Effect of thyroidectomy on the protein content of rat adrenal cortex mitochondria and microsomes

Effect of thyroidectomy on pregnenolone and progesterone biosynthesis in rat adrenal cortex

The effects of thyroidectomy on pregnenolone and progesterone biosynthesis were investigated in rat adrenal cortex mitochondria and microsomes. The sequential hydroxylations of cholesterol, and the latter's side-chain cleavage, which constitute the limiting step in steroidogenesis, were studied by measuring oxygen consumption rates in the presence of cholesterol derivatives. The addition of (20R)-hydroxycholesterol, (22R)-hydroxycholesterol or (20R,22R)-dihydroxycholesterol stimulated these rates, but addition of cholesterol or (22S)-hydroxycholesterol had little effect. Thyroidectomy significantly reduced oxygen consumption rates in the presence of the sterols by about 30%. Oxygen uptake was small in the presence of respiratory inhibitors; the addition of sterols raised this uptake but subsequent thyroidectomy did not change it. Rat adrenal cortex mitochondria and microsomes converted pregnenolone ino progesterone through 3 beta ol dehydrogenase/delta 4-5 isomerase, in two different successive steps. Values for enzyme activities were 0.18, 0.26 and 0.81 nmol progesterone/min/mg protein for the overall complex, the 3 beta ol dehydrogenase and the delta 4-5 isomerase respectively. All enzyme activities were unchanged by thyroidectomy. Similar results were obtained for corresponding microsomal activities whose values were in the same range. For both microsomes and mitochondria, the dehydrogenase reaction was the limiting step in the enzyme reaction leading to progesterone formation from pregnenolone. The limiting step in corticosteroidogenesis leading to prenenolone formation by an NADPH-dependent step was slowed down by thyroidectomy, probably because the reaction that transfers energy from NADH to NADP was inhibited. The enzyme complex leading to progesterone which involves NAD+ as cofactor, was unchanged by thyroidectomy. Thyroid hormones may therefore affect the availability of the energy mechanisms connected with the proton motive force, since thyroidectomy reduces both the phosphorylative oxidation and energy-dependent hydroxylation reactions involved in steroidogenesis.

Effect of thyroidectomy on the rat adrenal cortex enzyme activities involved in corticosterone and aldosterone biosynthesis

The effect of thyroidectomy on corticosterone and aldosterone biosynthesis, in rat adrenal cortex, were investigated in vitro. Thyroidectomy slowed down by about 30% the activity of microsomal 21 hydroxylase and mitochondrial 11 beta hydroxylase, the two stages leading to corticosterone formation from progesterone. The plasma corticosterone concentration also diminished in thyroidectomized rat. The mitochondrial enzyme system catalyzing the conversion of corticosterone into aldosterone included both 18 hydroxylase and 180H dehydrogenase. In the absence of thyroid hormone, values of both enzyme activity slowed down by about 30%. Thus thyroidectomy induced a general decrease in all mitochondrial hydroxylation processes requiring NNADPH as energetic cofactor. Mitochondrial NADPH was mainly synthesized by the activity of NADP+ malic enzyme and pyridine nucleotide transhydrogenase; the activity of both enzymes was determined in submitochondrial particles from adrenal cortex of normal and thyroidectomized rats. The activity of NADP+ malic enzyme and non energy-dependent transhydrogenase in the direction of NADPH formation dropped significantly after thyroidectomy, thus reducing the amount of NADPH available for hydroxylating mechanisms. The results should be compared to the large rise in th cytosolic malic enzyme level caused by thyroidectomy. The latter also ensured that the transhydrogenase reaction did not vary in the direction of NADP+ formation. Further, the drop in NADPH synthesis after thyroidectomy was coupled with a decrease in phosphorylation rate of added ADPH by adrenal cortex mitochondria of thyroidectomized rat. These findings might account for the general decline in the energy-dependent processes involved in steroidogenesis, a decline mainly due to the lowering of the H+ ions gradient driving ATP and NADPH synthesis through electron transfer.

Atrophy of the zona fasciculata in the adrenal cortex of thyroparathyroidectomized rats: a quantitative study

Atrophy of the adrenal gland induced by thyroparathyroidectomy (TPX) is attributable primarily to narrowing of the zona fasciculata. But absolute volumes of the adrenal gland and zona fasciculata, not the zona glomerulosa and zona reticularis, were decreased significantly 7 weeks after TPX. Changes consistent with atrophy were also seen in the zona fasciculata by electron microscopy. A slight decrease in volume of cytoplasm in cells of the zona fasciculata was evident 2 weeks after TPX as shown by quantitative stereological techniques. Seven weeks after TPX, there was a significant decrease in average cytoplasmic volume as well as mitochondrial volume and surface density of mitochondrial membranes. A decrease in total volume of the zona fasciculata, as well as volume per cell of mitochondria, correlates directly with decreased production of corticosterone in response to stress in TPX rats. Parathyroidectomy (PX) had no effect on the volume of the adrenal gland, on the volume of the individual cortical zones, or on the volume per cell of cytoplasm or mitochondria; these observations indicate that changes in TPX rats are due primarily to ablation of the thyroid gland.