Differential phosphoproteome analysis of rat brain regions after organophosphorus compound sarin intoxication.

IF 2.2 4区医学 Q3 TOXICOLOGY

Toxicology Research Pub Date : 2023-03-09 eCollection Date: 2023-04-01 DOI:10.1093/toxres/tfad013

Kalyani Chaubey, Syed Imteyaz Alam, Chandra Kant Waghmare, Bijoy K Bhattacharya

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Abstract

Introduction: Sarin is a highly toxic organophosphorus nerve agent that irreversibly inhibits neuronal enzyme acetylcholinesterase. In the prevailing scenario, it is of paramount importance to develop early diagnosis and medical countermeasures for sarin exposure. A deeper understanding of the molecular mechanism of sarin intoxication and perturbations in the associated cellular processes is likely to provide valuable clues for the elucidation of diagnostic markers and therapeutic targets for sarin exposure.

Methods: Present study, uncovered the changes in phosphorylation patterns of multiple proteins in different rat brain regions after sarin intoxication using 2-DE/MS approach. It provided a holistic view of the phosphorylation-mediated changes in the cellular proteome and highlighted various signaling and response pathways affected at an early time point of sarin intoxication.

Results: We found total 22 proteins in the cortex, 25 proteins in the corpus striatum, and 17 proteins in the hippocampus, showed ≥1.5 fold changes (hyper- or hypo- phosphorylated) with respect to control, either at 2.5 h or 1 d after sarin exposure. These results indicated the differential expression of phosphoproteins involved in protein folding in the endoplasmic reticulum, carbon metabolism, metabolic function, and energy metabolism.

Conclusion: Four candidates (protein disulfide-isomerase A3, heat shock cognate 71 kDa protein, alpha-enolase, and creatine kinase B-type), hyperphosphorylated in all three brain regions, can be further studied to understand the molecular mechanism behind neurodegenerative changes mediated by sarin exposure. The study sheds light on major pathogenic processes initiated during sarin intoxication and provides putative diagnostic markers/therapeutic targets for further validation.

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有机磷化合物沙林中毒后大鼠脑区的差异磷蛋白组分析

简介沙林是一种毒性极强的有机磷神经毒剂，能不可逆地抑制神经元酶乙酰胆碱酯酶。在当前形势下，制定沙林暴露的早期诊断和医疗对策至关重要。深入了解沙林中毒的分子机制和相关细胞过程的扰动，可能会为阐明沙林暴露的诊断标记和治疗目标提供有价值的线索：本研究采用 2-DE/MS 方法揭示了沙林中毒后大鼠不同脑区多种蛋白质磷酸化模式的变化。方法：本研究采用 2-DE/MS 方法揭示了沙林中毒后大鼠不同脑区多种蛋白质磷酸化模式的变化，提供了细胞蛋白质组中磷酸化介导的变化的整体视图，并强调了沙林中毒早期受影响的各种信号和反应途径：结果：我们发现，与对照组相比，在沙林暴露后2.5 h或1 d，大脑皮层共有22种蛋白质、纹状体共有25种蛋白质、海马共有17种蛋白质出现了≥1.5倍的变化（磷酸化水平过高或过低）。这些结果表明，参与内质网蛋白质折叠、碳代谢、新陈代谢功能和能量代谢的磷蛋白表达存在差异：结论：四种候选蛋白（蛋白质二硫化物异构酶 A3、热休克认知 71 kDa 蛋白、α-烯醇化酶和 B 型肌酸激酶）在三个脑区均出现高磷酸化，可对其进行进一步研究，以了解沙林暴露导致神经退行性变化背后的分子机制。这项研究揭示了沙林中毒期间的主要致病过程，并提供了可供进一步验证的诊断标志物/治疗目标。

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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来源期刊

Toxicology Research TOXICOLOGY-

CiteScore

3.60

自引率

0.00%

发文量

期刊介绍： A multi-disciplinary journal covering the best research in both fundamental and applied aspects of toxicology