Farnesol-derived dicarboxylic acids in the urine of animals treated with zaragozic acid A or with farnesol.

Farnesyl diphosphate, the substrate for squalene synthase, accumulates in the presence of zaragozic acid A, a squalene synthase inhibitor. A possible metabolic fate for farnesyl diphosphate is its conversion to farnesol, then to farnesoic acid, and finally to farnesol-derived dicarboxylic acids (FDDCAs) which would then be excreted in the urine. Seven dicarboxylic acids were isolated by high performance liquid chromatography (HPLC) from urine of either rats or dogs treated with zaragozic acid A or rats fed farnesol. Their structures were determined by nuclear magnetic resonance analysis. Two 12-carbon, four 10-carbon, and one 7-carbon FDDCA were identified. The profile of urinary dicarboxylic acids from rats fed farnesol was virtually identical to that produced by treating with zaragozic acid A, establishing that these dicarboxylic acids are farnesol-derived. By feeding [1-14C]farnesol and comparing the mass of the dicarboxylic acids produced with the ultraviolet absorption of the HPLC peaks, a method to quantitate the ultraviolet-absorbing FDDCAs was devised. When rats were treated with zaragozic acid A, large amounts of FDDCAs were excreted in the urine. The high level of FDDCAs that were found suggests that their synthesis is the major metabolic fate for carbon diverted from cholesterol synthesis by a squalene synthase inhibitor. A metabolic pathway is proposed to explain the production of each of these FDDCAs.

Low-dose simvastatin is a well-tolerated and efficacious cholesterol-lowering agent in ciclosporin-treated kidney transplant recipients: double-blind, randomized, placebo-controlled study in 40 patients.

The high prevalence of hypercholesterolemia in kidney transplant recipients probably contributes to the high cardiovascular mortality in these patients. Except for diet, there is no generally recommended cholesterol-lowering treatment. We conducted a double-blind, randomized, placebo-controlled study with low-dose simvastatin in 40 ciclosporin (CS)-treated kidney transplant recipients during 16 weeks, focusing on side effects and dose finding. In the simvastatin group, the mean serum total and LDL cholesterol concentrations decreased by 23 and 33%, respectively, and the mean serum HDL cholesterol concentration increased by 12%, after 4 weeks of treatment with simvastatin 10 mg daily. Increasing the dose to 20 mg daily in a few patients only resulted in marginal further reductions of the serum cholesterol concentrations at the expense of doubling the plasma simvastatin 3-hydroxy-3-methylglutaryl-coenzyme A reductase inhibitory activity concentrations. The differences between the changes in the serum cholesterol concentrations in the simvastatin group and the negligible changes in the placebo group were statistically significant. There was no case of proximal myopathy and the serum creatine kinase concentrations did not differ between treatment groups. In conclusion, low-dose simvastatin appears to be a well tolerated and efficacious cholesterol-lowering treatment in CS-treated kidney transplant recipients. Simvastatin 10 mg daily seems to be the most suitable dose for the majority of these patients.

3-Hydroxy-3-methylglutaryl-coenzyme a reductase inhibitors. 7. Modification of the hexahydronaphthalene moiety of simvastatin: 5-oxygenated and 5-oxa derivatives.

Modification of the hexahydronaphthalene ring 5-position in simvastatin 2a via oxygenation and oxa replacement afforded two series of derivatives which were evaluated in vitro for inhibition of 3-hydroxy-3-methylglutaryl-coenzyme A reductase and acutely in vivo for oral effectiveness as inhibitors of cholesterogenesis in the rat. Of the compounds selected for further biological evaluation, the 6 beta-methyl-5-oxa 10 and 5 alpha-hydroxy 16 derivatives of 3,4,4a,5-tetrahydro 2a, as well as, the 6 beta-epimer 14 of 16 proved orally active as hypocholesterolemic agents in cholestyramine-primed dogs. Subsequent acute oral metabolism studies in dogs demonstrated that compounds 14 and 16 evoke lower peak plasma drug activity and area-under-the-curve values than does compound 10 and led to the selection of 14 and 16 for toxicological evaluation.

HMG-CoA reductase inhibitor-induced myopathy in the rat: cyclosporine A interaction and mechanism studies.

