Point mutations in the HIV-1 matrix protein turn off the myristyl switch

During the late phase of human immunodeficiency virus type-1 (HIV-1) replication, newly synthesized retroviral Gag proteins are targeted to lipid raft regions of specific cellular membranes, where they assemble and bud to form new virus particles. Gag binds preferentially to the plasma membrane (PM) of most hematopoietic cell types, a process mediated by interactions between the cellular PM marker phosphatidylinositol-(4,5)-bisphosphate (PI(4,5)P(2)) and Gag's N-terminally myristoylated matrix (MA) domain. We recently demonstrated that PI(4,5)P(2) binds to a conserved cleft on MA and promotes myristate exposure, suggesting a role as both a direct membrane anchor and myristyl switch trigger. Here we show that PI(4,5)P(2) is also capable of binding to MA proteins containing point mutations that inhibit membrane binding in vitro, and in vivo, including V7R, L8A and L8I. However, these mutants do not exhibit PI(4,5)P(2) or concentration-dependent myristate exposure. NMR studies of V7R and L8A MA reveal minor structural changes that appear to be responsible for stabilizing the myristate-sequestered (myr(s)) species and inhibiting exposure. Unexpectedly, the myristyl group of a revertant mutant with normal PM targeting properties (V7R,L21K) is also tightly sequestered and insensitive to PI(4,5)P(2) binding. This mutant binds PI(4,5)P(2) with twofold higher affinity compared with the native protein, suggesting a potential compensatory mechanism for membrane binding.     

Structure of the myristylated human immunodeficiency virus type 2 matrix protein and the role of phosphatidylinositol-(4,5)-bisphosphate in membrane targeting

During the late phase of retroviral replication, newly synthesized Gag proteins are targeted to the plasma membrane (PM), where they assemble and bud to form immature virus particles. Membrane targeting by human immunodeficiency virus type 1 (HIV-1) Gag is mediated by the PM marker molecule phosphatidylinositol-(4,5)-bisphosphate [PI(4,5)P₂], which is capable of binding to the matrix (MA) domain of Gag in an extended lipid conformation and of triggering myristate exposure. Here, we show that, as observed previously for HIV-1 MA, the myristyl group of HIV-2 MA is partially sequestered within a narrow hydrophobic tunnel formed by side chains of helices 1, 2, 3, and 5. However, the myristate of HIV-2 MA is more tightly sequestered than that of the HIV-1 protein and does not exhibit concentration-dependent exposure. Soluble PI(4,5)P₂ analogs containing truncated acyl chains bind HIV-2 MA and induce minor long-range structural changes but do not trigger myristate exposure. Despite these differences, the site of HIV-2 assembly in vivo can be manipulated by enzymes that regulate PI(4,5)P₂ localization. Our findings indicate that HIV-1 and HIV-2 are both targeted to the PM for assembly via a PI(4,5)P₂-dependent mechanism, despite differences in the sensitivity of the MA myristyl switch, and suggest a potential mechanism that may contribute to the poor replication kinetics of HIV-2.     

Efficient HIV-1 replication can occur in the absence of the viral matrix protein.

Matrix (MA), a major structural protein of retroviruses, is thought to play a critical role in several steps of the HIV-1 replication cycle, including the plasma membrane targeting of Gag, the incorporation of envelope (Env) glycoproteins into nascent particles, and the nuclear import of the viral genome in non-dividing cells. We now show that the entire MA protein is dispensable for the incorporation of HIV-1 Env glycoproteins with a shortened cytoplasmic domain. Furthermore, efficient HIV-1 replication in the absence of up to 90% of MA was observed in a cell line in which the cytoplasmic domain of Env is not required. Additional compensatory changes in Gag permitted efficient virus replication even if all of MA was replaced by a heterologous membrane targeting signal. Viruses which lacked the globular domain of MA but retained its N-terminal myristyl anchor exhibited an increased ability to form both extracellular and intracellular virus particles, consistent with a myristyl switch model of Gag membrane targeting. Pseudotyped HIV-1 particles that lacked the structurally conserved globular head of MA efficiently infected macrophages, indicating that MA is dispensable for nuclear import in terminally differentiated cells.     

