Next Generation Techniques for Determination of Protein-Protein Interactions: Beyond the Crystal Structure.

Q1 Medicine

Current Pathobiology Reports Pub Date : 2019-09-01 Epub Date: 2019-07-01 DOI:10.1007/s40139-019-00198-2

Rachel Carter, Alessandra Luchini, Lance Liotta, Amanda Haymond

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Abstract

Purpose of review: We discuss recent advancements in structural biology methods for investigating sites of protein-protein interactions. We will inform readers outside the field of structural biology about techniques beyond crystallography, and how these different technologies can be utilized for drug development.

Recent findings: Advancements in cryo-electron microscopy (cryoEM) and micro-electron diffraction (microED) may change how we view atomic resolution structural biology, such that well-ordered macrocrystals of protein complexes are not required for interface identification. However, some drug discovery applications, such as lead peptide compound generation, may not require atomic resolution; mass spectrometry techniques can provide an expedited path to generation of lead compounds. New crosslinking compounds, more user-friendly data analysis, and novel protocols such as protein painting can advance drug discovery programs, even in the absence of atomic resolution structural data. Finally, artificial intelligence and machine learning methods, while never truly replacing experimental methods, may provide rational ways to stratify potential druggable regions identified with mass spectrometry into higher and lower priority candidates.

Summary: Electron diffraction of nanocrystals combines the benefits of both x-ray diffraction and cryoEM, and may prove to be the next generation of atomic resolution protein-protein interface identification. However, in situations such as peptide drug discovery, mass spectrometry techniques supported by advancements in computational methods will likely prove sufficient to support drug discovery efforts. In addition, these methods can be significantly faster than any crystallographic or cryoEM methods for identification of interacting regions.

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确定蛋白质-蛋白质相互作用的新一代技术：超越晶体结构

综述的目的：我们讨论了研究蛋白质-蛋白质相互作用位点的结构生物学方法的最新进展。我们将向结构生物学领域以外的读者介绍晶体学以外的技术，以及如何将这些不同的技术用于药物开发：最近的发现：低温电子显微镜（cryoEM）和微电子衍射（microED）技术的进步可能会改变我们对原子分辨率结构生物学的看法，从而使蛋白质复合物的有序宏观晶体不再是界面鉴定的必需品。然而，一些药物发现应用，如先导肽化合物的生成，可能并不需要原子分辨率；质谱技术可以为先导化合物的生成提供一条捷径。即使没有原子分辨率的结构数据，新的交联化合物、更方便用户的数据分析以及蛋白质涂色等新方案也能推进药物发现计划。最后，人工智能和机器学习方法虽然永远无法真正取代实验方法，但可以提供合理的方法，将质谱鉴定出的潜在可用药区域分为优先级较高和优先级较低的候选区域。摘要：纳米晶体电子衍射结合了 X 射线衍射和低温电子显微镜的优点，可能被证明是下一代原子分辨率蛋白质-蛋白质界面鉴定方法。然而，在肽类药物发现等情况下，质谱技术在计算方法进步的支持下很可能被证明足以支持药物发现工作。此外，在识别相互作用区域方面，这些方法比任何晶体学或低温电子显微镜方法都要快得多。

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来源期刊

Current Pathobiology Reports Medicine-Pathology and Forensic Medicine

CiteScore

6.40

自引率

0.00%

发文量

期刊介绍： This journal aims to offer expert review articles on the most important recent research pertaining to biological mechanisms underlying disease, including etiology, pathogenesis, and the clinical manifestations of cellular alteration. By providing clear, insightful, balanced contributions, the journal intends to serve those for whom the elucidation of new techniques and technologies related to pathobiology is essential. We accomplish this aim by appointing international authorities to serve as Section Editors in key subject areas across the field. Section Editors select topics for which leading experts contribute comprehensive review articles that emphasize new developments and recently published papers of major importance, highlighted by annotated reference lists. An Editorial Board of more than 20 internationally diverse members reviews the annual table of contents, ensures that topics include emerging research, and suggests topics of special importance to their country/region. Topics covered may include autophagy, cancer stem cells, induced pluripotential stem cells (iPS cells), inflammation and cancer, matrix pathobiology, miRNA in pathobiology, mitochondrial dysfunction/diseases, and myofibroblast.