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在 native MS 中对蛋白质进行电热超增压:蛋白质等电点、缓冲液和纳喷电喷雾发射器尖端大小的影响。

Electrothermal supercharging of proteins in native MS: effects of protein isoelectric point, buffer, and nanoESI-emitter tip size.

机构信息

Department of Chemistry, University of California, Berkeley, California 94720-1460, USA.

出版信息

Analyst. 2016 Oct 7;141(19):5598-606. doi: 10.1039/c6an01380e. Epub 2016 Jul 21.

DOI:10.1039/c6an01380e
PMID:27441318
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5239670/
Abstract

The extent of charging resulting from electrothermal supercharging for protein ions formed from various buffered aqueous solutions using nanoESI emitters with tip diameters between ∼1.5 μm and ∼310 nm is compared. Charging increases with decreasing tip size for proteins that are positively charged in solution but not for proteins that are negatively charged in solution. These results suggest that Coulombic attraction between positively charged protein molecules and the negatively charged glass surfaces in the tips of the emitters causes destabilization and even unfolding of proteins prior to nanoESI. Coulombic attraction to the negatively charged glass surfaces does not occur for negatively charged proteins and the extent of charging with electrothermal supercharging decreases with decreasing tip size. Smaller droplets are formed with smaller tips, and these droplets have shorter lifetimes for protein unfolding with electrothermal supercharging to occur prior to gaseous ion formation. Results from this study demonstrate simple principles to consider in order to optimize the extent of charging obtained with electrothermal supercharging, which should be useful for obtaining more structural information in tandem mass spectrometry.

摘要

比较了使用尖端直径在 1.5μm 到 310nm 之间的纳喷雾电喷射发射器,从各种缓冲水溶液中形成的蛋白质离子的电热超电荷的程度。对于在溶液中带正电荷的蛋白质,随着尖端尺寸的减小,充电量增加,但对于在溶液中带负电荷的蛋白质,充电量则不会增加。这些结果表明,在纳喷雾电喷射之前,库仑吸引力使带正电荷的蛋白质分子和发射器尖端的带负电荷的玻璃表面不稳定,甚至使蛋白质展开。对于带负电荷的蛋白质,不会发生库仑吸引力到带负电荷的玻璃表面,并且随着尖端尺寸的减小,电热超电荷的充电程度减小。较小的尖端形成较小的液滴,并且这些液滴具有较短的寿命,从而使在形成气相离子之前通过电热超电荷发生蛋白质展开。这项研究的结果证明了一些需要考虑的简单原则,以优化电热超电荷获得的充电程度,这对于串联质谱法获得更多的结构信息应该是有用的。

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