4-酮脯氨酸：一种用于生物共轭的亲电脯氨酸类似物。

4-ketoproline: An electrophilic proline analog for bioconjugation.

作者信息

Choudhary Amit, Kamer Kimberli J, Shoulders Matthew D, Raines Ronald T

机构信息

Graduate Program in Biophysics, University of Wisconsin-Madison, Madison, WI.

出版信息

Biopolymers. 2015 Mar;104(2):110-5. doi: 10.1002/bip.22620.

DOI:10.1002/bip.22620

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4376587/

Abstract

Installing an electrophilic amino-acid residue can engender a peptide or protein with chemoselective reactivity. Such a modification to collagen, which is the most abundant protein in animals, could facilitate the development of new biomaterials. Collagen has an abundance of proline-like residues. Here, we report on the incorporation of an electrophilic proline congener, (2S)-4-ketoproline (Kep), into a collagen-mimetic peptide (CMP). An ab initio conformational analysis of Kep revealed its potential to be accommodated within a collagen triple helix. A synthetic CMP containing a Kep residue was indeed able to form a stable triple helix. Moreover, the condensation of its carbonyl group with aminooxy-biotin did not compromise the conformational stability of the triple helix. These data encourage the use of 4-ketoproline as an electrophilic congener of proline.

摘要

引入亲电氨基酸残基能够赋予肽或蛋白质化学选择性反应活性。对动物体内最为丰富的蛋白质——胶原蛋白进行这样的修饰，可能会促进新型生物材料的开发。胶原蛋白含有大量脯氨酸样残基。在此，我们报道了将亲电脯氨酸类似物（2S）-4-酮脯氨酸（Kep）掺入模拟胶原蛋白肽（CMP）的情况。对Kep进行的从头构象分析表明，它有潜力被容纳在胶原蛋白三螺旋结构中。含有Kep残基的合成CMP确实能够形成稳定的三螺旋结构。此外，其羰基与氨氧基生物素的缩合反应并未损害三螺旋结构的构象稳定性。这些数据促使人们将4-酮脯氨酸用作脯氨酸的亲电类似物。

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