Orsay is the only known virus capable of naturally infecting Caenorhabditis elegans (C. elegans), a key model organism in biological research. The chronic, non-lethal nature of Orsay infection combined with the ease of handling C. elegans provides an excellent opportunity to characterize virus infection in an intact animal. Orsay has a +ssRNA genome of ~6.3 kb with three open reading frames (ORFs) encoding the putative viral RNA polymerase, the viral capsid protein (CP), and a nonstructural protein δ. The δ ORF can also be expressed as a CP-δ fusion protein through ribosomal frameshift. Work from our lab revealed that CP-δ forms a pentameric fiber that is incorporated into the infectious virion. In addition, we have established that the CP-δ head fiber mediates receptor binding and host entry, while the free δ protein is important for nonlytic viral egress. Compared to other viruses, Orsay is unique in having a virion-associated head fiber that is covalently attached to the infectious particle. Our long-term goal is to obtain a comprehensive, molecular understanding of the Orsay life cycle. Previous research on Orsay infection in the field has mostly focused on the host, and therefore there is a major knowledge gap in our understanding of Orsay replication mechanisms from the viral standpoint. The overarching goals of this project are to elucidate the molecular basis of Orsay host entry mediated by the virion- associated CP-δ head fiber. Our proposed research is supported by strong preliminary data: (1) an icosahedrally averaged cryo-electron microscopy (cryo-EM) reconstruction of the Orsay virion shows fiber-like densities at 5- fold symmetry axes; (2) antisera raised against the full-length δ protein can effectively neutralize Orsay; (3) Orsay infection was significantly reduced in fshr-1 mutants and RNAi knock-down worms, but infection could be rescued by overexpressing fshr-1 in intestinal cells. Our research plan consists of three independent but complementary aims. Aim 1 is to generate a high-resolution structure of native Orsay virions with the CP-δ head fiber. We will use cryo-EM to obtain a high-resolution structure of the CP-δ head fiber in situ within the infectious virion, and examine the structure of emptied Orsay particles to determine the role of the CP-δ head fiber in genome release. Aim 2 is to map functional regions of the CP-δ head fiber responsible for host receptor binding. We will determine the role of the δ CTD in receptor binding by testing the ability of different δ truncation mutants to block Orsay infection, and test the neutralization activity of antisera raised against different parts of δ including the δ CTD. Aim 3 is to explore the functional role of FSHR-1 in Orsay entry. We will test for direct interactions between FSHR-1 and Orsay, and determine the impact of FSHR-1 expression in expanding the host cell tropism of Orsay. Our research uses a combination of experimental techniques including cryo-EM, biochemistry, w...