Critical role of conserved hydrophobic residues within the major homology region in mature retroviral capsid assembly

During retroviral maturation, the CA protein undergoes dramatic structural changes and establishes unique intermolecular interfaces in the mature capsid shell that are different from those that existed in the immature precursor. The most conserved region of CA, the major homology region (MHR), has been implicated in both immature and mature assembly, although the precise contribution of the MHR residues to each event has been largely undefined. To test the roles of specific MHR residues in mature capsid assembly, an in vitro system was developed that allowed for the first-time formation of Rous sarcoma virus CA into structures resembling authentic capsids. The ability of CA to assemble organized structures was destroyed by substitutions of two conserved hydrophobic MHR residues and restored by second-site suppressors, demonstrating that these MHR residues are required for the proper assembly of mature capsids in addition to any role that these amino acids may play in immature particle assembly. The defect caused by the MHR mutations was identified as an early step in the capsid assembly process. The results provide strong evidence for a model in which the hydrophobic residues of the MHR control a conformational reorganization of CA that is needed to initiate capsid assembly and suggest that the formation of an interdomain interaction occurs early during maturation.     

Mutational analysis of the major homology region of Mason-Pfizer monkey virus by use of saturation mutagenesis.

The major capsid (CA) protein of retroviruses possesses a stretch of 20 amino acids, called the major homology region (MHR), which is evolutionarily conserved and invariant in location within the primary sequence of the protein. The function of this region was investigated by examining the effect of random single-amino-acid substitutions within the central 13 positions of the MHR on the life cycle of Mason-Pfizer monkey virus (M-PMV), an immunosuppressive D-type retrovirus. When these mutants were subcloned into an M-PMV proviral vector and expressed in COS cells, one of two major phenotypes was observed. The first group, containing three mutants bearing drastic amino acid substitutions, was unable to assemble capsids in the cytoplasm of the host cell. The second and more common group of mutants was able to assemble and release virions, but these either displayed greatly reduced levels of infectivity or were completely noninfectious. Included within this second group were two mutants with unusual phenotypes; mutant D158Y exhibited a novel cleavage site for the viral protease that resulted in cleavage of the major capsid protein, p27 (CA), within the MHR, whereas mutant F156L appeared to have lost a major site for antibody recognition within the mature CA protein. The results of this mutagenic analysis suggest that changes in the MHR sequence can interfere with the assembly of viral capsids and block an early stage of the infection cycle of M-PMV.     

Functional domains of the capsid protein of human immunodeficiency virus type 1.

A series of deletions was introduced into the CA domain of the human immunodeficiency virus type 1 Gag polyprotein to examine its role in virus particle and core formation. The mutations resulted in two phenotypes, indicating the existence of two functionally distinct regions within the CA domain. Deletions within a conserved stretch of 20 amino acids referred to as the major homology region (MHR) and deletions C terminal to this region blocked virus replication and significantly reduced the ability to form viral particles. Deletions N terminal to the MHR also prevented virus replication, but the mutants retained the ability to assemble and release viral particles with the same efficiency as the wild-type virus. The mutant particles contained circular rather than cone-shaped cores, and while they were of a density similar to that of wild-type particles, they were more heterogeneous in size. These results indicate that CA domain sequences N terminal to the MHR are essential for the morphogenesis of the mature cone-shaped core.     

Role of the major homology region of human immunodeficiency virus type 1 in virion morphogenesis.

