Jia Wang, Shaling Yang, Yi Zhou, Huaxin Cai, Jinrong Feng
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引用次数: 0
Abstract
The DNA damage response (DDR), an evolutionarily conserved surveillance mechanism enabling cells to detect genomic lesions and cell cycle arrest for repair, coordinates genomic stability through key effector kinases. In Candida albicans, our prior work characterized Rad53-mediated transcriptional reprogramming based on the RAD53 deletion strain, establishing its canonical DDR functions. However, Rad53 activation dynamically orchestrates cell cycle synchronization and repair coordination during genotoxic challenge. Investigating cellular modifications resulting from increased Rad53 functionality is essential for a deeper understanding of its regulatory response. To this end, we overexpressed Rad53 revealing its dual regulatory capacity in stress adaptation and developmental plasticity. Global transcriptomic profiling demonstrated that RAD53 overexpression enhances methyl methanesulfonate (MMS) resistance while paradoxically stimulating filamentous growth, accompanied by upregulation of DNA repair/replication genes (RFA3, POL30) and non-canonical DDR targets including cell wall remodeling factors. Comparative analysis of RAD53 deletion and overexpression transcriptomes identified enriched transcription factors, notably Sfl1, Yox1, and Rfx1. In particular, Rfx1 mediated the resistance to genotoxic stress resulting from RAD53 overexpression or deletion. Surprisingly, Rad53 overexpression substantially hindered hyphal formation and virulence, whereas its kinase-dead mutation restored these deficiencies. Notably, Rad53's role in mediating morphogenesis was independent of Rfx1. This multi-modal functionality positions Rad53 as a critical node interfacing genomic stability, developmental plasticity, and pathogenicity in C. albicans. Our study enhances the understanding of the DDR pathway in C. albicans, providing a potential target for treating this fungal pathogen.
期刊介绍:
Virulence is a fully open access peer-reviewed journal. All articles will (if accepted) be available for anyone to read anywhere, at any time immediately on publication.
Virulence is the first international peer-reviewed journal of its kind to focus exclusively on microbial pathogenicity, the infection process and host-pathogen interactions. To address the new infectious challenges, emerging infectious agents and antimicrobial resistance, there is a clear need for interdisciplinary research.
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