Negative regulation of cell proliferation by mevalonate or one of the mevalonate phosphates

The role of mevalonate and its products in the regulation of cellular proliferation was examined using 6-fluoromevalonate (Fmev), a compound that blocks the conversion of mevalonate pyrophosphate to isopentenyl pyrophosphate. Fmev suppressed DNA synthesis by a variety of transformed and malignant T cell, B cell, and myeloid cell lines. In contrast to results previously reported with mitogen-stimulated human peripheral blood T cell DNA synthesis, low concentrations of low density lipoprotein (LDL) alone could not restore proliferation to these cell lines. The same concentrations of LDL were able to provide sufficient cholesterol and support the growth of all cell lines when mevalonate synthesis was blocked with a specific inhibitor of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase, lovastatin. Fmev-mediated inhibition was totally prevented in some but not all cell lines when the concentration of exogenous LDL was increased 5-10-fold above that required to permit proliferation of lovastatin-blocked cells. Residual HMG-CoA reductase activity of cells cultured with LDL inversely correlated with the restoration of growth to Fmev-blocked cultures. Confirmation of the critical role of HMG-CoA reductase activity and mevalonate synthesis in the inhibition of cellular proliferation by Fmev was obtained by demonstrating that the specific inhibitor of this enzyme, lovastatin, restored proliferation of Fmev-blocked cells. Furthermore, supplementation of cultures with mevalonate, the product of HMG-CoA reductase activity, markedly inhibited proliferation of Fmev-blocked cells. These findings indicate that mevalonate or one of the mevalonate phosphates, which accumulates in Fmev-blocked cells, is a critical negative regulator of cellular proliferation.     

Dose-dependent effects of lovastatin on cell cycle progression. Distinct requirement of cholesterol and non-sterol mevalonate derivatives

The mevalonate pathway is tightly linked to cell proliferation. The aim of the present study is to determine the relationship between the inhibition of this pathway by lovastatin and the cell cycle. HL-60 and MOLT-4 human cell lines were cultured in a cholesterol-free medium and treated with increasing concentrations of lovastatin, and their effects on cell proliferation and the cell cycle were analyzed. Lovastatin was much more efficient in inhibiting cholesterol biosynthesis than protein prenylation. As a result of this, lovastatin blocked cell proliferation at any concentration used, but its effects on cell cycle distribution varied. At relatively low lovastatin concentrations (less than 10 microM), cells accumulated preferentially in G(2) phase, an effect which was both prevented and reversed by low-density lipoprotein cholesterol. At higher concentrations (50 microM), the cell cycle was also arrested at G(1) phase. In cells treated with lovastatin, those arrested at G(1) progressed through S upon mevalonate provision, whereas cholesterol supply allowed cells arrested at G(2) to traverse M phase. These results demonstrate the distinct roles of mevalonate, or its non-sterol derivatives, and cholesterol in cell cycle progression, both being required for normal cell cycling.     

Post-translational isoprenylation of cellular proteins is altered in response to mevalonate availability

Cells incorporate isoprenoid products derived from mevalonate (MVA) into several unique proteins. The aim of this study was to delineate the effects of blocking MVA synthesis on the covalent isoprenylation of these proteins in murine erythroleukemia cells. Inhibition of protein synthesis with cycloheximide prevented the incorporation of [3H]MVA into proteins, suggesting that isoprenylation normally occurs immediately after synthesis of the polypeptides. However, incubation of cells with lovastatin, a competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, for as little as 1 h prior to addition of cycloheximide rendered the isoprenylation step insensitive to cycloheximide. Lovastatin had no apparent effect on the stability of the isoprenylated proteins, but the development of cycloheximide insensitivity during the lovastatin preincubation was dependent on synthesis of new protein during that period. Addition of 50-200 microM MVA to the culture medium eliminated the effects of preincubation with lovastatin. Preincubation of cells with 25-hydroxycholesterol, which suppresses the synthesis and enhances the degradation of HMG-CoA reductase but is not a competitive enzyme inhibitor, did not induce cycloheximide-insensitivity of the isoprenylation reaction. The results suggest that blocking MVA synthesis with lovastatin causes a rapid depletion of isoprenoid groups available for protein modification. Consequently, there is an accumulation of non-isoprenylated substrate proteins. Shifts in the ratio of modified vs. unmodified proteins in response to MVA availability may have implications for the changes in cell morphology, cell proliferation and HMG-CoA reductase gene expression that occur when cells are subjected to MVA deprivation.     

