Apolipoprotein E expression in Y1 adrenal cells is associated with increased intracellular cholesterol content and reduced free cholesterol efflux.

The expression of apoE mRNA in the adrenal gland is inversely correlated to steroidogenesis and directly correlated to the level of cholesteryl ester stores. To further investigate the relationship between apoE and cellular cholesterol homeostasis, several parameters of cholesterol metabolism in the murine Y1 adrenal cell line engineered to constitutively express human apoE (Y1-E cells) have been studied. It is reported here that Y1-E cells have increased cellular cholesterol content and markedly reduced efflux of free cholesterol as compared to control Y1 cells that do not express apoE. Y1-E cells have increases in both free and esterified cholesterol. However, Y1 and Y1-E cells incorporate [14C]oleate into cholesteryl ester at similar rates and have similar levels of maximal ACAT activity in isolated microsomes. Turnover of cholesteryl ester stores prelabeled with [14C]oleate occurred at similar rates in Y1-E and control Y1 cells, suggesting that increased cholesteryl ester stores in Y1-E cells do not result from reduced cholesteryl ester hydrolysis. Y1-E cells showed reduced cholesterol efflux as compared to control Y1 cells with either native high-density lipoprotein or cholesterol-free reconstituted particles as extracellular acceptors. Cholesterol efflux was not altered by inhibition of ACAT, suggesting that cholesterol esterification in Y1-E cells is not inhibiting efflux. These results suggest that reduced cholesterol efflux is responsible, at least in part, for the cholesterol accumulation in Y1-E cells. In comparison to the rat adrenal gland in vivo, Y1-E cells resemble adrenocortical cells under conditions where steroidogenesis is suppressed and apoE expression and cholesteryl ester storage are increased.(ABSTRACT TRUNCATED AT 250 WORDS)

Elevated levels of protein kinase C in Y1 cells which express apolipoprotein E decrease basal steroidogenesis by inhibiting expression of P450-cholesterol side chain cleavage mRNA.

We have previously reported that steroidogenesis is dramatically reduced in mouse Y1 adrenocortical cells which express the human apolipoprotein E gene (Y1-E cells). This suppression results in part from inhibition of cAMP-mediated events. In this report we have examined the expression of protein kinase C (PKC) in the Y1-E cell lines. Total cellular PKC activity in vitro is increased 3-5-fold in the Y1-E cell lines. PKC activity in the particulate and cytosolic fractions is increased to the same relative extent. Increased PKC activity reflects increased levels of PKC mRNA, as determined by Northern blot analysis, and PKC protein, as determined by immunoblot analysis. Increased expression of PKC in the Y1-E cell lines is accompanied by a 2-3-fold increase in diacylglycerol, an in vivo activator of PKC. To determine the contribution of elevated PKC expression to the Y1-E cell phenotype, we utilized the PKC inhibitors, staurosporine and calphostin C. Upon treatment with staurosporine or calphostin C, expression of P450-cholesterol side chain cleavage mRNA is increased severalfold to a level equal to, or greater than, basal expression in the Y1-neo control cell line. Treatment with calphostin C also results in recovery of steroidogenesis in the Y1-E cells to a level comparable to the basal level observed in the Y1-neo control cell line. These results indicate that increased expression of PKC in the Y1-E cell lines decreases basal steroidogenesis by suppressing P450-cholesterol side chain cleavage mRNA expression. Inhibition of PKC, however, does not reverse the block in cAMP-stimulated steroidogenesis in Y1-E cells, suggesting that the pleiotropic effects of apoE expression are not mediated entirely through altered PKC expression.

Apolipoprotein-E messenger RNA in rat ovary is expressed in theca and interstitial cells and presumptive macrophage, but not in granulosa cells.

Apolipoprotein-E (apoE) is a constituent of various lipoproteins and is a ligand for cellular lipoprotein receptors. Unlike most apolipoproteins, apoE is synthesized in peripheral tissues, including those engaged in steroidogenesis. ApoE expression in adrenal cells inhibits cholesterol utilization for steroid synthesis and blocks signal transduction via the protein kinase-A pathway. In cultured ovarian thecal/interstitial cells, exogenous apoE has been shown to inhibit LH-induced androgen synthesis. These findings support a role for apoE as an autocrine or paracrine factor involved in regulating steroidogenesis. In the present study in situ hybridization was used to identify cell types that express apoE mRNA in ovaries from rats with a 4-day estrous cycle, from pregnant rats, from immature rats treated with PMSG to stimulate follicular development, and from PMSG-treated rats that were subsequently administered hCG to stimulate ovulation and luteinization. ApoE mRNA was localized to theca and interstitial cells of follicles in animals at all stages of the estrous cycle as well as in immature rats treated with PMSG. ApoE mRNA was not detected in oocytes, cumulus cells, or granulosa cells. High levels of apoE mRNA also were expressed by localized clusters of presumptive macrophages in atretic follicles and degenerating corpora lutea. This complex pattern of expression may indicate that apoE has multiple functions in the rat ovary. ApoE made by theca and interstitial cells may act locally as an autocrine factor to regulate androgen production. ApoE made in atretic follicles and regressing corpora lutea may serve to facilitate local transport and reutilization of lipid released as these structures degenerate.

