Essential fatty acids and adrenal steroidogenesis

Tissue-Specific Ablation of ACSL4 Results in Disturbed Steroidogenesis

ACSL4 is a member of the ACSL family that catalyzes the conversion of long-chain fatty acids to acyl-coenzyme As, which are essential for fatty-acid incorporation and utilization in diverse metabolic pathways, including cholesteryl ester synthesis. Steroidogenic tissues such as the adrenal gland are particularly enriched in cholesteryl esters of long-chain polyunsaturated fatty acids, which constitute an important pool supplying cholesterol for steroid synthesis. The current studies addressed whether ACSL4 is required for normal steroidogenesis. CYP11A1 promoter‒mediated Cre was used to generate steroid tissue‒specific ACSL4 knockout (KO) mice. Results demonstrated that ACSL4 plays an important role in adrenal cholesteryl ester formation, as well as in determining the fatty acyl composition of adrenal cholesteryl esters, with ACSL4 deficiency leading to reductions in cholesteryl ester storage and alterations in cholesteryl ester composition. Statistically significant reductions in corticosterone and testosterone production, but not progesterone production, were observed in vivo, and these deficits were accentuated in ex vivo and in vitro studies of isolated steroid tissues and cells from ACSL4-deficient mice. However, these effects on steroid production appear to be due to reductions in cholesteryl ester stores rather than disturbances in signaling pathways. We conclude that ACSL4 is dispensable for normal steroidogenesis.

Biosynthesis of polyunsaturated fatty acids of (n-6) and (n-3) series in isolated adrenocortical cells of rats. Effect of ACTH

Both the capacity of isolated adrenocortical cells to incorporate and transform [1-14C]linoleic and [1-14C]alpha-linolenic acids and the effect of ACTH on the biosynthesis of polyunsaturated fatty acids from [1-14C]alpha-linolenic acid were investigated. The cells were able to incorporate both labeled precursor acids and convert them into higher homologs. This transformation increases along the incubation time tested. When linoleic acid was the precursor, the biosynthesis of higher homologs was carried out following the desaturating-elongating route. Both pathways, the desaturating-elongating and the elongating, were detected when the substrate was alpha-linolenic acid. The results proved the existence of delta 6, delta 5 and delta 4-desaturases in this type of cells. Isolated adrenocortical cells obtained from rats treated with ACTH showed an increase in the amount of [1-14C]alpha-18:3 that remained in the cells without metabolization and, consequently, a decrease in the last product formed (20:5 n-3) was evident compared to the controls. Simultaneously, the desaturation-elongation products decreased significantly. Similar results were obtained when cells isolated from untreated rats were incubated for 3 h in the presence of ACTH. In this case, the values obtained returned to normal levels 6 h after incubation. These results were mimicked by dibutyryl-cyclic AMP. It can be concluded that the effect of ACTH on the biosynthesis of polyunsaturated fatty acids from alpha-linolenic acid was mediated through an enhancement of the intracellular levels of cAMP.

Effect of epinephrine on the oxidative desaturation of fatty acids in the rat adrenal gland

Delta-6 and delta 5 desaturation activity of rat adrenal gland microsomes was studied to determine the effect of microsomal protein and the substrate saturation curves. This tissue has a very active delta 6 desaturase for linoleic and alpha-linolenic acids. The administration of epinephrine (1 mg/kg body weight) 12 hr before killing, produced approximately a 50% decrease in desaturation of [1-14C]linoleic acid to gamma-linolenic acid, [1-14C]alpha-linolenic acid to octadeca-6,9,12,15-tetraenoic acid and [1-14C]eicosa-8,11,14-trienoic acid to arachidonic acid. A 30% decrease in delta 5 desaturation activity was also shown after 7 hr of epinephrine treatment. The changes on the oxidative desaturation of the same fatty acids in liver microsomes were similar. No changes were observed in the total fatty acid composition of adrenal microsomes 12 hr after epinephrine treatment. Mechanisms of action of the hormone on the biosynthesis of polyunsaturated fatty acids in the adrenal gland are discussed.

Autoradiographic studies with fatty acids and some other lipids: a review

In this review, we have mainly included studies in which whole-body autoradiography was used. In lipid research, most studies have been done with fatty acids. These studies showed some common characteristics in the pattern of tissue distribution. A major uptake was seen in the brown fat, liver and adrenal cortex but also to some extent in other tissues with a high metabolic activity or high cell turn-over, e.g. the gastric and intestinal mucosa, diaphragm, kidney cortex and bone marrow. Low levels of radioactivity were generally found in the brain, testes, thymus, white fat, skeletal muscles, lungs and spleen. Most fatty acids showed some specific features, e.g the strong uptake of erucic, arachidonic and docosahexaenoic acid in myocardium and of eicosapentaenoic acid in the adrenal cortex. Studies with PGE1 and LTC3 showed that the liver and kidney and to a lesser degree the lungs were the major sites of metabolism. The distribution of free cholesterol and triolein emulsion labelled in the fatty acid moieties did show some similarities with respect to the general pattern found with most fatty acids. Specific for cholesterol was a very strong uptake in the adrenal cortex. There was also a significant uptake in the spleen whereas the uptake in the brown fat was not as marked as for most fatty acids. Specific for triolein was a marked uptake in the spleen and myocardium, in fed animals also in the white adipose tissue. These studies show that whole-body autoradiography can give much valuable information of the uptake and distribution of lipids that would be rather difficult to obtain with conventional methods. Combined with electron-microscopy, autoradiography can be used to study cellular and even subcellular distribution, and thus given further data on the metabolism of lipids in the body.