Atomic model of human cystic fibrosis transmembrane conductance regulator: membrane-spanning domains and coupling interfaces.

We describe herein an atomic model of the outward-facing three-dimensional structure of the membrane-spanning domains (MSDs) and nucleotide-binding domains (NBDs) of human cystic fibrosis transmembrane conductance regulator (CFTR), based on the experimental structure of the bacterial transporter Sav1866. This model, which is in agreement with previous experimental data, highlights the role of some residues located in the transmembrane passages and directly involved in substrate translocation and of some residues within the intracellular loops (ICL1-ICL4) making MSD/NBD contacts. In particular, our model reveals that D173 ICL1 and N965 ICL3 likely interact with the bound nucleotide and that an intricate H-bond network (involving especially the ICL4 R1070 and the main chain of NBD1 F508) may stabilize the interface between MSD2 and the NBD1F508 region. These observations allow new insights into the ATP-binding sites asymmetry and into the molecular consequences of the F508 deletion, which is the most common cystic fibrosis mutation.

Hydrophobic cluster analysis and modeling of the human Rh protein three-dimensional structures.

Rh (Rhesus) is a major blood group system in man, which is clinically significant in transfusion medicine. Rh antigens are carried by an oligomer of two major erythroid specific polypeptides, the Rh (D and CcEe) proteins and the RhAG glycoprotein, that shared a common predicted structure with 12 transmembrane a-helices (M0 to M11). Non erythroid homologues of these proteins have been identified (RhBG and RhCG), notably in diverse organs specialized in ammonia production and excretion, such as kidney, liver and intestine. Phylogenetic studies and experimental evidence have shown that these proteins belong to the Amt/Mep/Rh protein superfamily of ammonium/methylammonium permease, but another view suggests that Rh proteins might function as CO2 gas channels. Until recently no information on the structure of these proteins were available. However, in the last two years, new insight has been gained into the structural features of Rh proteins (through the determination of the crystal structures of bacterial AmtB and archeaebacterial Amt-1. Here, models of the subunit and oligomeric architecture of human Rh proteins are proposed, based on a refined alignment with and crystal structure of the bacterial ammonia transporter AmtB, a member of the Amt/Mep/Rh superfamily. This alignment was performed considering invariant structural features, which were revealed through Hydrophobic Cluster Analysis, and led to propose alternative predictions for the less conserved regions, particularly in the N-terminal sequences. The Rh models, on which an additional Rh-specific, N-terminal helix M0 was tentatively positioned, were further assessed through the consideration of biochemical and immunochemical data, as well as of stereochemical and topological constraints. These models highlighted some Rh specific features that have not yet been reported. Among these, are the prediction of some critical residues, which may play a role in the channel function, but also in the stability of the subunit structure and oligomeric assembly. These results provide a basis to further understand the structure/function relationships of Rh proteins, and the alterations occurring in variant phenotypes.

Nucleotide binding domains of human CFTR: a structural classification of critical residues and disease-causing mutations.

Defective function of the cystic fibrosis (CF) transmembrane conductance regulator (CFTR) causes CF, the most frequent lethal inherited disease among the Caucasian population. The structure of this chloride ion channel includes two nucleotide-binding domains (NBDs), whose ATPase activity controls channel gating. Recently, the experimental structures of mouse and human CFTR NBD1 and our model of the human CFTR NBD1/NBD2 heterodimer have provided new insights into specific structural features of the CFTR NBD dimer. In the present work, we provide a structural classification of CF-causing mutations which may complement the existing functional classification. Our analysis also identified amino acid residues which may play a critical role in interdomain interaction and are located at the NBD1-NBD2 interface or on the surface of the dimer. In particular, a cluster of aromatic amino acids, which includes F508 and straddles the two NBDs, might be directly involved in the interaction of the NBD1/NBD2 heterodimer with the channel-forming membrane-spanning domains.

Nucleotide-binding domains of human cystic fibrosis transmembrane conductance regulator: detailed sequence analysis and three-dimensional modeling of the heterodimer.

