Microchip-Based Structure Determination of Small Proteins Using Cryo-EM

Materials Science eJournal Pub Date : 2020-11-25 DOI:10.2139/ssrn.3737809

Michael A. Casasanta, G. Jonaid, Liam Kaylor, William Y. Luqiu, Maria J. Solares, Mariah Schroen, W. Dearnaley, Jarad J. Wilson, M. Dukes, Deborah F. Kelly

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Abstract

Interest in cryo-Electron Microscopy (EM) imaging has skyrocketed in recent years due to its pristine views of macromolecules and materials. As advances in instrumentation and computing algorithms spurred this progress, there is renewed focus to address specimen-related challenges. Here we contribute a microchip-based toolkit to perform complementary structural and biochemical analysis on low molecular-weight proteins. As a model system, we used the SARS-CoV-2 nucleocapsid (N) protein (48 kDa) due to its stability and important role in therapeutic development. Cryo-EM structures of the N protein monomer revealed a flexible N-terminal “top hat” motif and a helical-rich C-terminal domain. To complement our structural findings, we engineered microchip-based immunoprecipitation assays that led to the discovery of the first antibody binding site on the N protein. The data also facilitated molecular modeling of a variety of pandemic and common cold-related coronavirus proteins. Such insights may guide future pandemic-preparedness protocols through immuno-engineering strategies to mitigate viral outbreaks.

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基于微芯片的小分子蛋白质结构的冷冻电镜测定

近年来，由于其对大分子和材料的原始观点，对低温电子显微镜(EM)成像的兴趣激增。随着仪器和计算算法的进步推动了这一进展，人们重新关注解决与样本相关的挑战。在这里，我们贡献了一个基于微芯片的工具包来执行低分子量蛋白质的互补结构和生化分析。我们使用SARS-CoV-2核衣壳蛋白(48 kDa)作为模型系统，因为它的稳定性和在治疗开发中的重要作用。N蛋白单体的Cryo-EM结构揭示了一个灵活的N端“顶帽”基序和一个富含螺旋的c端结构域。为了补充我们的结构发现，我们设计了基于微芯片的免疫沉淀测定，从而发现了N蛋白上的第一个抗体结合位点。这些数据还促进了各种大流行和普通感冒相关冠状病毒蛋白的分子建模。这些见解可以通过免疫工程策略来指导未来的大流行防备方案，以减轻病毒爆发。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Materials Science eJournal

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