Differential regulation of apolipoprotein-E messenger RNA in zona fasciculata cells of rat adrenal gland determined by in situ hybridization.

Previous studies showed that apolipoprotein-E (apoE) mRNA is regulated in rat adrenal gland by treatments that alter adrenal gland cholesterol content and steroidogenesis. In the present study cell types expressing apoE mRNA were determined by in situ hybridizations using an [alpha-35S]UTP-labeled RNA probe. Autoradiographic grains were counted to compare apoE expression in adrenal glands from control and experimentally treated animals. In control adrenal gland, zona (z.) fasciculata and z. reticularis exhibited the highest level of apoE mRNA expression, with lower levels in z. glomerulosa and medulla. Dexamethasone (DEX) treatment selectively increased apoE mRNA 3-fold in outer z. fasciculata, but not in other adrenal zones. ApoE mRNA expression appeared to be lower in adrenal glands from 4-aminopyrazolopyrimidine-treated rats, in that differences among adrenal gland zones were abolished. DEX treatment increased adrenal gland cholesteryl ester and oil red O staining in z. fasciculata cells in which the apoE mRNA concentration was increased as well as in other cortical cells in which apoE mRNA was unchanged. Aminoglutethimide administration led to a large increase in oil red O staining throughout the cortex, including z. fasciculata, without affecting apoE mRNA expression. These data suggest that adrenal gland apoE mRNA expression is not closely coupled to cellular cholesterol concentrations. Increased apoE mRNA expression in z. fasciculata of DEX-treated animals suggests an inverse relationship between apoE mRNA concentration and the level of steroidogenesis. This result is consistent with the proposal that apoE may play a role in regulating the utilization of cholesterol for steroid production.

Relationship between apolipoprotein E mRNA expression and tissue cholesterol content in rat adrenal gland.

Among extrahepatic tissues the adrenal gland has one of the highest concentrations of apoE mRNA and the highest rate of apoE synthesis. In the present investigation several previously described in vivo treatments were used to assess the relationship between apoE expression and cellular cholesterol in the rat adrenal gland. Treatment of rats with 4-aminopyrazolo[3,4-d]pyrimidine (4-APP) to lower serum cholesterol concentration and deplete adrenal gland cholesterol content decreased adrenal gland apoE mRNA concentration. These adrenal responses were blocked by dexamethasone (DEX) suggesting that the effect of 4-APP occurred indirectly via stimulation of the adrenal gland by endogenous adrenocorticotrophic (ACTH). Relative to control rats, DEX treatment increased both adrenal gland cholesterol content and apoE mRNA concentration. Concurrent ACTH and DEX administration reduced both adrenal gland cholesterol content and apoE mRNA concentration relative to DEX-treated rats. ACTH administration also rapidly decreased adrenal gland apoE mRNA concentration and cholesterol content in rats pretreated with DEX. In all the above experiments, adrenal gland cholesterol content and apoE mRNA concentration were positively correlated (r = 0.78, P = 0.0001). In contrast, aminoglutethimide treatment, which blocks adrenal gland steroidogenesis and greatly increases adrenal gland cholesterol content, was without effect on apoE mRNA concentration. ACTH administration to rats treated with DEX + aminoglutethimide resulted in decreased adrenal apoE mRNA despite greatly increased adrenal cholesterol content. This uncoupling of adrenal gland cholesterol content and apoE mRNA concentration suggests that apoE mRNA expression and cellular cholesterol are regulated independently by ACTH.

Expression of the human apolipoprotein E gene suppresses steroidogenesis in mouse Y1 adrenal cells.

