Amino acid Mutations at the Interface of Sudan Virus VP40 alter transport and budding

The matrix protein VP40 of orthoebolaviruses coordinates virion release and downregulates viral RNA synthesis through distinct oligomeric states, including dimers, octamers, and filamentous assemblies. To dissect the contributions of two oligomeric interface residues, L117 and W95, in the Sudan virus (SUDV) VP40 (sVP40), we created variants carrying alanine substitutions and assessed their structural and functional properties. sVP40 L117A failed to form dimers and was predominantly monomeric showing increased structural flexibility, reduced thermal stability together with loss of plasma membrane transport, budding activity, and the ability to regulate viral RNA synthesis. VP40 W95A preserved dimerization but also exhibited increased structural flexibility and reduced thermal stability. Functionally, sVP40 W95A more strongly inhibited viral RNA synthesis and markedly enhanced budding. However, in a transcription- and replication-competent virus-like particle (trVLP) assay, trVLPs produced with sVP40 W95A induced substantially reduced reporter activity in target cells, indicating impaired particle infectivity or functionality and suggesting possible defects in minigenome packaging, entry, or early post-entry steps. These results demonstrate that mutations at key oligomerization interfaces exert distinct structural and functional effects and highlight the requirement for precise oligomerization in coordinating sVP40?s dual roles in genome regulation and virion release. By defining the contributions of L117 and W95, this study advances mechanistic understanding of sVP40 function and identifies processes that may serve as targets for antiviral intervention.