Characterization of hepatitis B virus surface antigen variability and impact on HBs antigen clearance under nucleos(t)ide analogue therapy.

For hepatitis B virus (HBV)-related chronic infection under treatment by nucleos(t)ide analogues (NUCs), HBsAg clearance is the ultimate therapeutic goal but very infrequent. We investigated how HBV envelope protein variability could lead to differential HBsAg clearance on NUCs. For 12 HBV genotype D patients receiving NUCs, six resolvers (HBsAg clearance) were compared to six matched nonresolvers (HBsAg persistence). PreS/S amino acid (aa) sequences were analysed with bioinformatics to predict HBV envelope antigenicity and aa covariance. To enrich our analyses on very rare resolvers, these were compared with other HBV genotype D strains in three characterized clinical cohorts including common chronically infected patients. The sT125M+sP127T combination was observed in four nonresolvers of six, corroborated by aa covariance analysis, associated with a lower predicted antigenicity than sT125T+sP127P. Concordant features within this HBV key functional domain, at positions 125 and 127, were reported from two of the three comparative cohorts. In our hands, a lower ELISA reactivity of HBV-vaccinated mice sera was observed against the sT125M mutant. In the S gene, 56 aa changes in minor variants were detected in non-resolvers, mainly in the major hydrophilic region, vs 28 aa changes in resolvers. Molecular features in patients showing HBsAg persistence on NUCs argue in favour of a different aa pattern in the HBV S gene compared to those showing HBsAg clearance. In nonresolvers, a decrease in HBs 'a' determinant antigenicity and more frequent mutations in the S gene suggest a role for the HBV envelope characteristics in HBsAg persistence.

The recombination-activating gene 1 of Pleurodeles waltl (urodele amphibian) is transcribed in lymphoid tissues and in the central nervous system.

The recombination-activating gene 1 (RAG1) product is required for the somatic rearrangement of immunoglobulin and T-cell receptor genes. We cloned and sequenced the large continuous open reading frame coding for the salamander Pleurodeles waltl RAG1 protein. Semi-quantitative RT-PCR experiments were performed to quantify the expression of RAG1 in different tissues. The strongest signal was observed in the thymus of juvenile animals, confirming the primary lymphoid nature of that organ. Weaker expression was observed in the spleen, brain, and eyes of adults. Signals in these tissues represented 5.5%, 4.6%, and 2.0%, respectively, of the signal detected in the thymus. Expression in brain was confirmed by in situ hybridization. Similarly, low amounts of RAG1 transcripts were previously detected in the mouse brain. Moreover, the transcription of RAG1 begins as early as the neurula stages of development. These data suggest that the RAG1 protein could play a role in the central nervous system of vertebrates.

Allelic polymorphisms and RFLP in the human immunoglobulin lambda light chain locus.

The organization of the human immunoglobulin lambda light chain locus (IGL) was recently described. This locus has been entirely sequenced. To evaluate the extent of the genomic variability existing inside that locus, we compiled all the available sequences of germline IGLV genes to find variants of Vlambda sequences. We also looked for RFLP polymorphisms in a reputedly highly polymorphic human population from eastern Senegal, and compiled all RFLP data previously published. Analysis of these data indicates that IGLV alleles are frequent and increase the diversity of the lambda light chain repertoire in the human population. In contrast, RFLP and polymorphism by insertion and/or deletion are limited in that locus. This observation reinforces our hypothesis that the human IGL locus has undergone less evolutionary shuffling than the human kappa or heavy-chain loci.

The human immunoglobulin lambda variable (IGLV) genes and joining (IGLJ) segments.

The first report of the 'IMGT Locus on Focus' section comprises five tables entitled: (1) 'Number of human germline IGLV genes at 22q11.1-q11.2 and potential repertoire'; (2) 'Human germline IGLV gene table'; (3) 'Human IGLV allele table', (4) 'Human germline IGLJ table' and (5) 'Human IGLJ allele table'. These tables are available at the MariePaule page from IMGT, the international ImMunoGeneTics database (http:/(/)imgt.cnusc.fr:8104) created by Marie-Paule Lefranc, CNRS, Université Montpellier II, Montpellier, France.

Immunoglobulin lambda light chain orphons on human chromosome 8q11.2.

We have identified two V lambda genes outside the major lambda locus on chromosome 22q11.2, and shown that they reside on chromosome 8q11.2. One gene (Orphée1), hybridizing strongly to the V lambda probes, was sequenced and found to belong to the V lambda 8 family; the other gene (Orphée2) only hybridized weakly. Orphée1 was present in all individuals tested (140) from three different populations, and was also found in gorillas. We envisage that these genes were generated by duplication and translocation of the V lambda 8a gene (and a V lambda pseudogene) from the major locus, and that this event occurred before the evolutionary divergence of humans and gorillas. As there is no other evidence for V lambda genes outside the major locus, it appears that the human lambda locus has undergone considerably less evolutionary shuffling than either the human light chain kappa locus or the heavy chain locus.

The IGHG3 gene shows a structural polymorphism characterized by different hinge lengths: sequence of a new 2-exon hinge gene.

Four of the five human IGHG genes (G1, GP, G2, and G4) display a hinge region consisting of a unique exon. In contrast, IGHG3 exhibits a different structure in which the hinge is constituted by four or, less frequently, three exons. We report here the nucleotide sequence of a new 2-exon hinge G3 gene found in a Mandenka individual from Eastern Senegal. A comparison of this sequence with that of 4-exon and 3-exon hinge G3 genes suggests that the 3-exon and 2-exon hinge forms arose independently by deletion events in a 4-exon hinge gene.

Sequence and evolution of the human germline V lambda repertoire.

