9VS3 image
Deposition Date 2025-07-08
Release Date 2026-05-13
Last Version Date 2026-05-27
Entry Detail
PDB ID:
9VS3
Keywords:
Title:
Apo structure of Ebinur lake virus polymerase
Biological Source:
Source Organism(s):
Expression System(s):
Method Details:
Experimental Method:
Resolution:
3.55 Å
Aggregation State:
PARTICLE
Reconstruction Method:
SINGLE PARTICLE
Macromolecular Entities
Structures with similar UniProt ID
Protein Blast
Polymer Type:polypeptide(L)
Molecule:RNA-directed RNA polymerase L
Gene (Uniprot):RdRp
Mutagens:D79A,D92A
Chain IDs:A
Chain Length:2238
Number of Molecules:1
Biological Source:Ebinur lake virus
Ligand Molecules
Primary Citation
Structural basis for RNA synthesis and inhibition of the orthobunyavirus polymerase.
Nat Commun ? ? ? (2026)
PMID: 42140913 DOI: 10.1038/s41467-026-72944-1

Abstact

Orthobunyaviruses are segmented negative-sense RNA viruses that encompass several life-threatening human and animal pathogens. However, no licensed antivirals are currently available. The viral RNA-dependent RNA polymerase (RdRp) is a multi-domain enzyme critical for genome replication and transcription, representing a promising target for antiviral drug development. Here, we establish robust in vitro enzymatic activity assays for the Ebinur Lake virus (EBIV) polymerase and identify suramin, a century-old drug, as an inhibitor of EBIV polymerase. We further determine cryo-EM structures of the EBIV polymerase in apo, elongation, and suramin-bound states. These structures reveal conformational rearrangements of the polymerase during RNA synthesis, including conformational transitions of the prime-and-realign (PR) loop and a unique beta-hairpin that bridges the zinc-binding domain (ZBD) to the RdRp core. The structural observations are correlated with in vitro enzymatic activity and cell-based minireplicon assays. The suramin-bound structure reveals two distinct inhibitory binding sites. One site sterically clashes with the vRNA promoter. The other site directly blocks RNA template strand binding, thereby inhibiting polymerase activity. These findings advance our understanding of orthobunyavirus RNA synthesis mechanisms and offer a structural framework for the rational design and optimization of antiviral drugs.

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Primary Citation of related structures
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