond to those expressed in the monolayered epithelia. In fact, the immunoblotting analysis showed that the NCL-5D3 antibody, specific for human low molecular weight cytokeratins expressed in monolayered epithelia, reacted with the cytokeratins extracted both from the ovary and from the monolayered intestinal mucosa of Podarcis sicula. Furthermore, this antibody, in this reptile as in humans, clearly immunolabeled sections of corresponding tissues. The organization of the cytokeratin cytoskeleton in the main steps of the ovarian follicle differentiation was also clarified. The reported observations suggest that in Podarcis sicula, the cytokeratin cytoskeleton is absent in the early oocytes. It first appears in the growing oocytes as a thin cortical layer in concomitance with its becoming visible also in the enlarging follicle cells. In the larger follicles, this cytoskeleton appears well organized in intermediate cells and in particular in fully differentiated pyriform cells. In both these cells a cytokeratin network connects the cytoplasm to the oocyte cortex through intercellular bridges. At the end of the previtellogenic oocyte growth, the intense immunolabeling of the apex in the regressing pyriform cells suggests that the cytokeratin, as other cytoplasmic components, may be transferred from these follicle cells to the oocyte. At the end of the oocyte growth, in the larger vitellogenic oocytes surrounded by a monolayer of follicle cells, the cytokeratin constitutes a heavily immunolabeled cortical layer thicker than in the previous stages.
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