J R Faust

Membrane-bound domain of HMG CoA reductase is required for sterol-enhanced degradation of the enzyme

3-Hydroxy-3-methylglutaryl coenzyme A reductase (HMG CoA reductase) is a single polypeptide chain with two contiguous domains: a soluble domain (548 amino acids) that catalyzes the rate-controlling step in cholesterol synthesis and a membrane-bound domain (339 amino acids) that anchors the protein to the endoplasmic reticulum (ER). HMG CoA reductase is degraded at least 10-fold more rapidly than other ER proteins; degradation is accelerated in the presence of cholesterol. To understand this controlled degradation, we transfected reductase-deficient Chinese hamster ovary (CHO) cells with a plasmid expression vector containing a reductase cDNA that lacks the segment encoding the membrane domain. The plasmid produced a truncated reductase (37 kd smaller than normal) that was enzymatically active with normal kinetics; most of the truncated enzyme was found in the cytosol. The truncated enzyme was degraded one-fifth as fast as the holoenzyme; degradation was no longer accelerated by sterols. We conclude that the membrane-bound domain of reductase plays a crucial role in the rapid and regulated degradation of this ER protein.

Role of the low density lipoprotein receptor in regulating the content of free and esterified cholesterol in human fibroblasts.

The transfer of normal human fibroblasts from medium containing whole serum to medium devoid of lipoproteins produced a 90 percent decrease in the cellular content of cholesteryl esters and a 30 percent decrease in the free cholesterol content. When these lipoprotein-deprived cells were subsequently incubated with human low density lipoprotein (LDL), there was a 7-fold increase in the cellular content of esterified cholesterol and a 1.6-fold increase in the cellular content of free cholesterol. The concentration at which LDL produced its half-maximal effect in elevating cellular sterol content (30 mug/ml of LDL-cholesterol) was similar to the half-maximal concentration previously reported for high affinity binding of LDL to its cell surface receptor. High density lipoprotein (HDL) and whole serum from a patient with abetalipoproteinemia (neither of which contains a component that binds to the LDL receptor) did not produce a significant increase in the content of either cholesterol or cholesteryl esters in normal cells. Furthermore, in fibroblasts from patients with the homozygous form of familial hypercholesterolemia, which lack functional LDL receptors, LDL had no effect in raising the cellular content of either free or esterified cholesterol even when present in the medium at concentrations as high as 450 mug sterol/ml. It is concluded that LDL-receptor interactions constitute an important biochemical mechanism for the regulation of the cholesterol content of normal human fibroblasts. Moreover, when considered in light of current concepts of LDL metabolism in intact mammals, the present data suggest that a major function of plasma LDL may be to transport cholesterol from its site of synthesis in liver and intestine to its site of uptake in peripheral tissues.

Synthesis of ubiquinone and cholesterol in human fibroblasts: Regulation of a branched pathway☆

Abstract The current studies demonstrate that cultured human flbroblasts utilize mevalonate for the synthesis of ubiquinone-10 as well as for the synthesis of cholesterol. Study of the regulation of this branched pathway was facilitated by incubating the cells with compactin (ML-236B), a competitive inhibitor of 3-hydroxy-3-methylglutaryI coenzyme A reductase, which blocked the formation of mevalonate within the cell. The addition of known amounts of [ 3 H]mevalonate to the culture medium in the presence of compactin permitted the study of the relative rates of mevalonate incorporation into cholesterol and ubiquinone-10 under controlled conditions. When low concentrations of exogenous [ 3 H]mevalonate (10 to 50 μ m ) were added to cells that were provided with exogenous cholesterol in the form of plasma low density lipoprotein (LDL), the cells incorporated the [ 3 H]mevalonate into ubiquinone-10 at a rate that was two- to threefold faster than the incorporation into cholesterol. When the cells were deprived of exogenous LDL-cholesterol, the incorporation of [ 3 H]mevalonate into ubiquinone-10 decreased and the incorporation of [ 3 H]mevalonate into cholesterol increased. As a result, in the absence of exogenous cholesterol more than 60 times as much [ 3 H]mevalonate was incorporated into cholesterol as into ubiquinone-10. Considered together with previous findings, the current data are compatible with a regulatory mechanism in which LDL inhibits cholesterol synthesis in fibroblasts at two points: (1) at the level of 3-hydroxy-3-methylglutaryl coenzyme A reductase, thereby inhibiting mevalonate synthesis, and (2) at one or more points distal to the last intermediate common to the cholesterol and ubiquinone-10 biosynthetic pathways. The latter inhibition allows ubiquinone-10 synthesis to continue in the presence of LDL despite a 98% reduction in mevalonate synthesis.

Sterols accelerate degradation of hamster 3-hydroxy-3-methylglutaryl coenzyme A reductase encoded by a constitutively expressed cDNA.

A recombinant plasmid containing a full-length cDNA for hamster 3-hydroxy-3-methylglutaryl coenzyme A reductase was introduced by calcium phosphate-mediated transfection into UT-2 cells, a mutant line of Chinese hamster ovary cells that lack 3-hydroxy-3-methylglutaryl coenzyme A reductase activity and thus require low density lipoprotein-cholesterol and mevalonate for growth. We selected a line of permanently transfected cells, designated TR-36 cells, that expressed high levels of 3-hydroxy-3-methylglutaryl coenzyme A reductase activity and thus grew in the absence of low density lipoprotein and mevalonate. Constitutive synthesis of reductase mRNA in TR-36 cells was driven by the simian virus 40 early promoter, and therefore the mRNA was not suppressed by sterols, such as 25-hydroxycholesterol or cholesterol derived from low density lipoprotein, which normally suppresses transcription of reductase mRNA when the reductase gene is driven by its own promoter. Although TR-36 cells continued to synthesize large amounts of reductase mRNA and protein in the presence of sterols, reductase activity declined by 50 to 60%. This decline was caused by a twofold increase in the rate of degradation of preformed enzyme molecules. The current data demonstrate that sterols accelerate the degradation of reductase protein independently of any inhibitory effect on the synthesis of the protein.

Heterozygous familial hypercholesterolemia: failure of normal allele to compensate for mutant allele at a regulated genetic locus.

In normal human fibroblasts, the synthesis of a cell surface receptor for plasma low density lipoprotein (LDL) is regulated by a sensitive system of feedback suppression. The number of functional LDL receptors declines by more than 20 fold when cellular stores of esterified cholesterol are increased by incubation of cells with an exogenous source of cholesterol. Fibroblasts from patients with the heterozygous form of familial hypercholesterolemia (FH) possess one functional allele and one nonfunctional allele at the LDL receptor locus. In the current studies, we have examined the effect that this deficiency produces upon the pattern of regulation of the single functional allele at the LDL receptor locus. Under growth conditions that induced a maximal rate of LDL receptor synthesis (that is, growth in the absence of an exogenous source of cholesterol), the FH heterozygote cells produced about one half as many functional LDL receptors as did the normal cells. More importantly, when grown in the presence of increasing amounts of exogenous cholesterol, the FH heterozygote and normal cells suppressed their respective LDL receptor activities in parallel. Over a wide range of LDL receptor activities, at each level of cellular esterified cholesterol, the FH heterozygote cells expressed about one half as many receptors as did the normal cells. These data indicate that in the FH heterozygote cells, the receptor regulatory mechanism dictates that the normal allele produce only the amount of gene product that it would normally produce at a given level of cellular esterified cholesterol. The failure of the regulatory mechanism to stimulate the normal allele at the LDL receptor locus to produce twice its normal amount of gene product leaves the FH heterozygote cells with a persistent 50% deficiency in LDL receptors under all conditions of cell growth.