Sterol-independent regulation of 3-hydroxy-3-methylglutaryl-CoA reductase by mevalonate in Chinese hamster ovary cells. Magnitude and specificity

In this paper, we assess the relative degree of regulation of the rate-limiting enzyme of isoprenoid biosynthesis, 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, by sterol and nonsterol products of mevalonate by utilizing cultured Chinese hamster ovary cells blocked in sterol synthesis. We also examine the two other enzymes of mevalonate biosynthesis, acetoacetyl-CoA thiolase and HMG-CoA synthase, for regulation by mevalonate supplements. These studies indicate that in proliferating fibroblasts, treatment with mevalonic acid can produce a suppression of HMG-CoA reductase activity similar to magnitude to that caused by oxygenated sterols. In contrast, HMG-CoA synthase and acetoacetyl-CoA thiolase are only weakly regulated by mevalonate when compared with 25-hydroxycholesterol. Furthermore, neither HMG-CoA synthase nor acetoacetyl-CoA thiolase exhibits the multivalent control response by sterol and mevalonate supplements in the absence of endogenous mevalonate synthesis which is characteristic of nonsterol regulation of HMG-CoA reductase. These observations suggest that nonsterol regulation of HMG-CoA reductase is specific to that enzyme in contrast to the pleiotropic regulation of enzymes of sterol biosynthesis observed with oxygenated sterols. In Chinese hamster ovary cells supplemented with mevalonate at concentrations that are inhibitory to reductase activity, at least 80% of the inhibition appears to be mediated by nonsterol products of mevalonate. In addition, feed-back regulation of HMG-CoA reductase by endogenously synthesized nonsterol isoprenoids in the absence of exogenous sterol or mevalonate supplements also produces a 70% inhibition of the enzyme activity.     

The cytotoxicity of mevalonate, lovastatin and carminomycin with respect to MOLT-4 human malignant T-lymphoblasts in vitro]

It was shown in vitro that high concentrations of lovastatin, a competitive inhibitor of hydroxymethyl glutaryl coenzyme A (HMG-CoA) reductase inhibited human malignant cells MOLT-4. The activity of lovastatin in doses of 50-250 microM was dose-dependent. Addition of mevalonate in a concentration of 3 mM to the growth medium completely prevented the cytotoxic effect of 100 microM of lovastatin. At the same time, exogenous mevalonate did not decrease the cytotoxicity of the anthracycline antibiotic carminomycin. Moreover, in a high concentration (7 mM) mevalonate slowly but significantly inhibited the growth of the malignant target cells and the effect was added to the cytotoxic effect of carminomycin low concentrations (0.08 to 0.175 microgram/ml). The results and the literature data suggested that combination of mevalonate, HMG-CoA reductase inhibitors and anthracyclines could be useful in tumor chemotherapy. The suggestion needs further investigation.     

A mevalonate requirement for maintenance of fatty acid and protein synthesis during hormonally stimulated development of mammary gland in vitro

The effect of compactin on hormonally induced lipogenesis and protein synthesis was studied in vitro in explants of mammary gland from mid-pregnant rabbits. Compactin blocks mevalonate synthesis by the specific inhibition of 3-hydroxy-3-methylglutaryl-CoA reductase, and in this system, culture with 10 microM compactin for 24, 48, and 72 h inhibited incorporation of [1-14C]acetate (but not [2-14C]mevalonate) into sterol by 98, 95, and 86%, respectively. Removal of compactin prior to assay rapidly reversed this effect and was associated with increased tissue 3-hydroxy-3-methylglutaryl-CoA reductase activity. Fatty acid synthesis (measured by incorporation of [1-14C]acetate or [4,5-3H]leucine) and protein synthesis (measured by incorporation of [4,5-3H]leucine) were both inhibited by around 50% after culture with compactin. This inhibition was not rapidly reversed by removal of compactin prior to assay, but it was prevented by inclusion of 1 mM mevalonolactone in the culture medium. After removal of compactin and continued culture in its absence for 24 h with hormones, the normal tissue capacity for fatty acid and protein synthesis was restored, indicating no permanent cell damage. The results suggest a specific requirement for mevalonate (or derived products) for the hormonal maintenance of the increased fatty acid and protein synthesis characteristic of the development of the mammary gland.     

