Corey M J, Corey E
Urology Department, University of Washington School of Medicine, Seattle 98195, USA.
Proc Natl Acad Sci U S A. 1996 Oct 15;93(21):11428-34. doi: 10.1073/pnas.93.21.11428.
While the elegance and efficiency of enzymatic catalysis have long tempted chemists and biochemists with reductionist leanings to try to mimic the functions of natural enzymes in much smaller peptides, such efforts have only rarely produced catalysts with biologically interesting properties. However, the advent of genetic engineering and hybridoma technology and the discovery of catalytic RNA have led to new and very promising alternative means of biocatalyst development. Synthetic chemists have also had some success in creating nonpeptide catalysts with certain enzyme-like characteristics, although their rates and specificities are generally much poorer than those exhibited by the best novel biocatalysts based on natural structures. A comparison of the various approaches from theoretical and practical viewpoints is presented. It is suggested that, given our current level of understanding, the most fruitful methods may incorporate both iterative selection strategies and rationally chosen small perturbations, superimposed on frameworks designed by nature.
长期以来,酶催化的优雅性和高效性吸引了倾向于还原论的化学家和生物化学家,他们试图在小得多的肽中模拟天然酶的功能,但这种努力很少能产生具有生物学意义特性的催化剂。然而,基因工程和杂交瘤技术的出现以及催化RNA的发现,带来了生物催化剂开发的新的且非常有前景的替代方法。合成化学家在创造具有某些类似酶特征的非肽催化剂方面也取得了一些成功,尽管它们的速率和特异性通常比基于天然结构的最佳新型生物催化剂所表现出的要差得多。本文从理论和实践的角度对各种方法进行了比较。有人认为,鉴于我们目前的理解水平,最有成效的方法可能是将迭代选择策略和合理选择的小扰动结合起来,并叠加在自然设计的框架上。