Understanding the mechanism of asymmetric gene regulation determined by the VqmA of vibriophage.

The quorum-sensing (QS) system between the phages and their hosts is important for the phage lysis-lysogeny decision. In Vibrio cholerae, the QS system consists of a LuxR-type receptor VqmA (VqmAVc) and an autoinducer molecule 3,5-dimethylpyrazin-2-ol (DPO). A VqmA homolog encoded by vibriophage VP882 (VqmAPhage) can intervene the host QS system via binding to both the host-produced DPO and its cognate promoter (Pqtip) to induce the phage lysogeny-to-lysis transition, whereas VqmAVc cannot influence the VqmAPhage-induced pathway, suggesting an asymmetry regulation. In this study, we report the crystal structure of VqmAPhage-DPO complex at 2.65 Å and reveal that the mechanism of DPO recognition is conserved in VqmA homologs. Besides, we identify a non-classical palindrome sequence in Pqtip, which can be effectively recognized by VqmAPhage but not VqmAVc. The sequence contains an interval longer than that in the vqmR promoter recognized by VqmAVc. In addition, the two DBD regions in the VqmAPhage dimer exhibit more relaxed architecture than that of the reported VqmAVc, which is likely to be in the conformation that may easily bind to target promoter containing a longer interval. In summary, our findings provide a structural and biochemical basis for the DBD-dependent DNA recognition in different promoter regions in the phage lysogeny-to-lysis decision communication system, and provide clues for developing phage therapies against Vibrio cholerae infection.

Molecular mechanism governing RNA-binding property of mammalian TRIM71 protein.

TRIM71 is an RNA-binding protein with ubiquitin ligase activity. Numerous functions of mammalian TRIM71, including cell cycle regulation, embryonic stem cell (ESC) self-renewal, and reprogramming of pluripotent stem cells, are related to its RNA-binding property. We previously reported that a long noncoding RNA (lncRNA) Trincr1 interacts with mouse TRIM71 (mTRIM71) to repress FGF/ERK pathway in mouse ESCs (mESCs). Herein, we identify an RNA motif specifically recognized by mTRIM71 from Trincr1 RNA, and solve the crystal structure of the NHL domain of mTRIM71 complexed with the RNA motif. Similar to the zebrafish TRIM71, mTRIM71 binds to a stem-loop structured RNA fragment of Trincr1, and an adenosine base at the loop region is crucial for the mTRIM71 interaction. We map similar hairpin RNAs preferably bound by TRIM71 in the mRNA UTRs of the cell-cycle related genes regulated by TRIM71. Furthermore, we identify key residues of mTRIM71, conserved among mammalian TRIM71 proteins, required for the RNA-binding property. Single-site mutations of these residues significantly impair the binding of TRIM71 to hairpin RNAs in vitro and to mRNAs of Cdkn1a/p21 and Rbl2/p130 in mESCs. Furthermore, congenital hydrocephalus (CH) specific mutation of mTRIM71 impair its binding to the RNA targets as well. These results reveal molecular mechanism behind the recognition of RNA by mammalian TRIM71 and provide insights into TRIM71 related diseases.