Enhanced sterol synthesis in concanavalin A-stimulated lymphocytes: correlation with phospholipid synthesis and DNA synthesis.

Incorporation of (14C)choline and (3H)myo-inositol into the total lipid fraction, incorporation of (14C)acetate into the sterol fraction and incorporation of (3H)thymidine into DNA were studied in human lymphocyte cultures. Concanavalin A induced an increase in the incorporation of these labels with the following features: (a) Phospholipid synthesis was increased promptly. The lag time for the increase in sterol synthesis and DNA synthesis were 5 hours and 27 hours respectively; (b) The increase in phospholipid synthesis and sterol synthesis was proportional to ConA concentration initially. Cells treated with a high concentration of ConA showed very low levels of DNA synthesis; (c) The increase in phospholipid synthesis could be abolished immediately by alpha-Methyl-Mannoside. alpha-Methyl-Mannoside blunted but did not abolish the increase in sterol synthesis. alpha-Methyl-Mannoside enhanced DNA synthesis of those cells which had been treated by a high concentration of ConA; and (d) Selective inhibition of sterol synthesis with 25-hydroxycholesterol did not prevent the increase in phospholipid synthesis, but it blocked the increase in DNA synthesis. Supplement of LDL, HDL or total lipoproteins to lymphocyte cultures was effective in preventing the inhibition of DNA synthesis by 25-hydroxy-cholesterol. These results suggest that in lymphocyte activation by ConA phospholipid synthesis, sterol synthesis and DNA synthesis were sequentially increased. The rate of cellular commitment to mitogenesis was proportional to ConA concentrations. High concentrations of ConA arrested the cell growth at a postcommitment point in the G1 phase. Enhanced phospholipid synthesis was a precommitment event. Enhanced sterol synthesis was a postcommitment event and reflected the requirement of an increased cholesterol supply for the passage of cell growth through G1.     

Isoprenoids and astroglial cell cycling: diminished mevalonate availability and inhibition of dolichol-linked glycoprotein synthesis arrest cycling through distinct mechanisms.

Primary astroglial cultures were used to compare the relationships to cell cycling of dolichol-linked glycoprotein synthesis, and of availability of mevalonate, the precursor of dolichol and other isoprenoid lipids. With shift-up to 10% serum (time 0) after 48 h of serum depletion, the proportion of cells in S phase (bromodeoxyuridine immunofluorescence) remained under 15% for 12 h, then increased by 20 h to 72 +/- 10%; DNA synthetic rates (thymidine incorporation) increased 5-fold. S phase transition was prevented by addition at 10-12 h of tunicamycin, an inhibitor of transfer of saccharide moieties to dolichol. Mevinolin, an inhibitor of mevalonate biosynthesis, also blocked cycle progression when added at this time. However, mevinolin markedly inhibited the isoprenoid pathway, as reflected by over 90% reduction of sterol synthesis, without inhibiting net glycoprotein synthesis. Removal of mevinolin after a 24 h exposure delayed S phase until 48 h, following recovery of sterol synthesis, even though kinetics of glycoprotein synthesis were unaffected. Tunicamycin removal after 24 h spared sterol synthesis, but caused delay of S phase until 72 h, following recovery of glycoprotein synthesis. In mevinolin-treated cultures, S phase transition was restored by 1 h of exposure to mevalonate at 10 h, although cycling was thereby rendered sensitive to inhibition by cycloheximide and by tunicamycin. Cell cycle progression following hydroxyurea exposure and release was unaffected by mevinolin, tunicamycin, or cycloheximide. Thus, in these developing astroglia, mevalonate and its isoprenoid derivatives have at least two cell cycle-specific roles: dolichol-linked glycoprotein synthesis is required at or before the G1/S transition, while a distinct mevalonate requirement is apparent also in late G1.     

