Gao Tianwen, Hao Wanshan, Gao Jin, Sun Yiyang, Sun Yukang, Yang Jieyu, Cheng Kaiying
Zhejiang Key Laboratory of Medical Epigenetics, Department of Immunology and Pathogen Biology, School of Basic Medical Sciences, Affiliated Hospital of Hangzhou Normal University, Hangzhou Normal University, Hangzhou, Zhejiang, China.
State Key Laboratory for Diagnosis and Treatment of Infectious Diseases, The First Affiliated Hospital, College of Medicine, Zhejiang University, Hangzhou, Zhejiang, China.
mBio. 2025 Jun 30:e0088425. doi: 10.1128/mbio.00884-25.
Damage-inducible gene G (DinG), a bacterial homolog of SF2 helicase, has been extensively studied in . However, the structural and functional characteristics of DinG homologs fused with an N-terminal 3'-5' exonuclease domain, such as DinG (SaDinG), remain unexplored. In this study, we demonstrate that SaDinG possesses 3'-5' exonuclease activity and exhibits 5'-3' helicase activity on diverse DNA substrates, including splayed duplexes, 5'-overhangs, double flaps, bubbles, and gapped duplexes, resolving prior ambiguities about its biochemical functions. Intriguingly, both enzymatic activities were inhibited by elevated ATP concentrations, suggesting a potential ATP-dependent regulatory mechanism . We determined the crystal structures of SaDinG bound to ssDNA at ~3.2 Å resolution and identified key residues essential for its helicase and exonuclease activities through mutational analysis. Phenotypic studies revealed that a SaDinG deletion mutant exhibited heightened sensitivity to DNA crosslinking agents (mitomycin C and formaldehyde) but retained wild-type susceptibility to other DNA-damaging compounds. Complementation with either nuclease-dead or helicase-dead variants failed to restore crosslink resistance, indicating that both activities are indispensable for DNA crosslink repair. These results support a model in which SaDinG functions as a coordinated nuclease-helicase machine specifically adapted for DNA crosslink repair, with its dual enzymatic activities being tightly regulated by physiological ATP concentrations.
DNA helicases and exonucleases play essential roles in genome maintenance; however, little is known about bacterial helicase-exonuclease fusion proteins. This study examines DNA helicases and exonucleases that play essential roles in genome maintenance; however, little is known about bacterial helicase-exonuclease fusion proteins. This study provides the first structural and functional characterization of DinG (SaDinG), a unique enzyme that combines 5'-3' helicase and 3'-5' exonuclease activities. Our findings resolve previous uncertainties about SaDinG's function and reveal an ATP-dependent regulatory mechanism that modulates its activity. Additionally, we demonstrate that SaDinG is critical for bacterial resistance to DNA crosslinking agents. These insights not only expand our understanding of bacterial DNA repair but also suggest potential avenues for targeting DinG-like enzymes in antimicrobial strategies. Given the growing concerns over antibiotic resistance, understanding how bacteria maintain genome integrity under stress conditions is crucial. This work lays the foundation for further exploration of bacterial helicase-exonuclease systems and their role in genome stability and adaptive survival.
损伤诱导基因G(DinG)是SF2解旋酶的细菌同源物,已在……中得到广泛研究。然而,与N端3'-5'核酸外切酶结构域融合的DinG同源物的结构和功能特性,如DinG(SaDinG),仍未被探索。在本研究中,我们证明SaDinG具有3'-5'核酸外切酶活性,并在多种DNA底物上表现出5'-3'解旋酶活性,包括展开的双链体、5'-突出端、双瓣结构、气泡结构和有缺口的双链体,解决了此前关于其生化功能的模糊之处。有趣的是,两种酶活性均受到ATP浓度升高的抑制,提示存在潜在的ATP依赖性调节机制。我们以约3.2 Å的分辨率确定了与单链DNA结合的SaDinG的晶体结构,并通过突变分析确定了其解旋酶和核酸外切酶活性所必需的关键残基。表型研究表明,SaDinG缺失突变体对DNA交联剂(丝裂霉素C和甲醛)表现出更高的敏感性,但对其他DNA损伤化合物仍保持野生型敏感性。用核酸酶失活或解旋酶失活变体进行互补均未能恢复交联抗性,表明两种活性对于DNA交联修复都是不可或缺的。这些结果支持了一个模型,其中SaDinG作为一种协同的核酸酶-解旋酶机器,专门适应于DNA交联修复,其双重酶活性受到生理ATP浓度的严格调节。
DNA解旋酶和核酸外切酶在基因组维持中起重要作用;然而,对于细菌解旋酶-核酸外切酶融合蛋白知之甚少。本研究对在基因组维持中起重要作用的DNA解旋酶和核酸外切酶进行了研究;然而,对于细菌解旋酶-核酸外切酶融合蛋白知之甚少。本研究首次对DinG(SaDinG)进行了结构和功能表征,DinG是一种独特的酶,兼具5'-3'解旋酶和3'-5'核酸外切酶活性。我们的发现解决了此前关于SaDinG功能的不确定性,并揭示了一种调节其活性的ATP依赖性调节机制。此外,我们证明SaDinG对于细菌抵抗DNA交联剂至关重要。这些见解不仅扩展了我们对细菌DNA修复的理解,还为在抗菌策略中靶向DinG样酶提供了潜在途径。鉴于对抗生素耐药性的日益关注,了解细菌在应激条件下如何维持基因组完整性至关重要。这项工作为进一步探索细菌解旋酶-核酸外切酶系统及其在基因组稳定性和适应性生存中的作用奠定了基础。
