化学
蛋白质组学
蛋白质组
半胱氨酸
氧化还原
生物信息学
氧化应激
蛋白质聚集
质谱法
组合化学
计算生物学
生物物理学
纳米技术
生物化学
色谱法
酶
有机化学
生物
基因
材料科学
作者
Ana Martínez‐Val,Samuel Lozano-Juárez,Jorge Lumbreras Burgueño,Ignacio Sacaluga Rodríguez,Marinela Couselo‐Seijas,Ana Simón-Chica,Carlos Galán‐Arriola,Rodrigo Fernández‐Jiménez,Estefanía Núñez,Inmaculada Jorge,David Filgueiras‐Rama,Borja Ibáñez,Jesús Vázquez
标识
DOI:10.1021/acs.analchem.5c03294
摘要
Oxidative damage plays a critical role in various diseases including cardiovascular and neurological disorders. Thiol redox reactions, acting as oxidative stress sensors, influence protein structure and function. Redox proteomics, based on the differential alkylation of cysteine sites followed by mass spectrometry, enables the comprehensive analysis of thiol redox status in cells and tissues. However, these approaches require extensive sample manipulation and are not compatible with data-independent acquisition techniques. Here, we introduce PACREDOX, an innovative strategy based on protein aggregation capture (PAC), and demonstrate its compatibility with library-free DIA. Compared with traditional methods such as FASILOX, PACREDOX reduces preparation time and costs while maintaining thiol and proteome coverage. To enable library-free DIA, we corrected in silico spectral libraries in DIA-NN using experimental retention time data from methylthiolated-Cys peptides. PACREDOX with DIA was benchmarked against FASILOX in a myocardial infarction model, yielding the same biological insights, while enhancing peptide and protein coverage. Our results underscore the potential and efficiency of this methodology for studying oxidative damage. Overall, PACREDOX offers an automatable, high-throughput, and cost-effective strategy for redox proteomics.
科研通智能强力驱动
Strongly Powered by AbleSci AI