The C terminus of infectious bursal disease virus (IBDV) VP3 encodes a predicted intrinsically disordered region (IDR), which promotes the formation of cytoplasmic puncta and modulates their physical properties

The virus factories (VFs) of infectious bursal disease virus (IBDV) form through liquid-liquid phase separation (LLPS). A major component of the IBDV VF is the nonstructural protein VP3. Here, we predicted the full-length structure of the VP3 monomer and homodimer and employed molecular dynamics simulations to characterize their behavior. We identified the 36 amino acid carboxy(C)-terminus as a highly dynamic intrinsically disordered region (IDR). We then compared the cytoplasmic puncta that were made in the presence of the wild type (wt) VP3 with those made with a VP3 that lacked the C-terminus (VP3ΔC). Using live-cell imaging with fluorescent reporter tagged proteins, we found that VP3ΔC puncta were significantly less numerous (p<0.0001), smaller (p<0.0001), and more irregular in shape than puncta formed in the presence of wt VP3, demonstrating that the VP3 C terminal IDR promoted their formation. Moreover, by fluorescence recovery after photobleaching (FRAP), the VP3ΔC puncta had a significantly reduced mobile fraction (0.29) as compared to full-length VP3 puncta (0.70) (p<0.001), demonstrating that the VP3 C terminal IDR modulated their physical properties. However, the VP3ΔC puncta still exhibited liquid-like fusion events in the cytoplasm and were sensitive to treatment with aliphatic diols. Moreover, VP3 did not form puncta when expressed alone, and the removal of the C terminus did not abolish puncta formation completely. We propose that VP3 forms part of a higher order complex with other biomolecules to drive LLPS, and that the VP3 C terminal IDR modulates the physical properties of the resultant LLPS structures.