Glucuronidation of Statins in Animals and Humans: A Novel Mechanism of Statin Lactonization
ABSTRACT:The active forms of all marketed hydroxymethylglutaryl (HMG)-CoA reductase inhibitors share a common dihydroxy heptanoic or heptenoic acid side chain. In this study, we present evidence for the formation of acyl glucuronide conjugates of the hydroxy acid forms of simvastatin (SVA), atorvastatin (AVA), and cerivastatin (CVA) in rat, dog, and human liver preparations in vitro and for the excretion of the acyl glucuronide of SVA in dog bile and urine. Upon incubation of each statin (SVA, CVA or AVA) with liver microsomal preparations supplemented with UDP-glucuronic acid, two major products were detected. Based on analysis by high-pressure liquid chromatography, UV spectroscopy, and/or liquid chromatography (LC)-mass spectrometry analysis, these metabolites were identified as a glucuronide conjugate of the hydroxy acid form of the statin and the corresponding ␦-lactone.
ABSTRACT:This study investigated the metabolic interaction between fibrates and statin hydroxy acids in human hepatocytes. Gemfibrozil (GFZ) modestly affected the formation of -oxidative products and CYP3A4-mediated oxidative metabolites of simvastatin hydroxy acid (SVA) but markedly inhibited the glucuronidation-mediated lactonization of SVA and the glucuronidation of a -oxidation product (IC 50 ϳ50 and 15 M, respectively). In contrast, fenofibrate had a minimal effect on all the metabolic pathways of SVA. GFZ also significantly inhibited (IC 50 ϳ50-60 M) the oxidation of cerivastatin (CVA) and rosuvastatin (RVA), but not of atorvastatin (AVA), while effectively decreasing (IC 50 ϳ30 to 60 M) the lactonization of all three statins. As was observed previously with other statin hydroxy acids, RVA underwent significant glucuronidation to form an acyl glucuronide conjugate and lactonization to form RVA lactone in human liver microsomes and by UGT 1A1 and 1A3. While GFZ is not an inhibitor of CYP3A4, it is a competitive inhibitor (K i ؍ 87 M) of CYP2C8, a major catalyzing enzyme for CVA oxidation. These results suggest that 1) the pharmacokinetic interaction observed between GFZ and statins was not likely mediated by the inhibitory effect of GFZ on the -oxidation, but rather by its effect primarily on the glucuronidation and non-CYP3A-mediated oxidation of statin hydroxy acids, and 2) there is a potential difference between fibrates in their ability to affect the pharmacokinetics of statins, and among statins in their susceptibility to metabolic interactions with GFZ in humans.Fibrates, lipid-regulating agents, and hydroxymethylglutaryl-coenzyme A reductase inhibitors or so called "statins", cholesterol lowering agents, are frequently prescribed together to treat patients with mixed hyperlipidemia (Shek and Ferrill, 2001). There have been reports of increased risk of myopathy, including rhabdomyolysis with this coadministration (Murdock et al., 1999). Despite being generally accepted as a class effect for all fibrate-statin combinations, this increased risk has been observed at varied incidences with different fibrates and statins. More documented cases for myopathy have been reported with gemfibrozil (GFZ 1 )-statin combined therapy than with other fibrate-statin combinations (Shek and Ferrill, 2001). Recently, cerivastatin (CVA) was withdrawn from the market due to disproportionate numbers of fatal rhabdomyolysis cases (compared with other marketed statins), many of which occurred in patients receiving concomitant GFZ (Farmer, 2001).Although it has generally been accepted that the increased risk of myopathy is due primarily to a pharmacodynamic drug-drug interaction, recent studies have suggested that the increased risk might also have a pharmacokinetic origin. In recent clinical studies, increases in the exposure mainly to statin hydroxy acids, but minimally to the lactone form of statins, were observed following coadministration of GFZ and statins (Backman et al., 2000;Kyrklund et al., 2001). Subsequently, ...
