Identification and characterization of conserved and variable regions in the envelope gene of HTLV-III/LAV, the retrovirus of AIDS

To determine the extent and nature of genetic variation present in independent isolates of HTLV-III/LAV, the nucleotide sequences of the entire envelope gene and parts of gag and pol were determined for two AIDS viruses. The results indicated that variation throughout the viral genome is extensive and that the envelope gene in particular is most highly variable. Within the envelope, changes were most prevalent within the extracellular region where clustered nucleotide substitutions and deletions/insertions were evident. Based on predicted secondary protein structure and hydrophilicity, these hypervariable regions represent potential antigenic sites. In contrast to the hypervariable regions, other sequences in the extracellular envelope and the overall envelope structure (including 18 of 18 cysteine residues), as well as most of the transmembrane region, were highly conserved.     

Computer-assisted analysis of envelope protein sequences of seven human immunodeficiency virus isolates: prediction of antigenic epitopes in conserved and variable regions.

Independent isolates of human immunodeficiency virus (HIV) exhibit a striking genomic diversity, most of which is located in the viral envelope gene. Since this property of the HIV group of viruses may play an important role in the pathobiology of the virus, we analyzed the predicted amino acid sequences of the envelope proteins of seven different HIV strains, three of which represent sequential isolates from a single patient. By using a computer program that predicts the secondary protein structure and superimposes values for hydrophilicity, surface probability, and flexibility, we identified several potential antigenic epitopes in the envelope proteins of the seven different viruses. Interestingly, the majority of the predicted epitopes in the exterior envelope protein (gp120) were found in regions of high sequence variability which are interspersed with highly conserved regions among the independent viral isolates. A comparison of the sequential viral isolates revealed that changes concerning the secondary structure of the protein occurred only in regions which were predicted to be antigenic, predominantly in highly variable regions. The membrane-associated protein gp41 contains no highly variable regions; about 80% of the amino acids were found to be conserved, and only one hydrophilic area was identified as likely to be accessible to antibody recognition. These findings give insight into the secondary and possible tertiary structure of variant HIV envelope proteins and should facilitate experimental approaches directed toward the identification and fine mapping of HIV envelope proteins.     

Hypervariable regions in the putative glycoprotein of hepatitis C virus.

A comparison of the sequences of the putative glycoprotein region in three independent cDNA clones of hepatitis C virus and of sequences of four other clones revealed extensive genetic variation clustered and interspersed with highly conserved amino acid sequences. We obtained evidence for two hypervariable regions in the putative envelope glycoprotein, one region was assumed to be a potential antigenic site, as deduced from the hydrophilicity and analyses of secondary structures. These observations suggest the existence of a large pool of antigenic variants of hepatitis C virus, in Japan.     

Analysis of sequence diversity in hypervariable regions of the external glycoprotein of human immunodeficiency virus type 1.

Nucleotide sequences in three hypervariable regions of the human immunodeficiency virus type 1 (HIV-1) env gene were obtained by sequencing provirus present in peripheral blood mononuclear cells of HIV-infected individuals. Single molecules of target sequences were isolated by limiting dilution and amplified in two stages by the polymerase chain reaction, using nested primers. The product was directly sequenced to avoid errors introduced by Taq polymerase during the amplification process. There was extensive variation between sequences from the same individual as well as between sequences from different individuals. Interpatient variability was markedly less in individuals infected from a common source. A high proportion of amino acid substitutions in the hypervariable regions altered the number and positions of potential N-linked glycosylation sites. Sequences in two hypervariable regions frequently contained short (3- to 15-bp) duplications or deletions, and by amplifying peripheral blood mononuclear cell DNA containing 10(2) or 10(3) proviral molecules and analyzing the product by high-resolution electrophoresis, the total number and abundance of distinct length variants within an individual could be estimated, providing a more comprehensive analysis of the variants present than would be obtained by sequencing alone. Sequences from many individuals showed frequent amino acid substitutions at certain key positions for neutralizing-antibody and cytotoxic T-cell recognition in the immunodominant loop. The rates of synonymous and nonsynonymous nucleotide substitution in the region of this and flanking regions indicate that strong positive selection for amino acid change is operating in the generation of antigenic diversity.     