Dose-dependent dual effects of cholesterol and desmosterol on J774 macrophage proliferation

We addressed the ability of native, oxidized and acetylated low-density lipoproteins (nLDL, oxLDL and acLDL, respectively) and desmosterol to act as sources of sterol for the proliferation of J774A.1 macrophages. Treatment with 0.5 μM lovastatin and lipoprotein-deficient serum suppressed cell proliferation. This inhibition was effectively prevented by nLDL, but only to a lesser extent by oxLDL. AcLDL, despite its ability to deliver a higher amount of cholesterol to J774 macrophages than the other LDLs, was dependent on mevalonate supply to sustain cell proliferation. Similarly, exogenous desmosterol, which is not converted into cholesterol in J774 cells, required the simultaneous addition of mevalonate to support optimal cell growth. Expression of hydroxymethyl glutaryl coenzyme A reductase mRNA was potently down-regulated by acLDL and exogenous desmosterol, but the effect was weaker with other sterol sources. We conclude that nLDL is more efficient than modified LDL in sustaining macrophage proliferation. Despite the requirement of cholesterol or desmosterol for J774 cell proliferation, excessive provision of either sterol limits mevalonate availability, thus suppressing cell proliferation.     

Metabolism of intracerebrally injected mevalonate in brain of suckling and young adult rats

We have investigated the in vivo metabolism via sterol and nonsterol pathways of intracerebrally injected mevalonate (MVA) in brains from suckling (10-day-old) and young adult (60-day-old) rats. Results of our study indicated that increasing the amounts of MVA injected increased MVA incorporation into all the lipid fractions examined. The incorporation of MVA into nonsaponiable lipids (NSF) and digitonin precipitable sterols (DPS) was similar in brains from adult and suckling rats. In brain tissue from both suckling and young adult rats the synthesis of dolichol from MVA varied with the amounts of MVA injected. Significant amounts of MVA were recovered in phosphorylated and free polyprenols (farnesol and geraniol) in brain tissue from rats of both ages. Also in both groups of animals, the amounts of MVA incorporated in phosphorylated and free farnesol were higher than the amounts recovered in either, phosphorylated or free geraniol. The amounts of MVA incorporated into the prenoic/fatty acid fraction by brain tissue from both suckling and young adult rats were less than 1% of the total MVA incorporated (nonsaponifiable and saponifiable lipids). Incorporation of MVA into the prenoic/fatty acid fraction by brain tissue was higher in suckling than in young adult rats. These data indicate that the brain tissue from suckling and young adult rats do not differ in their capacity to metabolize MVA into squalene and sterols and that in brain, metabolism of MVA by a shunt pathway is minimal. This suggests that in vivo regulation of cholesterol synthesis during brain development must occur at a step(s) in the sterol synthetic pathway prior to mevalonate, and that metabolism of mevalonate by shunt pathway did not play a role in the developmental regulation of brain sterol synthesis. The data also suggest that in both groups of animals the synthesis of squalene by synthetase may in part control brain sterol synthesis and the synthesis of dolichol is regulated by MVA concentration in the tissue.     

Regulation of 3-hydroxy-3-methylglutaryl-CoA reductase mRNA contents in human hepatoma cell line Hep G2 by distinct classes of mevalonate-derived metabolites.

Hep G2 cells were incubated under conditions known to influence the HMG-CoA (3-hydroxy-3-methylglutaryl-CoA) reductase activity, e.g. in the presence of compactin (a competitive inhibitor of HMG-CoA reductase itself) and U18666A (a squalene-2,3-epoxide cyclase inhibitor). We studied the effects of these conditions both on the HMG-CoA reductase activity and on the reductase mRNA content. In the presence of compactin the mRNA content increased, but less than the enzyme activity, as determined after removal of the inhibitor. The increase in mRNA could be prevented by addition of mevalonate or by a combination of low-density lipoprotein (LDL) plus a low concentration of mevalonate. LDL alone prevented the compactin-induced increases in mRNA and activity only partially. The effect of U18666A on reductase mRNA content and activity was biphasic, i.e. a slight decrease at low (0.3-0.5 microM) concentrations, with a concomitant formation of polar sterols [Boogaard, Griffioen & Cohen (1987) Biochem. J. 241, 345-351], and an increase at high (20-30 microM) concentrations, with complete blockage of sterol formation. At these high concentrations of U18666A, additional compactin (2 microM) increased the reductase activity, but not the mRNA content. We conclude that non-sterol metabolites of mevalonate regulate exclusively at the enzyme level, whereas sterol metabolites regulate at the reductase mRNA level. In the latter group of regulators we distinguish mevalonate metabolites which can, and metabolites which cannot, be replaced by exogenous LDL.     

