| Literature DB >> 32966796 |
Yinlong Yang1, Yingying Yue2, Nannan Song2, Cuiling Li2, Zenglin Yuan3, Yan Wang4, Yue Ma1, Hui Li1, Fengyu Zhang3, Weiwei Wang2, Haihong Jia2, Peng Li2, Xiaobing Li2, Qi Wang1, Zhe Ding5, Hongjie Dong3, Lichuan Gu3, Bingqing Li6.
Abstract
Sensing stressful conditions and adjusting the cellular metabolism to adapt to the environment are essential activities for bacteria to survive in variable situations. Here, we describe a stress-related protein, YdiU, and characterize YdiU as an enzyme that catalyzes the covalent attachment of uridine-5'-monophosphate to a protein tyrosine/histidine residue, an unusual modification defined as UMPylation. Mn2+ serves as an essential co-factor for YdiU-mediated UMPylation. UTP and Mn2+ binding converts YdiU to an aggregate-prone state facilitating the recruitment of chaperones. The UMPylation of chaperones prevents them from binding co-factors or clients, thereby impairing their function. Consistent with the recent finding that YdiU acts as an AMPylator, we further demonstrate that the self-AMPylation of YdiU padlocks its chaperone-UMPylation activity. A detailed mechanism is proposed based on the crystal structures of Apo-YdiU and YdiU-AMPNPP-Mn2+ and on molecular dynamics simulation models of YdiU-UTP-Mn2+ and YdiU-UTP-peptide. In vivo data demonstrate that YdiU effectively protects Salmonella from stress-induced ATP depletion through UMPylation.Entities:
Keywords: AMPylation; UMPylation; bacterial stress resistence; chaperones; post-translational modification; the YdiU domain
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Year: 2020 PMID: 32966796 DOI: 10.1016/j.celrep.2020.108161
Source DB: PubMed Journal: Cell Rep Impact factor: 9.423