Structural features of T-cell recognition: applications to vaccine design

T lymphocytes, in contrast to antibodies, appear to recognize primarily a limited number of antigenic sites on any given antigenic protein. We find that a single site can so dominate the T-cell repertoire that the presence or absence of a response to one immunodominant site can make the difference between a high responder and a low responder, even though low responders respond to other sites almost as well as high responders. Besides interaction with major histocompatibility complex (MHC) molecules, the mode by which the antigen is processed into fragments for T-cell recognition also determines which sites are seen. The products of natural processing of the protein appear to be larger than the synthetic peptides and contain structures which hinder binding to certain MHC molecules or to the T-cell receptor. A third factor in immunodominance is the intrinsic structure of the antigenic site. We have shown that amphipathic helices have a higher than random chance of being immunodominant, and have developed a computer program to locate such structures in protein amino acid sequences. We prospectively predicted sites in the malaria circumsporozoite protein and found that the four most widely recognized sites in an endemic area of West Africa were all predicted. Similarly, we identified two helper T-cell sites from the HIV (AIDS virus) envelope, and have now shown that immunization with these elicits enhanced antibody responses to the whole envelope when injected into monkeys. These sites are also recognized by human T cells from volunteers who had been immunized with a recombinant vaccinia virus expressing the HIV envelope. Also, because cytotoxic T lymphocytes (CTLS) may play a critical role in defence against AIDS, we have used a recombinant vaccinia virus and transfectants expressing the HIV envelope gene to induce specific CTLS against the HIV envelope. Using synthetic peptides, we were able to identify the first CTL recognition site in the AIDS virus. These results may contribute to the rational design of vaccines.     

Recovery and altered neutralization specificities of chimeric viruses containing capsid protein domain exchanges from antigenically distinct strains of feline calicivirus

Feline calicivirus (FCV) strains can show significant antigenic variation when tested for cross-reactivity with antisera produced against other FCV strains. Previous work has demonstrated the presence of hypervariable amino acid sequences in the capsid protein of FCV (designated regions C and E) that were postulated to constitute the major antigenic determinants of the virus. To examine the involvement of hypervariable sequences in determining the antigenic phenotype, the nucleotide sequences encoding the E regions from three antigenically distinct parental FCV strains (CFI, KCD, and NADC) were exchanged for the equivalent sequences in an FCV Urbana strain infectious cDNA clone. Two of the three constructs were recovered as viable, chimeric viruses. In six additional constructs, of which three were recovered as viable virus, the E region from the parental viruses was divided into left (N-terminal) and right (C-terminal) halves and engineered into the infectious clone. A final viable construct contained the C, D, and E regions of the NADC parental strain. Recovered chimeric viruses showed considerable antigenic variation from the parental viruses when tested against parental hyperimmune serum. No domain exchange was able to confer complete recognition by parental antiserum with the exception of the KCD E region exchange, which was neutralized at a near-homologous titer with KCD antiserum. These data demonstrate that it is possible to recover engineered chimeric FCV strains that possess altered antigenic characteristics. Furthermore, the E hypervariable region of the capsid protein appears to play a major role in the formation of the antigenic structure of the virion where conformational epitopes may be more important than linear in viral neutralization.     

Molecular characterization of human immunodeficiency virus from Zaire: nucleotide sequence analysis identifies conserved and variable domains in the envelope gene

To examine the genetic relatedness of human immunodeficiency viruses (HIV) from different geographic locations, we molecularly cloned the genome of HIV isolated from a Zairian AIDS patient. Restriction mapping of the recombinant clone, designated HIV-Zr6, revealed both common (as observed in other HIV isolates) and unique restriction sites. The DNA clone of HIV-Zr6, shown to give rise to infectious cytopathic virus after transfection of cultured lymphoid cells, was sequenced in several regions. The long terminal repeat (LTR), open reading frame 1 (ORF1), C-terminal envelope (env) gene domain, and ORF2 showed less than 6% difference in nucleotide sequence when compared to other HIV isolates including human T-lymphotropic virus-type III (HTLV-III) clone B10, lymphadenopathy-associated virus-1 (LAV-1), and AIDS-associated retrovirus-2 (ARV-2). About 15% difference in nucleotide sequences was noted in the N-terminal env gene domain. Alignments of env gene sequences revealed conserved, moderately variable, and hypervariable stretches in the predicted amino acid sequences. This model provides a basis for assessing the significance of sequence variation on properties controlled by the viral Env glycoproteins such as cell tropism and immunogenicity.     