We recently completed a map of the human immunoglobulin lambda (IGL) locus on chromosome 22q11.2 and showed that the V lambda genes are arranged in three distinct clusters, each containing members of different V lambda families. We have now sequenced each of these V lambda genes and determined which are functional by comparison with the expressed repertoire. Our analysis indicates that there are approximately 30 functional V lambda genes, depending on the haplotype, that belong to ten V lambda families (five V lambda 1, five V lambda 2, eight V lambda 3, three V lambda 4, three V lambda 5, one V lambda 6, two V lambda 7, one V lambda 8, one V lambda 9 and one V lambda 10). V lambda genes related to the major human V lambda families (V lambda 1, V lambda 2 and V lambda 3) predominate in species that express mainly lambda light chains.

Assembly and extension of yeast artificial chromosomes to build up a large locus.

For the assembly of a large human locus, overlapping regions on yeast artificial chromosomes (YACs) and cosmids were linked up using their regions of homology. By site-specific recombination a YAC of 410 kb was created accommodating the major part of the human lambda light chain locus in authentic configuration with 28 variable (V) genes, all joining (J) segments, all constant (C) genes and the downstream enhancer. A contiguous region was first constructed from three overlapping cosmids. Each of these was linearized at unique sites in the vectors and YAC arms were ligated to the 5' and 3' ends. After cells of Saccharomyces cerevisiae were transformed with the three cosmids, YACs of 120 kb were obtained which contained the reassembled 3' J-C region in authentic configuration. The assembled YAC was further extended by mitotic recombination with a YAC containing a 280-kb region of the C-proximal part of the V gene cluster with a 15-kb 3' overlap. For this, a simple three-way selection procedure was developed involving the integration of different selectable marker genes at specific sites in the left and right YAC arms. Rare recombination events between two overlapping YACs could be identified in yeast clones able to grow in lysine- and adenine-deficient medium in the presence of 5-fluoro-orotic acid which is toxic for yeast cells containing a YAC with a functional URA3 gene. This approach made it possible to assemble and extend large YACs from an unlimited number of smaller overlapping YACs by positive-negative selection.

Organization of the human immunoglobulin lambda light-chain locus on chromosome 22q11.2.

The maps of the human immunoglobulin heavy-chain and kappa light-chain loci have recently been completed. We have now completed a map of the human lambda locus (IGL) located on chromosome 22q11.2. We mapped 52 V lambda genes from 10 V lambda families and 7 J lambda and C lambda genes on a 1140 kb contig constructed from eight YACs and 129 cosmid clones. The V lambda genes are arranged within 800 kb. Genes of the different V lambda families are organized in three clusters, V lambda II and III families (cluster A); V lambda I, V, VII and IX families (cluster B); V lambda IV, VI, VIII and X families (cluster C), in contrast to the dispersed organization of the different VH and V kappa families within the human VH and V kappa loci. We note that the most frequently used V lambda families (V lambda II and III) are proximal to the J lambda and C lambda genes. The VpreB gene, encoding part of the surrogate light chain, the GGT2 gene and the BCRL4 pseudogene were also mapped within the lambda locus.

Genomic organisation of 34 kb of the human immunoglobulin lambda locus (IGLV): restriction map and sequences of new V lambda III genes.

In order to improve our knowledge of the human immunoglobulin variable lambda locus (IGLV), we mapped one cosmid clone (designated as C40.2) isolated by screening a Colo320HSR genomic library. The 34 kb insert of the C40.2 clone was shown to contain six genes. One gene, IGLV2S1, belongs to the V lambda II subgroup. Four genes belong to the V lambda III subgroup. Two of them, IGLV3S1 and IGLV3S2, are potentially functional whereas the two others are pseudogenes. The size of the IGLV3S2 leader intron is four times longer than the classical intron size of 110 bp. The cosmid also contains a vestigial sequence lambda vg2. All these genes share the same orientation of transcription. Pulsed field gel electrophoresis analysis of the IGLV locus shows that most of the V lambda I subgroup genes are located at the 5' end of the locus.

Definition of a sequence-tagged site for the human immunoglobulin IGLV9S1 gene located at chromosome 22q11.

We have compared the sequences of the nine human immunoglobulin V lambda gene subgroups in order to define specific sequences for the IGLV9S1 gene. The oligonucleotides corresponding to these regions, in both forward and reverse positions, were used in polymerase chain reactions from human genomic DNA. A unique fragment of 177 base pairs was amplified from positions 136-312 of the IGLV9S1 gene and cloned in pUC18. When used as a probe in Southern hybridization with human genomic DNA, a unique band was detected, indicating that IGLV9S1 is a single-copy gene. We have defined this fragment as a sequence-tagged site designated IGLV9S1 [/22q11] for the IGL locus.

Haplotypes of the human immunoglobulin lambda IGLV7S1 and IGLV1S1 genes defined by restriction-site polymorphism and insertion/deletion of a 6-kb DNA fragment.

Haplotypes were defined in the human immunoglobulin lambda locus by using three probes--V lambda VII, V lambda A, and V lambda I--hybridized to BamHI, KpnI, EcoRI, and HindIII digests. Four KpnI alleles were described. Two of them, 13 kb and 16 kb, detected with both the V lambda VII and V lambda A probes, were correlated with 4.6-kb and 10.5-kb KpnI fragments, respectively, which hybridize to the V lambda I probe. The two others (17 kb and 24 kb) were detected with the three probes V lambda VII, V lambda A, and V lambda I. Moreover, we show that two of those haplotypes may reflect an insertion of 6 kb between V lambda A and V lambda 1S1. Familial studies were performed to demonstrate the Mendelian inheritance. Our results demonstrate the absence of association between the C lambda alleles and V lambda haplotypes.