Binding of human immunodeficiency virus type 1 Gag to membrane: role of the matrix amino terminus

Binding of the human immunodeficiency virus type 1 (HIV-1) Gag protein precursor, Pr55(Gag), to membrane is an indispensable step in virus assembly. Previously, we reported that a matrix (MA) residue 6 substitution (6VR) imposed a virus assembly defect similar to that observed with myristylation-defective mutants, suggesting that the 6VR change impaired membrane binding. Intriguingly, the 6VR mutation had no effect on Gag myristylation. The defective phenotype imposed by 6VR was reversed by changes at other positions in MA, including residue 97. In this study, we use several biochemical methods to demonstrate that the residue 6 mutation, as well as additional substitutions in MA amino acids 7 and 8, reduce membrane binding without affecting N-terminal myristylation. This effect is observed in the context of Pr55(Gag), a truncated Gag containing only MA and CA, and in MA itself. The membrane binding defect imposed by the 6VR mutation is reversed by second-site changes in MA residues 20 and 97, both of which, when present alone, increase membrane binding to levels greater than those for the wild type. Both reduced and enhanced membrane binding imposed by the MA substitutions depend upon the presence of the N-terminal myristate. The results support the myristyl switch model recently proposed for the regulation of Gag membrane binding, according to which membrane binding is determined by the degree of exposure or sequestration of the N-terminal myristate moiety. Alternatively, insertion of the myristate into the lipid bilayer might be a prerequisite event for the function of other distinct MA-encoded membrane binding domains.     

Opposing effects of human immunodeficiency virus type 1 matrix mutations support a myristyl switch model of gag membrane targeting

Targeting of the human immunodeficiency virus type 1 (HIV-1) Gag precursor Pr55(gag) to the plasma membrane, the site of virus assembly, is primarily mediated by the N-terminal matrix (MA) domain. N-myristylation of MA is essential for the stable association of Pr55(gag) with membranes and for virus assembly. We now show that single amino acid substitutions near the N terminus of MA can dramatically impair assembly without compromising myristylation. Subcellular fractionation demonstrated that Gag membrane binding was compromised to a similar extent as in the absence of the myristyl acceptor site, indicating that the myristyl group was not available for membrane insertion. Remarkably, the effects of the N-terminal modifications could be completely suppressed by second-site mutations in the globular core of MA. The compensatory mutations enhanced Gag membrane binding and increased viral particle yields above wild-type levels, consistent with an increase in the exposure of the myristyl group. Our results support a model in which the compact globular core of MA sequesters the myristyl group to prevent aberrant binding to intracellular membranes, while the N terminus is critical to allow the controlled exposure of the myristyl group for insertion into the plasma membrane.     

Myristate exposure in the human immunodeficiency virus type 1 matrix protein is modulated by pH

Human immunodeficiency virus type 1 (HIV-1) encodes a polypeptide called Gag that is capable of forming virus-like particles (VLPs) in vitro in the absence of other cellular or viral constituents. During the late phase of HIV-1 infection, Gag polyproteins are transported to the plasma membrane (PM) for assembly. A combination of in vivo, in vitro, and structural studies have shown that Gag targeting and assembly on the PM are mediated by specific interactions between the myristoylated matrix [myr(+)MA] domain of Gag and phosphatidylinositol 4,5-bisphosphate [PI(4,5)P2]. Exposure of the MA myristyl (myr) group is triggered by PI(4,5)P2 binding and is enhanced by factors that promote protein self-association. In the studies reported here, we demonstrate that myr exposure in MA is modulated by pH. Our data show that deprotonation of the His89 imidazole ring in myr(+)MA destabilizes the salt bridge formed between His89(Hδ2) and Glu12(COO-), leading to tight sequestration of the myr group and a shift in the equilibrium from trimer to monomer. Furthermore, we show that oligomerization of a Gag-like construct containing matrix-capsid is also pH-dependent. Disruption of the His?Glu salt bridge by single-amino acid substitutions greatly altered the myr-sequestered?myr-exposed equilibrium. In vivo intracellular localization data revealed that the H89G mutation retargets Gag to intracellular compartments and severely inhibits virus production. Our findings reveal that the MA domain acts as a “pH sensor” in vitro, suggesting that the effect of pH on HIV-1 Gag targeting and binding to the PM warrants investigation.     

