Fowler Stephen, Kletzl Heidemarie, Finel Moshe, Manevski Nenad, Schmid Paul, Tuerck Dietrich, Norcross Roger D, Hoener Marius C, Spleiss Olivia, Iglesias Victor A
Roche Pharma Research and Early Development, Roche Innovation Center Basel, Basel, Switzerland (S.F., H.K., P.S., D.T., R.D.N., M.C.H., O.S., V.A.I.); and Pharmaceutical Chemistry, Faculty of Pharmacy, University of Helsinki, Helsinki, Finland (M.F., N.M.).
Roche Pharma Research and Early Development, Roche Innovation Center Basel, Basel, Switzerland (S.F., H.K., P.S., D.T., R.D.N., M.C.H., O.S., V.A.I.); and Pharmaceutical Chemistry, Faculty of Pharmacy, University of Helsinki, Helsinki, Finland (M.F., N.M.)
J Pharmacol Exp Ther. 2015 Feb;352(2):358-67. doi: 10.1124/jpet.114.220194. Epub 2014 Dec 12.
RO5263397 [(S)-4-(3-fluoro-2-methyl-phenyl)-4,5-dihydro-oxazol-2-ylamine], a new compound that showed promising results in animal models of schizophrenia, is mainly metabolized in humans by N-glucuronidation. Enzyme studies, using the (then) available commercial uridine 5'-diphosphate-glucuronosyltransferases (UGTs), suggested that UGT1A4 is responsible for its conjugation. In the first clinical trial, in which RO5263397 was administered orally to healthy human volunteers, a 136-fold above-average systemic exposure to the parent compound was found in one of the participants. Further administration in this trial identified two more such poor metabolizers, all three of African origin. Additional in vitro studies with recombinant UGTs showed that the contribution of UGT2B10 to RO5263397 glucuronidation is much higher than UGT1A4 at clinically relevant concentrations. DNA sequencing in all of these poor metabolizers identified a previously uncharacterized splice site mutation that prevents assembly of full-length UGT2B10 mRNA and thus functional UGT2B10 protein expression. Further DNA database analyses revealed the UGT2B10 splice site mutation to be highly frequent in individuals of African origin (45%), moderately frequent in Asians (8%) and almost unrepresented in Caucasians (<1%). A prospective study using hepatocytes from 20 individual African donors demonstrated a >100-fold lower intrinsic clearance of RO5263397 in cells homozygous for the splice site variant allele. Our results highlight the need to include UGT2B10 when screening the human UGTs for the enzymes involved in the glucuronidation of a new compound, particularly when there is a possibility of N-glucuronidation. Moreover, this study demonstrates the importance of considering different ethnicities during drug development.
RO5263397 [(S)-4-(3-氟-2-甲基苯基)-4,5-二氢恶唑-2-胺]是一种在精神分裂症动物模型中显示出有前景结果的新化合物,在人体内主要通过N-葡萄糖醛酸化代谢。使用当时可用的商业尿苷5'-二磷酸葡萄糖醛酸转移酶(UGTs)进行的酶研究表明,UGT1A4负责其结合。在第一项临床试验中,将RO5263397口服给予健康人类志愿者,其中一名参与者体内母体化合物的全身暴露量比平均水平高136倍。该试验中的进一步给药又发现了另外两名此类代谢不良者,他们均来自非洲。对重组UGTs进行的额外体外研究表明,在临床相关浓度下,UGT2B10对RO5263397葡萄糖醛酸化的贡献远高于UGT1A4。对所有这些代谢不良者进行的DNA测序发现了一个以前未表征的剪接位点突变,该突变阻止了全长UGT2B10 mRNA的组装,从而阻止了功能性UGT2B10蛋白的表达。进一步的DNA数据库分析显示,UGT2B10剪接位点突变在非洲裔个体中非常常见(45%),在亚洲人中频率适中(8%),而在白种人中几乎不存在(<1%)。一项使用来自20名非洲个体供体的肝细胞进行的前瞻性研究表明,在剪接位点变异等位基因纯合的细胞中,RO5263397的内在清除率降低了100倍以上。我们的结果强调,在筛选参与新化合物葡萄糖醛酸化的人类UGTs时,需要纳入UGT2B10,特别是当存在N-葡萄糖醛酸化可能性时。此外,这项研究证明了在药物开发过程中考虑不同种族因素的重要性。
