在温和pH条件下用铑卡宾对色氨酸进行化学选择性标记。
Chemoselective tryptophan labeling with rhodium carbenoids at mild pH.
作者信息
Antos John M, McFarland Jesse M, Iavarone Anthony T, Francis Matthew B
机构信息
Department of Chemistry, University of California, Berkeley, California 94720-1460, USA.
出版信息
J Am Chem Soc. 2009 May 6;131(17):6301-8. doi: 10.1021/ja900094h.
Abstract
Significant improvements have been made to a previously reported tryptophan modification method using rhodium carbenoids in aqueous solution, allowing the reaction to proceed at pH 6-7. This technique is based on the discovery that N-(tert-butyl)hydroxylamine promotes indole modification with rhodium carbenoids over a broad pH range (2-7). This methodology was demonstrated on peptide and protein substrates, generally yielding 40-60% conversion with excellent tryptophan chemoselectivity. The solvent accessibility of the indole side chains was found to be a key factor in successful carbenoid addition, as demonstrated by conducting the reaction at temperatures high enough to cause thermal denaturation of the protein substrate. Progress toward the expression of proteins bearing solvent accessible tryptophan residues as reactive handles for modification with rhodium carbenoids is also reported.
摘要
对先前报道的在水溶液中使用铑卡宾的色氨酸修饰方法进行了重大改进,使反应能够在pH 6 - 7的条件下进行。该技术基于以下发现:N-(叔丁基)羟胺在较宽的pH范围(2 - 7)内促进铑卡宾对吲哚的修饰。此方法已在肽和蛋白质底物上得到验证,通常能实现40 - 60%的转化率,且具有出色的色氨酸化学选择性。吲哚侧链的溶剂可及性被发现是卡宾成功加成的关键因素,在足以导致蛋白质底物热变性的温度下进行反应就证明了这一点。还报道了在表达带有溶剂可及色氨酸残基的蛋白质作为用铑卡宾进行修饰的反应性手柄方面取得的进展。
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