Identification of human immunodeficiency virus type 1 Gag protein domains essential to membrane binding and particle assembly.

Assembly of human immunodeficiency virus type 1 (HIV-1) particles occurs at the plasma membrane of infected cells. Myristylation of HIV-1 Gag precursor polyprotein Pr55Gag is required for stable membrane binding and for assembly of viral particles. We expressed a series of proteins representing major regions of the HIV-1 Gag protein both with and without an intact myristyl acceptor glycine and performed subcellular fractionation studies to identify additional regions critical for membrane binding. Myristylation-dependent binding of Pr55Gag was demonstrated by using the vaccinia virus/T7 hybrid system for protein expression. Domains within the matrix protein (MA) region downstream of the initial 15 amino acids were required for membrane binding which was resistant to a high salt concentration (1 M NaCl). A myristylated construct lacking most of the matrix protein did not associate with the plasma membrane but formed intracellular retrovirus-like particles. A nonmyristylated construct lacking most of the MA region also was demonstrated by electron microscopy to form intracellular particles. Retrovirus-like extracellular particles were produced with a Gag protein construct lacking all of p6 and most of the nucleocapsid region. These studies suggest that a domain within the MA region downstream from the myristylation site is required for transport of Gag polyprotein to the plasma membrane and that stable plasma membrane binding requires both myristic acid and a downstream MA domain. The carboxyl-terminal p6 region and most of the nucleocapsid region are not required for retrovirus-like particle formation.     

Mutations in capsid major homology region affect assembly and membrane affinity of HIV-1 Gag

We introduced mutations into the HIV-1 major homology region (MHR; capsids 153-172) and adjacent C-terminal region to analyze their effects on virus-like particle (VLP) assembly, membrane affinity, and the multimerization of the Gag structural protein. Results indicate that alanine substitutions at K158, F168 or E175 significantly diminished VLP production. All assembly-defective Gag mutants had markedly reduced membrane-binding capacities, but results from a velocity sedimentation analysis suggest that most of the membrane-bound Gag proteins were present, primarily in a higher-order multimerized form. The membrane-binding capacity of the K158A, F168A, and E175A Gag proteins increased sharply upon removal of the MA globular domain. While demonstrating improved multimerization capability, the two MA-deleted versions of F168A and E175A did not show marked improvement in VLP production, presumably due to a defect in association with the raft-like membrane domain. However, K158A bound to detergent-resistant raft-like membrane; this was accompanied by noticeably improved VLP production following MA removal. Our results suggest that the HIV-1 MHR and adjacent downstream region facilitate multimerization and tight Gag packing. Enhanced Gag multimerization may help expose the membrane-binding domain and thus improve Gag membrane binding, thereby promoting Gag multimerization into higher-order assembly products.     

Feline immunodeficiency virus Gag is a nuclear shuttling protein

Lentiviral genomic RNAs are encapsidated by the viral Gag protein during virion assembly. The intracellular location of the initial Gag-RNA interaction is unknown. We previously observed feline immunodeficiency virus (FIV) Gag accumulating at the nuclear envelope during live-cell imaging, which suggested that trafficking of human immunodeficiency virus type 1 (HIV-1) and FIV Gag may differ. Here we analyzed the nucleocytoplasmic transport properties of both Gag proteins. We discovered that inhibition of the CRM1 nuclear export pathway with leptomycin B causes FIV Gag but not HIV-1 Gag to accumulate in the nucleus. Virtually all FIV Gag rapidly became intranuclear when the CRM1 export pathway was blocked, implying that most if not all FIV Gag normally undergoes nuclear cycling. In FIV-infected feline cells, some intranuclear Gag was detected in the steady state without leptomycin B treatment. When expressed individually, the FIV matrix (MA), capsid (CA), and nucleocapsid-p2 (NC-p2) domains were not capable of mediating leptomycin B-sensitive nuclear export of a fluorescent protein. In contrast, CA-NC-p2 did mediate nuclear export, with MA being dispensable. We conclude that HIV-1 and FIV Gag differ strikingly in a key intracellular trafficking property. FIV Gag is a nuclear shuttling protein that utilizes the CRM1 nuclear export pathway, while HIV-1 Gag is excluded from the nucleus. These findings expand the spectrum of lentiviral Gag behaviors and raise the possibility that FIV genome encapsidation may initiate in the nucleus.     

