Lin C H, Hoffman T Z, Wirsching P, Barbas C F, Janda K D, Lerner R A
Department of Chemistry, The Scripps Research Institute and The Skaggs Institute for Chemical Biology, 10550 North Torrey Pines Road, La Jolla, CA 92037, USA.
Proc Natl Acad Sci U S A. 1997 Oct 28;94(22):11773-6. doi: 10.1073/pnas.94.22.11773.
Reactive immunization has emerged as a new tool for the study of biological catalysis. A powerful application resulted in catalytic antibodies that use an enamine mechanism akin to that used by the class I aldolases. With regard to the evolution of enzyme mechanisms, we investigated the utility of an enamine pathway for the allylic rearrangement exemplified by Delta5-3-ketosteroid isomerase (KSI; EC 5.3.3.1). Our aldolase antibodies were found to catalyze the isomerization of both steroid model compounds and steroids. The kinetic and chemical studies showed that the antibodies afforded rate accelerations up to a factor of 10(4) by means of an enamine mechanism in which imine formation was the rate-determining step. In light of our observations and the enzyme studies by other workers, we suggest that an enamine pathway could have been an early, viable KSI mechanism. Although this pathway is amenable to optimization for increased catalytic power, it appears that certain factors precluded its evolution in known KSI enzymes.
反应性免疫法已成为研究生物催化的一种新工具。一项重要应用产生了催化抗体,其使用类似于I类醛缩酶的烯胺机制。关于酶机制的进化,我们研究了烯胺途径在以Δ5-3-酮类固醇异构酶(KSI;EC 5.3.3.1)为例的烯丙基重排中的效用。我们发现醛缩酶抗体能催化类固醇模型化合物和类固醇的异构化。动力学和化学研究表明,抗体通过烯胺机制使反应速率加快了10^4倍,其中亚胺形成是速率决定步骤。根据我们的观察以及其他研究人员对该酶的研究,我们认为烯胺途径可能是早期可行的KSI机制。尽管该途径可通过优化来提高催化能力,但似乎某些因素阻碍了它在已知KSI酶中的进化。