Regulation of sterol biosynthesis and lysis of cultured hepatoma cells: inhibition of lanosterol demethylation by hydroxysterols

Demethylation of lanosterol by cultured HTC cells is impaired in the presence of 7_α- and 7_β-hydroxycholesterol, 22(R)-hydroxydesmosterol, and miconazole. The toxicity of these hydroxysterols does not correlate with their ability to inhibit lanosterol demethylation or to depress HMG-CoA reductase activity, although parallel changes in the latter two activities suggest that both are modulated by interaction of hydroxysterols with a single cellular target.     

Cytochrome P-450-dependent oxidation of lanosterol in cholesterol biosynthesis. Microsomal electron transport and C-32 demethylation

Electron transfer to rat liver microsomal cytochrome P-450 of 14 alpha-methyl group demethylation of 24,25-dihydrolanosterol (C30-sterol) has been studied with a new radio-high-performance liquid chromatography assay. The monooxygenase is dependent upon NADPH plus oxygen, insensitive to CN-, and sensitive to CO. Microsomal oxidation is also sensitive to trypsin digestion, and reactivation is dependent upon the addition of purified, detergent-solubilized cytochrome P-450 reductase. Electron transport of C-32 sterol demethylation can be fully supported by very low concentrations of NADPH (approximately 10 microM) only in the presence of saturating concentrations of NADH (approximately 200 microM) suggesting involvement of cytochrome b5-dependent electron transfer in addition to the NADPH-supported pathway. The cytochrome P-450 of 14 alpha-demethylation has been solubilized with detergents, resolved chromatographically from cytochrome P-450 reductase and cytochrome b5, and fully active C-32 demethylase reconstituted. Incubation of intact microsomes with NADH and very low concentrations of NADPH described above leads to interruption of demethylation without 14 alpha-methyl group elimination. Under these conditions, C-32 oxidation products of the C30-sterol substrate accumulate at the expense of formation of demethylated, C29-sterol products. This enzymic interruption of C-32 demethylation, accumulation of oxygenated C30-sterols, along with subsequent demethylation of the isolated C30-oxysterols under similar oxidative conditions supports the suggestion that 14 alpha-hydroxymethyl and aldehydic sterols are metabolic intermediates of sterol 14 alpha-demethylation. Only very modest inductions of the constitutive cytochrome P-450 isozyme of 14 alpha-methyl sterol oxidase can be obtained with just 2 out of 12 known, potent inducers of mammalian hepatic cytochrome P-450s. Alternatively, administration of complete adjuvant in mineral oil drastically reduces amounts of total microsomal cytochrome P-450 while activity of 14 alpha-methyl sterol oxidase is not affected dramatically. Thus, as much as 2.5-fold enhancement of C-32 oxidase specific activity is obtained when expressed per unit of cytochrome P-450.     

Mechanistic studies of lanosterol C-32 demethylation. Conditions which promote oxysterol intermediate accumulation during the demethylation process

Conditions have been established which promote the accumulation of the dihydrolanosterol C-32 demethylation intermediates lanost-8-en-3 beta,32-diol and 3 beta-hydroxylanost-8-en-32-aldehyde with intact hepatic microsomes. Accumulation of dihydrolanosterol-derived oxysterols occurs with a variety of assay manipulations which include short incubation times, limiting enzyme amounts, high pH, and increasing substrate concentration. In addition, competitive inhibition of dihydrolanosterol demethylation by lanosterol, or the reciprocal inhibition of lanosterol demethylation by dihydrolanosterol, leads to oxysterol accumulation at the expense of demethylated end product. Similarly, the nonsteroidal demethylase inhibitors miconazole and ketoconazole promote oxysterol accumulation in a concentration-dependent manner. Finally, cholesterol loading of isolated microsomes results in changes in the measured kinetic constants, Km and Vmax, and results in enhanced oxysterol accumulation above that seen in control microsomal preparations. The major oxysterol intermediate accumulated under all the conditions described above is the C-32 aldehyde in an approximate 3:1 ratio to the C-32 alcohol. These data support the conclusion that a single enzyme species is responsible for all three oxidations of the C-32 demethylation sequence. In addition, intermediates which do not routinely accumulate during demethylation are freely diffusible from the enzyme when appropriate conditions are established to prevent their further metabolism.     