CRM1-dependent trafficking of retroviral Gag proteins revisited

We analyzed the nuclear trafficking ability of Gag proteins from six retroviral genera. Contrary to a previous report, human immunodeficiency virus type 1 (HIV-1) Gag showed no propensity to cycle through the nucleus. The only Gag protein that displayed CRM1-dependent nuclear cycling was that of Rous sarcoma virus (RSV). Surprisingly, this cycling could be eliminated without compromising infectivity by replacing the RSV Gag N-terminal matrix (MA) domain with HIV MA.     

Gag localization and virus-like particle release mediated by the matrix domain of human T-lymphotropic virus type 1 Gag are less dependent on phosphatidylinositol-(4,5)-bisphosphate than those mediated by the matrix domain of HIV-1 Gag

The human immunodeficiency virus type 1 (HIV-1) Gag matrix (MA) domain facilitates Gag targeting and binding to the plasma membrane (PM) during virus assembly. Interaction with a PM phospholipid, phosphatidylinositol-(4,5)-bisphosphate [PI(4,5)P(2)], plays a key role in these MA functions. Previous studies showed that overexpression of polyphosphoinositide 5-phosphatase IV (5ptaseIV), which depletes cellular PI(4,5)P(2), mislocalizes HIV-1 Gag to the cytosol and greatly reduces HIV-1 release efficiency. In this study, we sought to determine the role of the MA-PI(4,5)P(2) interaction in Gag localization and membrane binding of a deltaretrovirus, human T-lymphotropic virus type 1 (HTLV-1). We compared the chimeric HIV-1 Gag (HTMA), in which MA was replaced with HTLV-1 MA, with wild-type HIV-1 and HTLV-1 Gag for PI(4,5)P(2) dependence. Our results demonstrate that, unlike HIV-1 Gag, subcellular localization of and VLP release by HTLV-1 and HTMA Gag were minimally sensitive to 5ptaseIV overexpression. These results suggest that the interaction of HTLV-1 MA with PI(4,5)P(2) is not essential for HTLV-1 particle assembly. Furthermore, liposome-binding analyses showed that both HTLV-1 and HTMA Gag can bind membrane efficiently even in the absence of PI(4,5)P(2). Efficient HTLV-1 Gag binding to liposomes was largely driven by electrostatic interaction, unlike that of HIV-1 Gag, which required specific interaction with PI(4,5)P(2). Furthermore, membrane binding of HTLV-1 Gag in vitro was not suppressed by RNA, in contrast to HIV-1 Gag. Altogether, our data suggest that Gag targeting and membrane binding mediated by HTLV-1 MA does not require PI(4,5)P(2) and that distinct mechanisms regulate HIV-1 and HTLV-1 Gag membrane binding.     

Effect of Multimerization on Membrane Association of Rous Sarcoma Virus and HIV-1 Matrix Domain Proteins

