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两种广泛使用的基于钌的 CO 释放分子与一系列具有重要生物学意义的试剂和分子的化学反应性。

Chemical Reactivities of Two Widely Used Ruthenium-Based CO-Releasing Molecules with a Range of Biologically Important Reagents and Molecules.

机构信息

Department of Chemistry and Center for Diagnostics and Therapeutics, Georgia State University, Atlanta, Georgia 30303, United States.

出版信息

Anal Chem. 2021 Mar 30;93(12):5317-5326. doi: 10.1021/acs.analchem.1c00533. Epub 2021 Mar 21.

DOI:10.1021/acs.analchem.1c00533
PMID:33745269
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8248650/
Abstract

Ruthenium-based CO-releasing molecules (CO-RMs), CORM-2 and CORM-3, have been widely used as surrogates of CO for studying its biological effects and with much success. However, several previous solution-phase and studies have revealed the ability of such CO-RMs to chemically modify proteins and reduce aromatic nitro groups due to their intrinsic chemical reactivity under certain conditions. In our own work of studying the cytoprotective effects of CO donors, we were in need of assessing chemical factors that could impact the interpretation of results from CO donors including CORM-2,3 in various assays. For this, we examined the effects of CORM-2,3 toward representative reagents commonly used in various bioassays including resazurin, tetrazolium salts, nitrites, and azide-based HS probes. We have also examined the effect of CORM-2,3 on glutathione disulfide (GSSG), which is a very important redox regulator. Our studies show the ability of these CO-RMs to induce a number of chemical and/or spectroscopic changes for several commonly used biological reagents under near-physiological conditions. These reactions/spectroscopic changes cannot be duplicated with CO-deleted CO-RMs (iCORMs), which are often used as negative controls. Furthermore, both CORM-2 and -3 are capable of consuming and reducing GSSG in solution. We hope that the results described will help in the future design of control experiments using Ru-based CO-RMs.

摘要

钌基一氧化碳释放分子(CO-RMs),如 CORM-2 和 CORM-3,已被广泛用作 CO 的替代物,用于研究其生物学效应,并取得了很大的成功。然而,一些之前的溶液相和研究揭示了这些 CO-RMs 由于其在某些条件下的固有化学反应性,能够化学修饰蛋白质并还原芳香族硝基基团。在我们研究 CO 供体的细胞保护作用的工作中,我们需要评估可能影响 CO 供体(包括 CORM-2 和 CORM-3)在各种测定中结果解释的化学因素。为此,我们研究了 CORM-2 和 CORM-3 对各种生物测定中常用的代表性试剂的影响,包括 Resazurin、四唑盐、亚硝酸盐和基于叠氮化物的 HS 探针。我们还研究了 CORM-2 和 CORM-3 对谷胱甘肽二硫化物(GSSG)的影响,GSSG 是一种非常重要的氧化还原调节剂。我们的研究表明,这些 CO-RMs 在近生理条件下能够诱导几种常用生物试剂发生许多化学和/或光谱变化。这些反应/光谱变化不能用 CO 缺失的 CO-RMs(iCORMs)复制,iCORMs 通常用作阴性对照。此外,CORM-2 和 CORM-3 都能够在溶液中消耗和还原 GSSG。我们希望描述的结果将有助于未来使用基于 Ru 的 CO-RMs 设计对照实验。

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