Abstract
HIV-1 Gag is a large multidomain poly-protein with flexible unstructured linkers connecting its globular subdomains. It is compact when in solution but assumes an extended conformation when assembled within the immature HIV-1 virion. Here, we use molecular dynamics (MD) simulations to quantitatively characterize the intra-domain interactions of HIV-1 Gag. We find that the matrix (MA) domain and the C-terminal subdomain CActd of the CA capsid domain can form a bound state. The bound state, which is held together primarily by interactions between complementary charged and polar residues, stabilizes the compact state of HIV-1 Gag. We calculate the depth of the attractive free energy potential between the MA/ CActd sites and find it to be about three times larger than the dimerization interaction between the CActd domains. Sequence analysis shows high conservation within the newly-found intra-Gag MA/CActd binding site, as well as its spatial proximity to other well known elements of Gag –such as CActd’s SP1 helix region, its inositol hexaphosphate (IP6) binding site and major homology region (MHR), as well as the MA trimerization site. Our results point to a high, but yet undetermined, functional significance of the intra-Gag binding site. Recent biophysical experiments that address the binding specificity of Gag are interpreted in the context of the MA/CActd bound state, suggesting an important role in selective packaging of genomic RNA by Gag.
Highlights
Despite intense research efforts, important aspects of the life-cycle of the HIV-1 virus are not understood
Specific inter-domain interactions stabilize a compact HIV-1 Gag conformation below on MA/CActd interaction and on CActd WM-dimeric interaction support the first but not the second hypothesis: we found a novel MA/CActd binding site different from the WM dimerization one, of predominantly electrostatic character, and that such intra-Gag interaction is significantly stronger than the WM-mediated CActd dimerization
As input to each of the protein-protein interaction (PPI) algorithms, we provided the bound MA/CActd structure obtained from pydock and confirmed to be bound after 25 ns of molecular dynamics (MD) simulation; such structure was supplemented with the missing hydrogen atoms in the source Protein Data Bank (PDB) files
Summary
Important aspects of the life-cycle of the HIV-1 virus are not understood. One of these unresolved issues concerns the initiation of the assembly of the capsid of HIV-1 virus particles ( known as virions) [1].
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