A series of studies were conducted to explore the mechanism of the pharmacokinetic interaction between simvastatin (SV) and gemfibrozil (GFZ) reported recently in human subjects. After administration of a single dose of SV (4 mg/kg p.o.) to dogs pretreated with GFZ (75 mg/kg p.o., twice daily for 5 days), there was an increase (ϳ4-fold) in systemic exposure to simvastatin hydroxy acid (SVA), but not to SV, similar to the observation in humans. GFZ pretreatment did not increase the ex vivo hydrolysis of SV to SVA in dog plasma. In dog and human liver microsomes, GFZ exerted a minimal inhibitory effect on CYP3A-mediated SVA oxidation, but did inhibit SVA glucuronidation. After i.v. administration of [14 C]SVA to dogs, GFZ treatment significantly reduced (2-3-fold) the plasma clearance of SVA and the biliary excretion of SVA glucuronide (together with its cyclization product SV), but not the excretion of a major oxidative metabolite of SVA, consistent with the in vitro findings in dogs. Among six human UGT isozymes tested, UGT1A1 and 1A3 were capable of catalyzing the glucuronidation of both GFZ and SVA. Further studies conducted in human liver microsomes with atorvastatin (AVA) showed that, as with SVA, GFZ was a less potent inhibitor of the CYP3A4-mediated oxidation of this drug than its glucuronidation. However, with cerivastatin (CVA), the glucuronidation as well as the CYP2C8-and CYP3A4-mediated oxidation pathways were much more susceptible to inhibition by GFZ than was observed with SVA or AVA. Collectively, the results of these studies provide metabolic insight into the nature of drug-drug interaction between GFZ and statins, and a possible explanation for the enhanced susceptibility of CVA to interactions with GFZ.
To determine whether 1,25-dihydroxyvitamin D (1,25(OH) 2 D) can exert an anti-osteoporosis role through anti-aging mechanisms, we analyzed the bone phenotype of mice with 1,25(OH) 2 D deficiency due to deletion of the enzyme, 25-hydroxyvitamin D 1α-hydroxylase, while on a rescue diet. 1,25(OH) 2 D deficiency accelerated age-related bone loss by activating the p16/p19 senescence signaling pathway, inhibiting osteoblastic bone formation, and stimulating osteoclastic bone resorption, osteocyte senescence, and senescence-associated secretory phenotype (SASP).Supplementation of exogenous 1,25(OH) 2 D 3 corrected the osteoporotic phenotype caused by 1,25(OH) 2 D deficiency or natural aging by inhibiting the p16/p19 pathway.The proliferation, osteogenic differentiation, and ectopic bone formation of bone marrow mesenchymal stem cells derived from mice with genetically induced deficiency of the vitamin D receptor (VDR) were significantly reduced by mechanisms including increased oxidative stress, DNA damage, and cellular senescence. We also demonstrated that p16 deletion largely rescued the osteoporotic phenotype caused by 1,25(OH) 2 D 3 deficiency, whereas 1,25(OH) 2 D 3 could up-regulate the enzyme Ezh2 via VDR-mediated transcription thereby enriching H3K27me3 and repressing p16/p19 transcription. Finally, we demonstrated that treatment with 1,25(OH) 2 D 3 improved the osteogenic defects of human BM-MSCs caused by repeated passages by stimulating their proliferation and inhibiting their senescence via the VDR-Ezh2-p16 axis. The results of this study therefore indicate that 1,25(OH) 2 D 3 plays a role in preventing age-related osteoporosis by up-regulating Ezh2 via VDR-mediated transcription, increasing H3K27me3 and repressing p16 transcription, thus promoting the proliferation and osteogenesis of BM-MSCs and inhibiting their senescence, while also stimulating osteoblastic bone formation, and inhibiting osteocyte senescence, SASP, and osteoclastic bone resorption. K E Y W O R D Scellular senescence, Ezh2, osteogenesis, osteoporosis, p16, Vitamin D
The mechanisms by which thymosin β 4 (Tβ(4)) regulates the inflammatory response to injury are poorly understood. Previously, we demonstrated that ectopic Tβ(4) treatment inhibits injury-induced proinflammatory cytokine and chemokine production. We have also shown that Tβ(4) suppresses TNF-α-mediated NF-κB activation. Herein, we present novel evidence that Tβ(4) directly targets the NF-κB RelA/p65 subunit. We find that enforced expression of Tβ(4) interferes with TNF-α-mediated NF-κB activation, as well as downstream IL-8 gene transcription. These activities are independent of the G-actin-binding properties of Tβ(4). Tβ(4) blocks RelA/p65 nuclear translocation and targeting to the cognate κB site in the proximal region of the IL-8 gene promoter. Tβ(4) also inhibits the sensitizing effects of its intracellular binding partners, PINCH-1 and ILK, on NF-κB activity after TNF-α stimulation. The identification of a functional regulatory role by Tβ(4) and the focal adhesion proteins PINCH-1 and ILK on NF-κB activity in this study opens a new window for scientific exploration of how Tβ(4) modulates inflammation. In addition, the results of this study serve as a foundation for developing Tβ(4) as a new anti-inflammatory therapy.
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