Effects of pravastatin sodium on mevalonate metabolism in common marmosets

In experimental animals and humans, the concentration of serum mevalonate (MVA), a direct product of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, is considered to reflect the activity of whole-body sterol synthesis. The relationship between the concentration of serum MVA and the activity of sterol synthesis in tissues, however, has not been fully clarified. In the present study, we examined MVA metabolism by using pravastatin, a liver-selective inhibitor of HMG-CoA reductase, and common marmosets, a good model animal for studying lipid metabolism. In the time course study, the maximal reduction in the concentration of serum MVA was observed 2 h after a single oral administration of 30 mg/kg pravastatin to common marmosets. We, therefore, examined the relationship between the concentrations of serum and hepatic MVA, and sterol synthesis in some tissues at this time point. Sterol synthesis was determined ex vivo in tissue slices by measuring the incorporation of [14C]acetate into digitonin-precipitable [14C]sterols. Pravastatin at 0.03-30 mg/kg reduced dose-dependently the activity of hepatic sterol synthesis, whereas no significant reduction of sterol synthesis was observed in other tissues such as intestine, kidney, testis and spleen, even with the highest dose (30 mg/kg). The liver-specific inhibition of sterol synthesis caused parallel reductions in the concentrations of both serum and liver MVA. In addition, there were good correlations between the concentration of either serum or hepatic MVA and the activity of hepatic sterol synthesis. These data indicate that the major origin of serum MVA is the liver, and that the concentration of serum MVA reflects the concentration of hepatic MVA and the activity of hepatic sterol synthesis 2 h after a single oral administration of pravastatin in common marmosets.     

Hepatic and nonhepatic sterol synthesis and tissue distribution following administration of a liver selective HMG-CoA reductase inhibitor, CI-981: comparison with selected HMG-CoA reductase inhibitors.

Since cholesterol biosynthesis is an integral part of cellular metabolism, several HMG-CoA reductase inhibitors were systematically analyzed in in vitro, ex vivo and in vivo sterol synthesis assays using [14C]acetate incorporation into digitonin precipitable sterols as a marker of cholesterol synthesis. Tissue distribution of radiolabeled CI-981 and lovastatin was also performed. In vitro, CI-981 and PD134967-15 were equipotent in liver, spleen, testis and adrenal, lovastatin was more potent in extrahepatic tissues than liver and BMY21950, pravastatin and PD135023-15 were more potent in liver than peripheral tissues. In ex vivo assays, all inhibitors except lovastatin preferentially inhibited liver sterol synthesis; however, pravastatin and BMY22089 were strikingly less potent in the liver. CI-981 inhibited sterol synthesis in vivo in the liver, spleen and adrenal while not affecting the testis, kidney, muscle and brain. Lovastatin inhibited sterol synthesis to a greater extent than CI-981 in the spleen, adrenal and kidney while pravastatin and BMY22089 primarily affected liver and kidney. The tissue distribution of radiolabeled CI-981 and lovastatin support the changes observed in tissue sterol synthesis. Thus, we conclude that a spectrum of liver selective HMG-CoA reductase inhibitors exist and that categorizing agents as liver selective is highly dependent upon method of analysis.     

Synthesis of ubiquinone and cholesterol in human fibroblasts: regulation of a branched pathway.

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 [³H]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 [³H]mevalonate (10 to 50 μm) were added to cells that were provided with exogenous cholesterol in the form of plasma low density lipoprotein (LDL), the cells incorporated the [³H]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 [³H]mevalonate into ubiquinone-10 decreased and the incorporation of [³H]mevalonate into cholesterol increased. As a result, in the absence of exogenous cholesterol more than 60 times as much [³H]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.     

