MurE ligase catalyzes the attachment of meso‐diaminopimelic acid to the UDP‐MurNAc‐l‐Ala‐d‐Glu using ATP and producing UDP‐MurNAc‐l‐Ala‐d‐Glu‐meso‐A2pm during bacterial cell wall biosynthesis. Owing to the critical role of this enzyme, MurE is considered an attractive target for antibacterial drugs. Despite extensive studies on MurE ligase, the structural dynamics of its conformational changes are still elusive. In this study, we present the substrate‐free structure of MurE from Acinetobacter baumannii, which is an antibiotic‐resistant superbacterium that has threatened global public health. The structure revealed that MurE has a wide‐open conformation and undergoes wide‐open, intermediately closed, and fully closed dynamic conformational transition. Unveiling structural dynamics of MurE will help to understand the working mechanism of this ligase and to design next‐generation antibiotics targeting MurE.
Modulation of RNA structure is essential in the life cycle of RNA viruses. Immediate replication upon infection requires RNA unwinding to ensure that RNA templates are not in intra-or intermolecular duplex forms. The calicivirus NS3, one of the highly conserved nonstructural (NS) proteins, has conserved motifs common to helicase superfamily 3 among six genogroups. However, its biological functions are not fully understood. In this study we report the oligomeric state and the nucleotide triphosphatase (NTPase) and RNA chaperone activities of the recombinant full-length NS3 derived from murine norovirus (MNV). The MNV NS3 has an Mg 2+ -dependent NTPase activity, and site-directed mutagenesis of the conserved NTPase motifs blocked enzyme activity and viral replication in cells. Further, the NS3 was found via fluorescence resonance energy transfer (FRET)-based assays to destabilize double-stranded RNA in the presence of Mg 2+ or Mn 2+ in an NTPindependent manner. However, the RNA destabilization activity was not affected by mutagenesis of the conserved motifs of NTPase. These results reveal that the MNV NS3 has an NTPase-independent RNA chaperone-like activity, and that a FRETbased RNA destabilization assay has the potential to identify new antiviral drugs targeting NS3.
Lipid II, the main component of the bacterial cell wall, is synthesized by the addition of UDP-N-acetylglucosamine to the UDP-N-acetylmuramic acid pentapeptide catalyzed by the glycosyltransferase MurG. Owing to its critical role in cell-wall biosynthesis, MurG is considered to be an attractive target for antibacterial agents. Although the Mur family ligases have been extensively studied, the molecular mechanism of the oligomeric scaffolding assembly of MurG remains unclear. In this study, MurG from Acinetobacter baumannii (abMurG), a human pathogen, was characterized and its hexameric crystal structure was unveiled; this is the first homo-oligomeric structure to be described in the MurG family and the Mur family. Homogeneous protein samples were produced for structural studies using size-exclusion chromatography, the absolute molecular mass was calculated via multi-angle light scattering, and protein–protein interactions were analyzed using the PDBePISA server. abMurG was found to form homo-oligomeric complexes in solution, which might serve as functional units for the scaffolding activity of MurG. Furthermore, analysis of this structure revealed the molecular assembly mechanism of MurG. This structural and biochemical study elucidated the homo-oligomerization mechanism of MurG and suggests a new potential antibiotic target on MurG.
Aminoglycoside acetyltransferases (AACs) catalyze the transfer of an acetyl group between acetyl-CoA and an aminoglycoside, producing CoA and an acetylated aminoglycoside. AAC(6′)-Ii enzymes target the amino group linked to the 6′ C atom in an aminoglycoside. Several structures of the AAC(6′)-Ii from Enterococcus faecium [Ef-AAC(6′)-Ii] have been reported to date. However, the detailed mechanism of its enzymatic function remains elusive. In this study, the crystal structure of Ef-AAC(6′)-Ii was determined in a novel substrate-free form. Based on structural analysis, it is proposed that Ef-AAC(6′)-Ii sequentially undergoes conformational selection and induced fit for substrate binding. These results therefore provide a novel viewpoint on the mechanism of action of Ef-AAC(6′)-Ii.
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