Thyroid hormone regulation of malic enzyme synthesis. Dual tissue-specific control

Precocious induction of malic enzyme by nutritional and hormonal factors in rat foetal hepatocyte primary cultures

Rat foetal hepatocytes in primary cultures were used as a model for the study of malic enzyme gene expression. Carbohydrates and glycolytic metabolites produced the precocious induction of the malic enzyme in foetal hepatocytes cultured in the absence of serum and hormones. Palmitate prevented this induction. Insulin and triiodothyronine produced a significant increase in the malic enzyme specific activity in all the conditions studied. A synergistic effect between the two hormones is observed only when high concentrations of glucose are present. Glucagon prevents partially the induction produced by insulin plus triiodothyronine. Both carbohydrate and hormonal inductions of malic enzyme activity are related to parallel increases in its expression, and are prevented by protein synthesis inhibitors.

Transcriptional and posttranscriptional regulation of malic enzyme synthesis by insulin and triiodothyronine

To investigate the transcriptional and posttranscriptional regulation of malate dehydrogenase (EC 1.1.1.40) induction by insulin, the transcriptional rate, mRNA concentration and enzyme induction of malic enzyme were compared in livers of normal and diabetic rats fed a high-carbohydrate diet. When rats were fed the diet for 4 days, the enzyme induction and mRNA concentration in livers of diabetic rats were only about 10% and 39%, respectively, of the values of normal rats, and the transcriptional rate was about 64%. Insulin treatment restored the transcriptional rate and mRNA concentration in 8 h and the enzyme induction in 4 days. Thus, it is suggested that insulin is involved in malic enzyme transcription of the gene and also possibly in the translation of the cytoplasm. On the other hand, by giving triiodothyronine treatment, the transcriptional rate and mRNA concentration were increased about twice and the enzyme induction, about 10-times in the diabetic animals. Triiodothyronine appears to stimulate malic enzyme transcription and possibly post-transcriptional steps even at a very low insulin level.

Thyroxine elicits divergent changes in mRNA levels for two urea cycle enzymes and one gluconeogenic enzyme in tadpole liver

Thyroxine-induced metamorphosis of the tadpole to the frog (Rana catesbeiana) is marked by increased activities of the urea cycle enzymes in liver. Cloned cDNAs for two mammalian urea cycle enzymes--carbamyl-phosphate synthetase I and argininosuccinate synthetase--were shown to cross-hybridize with the corresponding mRNAs in tadpole liver. Thyroxine treatment produced nearly 10-fold, coordinate increases in hybridizable mRNA levels for these two enzymes in tadpole liver. This increase is sufficient to account for reported increases in enzyme levels and synthesis rates, demonstrating that thyroxine largely regulates concentrations of these enzymes at a pretranslational step(s). In contrast, levels of phosphoenolpyruvate carboxykinase mRNA in tadpole liver decreased by more than 90% following thyroxine treatment. This differs from the thyroxine-induced increases in synthesis rates of enzyme and mRNA reported for phosphoenolpyruvate carboxykinase in rat liver. However, the decreased levels of this mRNA in tadpole liver may represent a secondary response due to thyroxine-stimulated release of insulin.

Influence of diet on the transcriptional and post-transcriptional regulation of malic enzyme induction in the rat liver

Fasted rats were refed a carbohydrate/protein diet, a carbohydrate diet (without protein) or a protein diet (without carbohydrate) to investigate, using a cDNA cloned in our laboratory, the regulatory mechanisms involved in hepatic malic enzyme induction. In the carbohydrate/protein diet, although the enzyme activity and the mRNA concentration of malic enzyme were increased about 7-fold above the levels in the fasted rat, the rate of transcription was increased only 2-fold. In the carbohydrate diet group the rate of transcription and the concentration of mRNA were increased to the levels in the carbohydrate/protein diet group, whereas the enzyme activity increased only to 60% of those levels. Protein appears to contribute to an increase in the translation of malic enzyme mRNA. In the protein diet group the transcriptional rate was not low, but the mRNA concentration was about half in comparison with the level of the carbohydrate/protein diet group. Further, dietary fat did not reduce the transcriptional activity, but reduced the mRNA concentration and the enzyme activity to half of the basal levels. Therefore, it is suggested that fat stimulates the degradation of the mRNA in liver cytosol, whereas carbohydrate tends to stabilize the mRNA. On the other hand 3,5,3'-triiodothyronine treatment increased the transcriptional activity by 1.5-2-fold above the basal values on all the diets and even on fasting. Thus, it is suggested that 3,5,3'-triiodothyronine increases the transcriptional activity of malic enzyme independently from nutritional regulation, while the nutrients are predominantly involved in the post-transcriptional steps.

Cellular mechanism of action of thyroid hormones

It has emerged in the last decade that the molecular mechanism of action of thyroid hormones resembles that of steroids; thyroid hormones indeed exert their effects mainly by directly regulating gene expression, on association with specific chromatin-bound receptors. Of the two thyroid hormones, thyroxine (T4) appears to be a sort of prohormone, whereas triiodothyronine (T3) seems to be the active form; in this respect, T4-deiodination, which occurs at the level of the target tissues, may be crucial in the local homeostasis of T3. Moreover, many cellular compartments, other than the nucleus, can bind thyroid hormone, and at least some of these further sites might play some role in modulating T3 supply to the nucleus. The binding of the T3-receptor complex to chromatin is likely to regulate the structural organization of specific genes and, in some instances, of the chromatin as a whole.

Turnover rates of HMG-CoA reductase mRNA: role of pituitary and thyroid hormones

When normal or hypophysectomized rats maintained on a diet containing mevinolin and colestipol were switched to a normal chow diet, HMG-CoA reductase mRNA fell rapidly with a half-life of 3 hrs. After a 90 min lag period, reductase activity and immunoreactive protein fell in parallel with the mRNA in normal rats. In hypophysectomized rats, reductase activity and protein required 10 and 18 hrs, respectively to fall to 50% of their original levels. Administration of thyroid hormones to hypophysectomized rats resulted in a 3 to 4 fold stabilization of reductase mRNA suggesting that the increased mRNA levels are due in part to a posttranscriptional regulatory effect of thyroid hormones.