The lipid transport protein, apolipoprotein E (apoE), is expressed in many peripheral tissues in vivo including the adrenal gland and testes. To investigate the role of apoE in adrenal cholesterol homeostasis, we have expressed a human apoE genomic clone in the Y1 mouse adrenocortical cell line. Y1 cells do not express endogenous apoE mRNA or protein. Expression of apoE in Y1 cells resulted in a dramatic decrease in basal steroidogenesis; secretion of fluorogenic steroid was reduced 7- to greater than 100-fold relative to Y1 parent cells. Addition of 5-cholesten-3 beta,25-diol failed to overcome the suppression of steroidogenesis in these cells. Cholesterol esterification under basal conditions, as measured by the production of cholesteryl [14C]oleate, was similar in the Y1 parent and the apoE-transfected cell lines. Upon incubation with adrenocorticotropin or dibutyryl cAMP, production of cholesteryl [14C]oleate decreased 5-fold in the Y1 parent cells but was unchanged in the apoE-transfected cell lines. These results suggest that apoE may be an important modulator of cholesterol utilization and steroidogenesis in adrenal cells.

Macrophages from nephrotic rats regulate apolipoprotein E biosynthesis and cholesterol content independently.

The effects of the nephrotic syndrome in rats on the cholesterol content and the biosynthesis of apolipoprotein E (apoE) by resident peritoneal macrophages have been investigated. Since the nephrotic syndrome has been associated with an increased risk of coronary atherosclerosis, we hypothesized that macrophages from nephrotic rats would accumulate cholesterol and undergo transformation into foam cells, with a concomitant increase in apoE biosynthesis. The nephrotic syndrome was induced in rats with puromycin aminonucleoside. Peritoneal macrophages exposed in vivo for 7-21 d to ascites fluid derived from plasma containing sixfold elevations of lipoproteins did not accumulate unesterified or esterified cholesterol. Nevertheless, immunoprecipitation assays after incubation of the isolated cells with [35S]methionine, or immunoblot analysis of the incubation medium demonstrated a 2.6-fold increase in apoE secretion compared with normal macrophages. This increase was accompanied by 5- to 10-fold increases in cellular apoE messenger RNA as determined by quantitative solution hybridization assay. Peritoneal macrophages cultured from nephrotic rats during the period of hypercholesterolemia also showed distinct and highly reproducible morphologic changes. The dissociation between apoE biosynthesis and macrophage cholesterol content provides new insight into the response of peritoneal macrophages in vivo to endogenous hyperlipemia.

Differential effects of dietary fat on the tissue-specific expression of the apolipoprotein A-I gene: relationship to plasma concentration of high density lipoproteins.

Isocaloric substitution of polyunsaturated fat for saturated fat reduces concentrations of total plasma cholesterol and high density lipoproteins (HDL) in nonhuman primates. The biochemical mechanisms through which polyunsaturated fat lowers plasma HDL concentrations are not well understood but must involve changes in HDL production or HDL clearance from plasma, or both. To determine whether dietary polyunsaturated fat (P/S = 2.2) alters apolipoprotein (apo) A-I production, African green monkeys (Cercopithecus aethiops) were fed diets containing polyunsaturated fat or saturated fat (P/S = 0.3) each in combination with high (0.8 mg/kcal) and low (0.03 mg/kcal) amounts of dietary cholesterol. Animals fed polyunsaturated fat at either cholesterol level had lower plasma concentrations of total cholesterol and HDL cholesterol. Plasma apoA-I concentration was reduced by 16% by polyunsaturated fat in the high cholesterol group. The rate of hepatic apoA-I secretion, as estimated by the accumulation of perfusate apoA-I during recirculating liver perfusion, was reduced by 19% in animals consuming the high cholesterol, polyunsaturated fat diet. Hepatic apoA-I mRNA concentrations, as measured by DNA-excess solution hybridization, also were reduced by 22% in the high cholesterol, polyunsaturated fat-fed animals. In contrast, intestinal apoA-I mRNA concentrations were not altered by the type of dietary fat. Plasma apoA-II and hepatic apoA-II mRNA concentrations also were not altered by the type of dietary fat. These data indicate that dietary polyunsaturated fat can selectively alter the expression of the apoA-I gene in a tissue-specific manner.(ABSTRACT TRUNCATED AT 250 WORDS)

Apolipoprotein (apo) A-I production and mRNA abundance explain plasma apoA-I and high density lipoprotein differences between two nonhuman primate species with high and low susceptibilities to diet-induced hypercholesterolemia.

