Effects of neonatal hypothyroidism on rat brain gene expression.

To define at the molecular biological level the effects of thyroid hormone on brain development we have examined cDNA clones of brain mRNAs and identified several whose expression is altered in hypothyroid animals during the neonatal period. Clones were identified with probes prepared by subtractive or differential hybridization, and those corresponding to mRNAs altered in hypothyroidism were further studied by Northern blot analysis. Using RNA prepared from whole brains, no effect of hypothyroidism was found on the expression of the astroglial gene coding for glial fibrillary acidic protein. Among genes of neuronal expression, no significant alterations were found in the steady state levels of mRNAs coding for neuron-specific enolase, microtubule-associated protein-2, Tau, or nerve growth factor. N-CAM mRNA increased slightly in hypothyroid brains. In contrast a 2- to 3-fold decrease was found in the mRNA coding for a novel neuronal gene, RC3. This is the first neuronal gene known to be significantly altered at the mRNA level by thyroid hormone deprivation. The abundance of the mRNAs for the major myelin proteins proteolipid protein, myelin basic protein, and myelin-associated glycoprotein, expressed by oligodendrocytes, were also decreased in hypothyroid brains. Developmental studies on RC3 and myelin-associated glycoprotein expression indicated that the corresponding mRNAs accumulate in the brain of normal rats during the first 15-20 days of neonatal life. A similar accumulation occurred in hypothyroid brains, but at much reduced levels. The results demonstrate that thyroid hormone controls the steady state levels of particular mRNAs during brain development.     

Beta 1 isoform-specific regulation of a triiodothyronine-induced gene during cerebellar development.

Although tissue-specific expression of the alpha 1 and beta 1 thyroid hormone receptors (TR-alpha 1 and TR-beta 1) suggests isoform-specific function, transfection studies to date have failed to show consistent differences in their ability to regulate gene expression. We here provide evidence that TR-beta 1 but not TR-alpha 1 regulates the expression of the gene coding for PCP-2 in cerebellar Purkinje cells during neonatal rat development and that such regulation appears to be both T3 dependent and T3 independent. Examination of neonatal rats revealed that the levels of three mRNAs expressed in cerebellar Purkinje cells (myoinositol-1,4,5-triphosphate receptor, calbindin, and PCP-2) rise from neonatal day 1 to day 15. This rise is preceded by the previously documented surge in brain T3 and TR-beta 1. Methimazole-induced hypothyroidism sharply reduces, but does not abolish, the rise in these mRNAs. Concomitant T3 administration normalizes the process. In order to establish more directly the role of TR-beta 1 and T3, cotransfection experiments were performed in CHO cells with PCP-2-lacZ construct and TR isoforms. These studies showed that TR-beta 1, even in the absence of T3, regulated the expression of the transfected PCP-2 construct. T3 augments the response to TR-beta 1 alone by 40% (P < .01). TR-alpha 1 had no effect on PCP-2-lacZ expression either in the presence or absence of T3.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thyroid hormone regulates the obesity gene tub

Thyroid hormone T3/T4 is a major regulator of energy metabolism in vertebrates, and defects in thyroid status are frequently associated with changes in body weight. It is demonstrated here that thyroid hormone regulates in vivo and in vitro the tub gene, which when mutated in tubby mice causes obesity, insulin resistance and sensory deficits. Hypothyroidism in rats altered tub mRNA and protein in discrete brain areas. These changes could be attributed to thyroid hormone deficiency since T3/T4 treatment restored normal tub expression. T3 also upregulated tub mRNA within 4–6 h in neuronal cells in culture, suggesting that T3 is a positive regulator of tub gene expression. Thus, these results establish a novel pathway of T3 action and provide an important molecular link between thyroid status and the tubby-associated syndrome.     

Thyroidal regulation of different isoforms of NaKATPase in glial cells of developing rat brain.

The developmental profile of the different isoforms of NaKATPase have been investigated during the first three weeks of postnatal development using primary cultures of isolated glial cells derived from neonatal rat cerebra. Northern and Western blot analysis show that the expression of four isoforms (alpha1, alpha2, beta1 and beta2) in these cells increases progressively between 5 to 20 days of culture. Comparison of the mRNA levels of these isoforms in thyroid hormone deficient (TH def) and thyroid hormone supplemented (TH sup) cells cultured for 5-10 days, revealed for the first time that all four isoforms are sensitive to T3 in the glial cells. Furthermore immunocytochemical staining of these cells with isoform specific NaKATPase antibodies also showed that the localization of the different isoforms in the TH def cells were altered in comparison to that in the TH sup cells. These results establish glial cells as the target cells for the regulation of NaKATPase by TH in the developing brain.