Conformation of the HIV-1 Gag Protein in Solution (original) (raw)
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Journal of Molecular Biology, 2011
The retroviral Gag polyprotein mediates viral assembly. The Gag protein has been shown to interact with other Gag proteins, with the viral RNA, and with the cell membrane during the assembly process. Intrinsically disordered regions linking ordered domains make characterization of the protein structure difficult. Through small angle scattering and molecular modeling we have previously shown that monomeric human immunodeficiency virus (HIV-1) Gag protein in solution adopts compact conformations. However, cryo-electron microscopic analysis of immature virions shows that in these particles, HIV-1 Gag protein molecules are rod-shaped. These differing results imply that large changes in Gag conformation are possible and may be required for viral formation. By recapitulating key interactions in the assembly process and characterizing the Gag protein using neutron scattering, we have identified interactions capable of reversibly extending the Gag protein. In addition, we demonstrate advanced applications of neutron reflectivity in resolving Gag conformations on a membrane. Several kinds of evidence show that basic residues found on the distal N & C-terminal domains enable both ends of Gag to bind to either membranes or to nucleic acid. These results, together with other published observations, suggest that simultaneous interactions of a HIV-1 Gag molecule with all three: protein, nucleic acid and membrane, are required for full extension of the protein.
Solution Properties of Murine Leukemia Virus Gag Protein: Differences from HIV-1 Gag
Journal of Virology, 2011
Immature retrovirus particles are assembled from the multidomain Gag protein. In these particles, the Gag proteins are arranged radially as elongated rods. We have previously characterized the properties of HIV-1 Gag in solution. In the absence of nucleic acid, HIV-1 Gag displays moderately weak interprotein interactions, existing in monomer-dimer equilibrium. Neutron scattering and hydrodynamic studies suggest that the protein is compact, and biochemical studies indicate that the two ends can approach close in three-dimensional space, implying the need for a significant conformational change during assembly. We now describe the properties of the Gag protein of Moloney murine leukemia virus (MLV), a gammaretrovirus. We found that this protein is very different from HIV-1 Gag: it has much weaker protein-protein interaction and is predominantly monomeric in solution. This has allowed us to study the protein by small-angle X-ray scattering and to build a low-resolution molecular envelo...
Journal of Virology, 2014
The conformational changes within single HIV-1 Gag molecules that occur during assembly into immature viruses are poorly understood. Using an in vitro assembly assay, it has been proposed that HIV-1 Gag undergoes a conformational transition from a compact conformation in solution to an extended rod-like conformation in virus-like particles (VLPs). Here we used single-molecule Förster resonance energy transfer (smFRET) to test this model by directly probing the conformation of single HIV-1 Gag molecules. We demonstrate that monomeric HIV-1 Gag lacking the p6 domain and the N-terminal myristoyl moiety is found in solution predominantly in a compact conformation. Gag in this conformation, and in the presence of nucleic acid, assembles into 30-nm-diameter particles. However, with the addition of inositol hexakisphosphate, Gag adopts a linear conformation and assembles into full-sized ∼100-to-150-nm-diameter VLPs. Parallel fluorescence correlation spectroscopy measurements show that this...
Interactions between HIV-1 Gag Molecules in Solution: An Inositol Phosphate-mediated Switch
Journal of Molecular Biology, 2007
Retrovirus particle assembly is mediated by the Gag protein. Gag is a multi-domain protein containing discrete domains connected by flexible linkers. When recombinant HIV-1 Gag protein (lacking myristate at its N terminus and the p6 domain at its C terminus) is mixed with nucleic acid, it assembles into virus-like particles (VLPs) in a fully defined system in vitro. However, this assembly is defective in that the radius of curvature of the VLPs is far smaller than that of authentic immature virions. This defect can be corrected to varying degrees by addition of inositol phosphates to the assembly reaction. We have now explored the binding of inositol hexakisphosphate (IP6) to Gag and its effects upon the interactions between Gag protein molecules in solution. Our data indicate that basic regions at both ends of the protein contribute to IP6 binding. Gag is in monomer-dimer equilibrium in solution, and mutation of the previously described dimer interface within its capsid domain drastically reduces Gag dimerization. In contrast, when IP6 is added, Gag is in monomertrimer rather than monomer-dimer equilibrium. The Gag protein with a mutation at the dimer interface also remains almost exclusively monomeric in IP6; thus the "dimer interface" is essential for the trimeric interaction in IP6. We discuss possible explanations for these results, including a change in conformation within the capsid domain induced by the binding of IP6 to other domains within the protein. The participation of both ends of Gag in IP6 interaction suggests that Gag is folded over in solution, with its ends near each other in three-dimensional space; direct support for this conclusion is provided in a companion manuscript. As Gag is an extended rod in immature virions, this apparent proximity of the ends in solution implies that it undergoes a major conformational change during particle assembly.