Recombination among Protein II genes of Neisseria gonorrhoeae generates new coding sequences and increases structural variability in the Protein II family

Expression of Neisseria gonorrhoeae Protein II (P.II) is subject to phase variation and antigenic variation. The P.II proteins made by one strain possess both unique and conserved antigenic determinants. To study the mechanism of antigenic variation, we cloned several P.II genes, using as probes a panel of monoclonal antibodies (MAbs) specific for unique determinants. The DNA sequences of three P.II genes showed that they shared a conserved framework, with two short hypervariable (HV) regions being responsible for most of the differences among them. We demonstrated that unique epitopes recognized by the MAbs were at least partially encoded by one of the HV regions. Moreover, we found that reassortment of the two HV regions among P.II genes occurs, generating increased structural and antigenic variability in the P.II protein family.     

Canonical structures for the hypervariable regions of immunoglobulins

We have analysed the atomic structures of Fab and VL fragments of immunoglobulins to determine the relationship between their amino acid sequences and the three-dimensional structures of their antigen binding sites. We identify the relatively few residues that, through their packing, hydrogen bonding or the ability to assume unusual phi, psi or omega conformations, are primarily responsible for the main-chain conformations of the hypervariable regions. These residues are found to occur at sites within the hypervariable regions and in the conserved beta-sheet framework. Examination of the sequences of immunoglobulins of unknown structure shows that many have hypervariable regions that are similar in size to one of the known structures and contain identical residues at the sites responsible for the observed conformation. This implies that these hypervariable regions have conformations close to those in the known structures. For five of the hypervariable regions, the repertoire of conformations appears to be limited to a relatively small number of discrete structural classes. We call the commonly occurring main-chain conformations of the hypervariable regions "canonical structures". The accuracy of the analysis is being tested and refined by the prediction of immunoglobulin structures prior to their experimental determination.     

Stability of RNA stem-loop structure and distribution of non-random structure in the human immunodeficiency virus (HIV-I).

The stability of potential RNA stem-loop structures in human immunodeficiency virus isolates, HTLV-III and ARV, has been calculated, and the relevance to the local significant secondary structures in the sequence has been tested statistically using a Monte Carlo simulation method. Potentially significant structures exist in the 5'non-coding region, the boundary regions between the protein coding frames, and the 3' non-coding region. The locally optimal secondary structure occurring in the 5' terminal region has been assessed using different overlapping segment sizes and the Monte Carlo method. The results show that the most favorable structure for the 5' mRNA leader sequence of HIV has two stem-loops folded at nucleotides 5-104 in the R region (stem-loop I, 5-54 and stem-loop II, 58-104). A large fluctuation of segment score of the local optimal secondary structure also occurs in the boundary between the exterior glycosylated protein or outer membrane protein and transmembrane protein coding region. This finding is surprising since no RNA signals or RNA processing are expected to occur at this site. In addition, regions of the genome predicted to have significantly more open structure at the RNA level correlate closely with hypervariable sites found in these viral genomes. The possible importance of local secondary structure to the biological function of the human immunodeficiency virus genome is discussed.     

Characterization of variable regions in the envelope and S3 open reading frame of equine infectious anemia virus.

The polymerase chain reaction was used to amplify and clone parts of the envelope gene and overlapping S3 open reading frame, thought to encode rev, of the virulent in vivo-derived Th-1 isolate of equine infectious anemia virus (EIAV). The results indicated that EIAV consists of a heterogeneous mixture of genotypes present at the first febrile cycle after initial infection. We showed that the Th-1 isolate apparently contains nondefective genotypes as well as types which have transmembrane protein truncations or are rev deficient. Furthermore, we could confirm the presence of a hypervariable region in the gp90 envelope glycoprotein. Taken together with earlier data on the heterogeneity of the regulatory motifs present in the long terminal repeat sequences of viruses from the same in vivo isolate (S. Carpenter, S. Alexandersen, M. J. Long, S. Perryman, and B. Chesebro, J. Virol. 65:1605-1610, 1991), our findings indicate that EIAV uses a complex system of diversity in biological phenotypes together with variation in regulatory and antigenic makeup to evade host response and to cause persistent infection and recurrent chronic disease.     

