Altered cerebellum development and dopamine distribution in a rat genetic model with congenital hypothyroidism.

Thyroid hormones play crucial roles in the development and functional maintenance of the central nervous system. Despite extensive studies of the neural function of thyroid hormones, little is known about the effects of hypothyroidism on behavioural traits and the mechanisms underlying such effects. In the present study, we report an investigation of congenitally hypothyroid mutant rdw rats, revealing a novel function of thyroid hormones in the central nervous system. The rdw rats were subjected to behavioural analyses such as the rotarod test, open field test and circadian activity measurement. To determine the cause of behavioural disorders, cerebellar morphogenesis was examined by immunohistochemical analysis, and the axonal transport of dopamine in the nigrostriatal pathway was analysed by high-performance liquid chromatography and western blotting. The effects of thyroxine administration to the rdw rats were examined by behavioural analysis. The rdw rats showed severe impairment of motor coordination and balance. This could be explained by the fact that the rats showed severe retardation of cerebellar morphogenesis, which correlates with the small somata and poor dendritic arborisation of Purkinje cells and retarded migration of granule cells particularly during the first two postnatal weeks. Moreover, the rdw rats showed hypoactivity, characterised by decreased circadian locomotor activity. After weaning, thyroxine administration improved the dwarfism in rdw rats but had no effect on cerebellar function. In addition, the rdw rats showed anxiety and depression intrinsically to novel surroundings. Interestingly, the rdw rats showed high levels of dopamine in the substantia nigra and low levels in the striatum, an important centre for the coordination of behaviour. Furthermore, low levels of tubulin in the striatum were detected, indicating the aberrant axonal transport of dopamine in the nigrostriatal pathway as a result of the reduced delivery of microtubules. These findings indicate an important function of thyroid hormones in cerebellar formation and in the regulation of axonal transport of dopamine. Moreover, rdw rats will be useful for studies of brain function and behavioural disorders in congenital hypothyroidism.

Dopamine D(2)-like receptor function is converted from excitatory to inhibitory by thyroxine in the developmental hippocampus.

The mechanism by which a lack of thyroid hormone in the early development of the brain causes permanent mental retardation in cretins is currently unknown. On the other hand, an abnormality in dopamine-related brain function is believed to underlie some forms of mental illness. In this study, we demonstrate that although the activation of a dopaminergic D(2)-like receptor inhibited glutamatergic transmission in the hippocampal slices of normal adult rats, indicating the inhibitory action of the D(2)-like receptor on glutamatergic transmission, it markedly enhanced glutamatergic transmission both in a mutant hypothyroid rat with a missense mutation in thyroglobulin and in hypothyroid rats treated with methylmercaptoimidazole (MMI), indicating the excitatory action of the D(2)-like receptor on glutamatergic transmission. Paired pulse facilitation of field excitatory postsynaptic potentials was reduced by the activation of the D(2)-like receptors from MMI-induced hypothyroid rats, suggesting a presynaptic locus of the excitatory action of the D(2)-like receptors. In normal rats, the excitatory D(2)-like dopamine receptors were observed in the developing stages and were completely replaced by normal inhibitory responses up to adulthood. Furthermore, the continuous supplement of thyroxine from birth exerted a normalising effect on the abnormal excitatory property of D(2)-like dopamine receptors in the hippocampal slices of MMI-treated hypothyroid rats. From these results, it is suggested that thyroxine may play a crucial role in reversing the excitatory property of D(2)-like dopaminergic receptors in the immature brain to an inhibitory one in the mature brain. Moreover, we suggest that the abnormal excitatory property of D(2)-like dopaminergic receptors may develop in response to a lack of thyroxine and may contribute to some central nervous system deficits, including cognitive dysfunctions accompanied by hypothyroidism.

Missing secretory granules, dilated endoplasmic reticulum, and nuclear dislocation in the thyroid gland of rdw rats with hereditary dwarfism.

Previous studies on the rdw rat have suggested that its dwarfism is caused primarily by dysfunction of the thyroid gland. In this study, rat thyroid glands were analyzed endocrinologically and morphologically to clarify the primary cause of dwarfism in the rdw rat. The rdw rat showed lowered thyroid hormone (T4 and T3) levels but elevated TSH in serum. The rdw thyroid gland was almost proportional in size and it was not goiter in gross inspection. Our histological investigation produced three results that may lend important evidence in understanding the problem in the thyroid gland of rdw rats. First of all, secretory granules could not be detected in the follicular epithelial cells of the rdw. Secondly, thyroglobulin was found at very low levels in the follicular lumen by immunohistochemical analysis. In contrast, it could be detected in a substantial quantity inside the dilated rER and in the huge vacuoles that are formed by swelling of the rough endoplasmic reticulum (rER) at the basal side of the follicular epithelial cells. Additionally, the nucleus of the follicular epithelial cells was pressed to the luminal side by the enlarged rER. These morphological changes would indicate that the transport of thyroglobulin is stopped at or before the formation of the secretory granules and thyroglobulin is not secreted into the follicular lumen. The rdw characterization strongly supports that rdw dwarfism is induced by hypothyroidism due to some defect(s) in the thyroid gland.

Detection and identification of proteins related to the hereditary dwarfism of the rdw rat.

Proteins having relations to hereditary dwarfism of the rdw rat (gene symbol: rdw) were searched for in various tissues of the rat with an improved two-dimensional gel electrophoresis technique followed by immunoblotting and microsequencing. Tissues inspected were cerebral cortex, cerebellum, brain trunk, hypothalamus, pituitary, thyroid gland, liver, testis, spleen, and thymus. Only pituitary and thyroid glands among those tissues showed abnormalities in protein contents. GH and PRL contents in the rdw pituitary were much less than in the normal one, which in the former were 1/15 and less than 1/30 times as much as in the latter, respectively, but the abnormalities in the rdw thyroid were far more serious than in the pituitary. At least 18 protein levels in the rdw thyroid were above, and 17 were below the normal. Those identified among the increased proteins were endoplasmin (GRP94), immunoglobulin heavy chain binding protein (BiP/GRP78), and heat shock protein 70 (hsp70), the contents of which respectively were 40 times, 10 times and more than 50 times as much in the rdw thyroid as in the normal tissue. Because BiP and endoplasmin are known to be ER resident proteins, and because all three belong to a chaperone protein family, accumulation of these proteins in the rdw thyroid suggests that protein folding and secreting disorders underlie the hypothyroidism of the rdw rat.