Effects of a novel lanosterol 14 alpha-demethylase inhibitor on the regulation of 3-hydroxy-3-methylglutaryl-coenzyme A reductase in Hep G2 cells.

A 32-carboxylic acid derivative of lanosterol (SKF 104976) was found to be a potent inhibitor of lanosterol 14 alpha-demethylase (14 alpha DM). 14 alpha DM activity in a Hep G2 cell extract was inhibited 50% by 2 nM SKF 104976. Exposure of intact cells to similar concentrations of the compound resulted in the inhibition of incorporation of [14C]acetate into cholesterol with concomitant accumulation of lanosterol as well as a 40-70% decrease in 3-hydroxy-3-methylglutaryl-CoA reductase (HMGR) activity. SKF 104976 did not effect low density lipoprotein uptake and degradation in Hep G2 cells, suggesting that HMGR and low density lipoprotein receptor activity were not coordinately regulated under these conditions. Reduction of the flux of carbon units in the sterol synthetic pathway by as much as 80% did not alter the suppressing effect of SKF 104976 on HMGR activity. However, under conditions where sterol synthesis was almost completely blocked by lovastatin, HMGR activity was not suppressed by SKF 104976. Mevalonate, at concentrations that did not decrease HMGR activity, was able to restore the inhibiting effect of SKF 104976 on HMGR activity. The rapid inhibition (2-3 h) of HMGR activity by SKF 104976 to 30-60% of the level in controls was not dependent on the initial amount of HMGR enzyme present. These findings suggest that upon inhibition of 14 alpha DM by SKF 104976, a mevalonate-derived precursor regulates HMGR activity, even when the sterol synthetic rate is considerably reduced and when HMGR protein levels are very high. In Hep G2 cells, formation of oxylanostenols from [3H]mevalonate reached a maximum between 1 and 10 nM SKF 104976 and was negligible at higher concentrations. This result suggests that oxylanostenols are not the key mediators of the modulation of HMGR in Hep G2 cells upon 14 alpha DM inhibition.     

Requirement for mevalonate in cycling cells: quantitative and temporal aspects

In order to investigate a requirement for isoprenoid compounds in the cell cycle, DNA synthesis was examined in cultured Chinese hamster ovary cells in which mevalonate biosynthesis was blocked with mevinolin, a competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase. Treatment of exponentially-growing cultures with mevinolin led to a decline in DNA synthesis and cell cycle arrest in G1. Synchronous DNA synthesis and cell division could be restored in the arrested cultures, in the absence of exogenous mevalonate, by removing the inhibitor from the culture thereby allowing expression of an induced level of HMG-CoA reductase. In order to quantitate the mevalonate requirement for entry into S phase, recovery of DNA synthesis was made dependent upon added mevalonate by preventing the induction of the enzyme using 25-hydroxycholesterol, a specific repressor of HMG-CoA reductase synthesis. When cultures were treated with both inhibitors, optimal recovery of DNA synthesis was obtained with 200 micrograms/ml mevalonate following an 8 h lag, whereas a progressively longer lag-time was found with lower concentrations of mevalonate. Exogenous dolichol, ubiquinone, or isopentenyladenine had no effect on the arrest or recovery of DNA synthesis. Cholesterol was required during the arrest incubation for cell viability, but was not sufficient for recovery in the absence of mevalonate. The recovery of DNA synthesis by 200 micrograms/ml mevalonate, which was maximal 14-16 h after the addition of mevalonate, only required that the mevalonate be present for the first 4 h, whereas more than an 8-h incubation was required for maximal recovery with 25 micrograms/ml mevalonate. Maximal recovery at either concentration of mevalonate was achieved after approximately 400 fmol mevalonate/micrograms protein was incorporated into non-saponifiable lipids. This quantity represents approximately 0.1% of the mevalonate required for the synthesis of total cellular isoprenoid compounds. The results indicate that production of a quantitatively minor product(s) of mevalonate metabolism is required during the first 4 h following release of the block before other cellular events necessary for entry into S phase can occur.     