Canonical structures for the hypervariable regions of T cell alphabeta receptors

T cell alphabeta receptors have binding sites for peptide-MHC complexes formed by six hypervariable regions. Analysis of the six atomic structures known for Valpha and for Vbeta domains shows that their first and second hypervariable regions have one of three or four different main-chain conformations (canonical structures). Six of these canonical structures have the same conformation in complexes with peptide-MHC complexes, the free receptor and/or in an isolated V domain. Thus, for at least the first and second hypervariable regions in the currently known structures, the conformation of the canonical structures is well defined in the free state and is conserved on formation of complexes with peptide-MHC.We identified the key residues that are mainly responsible for the conformation of each canonical structure. The first and second hypervariable regions of Valpha and Vbeta domains are encoded by the germline V segments. Humans have 37 functional Valpha segments and 47 Vbeta segments, and mice have 20 Vbeta segments. Inspection of the size of their hypervariable regions, and of sites that contain key residues, indicates that close to 70 % of Valpha segments and 90 % of Vbeta segments have hypervariable regions with a conformation of one of the known canonical structures. The alpha and beta V gene segments in both humans and mice have only a few combinations of different canonical structure in their first and second hypervariable regions. In human Vbeta domains, the number of different sequences with these canonical structure combinations is larger than in mice, whilst for Valpha domains it is probably smaller.     

Structure of the Bordetella pertussis gene coding for the serotype 3 fimbrial subunit

Bordetella pertussis strains contain at least three distinct genes coding for fimbrial subunits, designated fim2, fim3, and fimX. The sequences of the fim2 and fimX genes have been published. Here we present the sequence of the fim3 gene. Proximal and distal to the fim3 gene, regions were observed that could function as rho-independent terminators, suggesting that the gene is not part of a larger operon. Comparison of the putative promoter regions of the fim2 and fim3 genes revealed a conserved region containing a stretch of approximately 13 C's. This region may be involved in fimbrial phase variation. A comparison of the deduced amino acid sequences of the three fimbrial subunits revealed conserved, variable, and hypervariable regions. The hypervariable regions coincided with predicted antigenic determinants. Peptides derived from the conserved regions may be incorporated into a future pertussis vaccine to induce antibodies which confer protection against strains producing different fimbrial serotypes.     

Structural repertoire of the human VH segments.

The VH gene segments produce the part of the VH domains of antibodies that contains the first two hypervariable regions. The sequences of 83 human VH segments with open reading frames, from several individuals, are currently known. It has been shown that these sequences are likely to form a high proportion of the total human repertoire and that an individual's gene repertoire produces about 50 VH segments with different protein sequences. In this paper we present a structural analysis of the amino acid sequences produced by the 83 segments. Particular residue patterns in the sequences of V domains imply particular main-chain conformations, canonical structures, for the hypervariable regions. We show that, in almost all cases, the residue patterns in the VH segments imply that the first hypervariable regions have one of three different canonical structures and that the second hypervariable regions have one of five different canonical structures. The different observed combinations of the canonical structures in the first and second regions means that almost all sequences have one of seven main-chain folds. We describe, in outline, structures of the antigen binding site loops produced by nearly all the VH segments. The exact specificity of the loops is produced by (1) sequence differences in their surface residues, particularly at sites near the centre of the combining site, and (2) sequence differences in the hypervariable and framework regions that modulate the relative positions of the loops.     

Antigenic heterogeneity of a foot-and-mouth disease virus serotype in the field is mediated by very limited sequence variation at several antigenic sites.

Antigenic variation in a major discontinuous site (site D) of foot-and-mouth disease virus (FMDV) of serotype C has been evaluated with neutralizing monoclonal antibodies. Isolates representing the major evolutionary sublines previously defined for serotype C were compared. Extensive variation, comparable to that of continuous epitopes within the hypervariable immunodominant site A (the VP1 G-H loop), was found. The amino acid sequences of the complete capsids of three antigenically highly divergent FMDVs (C1 Haute Loire-Fr/69, C5 Argentina/69, and C3 Argentina/85) have been determined and compared with the corresponding sequences previously determined for seven additional type C viruses. Differences in antigenicity are due to a very limited number of substitutions of surface amino acids accessible to antibodies and located within antigenic sites previously identified on FMDV. A significant number of residues at these positions were also replaced in monoclonal antibody escape mutants. Depending on the variants compared, replacements within site A or at site D, or at both sites, contributed significantly to their antigenic differences. Examples of divergence mediated by a few amino acid replacements were found among FMDVs of Europe and South America. The results suggest that within a serotype of FMDV, antigenically highly divergent viruses can arise in the field by very limited sequence variation at exposed key residues of each of several antigenic sites.     