Retroviral capsid (CA) proteins contain a uniquely conserved stretch of 20 amino acids which has been named the major homology region (MHR). To examine the role of this region in human immunodeficiency virus type 1 morphogenesis and replication, four highly conserved positions in the MHR were individually altered by site-directed mutagenesis. Conservative substitution of two invariant residues (glutamine 155 and glutamic acid 159) abolished viral replication and significantly reduced the particle-forming ability of the mutant gag gene products. Conservative substitution of the third invariant residue in the MHR (arginine 167) or of an invariably aromatic residue (tyrosine 164) had only a moderate effect. However, removal of the extended side chains of these amino acids by substitution with alanine prevented viral replication and affected virion morphogenesis. The replacement of tyrosine 164 with alanine substantially impaired viral particle production. By contrast, the substitution of arginine 167 with alanine had only a two- to threefold effect on particle yield but led to the formation of aberrant core structures. The MHR mutant which were severely defective for particle production had a dominant negative effect on particle formation by the wild-type Gag product. The role of the MHR in the incorporation of the Gag-Pol precursor was examined by expressing the Gag and Gag-Pol polyproteins individually from separate plasmids. Only when the two precursor polyproteins were coexpressed did processed Gag and Pol products appear in the external medium. The appearance of these products was unaffected or only moderately affected by substitutions in the MHR of the Gag-Pol precursor, suggesting that the mutant Gag-Pol precursors were efficiently incorporated into viral particles. The results of this study indicate that specific residues within the MHR are required both for human immunodeficiency virus type 1 particle assembly and for the correct assembly of the viral core. However, mutant Gag and Gag-Pol polyproteins with substitutions in the MHR retained the ability to interact with wild-type Gag protein.     

Mutations in the alpha 2(IV) basement membrane collagen gene of Caenorhabditis elegans produce phenotypes of differing severities.

Type IV collagen forms a network that provides the major structural support of basement membranes. We have determined the nucleotide alterations and phenotypes of 17 mutant alleles of the Caenorhabditis elegans alpha 2(IV) collagen gene let-2. All 17 mutations are within the triple helical (Gly-X-Y) repeat domain of the molecule. Fifteen of the mutations are replacements of Gly-X-Y repeat glycines with aspartate, glutamate or arginine, and they cause a wide range of phenotypes. The mildest alleles are nearly wild-type at 15 and 20 degrees C but embryonic lethal at 25 degrees C, while the most severe allele is embryonic lethal at all three temperatures. Mutations resulting in severe phenotypes are generally located in areas of lower calculated thermal stability of the type IV collagen molecule. An alanine to threonine substitution at position X of a Gly-X-Y triplet immediately following an interruption results in a severe phenotype. This mutation is unusual because substitutions at positions X or Y have not generally been found to cause strong phenotypes in C. elegans or human collagens. An intron splice acceptor mutation causes a strict embryonic lethal phenotype, but does not completely abolish gene function. Pairs of independent mutations affect each of three glycines, indicating a non-random distribution of mutations in the molecule. It is suggested that this clustering results because many glycine substitutions may cause dominant lethal or sterile phenotypes.     

Lethal mutations in the major homology region and their suppressors act by modulating the dimerization of the rous sarcoma virus capsid protein C‐terminal domain

An infective retrovirus requires a mature capsid shell around the viral replication complex. This shell is formed by about 1500 capsid protein monomers, organized into hexamer and pentamer rings that are linked to each other by the dimerization of the C‐terminal domain (CTD). The major homology region (MHR), the most highly conserved protein sequence across retroviral genomes, is part of the CTD. Several mutations in the MHR appear to block infectivity by preventing capsid formation. Suppressor mutations have been identified that are distant in sequence and structure from the MHR and restore capsid formation. The effects of two lethal and two suppressor mutations on the stability and function of the CTD were examined. No correlation with infectivity was found for the stability of the lethal mutations (D155Y‐CTD, F167Y‐CTD) and suppressor mutations (R185W‐CTD, I190V‐CTD). The stabilities of three double mutant proteins (D155Y/R185W‐CTD, F167Y/R185W‐CTD, and F167Y/I190V‐CTD) were additive. However, the dimerization affinity of the mutant proteins correlated strongly with biological function. The CTD proteins with lethal mutations did not dimerize, while those with suppressor mutations had greater dimerization affinity than WT‐CTD. The suppressor mutations were able to partially correct the dimerization defect caused by the lethal MHR mutations in double mutant proteins. Despite their dramatic effects on dimerization, none of these residues participate directly in the proposed dimerization interface in a mature capsid. These findings suggest that the conserved sequence of the MHR has critical roles in the conformation(s) of the CTD that are required for dimerization and correct capsid maturation. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Mapping of functionally important residues of a cysteine-histidine box in the human immunodeficiency virus type 1 nucleocapsid protein.