In most retroviruses, plasma membrane (PM) association of the Gag structural protein is a critical step in viral assembly, relying in part on interaction between the highly basic Gag MA domain and the negatively charged inner leaflet of the PM. Assembly is thought to begin with Gag dimerization followed by multimerization, resulting in a hexameric lattice. To directly address the role of multimerization in membrane binding, we fused the MA domains of Rous sarcoma virus (RSV) and HIV-1 to the chemically inducible dimerization domain FK506-binding protein (FKBP) or to the hexameric protein CcmK4 from cyanobacteria. The cellular localization of the resulting green fluorescent protein (GFP)-tagged chimeric proteins was examined by fluorescence imaging, and the association of the proteins with liposomes was quantified by flotation in sucrose gradients, following synthesis in a reticulocyte extract or as purified proteins. Four lipid compositions were tested, representative of liposomes commonly reported in flotation experiments. By themselves, GFP-tagged RSV and HIV-1 MA proteins were largely cytoplasmic, but both hexamerized proteins were highly concentrated at the PM. Dimerization led to partial PM localization for HIV-1 MA. These in vivo effects of multimerization were reproduced in vitro. In flotation analyses, the intact RSV and HIV-1 Gag proteins were more similar to multimerized MA than to monomeric MA. RNA is reported to compete with acidic liposomes for HIV-1 Gag binding, and thus we also examined the effects of RNase treatment or tRNA addition on flotation. tRNA competed with liposomes in the case of some but not all lipid compositions and ionic strengths. Taken together, our results further underpin the model that multimerization is critical for PM association of retroviral Gag proteins. In addition, they suggest that the modulation of membrane binding by RNA, as previously reported for HIV-1, may not hold for RSV.     

An early stage of Mason-Pfizer monkey virus budding is regulated by the hydrophobicity of the Gag matrix domain core

Intracellular capsid transport and release of Mason-Pfizer monkey virus are dependent on myristylation of the Gag matrix domain (MA). A myristylated MA mutant, in which Thr41 and Thr78 are replaced with isoleucines, assembles capsids that are transported to the plasma membrane but are blocked in an early budding step. Since the nuclear magnetic resonance structure of MA showed that these Thr residues point into the hydrophobic core of the protein, it was hypothesized that the T41I/T78I mutant was defective in release of myristic acid from the more hydrophobic core. In order to further investigate whether an increase in the hydrophobicity of the MA core modulates capsid-membrane interactions and viral budding, three tyrosine residues (11, 28, and 67), oriented toward the MA core, were replaced individually or in a pair-wise combination with the more hydrophobic phenylalanine residue(s). As a control, Tyr82, oriented toward the outer surface of MA, was also replaced with phenylalanine. These Tyr-to-Phe substitutions did not alter capsid assembly compared to wild type in a capsid assembly assay. Pulse-chase, immunofluorescence, and electron microscopy studies demonstrated that single substitutions of Tyr11, Tyr28, and Tyr67 recapitulated the T41I/T78I mutant phenotype of decreased budding kinetics and accumulation of capsids at the plasma membrane. MA double mutants with a combination of these Tyr substitutions exhibited a phenotype that was even more defective in budding. In contrast, MA mutants with Tyr82 replaced by Phe resulted in a transport-defective phenotype. These results strongly support the hypothesis that myristic acid is sequestered inside MA prior to capsid-membrane interactions.     

Defect of human immunodeficiency virus type 2 Gag assembly in Saccharomyces cerevisiae

We have previously shown that the expression of human immunodeficiency virus type 1 (HIV-1) Gag protein in Saccharomyces cerevisiae spheroplasts produces Gag virus-like particles (VLPs) at the plasma membrane, indicating that yeast has all the host factors necessary for HIV-1 Gag assembly. Here we expand the study by using diverse primate lentiviral Gags and show that yeast does not support the production of HIV-2 or simian immunodeficiency virus SIVmac Gag VLPs but allows the production of SIVagm and SIVmnd Gag VLPs. Particle budding was observed at the surfaces of cells expressing SIVagm and SIVmnd Gags, but cells expressing HIV-2 and SIVmac Gags showed only membrane-ruffling structures, although they were accompanied with electron-dense submembrane layers, suggesting arrest at an early stage of particle budding. Comparison of HIV-1 and HIV-2 Gag expression revealed broadly equivalent levels of intracellular Gag expression and Gag N-terminal myristoylation in yeast. Both Gags showed the same membrane-binding ability and were incorporated into lipid raft fractions at a physiological concentration of salt. HIV-2 Gag, however, failed to form a high-order multimer and easily dissociated from the membrane, phenomena which were not observed in higher eukaryotic cells. A series of chimeric Gags between HIV-1 and HIV-2 and Gag mutants with amino acid substitutions revealed that a defined region in helix 2 of HIV-2 MA (located on the membrane-binding surface of MA) affects higher-order Gag assembly and particle production in yeast. Together, these data suggest that yeast may lack a host factor(s) for HIV-2 and SIVmac Gag assembly.     