The cystic fibrosis transmembrane conductance regulator (CFTR) protein is encoded by the gene that is defective in cystic fibrosis, the most common lethal inherited disease among the Caucasian population. CFTR belongs to the ABC transporter superfamily, whose members form macromolecular architectures composed of two membrane-spanning domains and two nucleotide-binding domains (NBDs). The experimental structures of NBDs from several ABC transporters have recently been solved, opening new avenues for understanding the structure/function relationships and the consequences of some disease-causing mutations of CFTR. Based on a detailed sequence/structure analysis, we propose here a three-dimensional model of the human CFTR NBD heterodimer. This model, which is in agreement with recent experimental data, highlights the specific features of the CFTR asymmetric active sites located at the interface between the two NBDs. Moreover, additional CFTR-specific features can be identified at the subunit interface, which may play critical roles in active site interdependence and are uncommon in other NBD dimers.

uDENN, DENN, and dDENN: indissociable domains in Rab and MAP kinases signaling pathways.

DENN domains are found in a variety of signaling proteins but their exact function remains undefined. Some of the DENN-containing proteins, such as rat Rab3GEP (Rab3 GDP/GTP exchange protein) or mouse Rab6IP1 (Rab6 interacting protein 1) interact with GTPases of the Rab family. Others, such as human MADD (MAP (Mitogen-activated protein) kinase activating protein containing death domain) and human ST5 (Suppressor of tumoreginicity 5) gene products are involved in regulation of MAPKs (Mitogen-activated protein kinases) signaling pathways. Using a combination of profile-based and bidimensional analyses, we show here that DENN domains are much larger than described to date in domain databases, always encircled on both sides by more divergent domains, that we called uDENN and dDENN. These however share conserved amino acids which could play a key role in the DENN functions.

Functional characterization of the phosphorylating D-glyceraldehyde 3-phosphate dehydrogenase from the archaeon Methanothermus fervidus by comparative molecular modelling and site-directed mutagenesis.

Phosphorylating archaeal D-glyceraldehyde 3-phosphate dehydrogenases (GraP-DHs) share only 15-20% identity with their glycolytic bacterial and eukaryotic counterparts. Unlike the latter which are NAD-specific, archaeal GraP-DHs exhibit a dual-cofactor specificity with a marked preference for NADP. In the present study, we have constructed a three-dimensional model of the Methanothermus fervidus GraP-DH based upon the X-ray structures of the Bacillus stearothermophilus and Escherichia coli GraP-DHs. The overall structure of the archaeal enzyme is globally similar to homology modelling-derived structures, in particular for the cofactor binding domain, which might adopt a classical Rossmann fold. M. fervidus GraP-DH can be considered as a dimer of dimers which exhibits negative and positive cooperativity in binding the coenzymes NAD and NADP, respectively. As expected, the differences between the model and the templates are located mainly within the loops. Based on the predictions derived from molecular modelling, site-directed mutagenesis was performed to characterize better the cofactor binding pocket and the catalytic domain. The Lys32Ala, Lys32Glu and Lys32Asp mutants led to a drastic increase in the Km value for NADP (i.e. 165-, 500- and 1000-fold, respectively), thus demonstrating that the invariant Lys32 residue is one of the most important determinants favouring the adenosine 2'-PO42- binding of NADP. The involvement of the side chain of Asn281, which was postulated to play a role equivalent to that of the Asn313 of bacterial and eukaryotic GraP-DHs in fixing the position of the nicotinamide ring in a syn orientation [Fabry, S. & Hensel, R. (1988) Gene 64, 189-197], was ruled out. Most of the amino acids involved in catalysis and in substrate recognition in bacterial and eukaryotic GraP-DHs are not conserved in the archaeal enzyme except for the essential Cys149. Inspection of our model suggests that side chains of invariant residues Asn150, Arg176, Arg177 and His210 are located in or near the active site pocket. The Arg177Asn mutation induced strong allosteric properties with the Pi, indicating that this residue should be located near to the intersubunit interfaces. The Arg176Asn mutation led to a 10-fold decrease in the kcat, a 35-fold increase in the Km value for D-glyceraldehyde 3-phosphate and a 1000-fold decrease in the acylation rate. These results strongly suggest that Arg176 is involved in the Ps site. The His210Asn mutation increased the pKapp of the catalytic Cys149 from 6.3 to 7.6, although no Cys-/His+ ion pair was detectable [Talfournier, F., Colloc'h, N., Mornon, J.P. & Branlant, G. (1998) Eur. J. Biochem. 252, 447-457]. No other invariant amino acid which can play a role as a base catalyst to favour the hydride transfer is located in the active site. The fact that the efficiency of phosphorolysis is 1000-fold lower when compared to the B. stearothermophilus GraP-DH suggests significant differences in the nature of the Pi site. Despite these differences, it is likely that the archaeal GraP-DHs and their bacterial and eukaryotic counterparts have evolved from a common ancestor.

Molecular cloning, expression analysis, and chromosomal localization of human syntaxin 8 (STX8).