Structure based sequence analysis & epitope prediction of gp41 HIV1 envelope glycoprotein isolated in Pakistan

ABSTRACT: BACKGROUND: Gp41 is an envelope glycoprotein of human immune deficiency virus (HIV). HIV viral glycoprotein gp41, present in complex with gp120, assists the viral entry into host cell. Over eighty thousands individuals are HIV infected in Pakistan which makes about 0.2% of 38.6 million infected patients worldwide. Hence, HIV gp41 protein sequences isolated in Pakistan were analyzed for the CD4 and CD8 T cells binding epitopes. RESULTS: Immunoinformatics tools were applied for the study of variant region of HIV gp41envelope protein. The protein nature was analyzed using freely accessible computational software. About 90 gp41 sequences of Pakistani origin were aligned and variable and conserved regions were found. Four segments were found to be conserved in gp41 viral protein. A method was developed, involving the secondary structure, surface accessibility, hydrophobicity, antigenicity and molecular docking for the prediction and location of epitopes in the viral glycoprotein. Some highly conserved CD4 and CD8 binding epitopes were also found using multiple parameters. The predicted continuous epitopes mostly fall in the conserved region of 1-12; 14-22 and 25-46 and can be used as effective vaccine candidates. CONCLUSION: The study revealed potential HIV subtype a derived cytotoxic T cell (CTL) epitopes from viral proteome of Pakistani origin. The conserved epitopes are very useful for the diagnosis of the HIV 1 subtype a. This study will also help scientists to promote research for vaccine development against HIV 1 subtype a, isolated in Pakistan.     

QUASI analysis of the HIV-1 envelope sequences in the Los Alamos National Laboratory HIV sequence database: pattern and distribution of positive selection sites and their frequencies over years.

The envelope (env) protein of human immunodeficiency virus type 1 (HIV-1) plays a crucial role in virus entry and is a central target for HIV vaccine design. Using the QUASI program, we analyzed the conserved regions of all currently available env sequences in the Los Alamos National Laboratory HIV Sequence Database and identified positive selection (PS) sites that are likely to be restricted by host immune responses. We found that PS sites are dispersed across conserved regions of env sequence, and that the C3, C4, and C5 regions were the most targeted. Several regions were identified as being PS free and were mainly distributed in the C1 and C2 regions. When comparing individual QUASI PS site frequencies across clades and geographical regions with the overall frequency of the entire env database, the env sequences from North America showed significantly lower PS site frequency, while those from Asia were significantly higher using Student's t test. The QUASI PS site frequency of env proteins from viruses isolated from different years showed that the PS site frequencies of the env population increased over time. Our study provides an overview of PS sites across the conserved regions of HIV-1 env sequences.     

Prediction of sequential antigenic regions in proteins

Prediction of antigenic regions in a protein will be helpful for a rational approach to the synthesis of peptides which may elicit antibodies reactive with the intact protein. Earlier methods are based on the assumption that antigenic regions are primarily hydrophilic regions at the surface of the protein molecule. The method presented here is based on the amino acid composition of known antigenic regions in 20 proteins which is compared with that of 314 proteins [(1978) Atlas of Protein Sequence and Structure, vol. 5, suppl. 3, 363-373]. Antigenicity values were derived from the differences between the two data sets. The method was applied to bovine ribonuclease, the B-subunit of cholera toxin and herpes simplex virus type 1 glycoprotein D. There was a good correlation between the predicted regions and previously determined antigenic regions.     

Comparative analysis of variable regions in the variola virus genome

Two segments of the variable terminal regions of the variola virus (VARV) genome were sequenced in 22 strains from the Russian collection, including about 13.5 kb of the left segment and about 10.5 kb of the right segment. The total length of the sequences was over 540 kb. Phylogenetic analysis of the new and published data determined the relationships among 70 VARV strains, the character of their clustering, and the intergroup and intragroup variation of the strain clusters. Loci with the highest polymorphism rate were identified and proved to map to noncoding regions or to regions of damaged open reading frames, characteristic of the ancestral virus. These loci offer attractive possibilities for developing a strategy of VARV strain genotyping. Recombination analysis by different methods did not detect, except for a single case, significant recombination events in the VARV strains examined.