The human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein contains two copies of a sequence motif, the cysteine-histidine box, that is conserved among retroviruses. To identify the functionally relevant positions of a cysteine-histidine box, each amino acid in the proximal copy of the motif was individually substituted by site-directed mutagenesis. Mutations at 5 of 14 positions abolished virus replication and reduced the viral RNA content of mutant particles to between 10 and 20% of parental levels. Mutations at other positions had either no or only a minor effect on virus replication and virion RNA content. In vitro binding of RNA to bacterially expressed mutant Pr55gag polyprotein correlated well with the effects of the mutations on particle-associated viral RNA levels. The two different copies of the motif in the HIV-1 nucleocapsid protein are not functionally equivalent, since the conversion of the proximal motif to an exact copy of the distal motif results in a defect in virus replication and a reduction in the viral RNA content of mutant particles. The simultaneous substitution of functionally relevant positions in both motifs led to a significant decline in gag protein export, indicating that the nucleocapsid domain of the gag precursor is also required for efficient assembly or release of the virion.     

Requirement of Cysteines and Length of the Human Respiratory Syncytial Virus M2-1 Protein for Protein Function and Virus Viability

The M2-1 protein of human respiratory syncytial virus (hRSV) promotes processive RNA synthesis and readthrough at RSV gene junctions. It contains four highly conserved cysteines, three of which are located in the Cys(3)-His(1) motif at the N terminus of M2-1. Each of the four cysteines, at positions 7, 15, 21, and 96, in the M2-1 protein of hRSV A2 strain was individually replaced by glycines. When tested in an RSV minigenome replicon system using beta-galactosidase as a reporter gene, C7G, C15G, and C21G located in the Cys(3)-His(1) motif showed a significant reduction in processive RNA synthesis compared to wild-type (wt) M2-1. C96G, which lies outside the Cys(3)-His(1) motif, was fully functional in supporting processive RNA synthesis in vitro. Each of these cysteine substitutions was introduced into an infectious antigenomic cDNA clone derived from hRSV A2 strain. Except for C96G, which resulted in a viable virus, no viruses were recovered with mutations in the Cys(3)-His(1) motif. This indicates that the Cys(3)-His(1) motif is critical for M2-1 function and for RSV replication. The functional requirement of the C terminus of the M2-1 protein was examined by engineering premature stop codons that caused truncations of 17, 46, or 67 amino acids from the C terminus. A deletion of 46 or 67 amino acids abolished the synthesis of full-length beta-galactosidase mRNA and did not result in the recovery of viable viruses. However, a deletion of 17 amino acids from the C terminus of M2-1 reduced processive RNA synthesis in vitro and was well tolerated by RSV. Relocation of the M2-1 termination codon upstream of the M2-2 initiation codons did not significantly affect the expression of the M2-2 protein. Both rA2-Tr17 and rA2-C96G did not replicate as efficiently as wt rA2 in HEp-2 cells and was restricted in replication in the respiratory tracts of cotton rats.     

The TetA(K) tetracycline/H(+) antiporter from Staphylococcus aureus: mutagenesis and functional analysis of motif C

Conserved motif C, identified within members of the major facilitator superfamily (MFS) of transport proteins that mediate drug export, was examined in the tetracycline resistance efflux protein TetA(K) from Staphylococcus aureus; motif C is contained within transmembrane segment 5. Using site-directed mutagenesis, the importance of the conserved glycine (G151, G155, G159, and G160) and proline (P156) residues within this motif was investigated. Over 40 individual amino acid replacements were introduced; however, only alanine and serine substitutions for glycine at G151, G155, and G160 were found to retain significant levels of tetracycline resistance and transport activity in cells expressing mutant proteins. Notably, P156 and G159 appear to be crucial, as amino acid replacements at these positions either significantly reduced or abolished tetracycline/H(+) activity. The highly conserved nature of motif C and its distribution throughout drug exporters imply that the residues of motif C play a similar role in all MFS proteins that function as antiporters.     

