The side-chain cleavage of cholesterol sulfate--II. The effect of phospholipids on the oxidation of the sterol sulfate by inner mitochondrial membranes and by a reconstituted cholesterol desmolase system

Underestimated reactions and regulation patterns of adrenal cytochromes P450

Although cytochrome P450 (CYP) systems including the adrenal ones are being investigated since many years, there are still reactions and regulation patterns that have been underestimated ever since. This review discusses neglected ones to bring them into the focus of investigators working in the field. Novel substrates and reactions described for adrenal CYPs recently point to the fact that different from what has been believed for many years, adrenal CYPs are less selective than previously thought. The conversion of steroid sulfates, intermediates of steroid biosynthesis as well as of exogenous compounds are being discussed here in more detail and consequences for further studies are drawn. Furthermore, it was shown that protein-protein interactions may have an important effect not only on the activity of adrenal CYPs, but also on the product pattern of the reactions. It was found that, as expected, the stoichiometry of CYP:redox partner plays an important role for tuning the activity. In addition, competition between different CYPs for the redox partner and for electrons and possible alterations by mutants in the efficiency of electron transfer play an important role for the activity and product pattern. Moreover, the influence of phosphorylation and small charged molecules like natural polyamines on the activity of adrenal systems has been demonstrated in-vitro indicating a possible regulation of adrenal CYP reactions by affecting redox partner recognition and binding affinity. Finally, an effect of the genetic background on the consequences of mutations in adrenal CYPs found in patients was suggested from corresponding in-vitro studies indicating that a different genetic background might be able to significantly affect the activity of a CYP mutant.

Effect of sulfonated steroids on steroidogenic cytochrome P450-dependent steroid hydroxylases

In the last decades, sulfonated steroids evolved from inactive metabolites intended for excretion to highly relevant compounds involved in many physiological processes. Investigations of the impact of sulfonated steroids on the steroid hormone biosynthesis revealed that, on the one hand, these can serve as substrate for steroidogenic cytochromes P450 and, on the other hand, these are able to influence the catalytic properties of these enzymes. In this review the relevance of sulfonated steroids for the steroid hormone biosynthesis will be discussed.

Side-chain cleavage of cholesterol sulfate by ovarian mitochondria

Mitochondria isolated from porcine corpora lutea and from the luteinized ovaries of gonadotropin-treated immature rats were found to efficiently cleave the side-chain of cholesterol sulfate to produce 3 beta-hydroxy-5-pregnen-20-one sulfate (pregnenolone sulfate). When mitochondria were preincubated with cholesterol sulfate, the time-course for the side-chain cleavage of cholesterol sulfate was biphasic. With 200 microM cholesterol sulphate, the initial rate of the reaction was the same as that observed for 25-hydroxycholesterol. This rate was not increased when both cholesterol sulfate and 25-hydroxycholesterol were incubated together. The rate of side-chain cleavage by isolated mitochondria supplied with 75 microM cholesterol sulfate as substrate was inhibited by 97% by aminoglutethimide, a specific inhibitor of cytochrome P-450scc. The slow phase of side-chain cleavage of cholesterol sulfate appeared to be limited by the rate of substrate movement to the mitochondrial site of the reaction. Cholesterol sulfate translocation rates were however up to 8 times greater than those observed for cholesterol when equivalent concentrations of the two substrates were added to the mitochondria. We conclude that cholesterol sulfate is a better substrate than cholesterol for side-chain cleavage by isolated mitochondria and that both reactions are catalysed by the same cytochrome P-450scc enzyme.

Cholesterol sulfate: a naturally-occurring inhibitor of cholesterol side-chain cleavage which functions at the level of intramitochondrial cholesterol translocation

Cholesterol sulfate is a naturally occurring compound which is widely distributed among various tissues including the adrenal cortex. When added to adrenal mitochondria from ether-stressed rats, it inhibits pregnenolone synthesis from exogenous but not endogenous cholesterol. Evidence supports a locus of action at the level of an intramitochondrial cholesterol translocation system with no effect on the side-chain cleavage enzymatic system (cytochrome P-450scc). Levels of endogenous cholesterol sulfate in the adrenal are similar to the Ki for inhibition by this compound, suggesting a possible physiological role. Moreover, quantities of cholesterol sulfate present in isolated mitochondria from ether-stressed animals are variable, and levels correlate inversely with rates of pregnenolone production by these preparations. In the presence of malate, mitochondrial cholesterol sulfate is metabolized slowly to pregnenolone sulfate, and its removal correlates with activation of cholesterol side-chain cleavage. Cholesterol sulfate levels are not regulated acutely by stress, but can be decreased significantly after several weeks of daily injection of ACTH (a model of chronic stress). Such treatments result in an increased capacity of isolated adrenal mitochondria to synthesize pregnenolone, and increased activity correlates with increased levels of circulating corticosterone. Thus, we propose that cholesterol sulfate is a new physiological regulator of steroid hormone biosynthesis which may function to regulate the magnitude of the steroidogenic response of the adrenal cortex to ACTH.

The side-chain cleavage of cholesterol sulfate--III. The effect of adrenodoxin, membrane phospholipids and Tween 80 on the kinetics of oxidation of the sterol sulfate by a reconstituted cholesterol desmolase system

This paper reports the Km values of a reconstituted cholesterol side-chain cleavage system for cholesterol sulfate, cholesterol, and adrenodoxin, determined under several experimental conditions. The Km values for adrenodoxin change depending on whether cholesterol or its sulfate is used as the substrate. Moreover, the Km values for both of the substrates and for adrenodoxin are greatly modulated by both membrane phospholipids, isolated from adrenal mitochondria, and Tween 80, 0.002%. In the absence of detergents or phospholipids, the enzyme system shows a high affinity for cholesterol sulfate, but is inhibited when high concentrations of the sterol sulfate are added to the incubation mixture. Raising the concentration of adrenodoxin in the assay mixture prevents the substrate inhibition. When cholesterol sulfate is incorporated into micelles containing the phospholipids, the enzyme system does not display substrate inhibition, and the kinetics of cleavage of the sterol sulfate are relatively independent of the concentration of adrenodoxin in the assay mixture. In the absence of phospholipids, the apparent kinetics of cleavage of cholesterol and its sulfate are quite different from each other, but when incorporated into micelles containing phospholipids, the kinetics of cleavage of the two substrates are similar to each other.