Role of the major homology region in assembly of HIV-1 Gag.

The major homology region (MHR) is a highly conserved sequence in the gag gene of all retroviruses, including HIV-1. Its role in assembly is unknown, but deletion of the motif significantly impairs membrane binding and viral particle formation. To begin characterizing this defect, we have determined the contribution of this region to the energetics of the assembly process. Intrinsic fluorescence studies were conducted to determine the change in free energy associated with membrane and RNA binding using tRNA and large unilamellar vesicles of 1-palmitoyl-2-oleoylphosphatidylserine as models. For the wild-type protein, the change in free energy was within RT [600 cal/(mol.K)] whether Gag binds first to RNA or to the membrane. Thus, the initial binding of Gag can be to either substrate, but in vivo conditions favor initial association to RNA presumably due to its higher local concentration. After establishing the pattern of assembly, we compared the binding energy of Gag(WT) versus the deletion mutant, Gag(Delta)(MHR). Gag(WT) bound to membranes with a 2-fold higher affinity than Gag(Delta)(MHR), and the binding to RNA was similar for the two proteins. Gag prebound to RNA or to membrane exhibited approximately 2-4-fold greater binding affinity than Gag(Delta)(MHR) for binding the membrane or RNA, respectively. Most importantly, the mutant was significantly impaired in its ability to self-associate on RNA or on membrane surfaces. This key role of the MHR in promoting productive protein-protein interactions was also seen in altered amounts of cleavage products and the lack of membrane-bound, RNA-containing replication intermediates in infected cells. These results suggest that Gag first binds to RNA and then assembles into a multimeric complex with a large membrane-binding face that facilitates subsequent membrane binding. Deletion of the MHR disrupts the protein-protein interactions required to complete this process.

Binding of equine infectious anemia virus matrix protein to membrane bilayers involves multiple interactions.

Human immunodeficiency virus (HIV) and equine infectious anemia virus (EIAV) are closely related lentiviruses that infect immune cells, but their pathogenesis differ. Localization to the cytosolic leaflet of the plasma membrane is critical for replication of both viruses. This localization is accomplished through the matrix (MA) domain of the Gag precursor protein. In HIV-1, association of MA to anionic membranes appears to be primarily driven by a linear cluster of basic residues in the MA domain and an N-myristoylation signal. Interestingly, the MA protein of EIAV does not contain either of these signals. To understand which factors could promote EIAV assembly we characterized the membrane binding properties of its MA protein using fluorescence and biochemical methods. We find that EIAV MA exists as a multimer in solution whose protein-protein interactions are destabilized by membrane binding. EIAV MA binds strongly to electrically neutral membranes as well as to negatively charged membranes. Fluorescence quenching and chemical modification techniques, as well as trypsin proteolysis, indicate a different exposure of the EIAV MA Trp residues when bound to the two types of membranes, and EIAV MA proteolysis by trypsin differs when bound to the two types of membranes. Based on these data and the known structures of closely related matrix proteins, we constructed a structural model. This model predicts that EIAV MA binds to negatively charged membranes, but EIAV MA has an additional membrane binding region rich in residues that partition favorably into the membrane headgroup region. This secondary site may play a role in early events of viral infection.