Center for Mitochondrial Biology and Medicine, The Key Laboratory of Biomedical Information Engineering of Ministry of Education, School of Life Science and Technology, Xi'an Jiaotong University, Xi'an 710049, China;; Department of Biochemistry, Schulich School of Medicine and Dentistry, Western University, London, Ontario N6A 5C1.
Donnelly Centre for Cellular and Biomolecular Research, 160 College St., Toronto ON M5S 3E1, Canada.
Mol Cell Proteomics. 2019 Feb;18(2):372-382. doi: 10.1074/mcp.RA118.001123. Epub 2018 Nov 27.
Src homology 2 (SH2) domains play an essential role in cellular signal transduction by binding to proteins phosphorylated on Tyr residue. Although Tyr phosphorylation (pY) is a prerequisite for binding for essentially all SH2 domains characterized to date, different SH2 domains prefer specific sequence motifs C-terminal to the pY residue. Because all SH2 domains adopt the same structural fold, it is not well understood how different SH2 domains have acquired the ability to recognize distinct sequence motifs. We have shown previously that the EF and BG loops that connect the secondary structure elements on an SH2 domain dictate its specificity. In this study, we investigated if these surface loops could be engineered to encode diverse specificities. By characterizing a group of SH2 variants selected by different pY peptides from phage-displayed libraries, we show that the EF and BG loops of the Fyn SH2 domain can encode a wide spectrum of specificities, including all three major specificity classes ( + 2, + 3 and + 4) of the SH2 domain family. Furthermore, we found that the specificity of a given variant correlates with the sequence feature of the bait peptide used for its isolation, suggesting that an SH2 domain may acquire specificity by co-evolving with its ligand. Intriguingly, we found that the SH2 variants can employ a variety of different mechanisms to confer the same specificity, suggesting the EF and BG loops are highly flexible and adaptable. Our work provides a plausible mechanism for the SH2 domain to acquire the wide spectrum of specificity observed in nature through loop variation with minimal disturbance to the SH2 fold. It is likely that similar mechanisms may have been employed by other modular interaction domains to generate diversity in specificity.
Src 同源结构域 2(SH2)通过与 Tyr 残基磷酸化的蛋白质结合在细胞信号转导中发挥重要作用。虽然 Tyr 磷酸化(pY)是迄今为止表征的所有 SH2 结构域结合的必要前提,但不同的 SH2 结构域更喜欢 pY 残基 C 末端的特定序列基序。由于所有 SH2 结构域都采用相同的结构折叠,因此尚不清楚不同的 SH2 结构域如何获得识别不同序列基序的能力。我们之前已经表明,连接 SH2 结构域中二级结构元件的 EF 和 BG 环决定了其特异性。在这项研究中,我们研究了这些表面环是否可以被工程化为编码不同的特异性。通过表征从噬菌体展示文库中选择的一组不同 pY 肽的 SH2 变体,我们表明 Fyn SH2 结构域的 EF 和 BG 环可以编码广泛的特异性,包括 SH2 结构域家族的所有三个主要特异性类别(+2、+3 和+4)。此外,我们发现给定变体的特异性与用于其分离的诱饵肽的序列特征相关,这表明 SH2 结构域可能通过与其配体共同进化而获得特异性。有趣的是,我们发现 SH2 变体可以采用多种不同的机制来赋予相同的特异性,这表明 EF 和 BG 环具有高度的灵活性和适应性。我们的工作为 SH2 结构域通过Loop 变化获得自然界中观察到的广泛特异性提供了一种合理的机制,这种机制可能对 SH2 折叠的最小干扰。其他模块化相互作用域可能采用类似的机制来产生特异性的多样性。