Journal of Molecular Graphics and Modelling, 2007
One of the main structural features of the mature HIV-1 virion is the matrix protein (p17). This partially globular protein presents four helixes centrally organized and a fifth one, H5, projecting away from the packed bundle of helixes. Comparison between solution and crystallographic data of p17 indicates a 6 Å displacement of a short 3 10 helix and a partial unfolding of H5 in solution related to crystal. While the behavior of the 3 10 helix has been previously addressed to virion assembly, the relevance and origin of H5 partial unfolding is possibly related to the contacts between p17 and other viral elements, such as p24. In this context, we present a 40 ns conformational sampling of monomeric p17 using molecular dynamics simulations. The performed simulations presented a progressive conversion of the p17 crystallographic structure to the NMR conformation, suggesting that the biological form of this protein may have its C-terminal portion partially unfolded.
Structure and Stoichiometry of Template-Directed Recombinant HIV-1 Gag Particles
Journal of Molecular Biology, 2011
Size polydispersity of immature human immunodeficiency virus type 1 particles represents a challenge for traditional methods of biological ultra-structural analysis. An in vitro model for immature HIV-1 particles constructed from recombinant Gag proteins lacking residues 16-99 and the p6 domain assembled around spherical nanoparticles functionalized with DNA. This templatedirected assembly approach led to a significant reduction in size polydispersity and revealed previously unknown structural features of immature-like HIV-1 particles. Electron microscopy and image reconstruction of these particles suggest that the Gag shell formed from different protein regions which are connected by a "scar"-an extended defect connecting the edges of two continuous, regularly packed protein layers. Thus, instead of a holey protein array, the experimental model presented here appears to consist of a continuous array of ~5000 proteins enveloping the core, in which regular regions are separated by extended areas of disorder.
Biological Chemistry, 2000
The central region of the matrix protein p17 of HIV-1 is known to be essential during virus assembly. We substituted alanines for amino acid triplets in this region of p17 (amino acid residues 47 to 55: NPG LLE TSE). Introduction of the respective mutations into the gag-coding sequence of HI-proviruses and subsequent transfection into Cos-7 cells led to particle production and release. Exchange of LLE resulted in the production of non-infectious particles. These residues may be important for correct folding and assembly of the processed matrix protein and the production of infectious HIV. In vitro studies of wild-type and mutated matrix proteins using spectroscopic methods (NMR, fluorescence, CD) yielded detailed data about structure and stability. Two-dimensional NMR spectroscopy showed that wild-type and mutant proteins (p17-NPG and p17-TSE) are well folded. Besides structural changes at the mutated site, chemical shift changes indicate small but significant long range structural rearrangements. The stability against chemically and thermally induced unfolding of the mutants p17-NPG and p17-TSE was slightly decreased, while that of p17-LLE was drastically diminished. The alterations have only a local effect on protein folding for the mutants p17-NPG and p17-TSE, and the globular tertiary structure remains nearly unchanged. For p17-LLE, however, the substitutions seem to trigger significant changes in structural elements.
The Journal of Chemical Physics, 2010
A coarse-grained model is used to study the structure and dynamics of a human immunodeficiency virus-1 protease (1DIFA dimer) consisting of 198 residues in an effective solvent medium on a cubic lattice by Monte Carlo simulations for a range of interaction strengths. Energy and mobility profiles of residues are found to depend on the interaction strength and exhibit remarkable segmental symmetries in two monomers. Lowest energy residues such as Arg41 and Arg140 (most electrostatic and polar) are not the least mobile; despite the higher energy, the hydrophobic residues (Ile, Leu, and Val) are least mobile and form the core by pinning down the local segments for the globular structure. Variations in the gyration radius (Rg) and energy (Ec) of the protein show nonmonotonic dependence on the interaction strength with the smallest Rg around the largest value of Ec. Pinning of the conformations by the hydrophobic residues at high interaction strength seems to provide seed for the protein ...
Biophysical Journal, 2007
The protein CA forms the mature capsid of human immunodeficiency virus. Hexamerization of the N-terminal domain and dimerization of the C-terminal domain, CAC, occur during capsid assembly, and both domains constitute potential targets for anti-HIV inhibitors. CAC homodimerization occurs mainly through its second helix, and is abolished when its sole tryptophan is mutated to alanine. Previous thermodynamic data obtained with the dimeric and monomeric forms of CAC indicate that the structure of the mutant resembles that of a monomeric intermediate found in the folding and association reactions of CAC. We have solved the three-dimensional structure in aqueous solution of the monomeric mutant. The structure is similar to that of the subunits in the dimeric, nonmutated CAC, except the segment corresponding to the second helix, which is highly dynamic. At the end of this region, the polypeptide chain is bent to bury several hydrophobic residues and, as a consequence, the last two helices are rotated 90°when compared to their position in dimeric CAC. The previously obtained thermodynamic data are consistent with the determined structure of the monomeric mutant. This extraordinary ability of CAC to change its structure may contribute to the different modes of association of CA during HIV assembly, and should be taken into account in the design of new drugs against this virus.