Effect of inhibition of cholesterol synthetic pathway on the activation of Ras and MAP kinase in mesangial cells

Intermediary metabolites of cholesterol synthetic pathway are involved in cell proliferation. Lovastatin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A reductase, blocks mevalonate synthesis, and has been shown to inhibit mesangial cell proliferation associated with diverse glomerular diseases. Since inhibition of farnesylation and plasma membrane anchorage of the Ras proteins is one suggested mechanism by which lovastatin prevents cellular proliferation, we investigated the effect of lovastatin and key mevalonate metabolites on the activation of mitogen-activated protein kinase (MAP kinase) and Ras in murine glomerular mesangial cells. The preincubation of mesangial cells with lovastatin inhibited the activation of MAP kinase stimulated by either FBS, PDGF, or EGF. Mevalonic acid and farnesyl-pyrophosphate, but not cholesterol or LDL, significantly prevented lovastatin-induced inhibition of agonist-stimulated MAP kinase. Lovastatin inhibited agonist-induced activation of Ras, and mevalonic acid and farnesylpyrophosphate antagonized this effect. Parallel to the MAP kinase and Ras data, lovastatin suppressed cell growth stimulated by serum, and mevalonic acid and farnesylpyrophosphate prevented lovastatin-mediated inhibition of cellular growth. These results suggest that lovastatin, by inhibiting the synthesis of farnesol, a key isoprenoid metabolite of mevalonate, modulates Ras-mediated cell signaling events associated with mesangial cell proliferation.     

Lovastatin is a potent inhibitor of cholecystokinin secretion in endocrine tumor cells in culture

Lovastatin prevents isoprene synthesis thereby affecting the structural organization of proteins involved in protein transport and secretion. Lovastatin at 1 microM decreases CCK 8 secretion by over 50% in WE cells and in CCK 8 expressing AtT20 cells. At 10 microM CCK 8 secretion was inhibited by two thirds and at 100 microM, cytotoxic effects were observed in both cell types. Addition of mevalonate does not restore CCK secretion and stimulation of secretion by forskolin is also partially inhibited. Cellular content of CCK 8 and pro-CCK were not altered in either of these cell lines except at 100 microM lovastatin. Our results clearly demonstrate that lovastatin at 1 microM strongly inhibits CCK 8 secretion at multiple levels while having little or no effect on its synthesis. This effect on secretion may be partly responsible for the adverse gastrointestinal side effects of lovastatin in patients.     

The mevalonate/isoprenoid pathway inhibitor apomine (SR-45023A) is antiproliferative and induces apoptosis similar to farnesol

Apomine (SR-45023A) is a new antineoplastic compound which is currently in clinical trials and representative of the family of cholesterol synthesis inhibitors 1,1-bisphosphonate esters. Apomine inhibits growth of a wide variety of tumor cell lines with IC(50) values ranging from 5 to 14 microM. The antiproliferative activity of apomine was studied in comparison with that of other inhibitors of the mevalonate/isoprenoid pathway of cholesterol synthesis, simvastatin, farnesol, and 25-hydroxycholesterol. All these compounds inhibit 3-hydroxy-3-methylglutaryl-coenzyme A reductase activity. Apomine (IC(50) = 14 microM), simvastatin (IC(50) = 3 microM), farnesol (IC(50) = 60 microM), and 25-hydroxycholesterol (IC(50) = 2 microM) inhibited HL60 cell growth. Growth inhibition due to simvastatin was reverted by mevalonate, whereas the antiproliferative activity of apomine, farnesol, and 25-hydroxycholesterol was not. Apomine triggered apoptosis in HL60 cells in less than 2 h. Apomine and farnesol induced caspase-3 activity at concentrations similar to their IC(50) values for cell proliferation, whereas a 10-fold excess of simvastatin was necessary to trigger apoptosis compared to its potency on proliferation. Caspase-3 activity was not induced by 25-hydroxycholesterol. The overall similar profile on mevalonate synthesis inhibition, cell growth inhibition, and apoptosis suggests that apomine acts as a synthetic mimetic of farnesol.