Flux of sterol intermediates in a yeast strain deleted of the lanosterol C-14 demethylase Erg11p

Lanosterol C-14 demethylase Erg11p of the yeast Saccharomyces cerevisiae catalyzes the enzymatic step following formation of lanosterol by the lanosterol synthase Erg7p in lipid particles (LP). Localization experiments employing microscopic inspection and cell fractionation revealed that Erg11p in contrast to Erg7p is associated with the endoplasmic reticulum (ER). An erg11Delta mutation in erg3Delta background, which is required to circumvent lethality of the erg11 defect, did not only change the sterol pattern but also the sterol distribution within the cell. Whereas in wild type the plasma membrane was highly enriched in ergosterol and LP harbored large amounts of sterol precursors in the form of steryl esters, sterol intermediates were more or less evenly distributed among organelles of erg11Delta erg3Delta. This distribution is not result of the erg3Delta background, because in the erg3Delta strain the major intermediate formed, ergosta-7,22-dienol, is also highly enriched in the plasma membrane similar to ergosterol in wild type. These results indicate that (i) exit of lanosterol from LP occurs independently of functional Erg11p, (ii) random supply of sterol intermediates to all organelles of erg11Delta erg3Delta appears to compensate for the lack of ergosterol in this mutant, and (iii) preferential sorting of ergosterol in wild type, but also of ergosta-7,22-dienol in erg3Delta, supplies sterol to the plasma membrane.     

Inhibition of sterol biosynthesis by ergosterol and cholesterol in Saccharomyces cerevisiae

When accumulation of squalene was used as a measure of the flow of carbon into the sterol pathway in whole cells of semi-anaerobic Saccharomyces cerevisiae, both ergosterol and cholesterol were found to be inhibitory. However, at equivalent concentrations in the medium ergosterol was substantially the more potent inhibitor. Marked differences found in the absorption and esterification of the two sterols failed to account for the observed difference in their capacities to act as feedback agents. Cholesterol was much more effectively absorbed as well as esterified, but, when the abilities of the two sterols to lower the squalene level were calculated on the basis of free sterol in the cells, ergosterol remained more effective by a factor of four.     

Novel cholesterol biosynthesis inhibitors targeting human lanosterol 14alpha-demethylase (CYP51)

Novel cholesterol biosynthesis inhibitors, a group of pyridylethanol(phenylethyl)amine derivatives, were synthesized. Sterol profiling assay in the human hepatoma HepG2 cells revealed that compounds target human lanosterol 14alpha-demethylase (CYP51). Structure-activity relationship study of the binding with the overexpressed human CYP51 indicates that the pyridine binds within the heme binding pocket in an analogy with the azoles.     

Regulation of hepatic cholesterol biosynthesis. Effects of a cytochrome P-450 inhibitor on the formation and metabolism of oxygenated sterol products of lanosterol.

The involvement of oxygenated cholesterol precursors in the regulation of 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) reductase activity was studied by examining the effect of ketoconazole on the metabolism of mevalonic acid, lanosterol and the lanosterol metabolites, lanost-8-ene-3 beta,32-diol,3 beta-hydroxylanost-8-en-32-al and 4,4-dimethylcholesta-8,14-dien-3 beta-ol, in liver subcellular fractions and hepatocyte cultures. Inhibition of cholesterol synthesis from mevalonate by ketoconazole at concentrations up to 30 microM was due exclusively to a suppression of cytochrome P-450LDM (LDM = lanosterol demethylase) activity, resulting in a decreased rate of lanosterol 14 alpha-demethylation. No enzyme after the 14 alpha-demethylase step was affected. When [14C]mevalonate was the cholesterol precursor, inhibition of cytochrome P450LDM was accompanied by the accumulation of several labelled oxygenated sterols, quantitatively the most important of which was the C-32 aldehyde derivative of lanosterol. There was no accumulation of the 24,25-oxide derivative of lanosterol, nor of the C-32 alcohol. Under these conditions the activity of HMG-CoA reductase declined. The C-32 aldehyde accumulated to a far greater extent when lanost-8-ene-3 beta,32-diol rather than mevalonate was used as the cholesterol precursor in the presence of ketoconazole. With both precursors, this accumulation was reversed at higher concentrations of ketoconazole in liver subcellular fractions. A similar reversal was not observed in hepatocyte cultures.     

