Iván Sánchez-Campillo, and , Juan B. Blanco-Canosa*,
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引用次数: 0
摘要
原生化学连接(NCL)是在水性缓冲液中连接两个未受保护的肽段。其中一个片段具有 C 端 α 硫代酯官能团,第二个片段具有 N 端半胱氨酸。反应机理分为两个步骤:分子间硫醇-硫代酯交换产生瞬时硫代酯,随后分子内 S-N酰基转移产生最终的原生肽键。虽然这一机制已被证实,但瞬时硫代酯的直接观察却一直难以实现,因为分子内的快速重排阻碍了其积累。在这里,使用 α-硫代酯肽可以更快地进行第一反应,及早积累中间体,从而对其进行定量,并对第一和第二步进行动力学监测。结果表明,α-硫酯残基中的立体阻碍与重排速率之间存在相关性。在笨重的残基中,S-N酰基转移对整个反应速率有显著的影响。这一点在缬氨酸中尤为明显,其他类似的 β-支链氨基酸也可能如此。
Kinetic and Mechanistic Studies of Native Chemical Ligation with Phenyl α-Selenoester Peptides
Native chemical ligation (NCL) ligates two unprotected peptides in an aqueous buffer. One of the fragments features a C-terminal α-thioester functional group, and the second bears an N-terminal cysteine. The reaction mechanism depicts two steps: an intermolecular thiol–thioester exchange resulting in a transient thioester, followed by an intramolecular S-to-N acyl shift to yield the final native peptide bond. Although this mechanism is well established, the direct observation of the transient thioester has been elusive because the fast intramolecular rearrangement prevents its accumulation. Here, the use of α-selenoester peptides allows a faster first reaction and an early buildup of the intermediate, enabling its quantification and the kinetic monitoring of the first and second steps. The results show a correlation between the steric hindrance in the α-thioester residue and the rearrangement rate. In bulky residues, the S-to-N acyl shift has a significant contribution to the overall reaction rate. This is particularly notable for valine and likely for other similar β-branched amino acids.