M-X-I Motif of Semliki Forest Virus Capsid Protein Affects Nucleocapsid Assembly

Alphavirus budding is driven by interactions between spike and nucleocapsid proteins at the plasma membrane. The binding motif, Y-X-L, on the spike protein E2 and the corresponding hydrophobic cavity on the capsid protein were described earlier. The spike-binding cavity has also been suggested to bind an internal hydrophobic motif, M113-X-I115, of the capsid protein. In this study we found that replacement of amino acids M113 and I115 with alanines, as single or double mutations, abolished formation of intracellular nucleocapsids. The mutants could still bud efficiently, but the NCs in the released virions were not stable after removal of the membrane and spike protein layer. In addition to wild-type spherical particles, elongated multicored particles were found at the plasma membrane and released from the host cell. We conclude that the internal capsid motif has a biological function in the viral life cycle, especially in assembly of nucleocapsids. We also provide further evidence that alphaviruses may assemble and bud from the plasma membrane in the absence of preformed nucleocapsids

In Vivo Generation and Characterization of a Soluble Form of the Semliki Forest Virus Fusion Protein

During infection of host cells, a number of enveloped animal viruses are known to produce soluble forms of viral membrane glycoproteins lacking the transmembrane domain. The roles of such soluble glycoproteins in viral life cycles are incompletely understood, but in several cases they are believed to modulate host immune response and viral pathogenesis. Semliki Forest virus (SFV) is an enveloped alphavirus that infects cells through low-pH-dependent fusion and buds from the plasma membrane. Fusion is mediated by the E1 subunit of the SFV spike protein. Previous studies described the in vivo generation of E1s, a truncated soluble form of E1, under conditions in which budding is inhibited in mammalian host cells. We have here examined the properties of E1s generation and the biological activity of E1s. E1s cleavage required spike protein transport out of the endoplasmic reticulum and was independent of virus infection. Cell surface E1 efficiently acted as a precursor for E1s. E1s generation was strongly pH dependent in BHK cells, with optimal cleavage at a pH of ≤7.0, conditions that inhibited the budding of SFV but not the budding of the rhabdovirus vesicular stomatitis virus. The pH dependence of E1s production and SFV budding was unaffected by the stability of the spike protein dimer but was a function of the host cell. Similar to the intact virus and in vitro-generated E1 ectodomain, treatment of E1s at low pH in the presence of target membranes triggered specific acid-dependent conformational changes. Thus, under a variety of conditions, SFV-infected cells can produce a soluble form of E1 that is biologically active

Membrane proteins organize a symmetrical virus

Alphaviruses are enveloped icosahedral viruses that mature by budding at the plasma membrane. According to a prevailing model maturation is driven by binding of membrane protein spikes to a preformed nucleocapsid (NC). The T = 4 geometry of the membrane is thought to be imposed by the NC through one-to-one interactions between spike protomers and capsid proteins (CPs). This model is challenged here by a Semliki Forest virus capsid gene mutant. Its CPs cannot assemble into NCs, or its intermediate structures, due to defective CP–CP interactions. Nevertheless, it can use its horizontal spike–spike interactions on membrane surface and vertical spike–CP interactions to make a particle with correct geometry and protein stoichiometry. Thus, our results highlight the direct role of membrane proteins in organizing the icosahedral conformation of alphaviruses