Functional constraints of influenza A virus epitopes limit escape from cytotoxic T lymphocytes

Viruses can exploit a variety of strategies to evade immune surveillance by cytotoxic T lymphocytes (CTL), including the acquisition of mutations in CTL epitopes. Also for influenza A viruses a number of amino acid substitutions in the nucleoprotein (NP) have been associated with escape from CTL. However, other previously identified influenza A virus CTL epitopes are highly conserved, including the immunodominant HLA-A*0201-restricted epitope from the matrix protein, M1(58-66). We hypothesized that functional constraints were responsible for the conserved nature of influenza A virus CTL epitopes, limiting escape from CTL. To assess the impact of amino acid substitutions in conserved epitopes on viral fitness and recognition by specific CTL, we performed a mutational analysis of CTL epitopes. Both alanine replacements and more conservative substitutions were introduced at various positions of different influenza A virus CTL epitopes. Alanine replacements for each of the nine amino acids of the M1(58-66) epitope were tolerated to various extents, except for the anchor residue at the second position. Substitution of anchor residues in other influenza A virus CTL epitopes also affected viral fitness. Viable mutant viruses were used in CTL recognition experiments. The results are discussed in the light of the possibility of influenza viruses to escape from specific CTL. It was speculated that functional constraints limit variation in certain epitopes, especially at anchor residues, explaining the conserved nature of these epitopes.     

Fine mapping and characterization of the Rous sarcoma virus Pr76gag late assembly domain.

The p2 region of the Rous sarcoma virus (RSV) Gag polyprotein contains an assembly domain, which is required late in replication for efficient budding of virus-like particles from cells (J. W. Wills, C. E. Cameron, C. B. Wilson, Y. Xiang, R. P. Bennett, and J. Leis, J. Virol. 68:6605-6618, 1994). This domain, referred to as the L domain, was previously mapped to the 11 amino acids of p2b. Through the analysis of a series of deletion and substitution mutations, the L domain has now been fine mapped to a highly conserved amino acid sequence, PPPPYV of p2b. Sequences flanking PPPPYV motif can be deleted without any effect on budding. Defects caused by L-domain deletions can be rescued by placing a wild-type copy of the sequence at several other positions in RSV Gag. A proline-rich P(S/T)APP motif is found in many retroviral Gag polyproteins; the motif found in the p6 region of human immunodeficiency virus type 1 has been implicated in late functions of the virus. Substitution of the RSV L domain with this motif in a 10-amino-acid sequence derived from visna leukemia virus results in wild-type release of virus particles from cells. In contrast, the slightly different sequences from Gibbon ape leukemia virus, Moloney leukemia virus, PSAPP alone, or a proline-rich SH3 binding sequence do not efficiently rescue RSV L-domain mutations.     

Active site mutants in the six regulatory particle ATPases reveal multiple roles for ATP in the proteasome.

A family of ATPases resides within the regulatory particle of the proteasome. These proteins (Rpt1-Rpt6) have been proposed to mediate substrate unfolding, which may be required for translocation of substrates through the channel that leads from the regulatory particle into the proteolytic core particle. To analyze the role of ATP hydrolysis in protein breakdown at the level of the individual ATPase, we have introduced equivalent site-directed mutations into the ATPbinding motif of each RPT gene. Non-conservative substitutions of the active-site lysine were lethal in four of six cases, and conferred a strong growth defect in two cases. Thus, the ATPases are not functionally redundant, despite their multiplicity and sequence similarity. Degradation of a specific substrate can be inhibited by ATP-binding-site substitutions in many of the Rpt proteins, indicating that they co-operate in the degradation of individual substrates. The phenotypic defects of the different rpt mutants were strikingly varied. The most divergent phenotype was that of the rpt1 mutant, which was strongly growth defective despite showing no general defect in protein turnover. In addition, rpt1 was unique among the rpt mutants in displaying a G1 cell-cycle defect. Proteasomes purified from an rpt2 mutant showed a dramatic inhibition of peptidase activity, suggesting a defect in gating of the proteasome channel. In summary, ATP promotes protein breakdown by the proteasome through multiple mechanisms, as reflected by the diverse phenotypes of the rpt mutants.     