We report the cloning of a cDNA encoding human syntaxin 8 (STX8), using the regulator (R) domain of the cystic fibrosis transmembrane conductance regulator (CFTR) as a bait to screen a human fetal lung cDNA library by the yeast two-hybrid system. This gene was found broadly transcribed and its mRNA size is about 1.3 kb. The STX8 gene maps to chromosomal band 17p12 and it encodes a 236-amino-acid protein. Syntaxin 8 contains in its C-terminal half a coiled-coil domain found highly conserved in the t-SNARE (SNAP receptor on target membrane) superfamily of proteins, which are involved in vesicular trafficking and docking. In syntaxin 8, a C-terminal hydrophobic domain may constitute a transmembrane anchor. It was recently shown that CFTR-mediated chloride currents can be regulated by syntaxin 1A, a t-SNARE family member, through direct protein-protein interaction. This raises the possibility that syntaxin 8 may also be involved in such regulations.

The characterization of murine BCMA gene defines it as a new member of the tumor necrosis factor receptor superfamily.

The BCMA gene is a new gene discovered by the molecular analysis of a t(4;16) translocation, characteristic of a human T cell lymphoma. It has no significant similarity with any known protein or motif, so that its function was unknown. This report describes the cloning of murine BCMA cDNA and its genomic counterpart. The mouse gene is organized into three exons, like the human gene, and lies in murine chromosome 16, in the 16B3 band, the counterpart of the human chromosome 16p13 band, where the human gene lies. Murine BCMA cDNA encodes a 185 amino acids protein (184 residues for the human), has a potential central transmembrane segment like the human protein and is 62% identical to it. The murine BCMA mRNA is found mainly in lymphoid tissues, as is human BCMA mRNA. Alignment of the murine and human BCMA protein sequences revealed a conserved motif of six cysteines in the N-terminal part, which strongly suggests that the BCMA protein belongs to the tumor necrosis factor receptor (TNFR) superfamily. Human BCMA is the first member of the TNFR family to be implicated in a chromosomal translocation.

Conservative mutations in the immunosuppressive region of the bovine leukemia virus transmembrane protein affect fusion but not infectivity in vivo.

Many retroviruses, including bovine leukemia virus (BLV), contain a highly conserved region located about 40 amino acids downstream from the fusion peptide within the sequence of the external domain of the transmembrane (TM) protein. This region is notably thought to be involved in the presentation of the NH2-terminal peptide to allow cell fusion. By using hydrophobic cluster analysis and by analogy with the influenza A hemagglutinin structures, the core of the TM structure including this particular region was predicted to consist, in the BLV and other retroviral envelope proteins, of an alpha-helix followed by a loop region, both docked against a subsequent alpha-helix that forms a triple-stranded coiled coil. The loop region could undergo, as in hemagglutinin, a major refolding into an alpha-helix integrating the coiled coil structure and putting the fusion peptide to one tip of the molecule. Based on this model, we have identified amino acids that may be essential to the BLV TM structure, and a series of mutations were introduced in the BLV env gene of an infectious molecular clone. A first series of mutations was designed to disturb the coiled coil structure (substitutions with proline residues), whereas others would maintain the general TM structure. When expressed by Semliki Forest virus recombinants, all the mutated envelope proteins were stable and efficiently synthesized in baby hamster kidney cells. Both proline-substituted and conservative mutants were strongly affected in their capacity to fuse to CC81 indicator cells. In addition, it appeared that the integrity of the TM coiled coil structure is essential for envelope protein multimerization, as analyzed by metrizamide gradient centrifugation. Finally, to gain insight into the role of this coiled coil in the infectious potential of BLV in vivo, the mutated TM genes were introduced in an infectious and pathogenic molecular clone and injected into sheep. It appeared that only the conservative mutations (A60V and A64S) allowed maintenance of viral infectivity in vivo. Since these mutations destroyed the ability to induce syncytia, we conclude that efficient fusion capacity of the recombinant envelopes is not a prerequisite for the infectious potential of BLV in vivo. Viral propagation of these mutants was strongly affected in some of the infected sheep. However, the proviral loads within half of the infected animals (2 out of 2 for A60V and 1 out of 4 for A64S) were close to the wild-type levels. In these sheep, it thus appears that the A60V and A64S mutants propagate efficiently despite being unable to induce syncytia in cell culture.

The immunoglobulin superfamily: an insight on its tissular, species, and functional diversity.