Microsomal enzymes of cholesterol biosynthesis from lanosterol. Solubilization and purification of steroid 8-isomerase

Steroid-8-ene isomerase that catalyzes isomerization of delta 8- to delta 7-sterols has been solubilized from rat liver microsomes with a mixture of two detergents, octylglucoside and sodium taurodeoxycholic acid. During a 40-fold enrichment of the solubilized enzyme, other enzymes of cholesterol biosynthesis, endogenous lipids, and electron carriers are removed. A comparison of properties of the solubilized and partially purified isomerase with the membrane-bound enzyme shows they are essentially identical with respect to pH profile, effect of inhibitors and cofactors, substrate specificity, and Km values. Addition of phospholipid to the partially purified enzyme stimulates activity as much as 1.8-fold over control rates. Although the relative rate of isomerization of cholesta-8,24-dien-3 beta-ol is six times that observed with cholest-8-en-3 beta-ol, the delta 8 to delta 7 ratio at equilibrium is approximately equal. The reversibility of the reaction has been demonstrated by the direct conversion of cholest-7-en-3 beta-ol to cholest-8-en-3 beta-ol; at equilibrium the delta 7-isomer is predominant (19/1). The purified enzyme does not catalyze isomerization of cholesta-8,14-dien-3 beta-ol and cholest-8(14)-en-3 beta-ol under conditions that result in equilibrium mixtures of isomers from cholest-8(9)-en-3 beta-ol. These results are consistent with the earlier suggestion that delta 8(14)-sterols are neither formed nor metabolized by the same microsomal enzymes that catalyze transformation of lanosterol to cholesterol.     

Role of sterol photoconversion products in the regulation of cholesterol biosynthesis in rat skin

In order to clarify the effect of products of photochemical conversion of sterols on cholesterol biosynthesis, rat skin samples were incubated with 2-(14)C-acetate in the presence of the antirachitic agent Dk and 7beta-hydroxycholesterol. The synthesis of sterols from acetate was activated in the presence of Dk. A correlation between the activation of sterol synthesis and the concentration of the antirachitic agent was found. An addition of 7beta-hydroxycholesterol to the incubation medium inhibited acetate incorporation into the sterols. The level of synthesis inhibition increased with an elevation of the 7beta-hydroxysterol concentration in the incubation medium. This indicates that both products of sterol photoconversion can be involved in the control of cholesterol biosynthesis.     

DNA and cholesterol biosynthesis in synchronized embryonic rat fibroblasts: II. Effects of sterol biosynthesis inhibitors on cell division

The relationships between cholesterogenesis and cell division were studied by using two inhibitors of hydroxymethylglutaryl-CoA reductase activity — 25-hydroxycholesterol and compactin. The effects of both compounds on DNA synthesis were compared in synchronized rat fibroblasts cultured in a cholesterol-containing medium. Compactin did not inhibit DNA synthesis, except after a long time of contact and at high and almost cytotoxic concentrations. 25-Hydroxycholesterol inhibited DNA synthesis (without cytotoxic effects) after only 9–16 h of contact, depending on the phase of the cell cycle at which this compound was added to the culture medium. Sensitivity of cells to 25-hydroxycholesterol was maximal at the end of the S phase/beginning of the G₂M phase. The rapid effect of 25-hydroxycholesterol on DNA synthesis appears to be separate from the inhibitory effect on sterol or non-sterol mevalonate-derived compound synthesis. Indeed, under our experimental conditions, the suppression of cholesterol biosynthesis is compensated by the presence of cholesterol in the culture medium, as demonstrated by the lack of effect of compactin on DNA synthesis; moreover, addition of mevalonolactone to the culture medium did not reverse the effect of 25-hydroxycholesterol. 25-Hydroxycholesterol could inhibit DNA synthesis by a direct action on the nucleus, after transfer by the intermediary of a specific hydroxysterol-binding protein.