Analysis of mutations in the integration function of Moloney murine leukemia virus: effects on DNA binding and cutting.

The 3' terminus of the pol gene of Moloney murine leukemia virus encodes the integration (IN) protein, required for the establishment of the integrated provirus. A series of six linker insertion mutations and two single-base substitutions were generated within the region encoding the IN protein. Mutations were initially generated within an Escherichia coli plasmid expressing the IN protein, and the resulting variants were assayed for DNA-binding activity. Mutations which altered conserved cysteine residues within a potential DNA finger-binding motif resulted in lower or variable DNA binding, which appeared to be the result of variable protein folding. Upon renaturation, these proteins were able to nonspecifically bind DNA in a manner similar to that of the other mutant IN proteins and the parent. When reconstructed back into full-length virus, seven of the eight mutations were lethal. All mutants produced a stable IN protein in virions and mediated normal conversion of the retroviral RNA to its three DNA forms. Fine-structure analysis of the linear double-stranded viral DNA indicated that all seven lethal alterations within the IN protein blocked the formation of the 3' recessed termini that normally precedes integration.     

Varicella-Zoster Virus ORF49 Functions in the Efficient Production of Progeny Virus through Its Interaction with Essential Tegument Protein ORF44

The ORF49 tegument protein of varicella-zoster virus (VZV) is one of the core gene products that is conserved among herpesvirus family members. Although ORF49 is known to be a cell-tropic factor, its detailed functions remain elusive. ORF44 is another core gene product reported to be essential, although its characterization and detailed functional analysis have not been reported. These two core gene products form a complex in other herpesviruses beyond the host species and herpesvirus subfamilies. Here, we show that complex formation between ORF44 and ORF49 is conserved in VZV. We serendipitously found that binding is eliminated by an amino acid substitution at position 129 (phenylalanine 129), and four amino acids in the carboxyl-terminal half of the acidic cluster in ORF49 (i.e., aspartate-phenylalanine-aspartate-glutamate from positions 41 to 44 [41DFDE44]) were identified as its binding motif. Alanine substitutions in each domain rendered the ORF44F129A mutation lethal for VZV, similar to deletion of the entire ORF44. The phenotype of the ORF49-41AAAA44 mutation was comparable to that of the ORF49-defective virus, including small-plaque formation, impaired growth, and low infectious virus production. These results suggest that the interaction between ORF44 and ORF49 is essential for their role in VZV infection and that ORF49 is required for the efficient production of infectious progeny virus mediated by the conserved interaction between the two proteins.     

Structural interactions between retroviral Gag proteins examined by cysteine cross-linking.

We have examined structural interactions between Gag proteins within Moloney murine leukemia virus (M-MuLV) particles by making use of the cysteine-specific cross-linking agents iodine and bis-maleimido hexane. Virion-associated wild-type M-MuLV Pr65Gag proteins in immature particles were intermolecularly cross-linked at cysteines to form Pr65Gag oligomers, from dimers to pentamers or hexamers. Following a systematic approach of cysteine-to-serine mutagenesis, we have shown that cross-linking of Pr65Gag occurred at cysteines of the nucleocapsid (NC) Cys-His motif, suggesting that the Cys-His motifs within virus particles are packed in close proximity. The M-MuLV Pr65Gag protein did not cross-link to the human immunodeficiency virus Pr55Gag protein when the two molecules were coexpressed, indicating either that they did not coassemble or that heterologous Gag proteins were not in close enough proximity to be cross-linked. Using an assembly-competent, protease-minus, cysteine-minus Pr65Gag protein as a template, novel cysteine residues were generated in the M-MuLV capsid domain major homology region (MHR). Cross-linking of proteins containing MHR cysteines showed above-background levels of Gag-Gag dimers but also identified a novel cellular factor, present in virions, that cross-linked to MHR residues. Although the NC cysteine mutation was compatible with M-MuLV particle assembly, deletions of the NC domain were not tolerated. These results suggest that the Cys-His motif is held in close proximity within immature M-MuLV particles by interactions between CA domains and/or non-Cys-His motif domains of the NC.     