Recent clinical evidence indicates a potential for skeletal muscle toxicity after therapy with HMG-CoA reductase inhibitors (HMGRIs) in man. Although the incidence of drug-induced skeletal muscle toxicity is very low (0.1-0.2%) with monotherapy, it may increase following concomitant drug therapy with the immunosuppressant, cyclosporine A (CsA), and possibly with certain other hypolipidemic agents. In the Sprague-Dawley rat, very high, pharmacologically comparable dosages (150-1200 mg/kg/day) of structurally similar HMGRIs (lovastatin, simvastatin, pravastatin and L-647, 318) produced dose-related increases in the incidence and severity of skeletal muscle degeneration. Physical signs included inappetence, decreased activity, loss of body weight, localized alopecia and mortality. To evaluate the interaction between HMGRIs and CsA, a rat model of CsA-induced cholestasis was developed. In this 2-week model, the skeletal muscle toxicity of the HMGRIs was clearly potentiated by CsA (10 mg/kg/day). Doses of HMGRIs which did not produce skeletal muscle toxicity when given alone caused between 75 and 100% incidence of myopathy (very slight to marked skeletal muscle degeneration) when CsA was coadministered. Typical light microscopic changes included myofiber necrosis with interstitial edema and inflammatory infiltration in areas of acute injury. Histochemical characterization of the muscle lesion indicated that type 2B fibers (primarily glycolytic white fibers) were most sensitive to this toxicity but that, with prolonged administration, all fiber types were ultimately affected. Results of pharmacokinetic studies in rats treated with various HMGRIs +/- CsA indicated that coadministration of CsA alters the disposition of these compounds, resulting in increased systemic exposure (e.g., increased area under the plasma drug concentration vs. time curve-AUC) and consequent (up to 13-fold) increases in skeletal muscle drug levels. Evaluation of the potential interaction between the HMGRI, lovastatin and CsA at the level of hepatic microsomal metabolism indicated that CsA did not inhibit the metabolism of lovastatin in isolated microsomes from female rats. In light of the above findings, it appears that HMGRI-induced myopathy is a class effect in the rat, which is potentiated by CsA as the result of altered clearance and resultant increased tissue exposure. Cholestasis associated with CsA and HMGRIs may form the basis for decreased elimination and the resultant elevated systemic exposure. Furthermore, this toxicity is muscle fiber-selective and may be associated with impaired skeletal muscle energy metabolism.

Studies on the mechanism of simvastatin-induced thyroid hypertrophy and follicular cell adenoma in the rat.

Female Sprague-Dawley rats were treated with either simvastatin (a novel competitive inhibitor of HMG CoA reductase) or phenobarbital (positive control) to ascertain the possible relationship between the effects of simvastatin on hepatic metabolism and the thyroid hypertrophy and follicular cell adenomas which it produces in this strain of rat. The test compounds were administered orally at doses of 100 mg/kg (divided doses at 50 mg/kg, b.i.d.). (This dose of simvastatin represents approximately 250 times the human dose.) After 5 weeks of treatment, either simvastatin or phenobarbital produced significant increases (35% and 39% above control, respectively) in serum thyroid stimulating hormone (TSH), a significant increase (39% and 120% above control, respectively) in the systemic clearance of 125I-thyroxine, and slight decreases in serum thyroxine levels. Statistically significant increases in liver and thyroid weights were associated with phenobarbital treatment. With simvastatin, increased liver weights occurred. At the microscopic level, thyroid hypertrophy was observed in all phenobarbital-treated rats and to a lesser degree in most simvastatin-treated animals. Simvastatin did not markedly alter liver microsomal enzyme activities with the exception of the anticipated induction of HMG CoA reductase (which increased approximately 4.4-fold). Conversely, phenobarbital produced large increases in liver microsomal enzymes, including glucuronosyl transferase, but did not affect the activity of HMG CoA reductase. Therefore, the increased clearance of thyroxine in simvastatin-treated female rats was not associated with enzyme induction but may have been related to the increase in functional liver mass produced by this compound at this dose.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue selectivity of the cholesterol-lowering agents lovastatin, simvastatin and pravastatin in rats in vivo.

Tissue selectivity of lovastatin, simvastatin and pravastatin was determined in male rats. Peak levels of active drug were found in all tissues examined between 0.5 and 2 hours after oral administration. The area under the curve describing 24 hour exposure of the tissues to drug indicated that the drugs were preferentially concentrated in the liver. However, the concentration of pravastatin was approximately 50% that of either lovastatin or simvastatin in the liver and 3-6 times higher in peripheral tissues. These studies demonstrate that the hydrophobic prodrugs, lovastatin and simvastatin show greater selectivity than the hydrophilic agent pravastatin towards the liver which is the target organ for inhibitors of 3-hydroxy-3-methylglutaryl-coenzyme A reductase.

Toxicity of the HMG-coenzyme A reductase inhibitor, lovastatin, to rabbits.