The immunoglobulin superfamily (IgSF) is a heterogenic group of proteins built on a common fold, called the Ig fold, which is a sandwich of two beta sheets. Although members of the IgSF share a similar Ig fold, they differ in their tissue distribution, amino acid composition, and biological role. In this paper we report an up-to-date compilation of the IgSF where all known members of the IgSF are classified on the basis of their common functional role (immune system, antibiotic proteins, enzymes, cytokine receptors, etc.) and their distribution in tissue (neural system, extracellular matrix, tumor marker, muscular proteins, etc.), or in species (vertebrates, invertebrates, bacteria, viruses, fungi, and plants). The members of the family can contain one or many Ig domains, comprising two basic types: the constant domain (C), with seven strands, and the variable domain (V), with eight, nine, or ten strands. The different overviews of the IgSF led to the definition of new domain subtypes, mainly concerning the C type, based on the distribution of strands within the two sheets. The wide occurrence of the Ig fold and the much less conserved sequences could have developed from a common ancestral gene and/or from a convergent evolutionary process. Cell adhesion and pattern recognition seem to be the common feature running through the entire family.

Comparative study of the catalytic domain of phosphorylating glyceraldehyde-3-phosphate dehydrogenases from bacteria and archaea via essential cysteine probes and site-directed mutagenesis.

Phosphorylating glyceraldehyde-3-phosphate dehydrogenase (GraP-DH) catalyzes the oxidative phosphorylation of D-glyceraldehyde-3-phosphate to form 1.3-diphosphoglycerate. The currently accepted mechanism involves an oxidoreduction step followed by a phosphorylation. Two essential aminoacids, Cys149 and His176 are involved in the chemical mechanism of bacterial and eukaryotic GraP-DHs. Roles have been assigned to the His176 as (a) a chemical activator for enhancing the reactivity of Cys149, (b) a stabilizator of the tetrahedral transition states, and (c) a base catalyst facilitating hydride transfer towards NAD. In a previous study carried out on Escherichia coli GraP-DH [Soukri, A., Mougin, A., Corbier, C., Wonacott, A. J., Branlant, C. & Branlant, G. (1989) Biochemistry, 28, 2586-2592], the role of His176 as an activator of the reactivity of Cys149 was studied. Here, we further investigated the role of the His residue in the chemical mechanism of phosphorylating GraP-DH from E. coli and Bacillus stearothermophilus. The chemical reactivity of Cys149 in the His176Asn mutant was reinvestigated. At neutral pH, its reactivity was shown to be at least as high as that observed in the Cys-/His+ ion pair present in the wild type. No pre-steady state burst of NADH was found with the His176Asn mutant in contrast to what is observed for the wild type, and a primary isotope effect was observed when D-[1-2H]glyceraldehyde-3-phosphate was used as the substrate. Therefore, the major role of the His176 in the catalytic mechanism under physiological conditions is not to activate the nucleophilicity of Cys149 but first to facilitate the hydride transfer. These results hypothesized that a phosphorylating GraP-DH possessing a different protein environment competent to increase the nucleophilic character of the essential Cys residue and to favor the hydride transfer in place of His, could be enzymically efficient. This is most likely the case for archaeal Methanothermus fervidus GraP-DH which shares less than 15% amino-acid identity with the bacterial or eukaryotic counterparts. No Cys-/His+ ion pair was detectable. Only one thiolate entity was observed with an apparent pKa of 6.2. This result was confirmed by the fact that none of the mutations of the five invariant His changed the catalytic efficiency.

Janus kinases and focal adhesion kinases play in the 4.1 band: a superfamily of band 4.1 domains important for cell structure and signal transduction.

The band 4.1 domain was first identified in the red blood cell protein band 4.1, and subsequently in ezrin, radixin, and moesin (ERM proteins) and other proteins, including tumor suppressor merlin/schwannomin, talin, unconventional myosins VIIa and X, and protein tyrosine phosphatases. Recently, the presence of a structurally related domain has been demonstrated in the N-terminal region of two groups of tyrosine kinases: the focal adhesion kinases (FAK) and the Janus kinases (JAK). Additional proteins containing the 4.1/JEF (JAK, ERM, FAK) domain include plant kinesin-like calmodulin-binding proteins (KCBP) and a number of uncharacterized open reading frames identified by systematic DNA sequencing. Phylogenetic analysis of amino acid sequences suggests that band 4.1/JEF domains can be grouped in several families that have probably diverged early during evolution. Hydrophobic cluster analysis indicates that the band 4.1/JEF domains might consist of a duplicated module of approximately 140 residues and a central hinge region. A conserved property of the domain is its capacity to bind to the membrane-proximal region of the C-terminal cytoplasmic tail of proteins with a single transmembrane segment. Many proteins with band 4.1/JEF domains undergo regulated intra- or intermolecular homotypic interactions. Additional properties common to band 4.1/JEF domains of several proteins are binding of phosphoinositides and regulation by GTPases of the Rho family. Many proteins with band 4. 1/JEF domains are associated with the actin-based cytoskeleton and are enriched at points of contact with other cells or the extracellular matrix, from which they can exert control over cell growth. Thus, proteins with band 4.1/JEF domain are at the crossroads between cytoskeletal organization and signal transduction in multicellular organisms. Their importance is underlined by the variety of diseases that can result from their mutations.