Nature and distribution of sites of temperature-sensitive folding mutations in the gene for the P22 tailspike polypeptide chain

Temperature-sensitive folding (tsf) mutations in gene 9 of bacteriophage P22 interfere with the folding and association of the tailspike polypeptide chain at restrictive temperature. We report here the location and amino acid substitutions for 24 independent tsf mutants. The distribution of these and previously identified mutations is distinctly non-random; all of the 32 unambiguous sites of tsf mutations are located in the central 350 residues of the 666 residue tailspike polypeptide chain. No ts mutation has been found among the N-terminal 140 amino acids, and none among the C-terminal 170 amino acids. Since the physiological defect in these mutants is the destabilization of an early intermediate in the folding pathway, the localization of the mutants suggests that the central region of the chain is critical for formation or stabilization of this early intermediate. The majority of amino acids that served as sites for the tsf mutations were hydrophilic residues. Sixty percent of the replacements of these residues represented charge changes. This probably reflects the selection for mutant sites at the mature protein surface where the substitutions can be best tolerated without interfering with function. None of the sites of tsf mutations were at aromatic residues, and only one proline site was found. Substitutions at these residues may cause lethal folding defects which are not recovered as tsf mutants. The local sequences at tsf sites resemble those reported for turns. Structural studies identify beta-sheet as the dominant secondary structure. These mutations may disrupt the formation of conformational features of beta-sheets which are repeated, such as turns, associations between pairs of strands, or sheet/sheet packing interactions. Such a model accounts for the occurrence of tsf mutations with similar defective phenotypes at multiple positions along the chain.     

Structural and Functional Insights into the HIV-1 Maturation Inhibitor Binding Pocket

Processing of the Gag precursor protein by the viral protease during particle release triggers virion maturation, an essential step in the virus replication cycle. The first-in-class HIV-1 maturation inhibitor dimethylsuccinyl betulinic acid [PA-457 or bevirimat (BVM)] blocks HIV-1 maturation by inhibiting the cleavage of the capsid-spacer peptide 1 (CA-SP1) intermediate to mature CA. A structurally distinct molecule, PF-46396, was recently reported to have a similar mode of action to that of BVM. Because of the structural dissimilarity between BVM and PF-46396, we hypothesized that the two compounds might interact differentially with the putative maturation inhibitor-binding pocket in Gag. To test this hypothesis, PF-46396 resistance was selected for in vitro. Resistance mutations were identified in three regions of Gag: around the CA-SP1 cleavage site where BVM resistance maps, at CA amino acid 201, and in the CA major homology region (MHR). The MHR mutants are profoundly PF-46396-dependent in Gag assembly and release and virus replication. The severe defect exhibited by the inhibitor-dependent MHR mutants in the absence of the compound is also corrected by a second-site compensatory change far downstream in SP1, suggesting structural and functional cross-talk between the HIV-1 CA MHR and SP1. When PF-46396 and BVM were both present in infected cells they exhibited mutually antagonistic behavior. Together, these results identify Gag residues that line the maturation inhibitor-binding pocket and suggest that BVM and PF-46396 interact differentially with this putative pocket. These findings provide novel insights into the structure-function relationship between the CA MHR and SP1, two domains of Gag that are critical to both assembly and maturation. The highly conserved nature of the MHR across all orthoretroviridae suggests that these findings will be broadly relevant to retroviral assembly. Finally, the results presented here provide a framework for increased structural understanding of HIV-1 maturation inhibitor activity.