HIV-1 Gag release from yeast reveals ESCRT interaction with the Gag N-terminal protein region

The HIV-1 protein Gag assembles at the plasma membrane and drives virion budding, assisted by the cellular endosomal complex required for transport (ESCRT) proteins. Two ESCRT proteins, TSG101 and ALIX, bind to the Gag C-terminal p6 peptide. TSG101 binding is important for efficient HIV-1 release, but how ESCRTs contribute to the budding process and how their activity is coordinated with Gag assembly is poorly understood. Yeast, allowing genetic manipulation that is not easily available in human cells, has been used to characterize the cellular ESCRT function. Previous work reported Gag budding from yeast spheroplasts, but Gag release was ESCRT-independent. We developed a yeast model for ESCRT-dependent Gag release. We combined yeast genetics and Gag mutational analysis with Gag-ESCRT binding studies and the characterization of Gag-plasma membrane binding and Gag release. With our system, we identified a previously unknown interaction between ESCRT proteins and the Gag N-terminal protein region. Mutations in the Gag-plasma membrane–binding matrix domain that reduced Gag-ESCRT binding increased Gag-plasma membrane binding and Gag release. ESCRT knockout mutants showed that the release enhancement was an ESCRT-dependent effect. Similarly, matrix mutation enhanced Gag release from human HEK293 cells. Release enhancement partly depended on ALIX binding to p6, although binding site mutation did not impair WT Gag release. Accordingly, the relative affinity for matrix compared with p6 in GST-pulldown experiments was higher for ALIX than for TSG101. We suggest that a transient matrix-ESCRT interaction is replaced when Gag binds to the plasma membrane. This step may activate ESCRT proteins and thereby coordinate ESCRT function with virion assembly.     

Solution NMR characterizations of oligomerization and dynamics of equine infectious anemia virus matrix protein and its interaction with PIP2

Budding of retroviruses requires the structural precursor polyprotein, Gag, to target the plasma membrane through its N-terminal matrix (MA) domain. For HIV-1, the interaction between membrane signaling molecule phosphatidylinositol 4,5-diphosphate (PIP2) and MA induces the exposure of myristate and promotes membrane binding. Here we studied oligomerization of the naturally unmyristylated equine infectious anemia virus (EIAV) MA and its interaction with PIP2-C4 primarily using solution NMR spectroscopy. The measured 1H-15N residual dipolar coupling agrees with the atomic coordinates from the EIAV MA crystal structure. The analytical ultracentrifugation results show a dominant population of monomeric EIAV MA at a concentration of 63 microM and 20 degrees C, along with a small trimer and a broad distribution of other oligomers. The monomer-trimer equilibrium model and the quaternary packing of the trimer were further established by the concentration-dependent 15N spin relaxation rates and chemical shifts. Binding of MA to PIP2-C4 was detected by chemical shift mapping (CSM) with an apparent Kd of 182 +/- 56 microM, a value similar to that reported for HIV-1 MA. The PIP2 binding site includes the Loop region between Helix2 and Helix3 in the EIAV MA. CSM and spin relaxation dispersion reveal a coupling of conformational change and submillisecond dynamics, respectively, between the Loop and trimeric Interface Residues due to PIP2 binding. We infer that PIP2 participates in the initial trimer formation of EIAV MA, but more importantly, the concentration effect is dominant in shifting the equilibrium toward trimer, in line with the entropic switch mechanism proposed for myristylated HIV-1 MA.     