Earlier studies have shown that African green monkeys develop a more modest hypercholesterolemia, higher high density lipoprotein (HDL) concentrations, and less atherosclerosis than cynomolgus monkeys fed diets with the same cholesterol content. In the present study, cynomolgus monkeys were fed less cholesterol than was fed to African green monkeys to induce equivalent hypercholesterolemia in both species. African green monkeys still had 2-fold higher plasma HDL cholesterol concentrations and 2.7-fold higher plasma apolipoprotein (apo) A-I concentrations. Therefore, the higher HDL concentration in African green monkeys appears to result from factors that act independently of dietary cholesterol intake or total plasma cholesterol concentration. Two aspects of HDL production were examined to determine the metabolic basis of the species difference in HDL concentration. The rate of hepatic apoA-I secretion, as estimated by the accumulation of apoA-I in the medium during recirculating liver perfusion, was 5-fold higher in livers of African green monkeys. In addition, the concentration of apoA-I mRNA was 2-fold higher in the liver and 3.7-fold higher in the intestine of African green monkeys. Taken together, these findings indicate that differences in apoA-I production in the liver and small intestine are large enough to be responsible for the differences in the plasma concentrations of HDL and apoA-I between these species. Factors which regulate apoA-I secretion, including modulation of tissue apoA-I mRNA concentrations, are important determinants of plasma HDL concentrations and may contribute to the relative resistance of African green monkeys to dietary cholesterol-induced hypercholesterolemia and atherosclerosis. ApoA-I mRNA was also detected at low levels in the kidney and testis of African green and cynomolgus monkeys but not in the adrenal or brain. The tissue distribution and abundance of apoA-I mRNA in peripheral tissues was very different than that seen for apoE mRNA. Kidney and testis apoA-I mRNAs were the same size as liver apoA-I mRNA when examined by Northern blot analysis. Testis apoA-I mRNA appeared to be functionally active as judged by its presence in cytoplasmic polyribosomes. The low levels of apoA-I expression in kidney and testis are unlikely to contribute significantly to the plasma apoA-I pool but might function in some aspect of local lipid metabolism within these tissues.

Physicochemical and histological changes in the arterial wall of nonhuman primates during progression and regression of atherosclerosis.

To identify the temporal changes occurring during progression and regression of atherosclerosis in nonhuman primates, we have studied the physicochemical and histological characteristics of arterial wall lesions during a 30-mo progression period of diet-induced hypercholesterolemia and during a 12-mo period of regression. Three groups of cynomolgous monkeys (Macaca fascicularis) were studied. Control groups were fed a basal chow diet for 18, 24, and 30 mo and were compared with progression groups that were fed a high-cholesterol-containing diet for up to 30 mo. Regression groups were fed a high-cholesterol diet for 18 mo to induce atherosclerosis and then fed monkey chow for up to 12 mo. The progression group monkeys were killed at 6, 12, 18, 24, and 30 mo, and the regression animals were killed at 24 and 30 mo (i.e., after 6 and 12 mo of being fed a noncholesterol-containing chow diet). Histology and morphometry, physical microscopy for cholesterol monohydrate crystals, foam cell and droplet melting points and chemical composition studies were completed on a large number of individual arterial lesions. Control animals had very little cholesterol ester, rare foam cells, and no extracellular cholesterol ester droplets or cholesterol crystals. During progression, the arteries first increased cholesterol ester content to produce high melting (approximately 45 degrees C) foam cell-rich lesions essentially devoid of cholesterol crystals. With time, the number of cholesterol crystals increased so that by 30 mo large numbers were present. Foam cells decreased with time but their melting temperature remained high while that of extracellular droplets fell to approximately 38 degrees C. Between 18 and 30 mo necrosis appeared and worsened. After 6-mo regression, unexpected changes occurred in the lesions. Compared with 24-mo progression, the chemical composition showed a relative increase in free cholesterol, a decrease in cholesterol ester and microscopy revealed large numbers of cholesterol crystals. Concomitantly, foam cells decreased and the melting temperature of both intra- and extracellular cholesterol ester markedly decreased. After 12-mo regression cholesterol decreased, cholesterol crystals and necrosis diminished and collagen appeared increased. Thus, during progression there is initially an increase in the number of foam cells containing very high-melting intracellular cholesterol ester droplets. By 30 mo, cholesterol crystals and necrosis dominate and high-melting foam cells appear only at lesion margins, suggesting that the initial process continues at the lesion edge. The lower melting point of extracellular esters indicates a lipid composition different from intracellular droplets. Thus, the changes observed in these animals generally reflect those predicted for progression of human atherosclerosis. During the initial 6 mo of regression, necrosis remains, the number of foam cell decreases, and cholesterol ester content decreases; however the relative proportion of free cholesterol content increases, and large numbers of cholesterol content are formed. Thus, large and rapid decreases in serum cholesterol concentration to produce regression in fact may result in the precipitation of cholesterol monohydrate and an apparent worsening of the lesions. More prolonged regression (12-mo) tends to return the lipid composition of the artery wall towards normal, partially reduces cholesterol crystals, and results in an improved but scarred intima.