From BRCA1 to RAP1: a widespread BRCT module closely associated with DNA repair.

Inherited mutations in BRCA1 predispose to breast and ovarian cancer, but the biological function of the BRCA1 protein has remained largely elusive. The recent correspondence of Koonin et al. [Koonin, E.V., Altschul, S.F. and Bork, P. (1996) Nature Genet. 13, 266-267] has emphasized the potential importance of the BRCA1 C-terminal region for BRCA1-mediated breast cancer suppression, as this domain shows similarities with the C-terminal regions of a p53-binding protein (53BP1), the yeast RAD9 protein involved in DNA repair, and two uncharacterized, hypothetical proteins (KIAA0170 and SPAC19G10.7). The highlighted domain has been suggested to be the result of an internal duplication, each of the tandem domains being designated as a 'BRCT domain' (for BRCA1 C-terminus). Sequence analysis using hydrophobic cluster analysis reveals here the presence of 50 copies of the BRCT domain in 23 different proteins, including, in addition to BRCA1, 53BP1 and RAD9, XRCC1, RAD4, Ect2, REV1, Crb2, RAP1, terminal deoxynucleotidyltransferases (TdT) and three eukaryotic DNA ligases. Most of these proteins are known to be involved in DNA repair. The BRCT domain is not limited to the C-termini of protein sequences and can be found in multiple copies or in a single copy as in RAP1 and TdT, suggesting that it could well constitute an autonomous folding unit of approx. 90-100 amino acids.

Cloning and characterization of MN, a human tumor-associated protein with a domain homologous to carbonic anhydrase and a putative helix-loop-helix DNA binding segment.

MN is a transmembrane glycoprotein that has been detected in HeLa cells and in some human carcinomas. The expression of MN protein in HeLa cells is regulated by cell density. In HeLa x fibroblast cell hybrids its expression correlates with tumorigenicity. Using a specific monoclonal antibody we have identified a cDNA clone coding for MN. Analysis of the deduced amino acid sequence revealed strong structural homology between the central region of the MN protein and carbonic anhydrases (CA). MN sequence retains the conserved zinc-binding site as well as the enzyme's active center. In accord with these findings, MN protein from HeLa cells was found to bind zinc and to have carbonic anhydrase activity. The N-terminal region of MN shares some similarity with DNA binding proteins of the helix-loop-helix (HLH) family, and the protein was found to have affinity for DNA by DNA-cellulose chromatography. The region between the CA-like domain and the putative HLH domain is rich in imperfect repeats of serine, proline, glycine and acidic residues with few hydrophobic amino acids, resembling thus an activation region of transcription factors. The fact that MN protein is detectable in several types of human carcinomas, but not in corresponding non-cancerous tissues, suggests its possible role in neoplasia. In addition, the analysis of biological consequences of MN expression of NIH3T3 cells provides the evidence in favour of MN protein involvement in control of cell proliferation and transformation.

Redox mechanism for the chaperone activity of heat shock proteins HSPs 60, 70 and 90 as suggested by hydrophobic cluster analysis: hypothesis.

We have recently shown that the N-terminal ATPase fragment of hsp70 (1-375, composed of domains I and II) as well as the subsequent domain III (376-520) may share three-dimensional similarities with hsp60. In this study, we propose that domain III, common to the hsp60s and hsp70s is also found in the hsp90s and adopts a beta-alpha-beta Rossmann-folded structure which is encountered in the NAD-binding domain of dehydrogenases. Consequently, with the help of the domain IV (in hsp70s and hsp90s) or of hsp10/GroES (in hsp60s) and possibly that of auxilliary partners, the hsp molecules could act as "unfoldases" or "reset systems" by disrupting secondary structures through redox reactions on the main polypeptidic chain with which they interact. The models built on this hypothesis may open up a new way for understanding the chaperone functions within the folding/unfolding processes.