The functionally exchangeable L domains in RSV and HIV-1 Gag direct particle release through pathways linked by Tsg101

The functionally exchangeable L domains of HIV-1 and Rous sarcoma virus (RSV) Gag bind Tsg101 and Nedd4, respectively. Tsg101 and Nedd4 function in endocytic trafficking, and studies show that expression of Tsg101 or Nedd4 fragments interfere with release of HIV-1 or RSV Gag, respectively, as virus-like particles (VLPs). To determine whether functional exchangeability reflects use of the same trafficking pathway, we tested the effect on RSV Gag release of co-expression with mutated forms of Vps4, Nedd4 and Tsg101. A dominant-negative mutant of Vps4A, an AAA ATPase required for utilization of endosomal sorting proteins that was shown previously to interfere with HIV-1 budding, also inhibited RSV Gag release, indicating that RSV uses the endocytic trafficking machinery, as does HIV. Nedd4 and Tsg101 interacted in the presence or absence of Gag and, through its binding of Nedd4, RSV Gag interacted with Tsg101. Deletion of the N-terminal region of Tsg101 or the HECT domain of Nedd4 did not prevent interaction; however, three-dimensional spatial imaging suggested that the interaction of RSV Gag with full-length Tsg101 and N-terminally truncated Tsg101 was not the same. Co-expression of RSV Gag with the Tsg101 C-terminal fragment interfered with VLP release minimally; however, a significant fraction of the released VLPs was tethered to each other. The results suggest that, while Tsg101 is not required for RSV VLP release, alterations in the protein interfere with VLP budding/fission events. We conclude that RSV and HIV-1 Gag direct particle release through independent ESCRT-mediated pathways that are linked through Tsg101-Nedd4 interaction.     

Beyond Plasma Membrane Targeting: Role of the MA domain of Gag in Retroviral Genome Encapsidation

The MA (matrix) domain of the retroviral Gag polyprotein plays several critical roles during virus assembly. Although best known for targeting the Gag polyprotein to the inner leaflet of the plasma membrane for virus budding, recent studies have revealed that MA also contributes to selective packaging of the genomic RNA (gRNA) into virions. In this Review, we summarize recent progress in understanding how MA participates in genome incorporation. We compare the mechanisms by which the MA domains of different retroviral Gag proteins influence gRNA packaging, highlighting variations and similarities in how MA directs the subcellular trafficking of Gag, interacts with host factors and binds to nucleic acids. A deeper understanding of how MA participates in these diverse functions at different stages in the virus assembly pathway will require more detailed information about the structure of the MA domain within the full-length Gag polyprotein. In particular, it will be necessary to understand the structural basis of the interaction of MA with gRNA, host transport factors and membrane phospholipids. A better appreciation of the multiple roles MA plays in genome packaging and Gag localization might guide the development of novel antiviral strategies in the future.     

Electrostatic interactions drive membrane association of the human immunodeficiency virus type 1 Gag MA domain

The assembly of most retroviruses occurs at the plasma membrane. Membrane association is directed by MA, the N-terminal domain of the Gag structural protein. For human immunodeficiency virus type 1 (HIV-1), this association is mediated in part by a myristate fatty acid modification. Conflicting evidence has been presented on the relative importance of myristoylation, of ionic interactions between protein and membrane, and of Gag multimerization in membrane association in vivo. We addressed these questions biochemically by determining the affinity of purified myristoylated HIV-1 MA for liposomes of defined composition, both for monomeric and for dimeric forms of the protein. Myristoylation increases the barely detectable intrinsic affinity of the apo-protein for liposomes by only 10-fold, and the resulting affinity is still weak, similar to that of the naturally nonmyristoylated MA of Rous sarcoma virus. Membrane binding of HIV-1 MA is absolutely dependent on the presence of negatively charged lipid and is abrogated at high ionic strength. Forced dimerization of MA increases its membrane affinity by several orders of magnitude. When green fluorescent protein fusions of monomeric or dimeric MA are expressed in cells, the dimeric but not the monomeric protein becomes strongly membrane associated. Computational modeling supports these results and suggests a molecular mechanism for the modest effect of myristoylation on binding, wherein the membrane provides a hydrophobic environment for the myristate that is energetically similar to that provided by the protein. Overall, the results imply that the driving force for membrane association stems largely from ionic interactions between multimerized Gag and negatively charged phospholipids.