Susanna E. Barrett, Song Yin, Peter Jordan, John K. Brunson, Jessica Gordon-Nunez, Gabriella Costa Machado da Cruz, Christopher Rosario, Bethany K. Okada, Kelsey Anderson, Thomas A. Pires, Ruoyang Wang, Diwakar Shukla, Mark J. Burk, Douglas A. Mitchell
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引用次数: 0
摘要
拉索肽是一类天然存在的多种多样的高稳定性分子,它们在动力学上被困在一种独特的 [1]rotaxane 构象中。由于体外酶的稳定性和活性较差,依赖 ATP 的拉索环化酶如何将相对非结构化的底物肽限制为低熵产物一直是个谜。在这项研究中,我们将底物耐受性数据与结构预测、生物信息分析、分子动力学模拟和突变扫描相结合,构建了底物肽在拉索环化酶活性位点中的三维取向模型。通过对多种系统发育不同的拉索环化酶进行合理工程设计,使其接受被野生型酶拒绝的底物,从而验证了预测的肽环化酶分子接触。最后,我们证明了拉索环化酶工程学的实用性,它能产生以前无法获得的变体,与整合素αvβ8紧密结合,而整合素αvβ8是转化生长因子β的主要激活剂,因此是重要的抗癌靶点。
Substrate interactions guide cyclase engineering and lasso peptide diversification
Lasso peptides are a diverse class of naturally occurring, highly stable molecules kinetically trapped in a distinctive [1]rotaxane conformation. How the ATP-dependent lasso cyclase constrains a relatively unstructured substrate peptide into a low entropy product has remained a mystery owing to poor enzyme stability and activity in vitro. In this study, we combined substrate tolerance data with structural predictions, bioinformatic analysis, molecular dynamics simulations and mutational scanning to construct a model for the three-dimensional orientation of the substrate peptide in the lasso cyclase active site. Predicted peptide cyclase molecular contacts were validated by rationally engineering multiple, phylogenetically diverse lasso cyclases to accept substrates rejected by the wild-type enzymes. Finally, we demonstrate the utility of lasso cyclase engineering by robustly producing previously inaccessible variants that tightly bind to integrin αvβ8, which is a primary activator of transforming growth factor β and, thus, an important anti-cancer target.
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