Lovastatin, a specific inhibitor of the rate-limiting enzyme in cholesterol biosynthesis, HMG-CoA reductase, has been shown to be highly effective in lowering serum cholesterol in animals and humans and thus represents a promising approach to the treatment and prevention of cardiovascular disease. During the preclinical safety assessment of lovastatin, oral doses that were tolerated by dogs, rats and mice were found to be lethal to rabbits in subacute studies. Postmortem findings in rabbits consisted of centrilobular hepatic necrosis, frequently accompanied by renal tubular necrosis and occasionally gallbladder necrosis. The liver lesions were associated with up to 300-fold elevations in serum aspartate and alanine aminotransferase activities, whereas the kidney lesions resulted in accumulations of serum urea nitrogen and creatinine. The organ damage was preceded by a progressive decline in food consumption and loss of body weight. All histopathological and serum biochemical changes induced by lovastatin were completely prevented by coadministration of mevalonate, the product of the inhibited HMG-CoA reductase enzyme. In addition, administration of mevalonate after the onset of lovastatin-induced hepatotoxicity effectively reversed the toxicity despite continued drug treatment. These findings indicated that the toxicity of high doses of lovastatin to rabbits is a consequence of a highly exaggerated pharmacologic action in blocking mevalonate synthesis. However, supplementation of lovastatin-treated rabbits with oral doses of the major product of mevalonate metabolism, cholesterol, paradoxically enhanced the liver and kidney damage, which suggested that the toxicity of lovastatin stemmed from depletion of a nonsterol metabolite(s) of mevalonate critical for cell viability.

Synthesis and structure determination of [8(-13)C]guanosine 5'-diphosphate.

A combined chemical and enzymatic synthesis of [8(-13)C]guanosine 5'-diphosphate (GDP) from H13COOH is described. About 35 mg nucleotide was obtained from 500 mg H13COOH. Analysis of the [8(-13)C]GDP by negative ion fast atom bombardment mass spectrometry and by 13C NMR confirmed that one atom of 13C was incorporated at the 8-position of the guanine ring at 90 +/- 10% enrichment. The chemical shift of the C(8) was 140.2 ppm downfield from internal trimethylsilylpropionate at neutral pH and room temperature, with a spin-spin coupling 1J(13C(8)-H(8] of 217 Hz and a 3J(13C(8)-H(1'] of 3.9 Hz.

A sensitive assay for phosphatidate phosphohydrolase in mouse liver microsomes.

A technique is described for the assay of phosphatidate phosphohydrolase using 1,2-[9,10-3H]dioleoyl-sn-glycero-3-phosphate as a substrate. This substrate was prepared enzymatically using mouse liver microsomes washed with 0.5 M NaCl, which synthesize minimal amounts of neutral lipids at high enzyme concentrations. Measurement of the product, 1,2-[9,10-3H]dioleoylglycerol, was 10-fold more sensitive than the usual colorimetric assay for inorganic phosphate release. In addition, the assay provides information about the relative contribution of other activities which limit the availability of diacylglycerols for further esterification to triacylglycerols and/or phospholipids.

Effect of halofenate and clofibrate on lipid synthesis in rat adipocytes.

The free acids of the plasma lipid-lowering agents, halofenate and clofibrate inhibited the incorporation of radioactive glucose and pyruvate into fatty acids of isolated adipocytes prepared from rat epididymal fat pads. The concentration which inhibited fatty acid synthesis was dependent on the bovine serum albumin concentration in the incubation. The 50 per cent inhibitory concentration of the free acid of halofenate in 1 per cent, 2 percent and 4 per cent albumin was 0.9 mM, 2.3 MM and 4.4 mM, respectively. The potency of clofibrate was also lowered by increasing the albumin concentration. These compounds inhibited the uptake of both [14C]glucose and [14C]pyruvate to the same degree as the incorporation of these substrates into fatty acids. However, the drugs either had no effect on , or stimulated the uptake of palmitate by the cells. Leucine accumulation by the adipocytes was unaffected by halofenate (free acid) and inhibited by clofibrate (free acid). A comparison of these agents with (minus)-hydroxycitrate, kynurenate and cerulenin (inhibitors of ATP-citrate lyase, acetyl CoA carboxylase and fatty acid synthetase, respectively) on the oxidation of pyruvate suggested that they inhibited pyruvate metabolism at or near the enzyme, pyruvate dehydrogenase.

Effect of halofenate and clofibrate on growth and lipid synthesis in Saccharomyces cerevisiae.

Halofenate-free acid (HFA) inhibited the growth of Saccharomyces cerevisiae by 50% at a concentration of 0.34 mm. This inhibitory effect was prevented by addition of either oleate or acetate, but not by pyruvate. When cell growth was supported by oleate, HFA inhibited the incorporation of radioactive carbon from glucose-U-(14)C or pyruvate-2-(14)C into fatty acids and sterols. The incorporation of radioactive carbon into fatty acids and sterols from acetate-2-(14)C was unaffected by the compound. When cell growth was supported by either oleate or acetate, HFA inhibited the conversion of pyruvate-1-(14)C to (14)CO(2). These results suggest that HFA inhibits the conversion of pyruvate to acetate in yeast. Partially purified yeast pyruvate dehydrogenase was inhibited 50% by 5.5 mm HFA; however, the concentration required for 50% inhibition was considerably reduced when the enzyme was preincubated with the compound at room temperature. In a similar manner, the hypolipidemic agent clofibrate-free acid inhibited the growth of yeast by 50% at 3.0 mm. This inhibition was also prevented by acetate and not by pyruvate. In addition, clofibrate-free acid inhibited partially purified pyruvate dehydrogenase by 50% at a concentration of 37.0 mm.