Identification of functional sites on bovine leukemia virus envelope glycoproteins using structural and immunological data.

Sequence analysis using the sensitive hydrophobic cluster analysis method shows that the bovine leukemia virus envelope glycoproteins conserve the general organization of the influenza hemagglutinin into a 'stem', containing the external part of the transmembrane glycoprotein and the N-terminal and C-terminal parts of the external glycoprotein, and a 'head', containing only external glycoprotein residues. However, our analysis suggests, for the first time, that the bovine leukemia virus envelope head will not adopt the typical 'jelly-roll' fold of the influenza A hemagglutinin head, but most likely folds into another type of 'Greek-key' structure corresponding to the overall topology of constant immunoglobulin domains. We constructed a three-dimensional model for the bovine leukemia virus envelope head by homology modeling using the crystal structure of the human histocompatibility antigen HLA-A2 alpha 3 domain. Furthermore, we propose a general model for the oligomeric organization of this head, based on the hemagglutinin trimer. The proposed structural organization of bovine leukemia virus external glycoprotein is further supported by antipeptide and monoclonal antibody reactivities. Our modeling study suggests that the loops of the two neutralizing peptides located in the head are adjacent at the top of the domain and define a potential interaction site of the external glycoprotein with its cellular receptor. This site is topologically similar to the binding site of hemagglutinin with its cellular receptor, sialic acid. The other neutralizing peptides are located within a small domain linking the head to the stem. These data are of interest for defining other oncoviral glycoproteins heads and receptor-binding sites.

Common prevalence of alanine and glycine in mobile reactive centre loops of serpins and viral fusion peptides: do prions possess a fusion peptide?

Serpin reactive centre loops and fusion peptides released by proteolytic cleavage are particularly mobile. Their amino acid compositions reveal a common and unusual abundance of alanine, accompanied by high levels of glycine. These two small residues, which are not simultaneously abundant in stable helices (standard or transmembrane), probably play an important role in mobility. Threonine and valine (also relatively small amino acids) are also abundant in these two kinds of peptides. Moreover, the known 3D structures of an uncleaved serpin reactive centre and a fusion peptide are strikingly similar. Such sequences possess many small residues and are found in several signal peptides and in PrP, a protein associated with spongiform encephalopathies and resembling virus envelope proteins. These properties may be related to the infection mechanisms of these diseases.

Automat: a novel software system for the systematic search for protein (or DNA) similarities with a notable application to autoimmune diseases and AIDS.

Automat is a novel program which finds exhaustively all the oligopeptide segments shared by a given protein of any size with the proteins of a whole databank. It allows the user to collect statistics on the composition of the sequence studied in reference to the databank used. We present here the rationale and the algorithm underlying this powerful software. Besides its immediate interest for identifying efficiently similarities between proteins (or DNAs), biological applications of this software have already been described in the case of HIV-1 viral proteins, and Automat should prove useful also for studying more generally autoimmune diseases.

The bovine leukemia virus (BLV) envelope glycoprotein gp51 as a general model for the design of a subunit vaccine against retroviral infection: mapping of functional sites through immunological and structural data.

Further advances in retroviral vaccine development require a better understanding of the antigenic structure of the envelope complex which is directly involved in infectivity events such as receptor recognition and membrane fusion. To design an optimal vaccine against BLV infection, we chose an approach based on the use of synthetic peptides covering 78% of the gp51 sequence in order to select only those segments that could induce a protective response via cellular and humoral immunity. On the other hand, we built a model of the BLV env glycoprotein 3D organization, based upon the very sensitive hydrophobic cluster analysis (HCA). The major information highlighted from this model is that the two loops, against which the most efficient neutralizing antipeptides antibodies are directed against, are in close proximity at the top of the "head" and could represent a potential site for receptor binding. These two peptides are of particular interest since they induce also a helper T-cell response. We further propose that the BLV envelope glycoprotein oligomerizes as a trimer.

Structural similarities between chaperone molecules of the HSP60 and HSP70 families deduced from hydrophobic cluster analysis.

In this study, the conservation of strong structural landmarks between all the members of two chaperone families (HSP60 and HSP70) was deduced from their sequences by hydrophobic cluster analysis. On this basis, we propose that the ATP-binding environment is maintained by a similar fold in both protein families. The observed similarities extend throughout the proteins, including both the ATPase domain and the C-terminal substrate-binding domain.