The evolution of the immunoglobulin heavy chain variable region (IgVH) in Leporids: an unusual case of transspecies polymorphism.

In domestic rabbit (Oryctolagus cuniculus), three serological types have been distinguished at the variable domain of the antibody H chain, the so-called V(H) a allotypes a1, a2, and a3. They correspond to highly divergent allelic lineages of the V(H) 1 gene, which is the gene rabbit utilizes in more than 80% of VDJ rearrangements. The sharing of serological V(H) a markers between rabbit and snowshoe hare (Lepus americanus) has suggested that the large genetic distances between rabbit V(H) 1 alleles (9-14% nucleotide differences) can be explained by unusually long lineage persistence times (transspecies polymorphism). Because this interpretation of the serological data is uncertain, we have determined the nucleotide sequences of V(H) genes expressed in specimens of Lepus species. Two sequence groups were distinguished, one of which occurred only in hare specimen displaying serological motifs of the rabbit V(H) a-a2 allotype. Sequences of this group are part of a monophyletic cluster containing the V(H) 1 sequences of the rabbit a2 allotype. The fact that this "transspecies a2 cluster" did not include genes of other rabbit V(H) a allotypes (a1, a3, and a4) is incompatible with the existence of a common V(H) a ancestor gene within the species, and suggests that the divergence of the V(H) a lineages preceded the Lepus vs Oryctolagus split. The sequence data are furthermore compatible with the hypothesis that the V(H)a polymorphism can be two times older than the divergence time between the Lepus and Oryctolagus lineages, which was estimated at 16-24 million years.

A single 3' alpha hs1,2 enhancer in the rabbit IgH locus.

Multiple cis-acting elements including the intronic enhancer and the 3'alpha enhancer (3'alphaE) regulate expression of the Ig heavy chain genes during B cell development. A 3'alphaE is composed of DNase I-hypersensitive sites, hs1,2, hs3a,b, and hs4, found 3' of the murine Calpha gene as well as 3' of both human Calpha genes, Calpha1 and Calpha2. Rabbits have 13 Calpha genes, and we tested whether a 3'alphaE is associated with each of these genes. To identify 3'alphaE regions we developed a rabbit hs1,2 probe and used this to search for enhancer homologues of human hs1,2 in a genomic fosmid library. We identified a single hs1,2 fragment 8-kb downstream of Calpha13, the presumed 3'-most Calpha gene. We also identified and partially sequenced a new Calpha gene, Calpha14, located 6 kb upstream of Calpha13. Genomic Southern blot analysis confirmed that the rabbit genome contains only one hs1,2 enhancer region. We tested the enhancer activity of the hs1,2 with the SV40, V(H), and Ialpha promoters using the luciferase reporter gene in transient transfection assays and found that it significantly enhanced the activity of SV40 and V(H) promoters and slightly enhanced an Ialpha promoter. We conclude that the rabbit has a single hs1,2 enhancer that resides at the 3' end of the IgH gene cluster and may constitute one of the cis-elements regulating the expression of IgH genes.

Development of the antibody repertoire in rabbit: gut-associated lymphoid tissue, microbes, and selection.

Rabbits generate their antibody repertoire in three stages. First, a neonatal repertoire is generated by B lymphopoiesis in fetal liver and bone marrow and is limited by preferential V(H) gene segment usage. Between 4 and 8 weeks after birth a complex primary antibody repertoire is developed by somatically diversifying the neonatal repertoire through somatic hypermutation and a somatic gene conversion-like mechanism in gut-associated lymphoid tissue (GALT). In rabbits, unlike other species, the development of the primary antibody repertoire through somatic diversification of Ig genes appears to be dependent on intestinal microbial flora. The primary antibody repertoire is subsequently modified during antigen-dependent immune responses in which VDJ genes further diversify both by somatic hypermutation and by a gene conversion-like mechanism (the secondary repertoire). During the various stages of development, the antibody repertoire is modified and shaped by selective processes. In this review, we discuss the roles of GALT, microbes, and B-cell selection in generating antibody diversity in rabbits.

Intestinal microflora and diversification of the rabbit antibody repertoire.

The rabbit establishes its primary Ab repertoire by somatically diversifying an initial repertoire that is limited by restricted VH gene segment usage during VDJ gene rearrangement. Somatic diversification occurs in gut-associated lymphoid tissue (GALT), and by about 1-2 mo of age nearly all Ig VDJ genes are somatically diversified. In other species that are known to establish their primary Ab repertoire by somatic diversification, such as chicken, sheep, and cattle, diversification appears to be developmentally regulated: it begins before birth and occurs independent of exogenous factors. Because somatic diversification in rabbit occurs well after birth in GALT, the diversification process may not be developmentally regulated, but may require interaction with exogenous factors derived from the gut. To test this hypothesis, we examined Ab repertoire diversification in rabbits in which the appendix was ligated shortly after birth to prevent microbial colonization and all other organized GALT was surgically removed. We found that by 12 wk of age nearly 90% of the Ig VDJ genes in PBL were undiversified, indicating that intestinal microflora are required for somatically diversifying the Ab repertoire. We also examined repertoire diversification in sterilely derived remote colony rabbits that were hand raised away from contact with conventional rabbits and thereby acquired a different gut microflora. In these remote colony rabbits, GALT was underdeveloped, and 70% of the Ig VDJ genes in PBL were undiversified. We conclude that specific, currently unidentified intestinal microflora are required for Ab repertoire diversification.

B lymphocyte selection and age-related changes in VH gene usage in mutant Alicia rabbits.

Young Alicia rabbits use VHa-negative genes, VHx and VHy, in most VDJ genes, and their serum Ig is VHa negative. However, as Alicia rabbits age, VHa2 allotype Ig is produced at high levels. We investigated which VH gene segments are used in the VDJ genes of a2 Ig-secreting hybridomas and of a2 Ig+ B cells from adult Alicia rabbits. We found that 21 of the 25 VDJ genes used the a2-encoding genes, VH4 or VH7; the other four VDJ genes used four unknown VH gene segments. Because VH4 and VH7 are rarely found in VDJ genes of normal or young Alicia rabbits, we investigated the timing of rearrangement of these genes in Alicia rabbits. During fetal development, VH4 was used in 60-80% of nonproductively rearranged VDJ genes, and VHx and VHy together were used in 10-26%. These data indicate that during B lymphopoiesis VH4 is preferentially rearranged. However, the percentage of productive VHx- and VHy-utilizing VDJ genes increased from 38% at day 21 of gestation to 89% at birth (gestation day 31), whereas the percentage of VH4-utilizing VDJ genes remained at 15%. These data suggest that during fetal development, either VH4-utilizing B-lineage cells are selectively eliminated, or B cells with VHx- and VHy-utilizing VDJ genes are selectively expanded, or both. The accumulation of peripheral VH4-utilizing a2 B cells with age indicates that these B cells might be selectively expanded in the periphery. We discuss the possible selection mechanisms that regulate VH gene segment usage in rabbit B cells during lymphopoiesis and in the periphery.

Antigen-induced somatic diversification of rabbit IgH genes: gene conversion and point mutation.

During T cell-dependent immune responses in mouse and human, Ig genes diversify by somatic hypermutation within germinal centers. Rabbits, in addition to using somatic hypermutation to diversify their IgH genes, use a somatic gene conversion-like mechanism, which involves homologous recombination between upstream VH gene segments and the rearranged VDJ genes. Somatic gene conversion and somatic hypermutation occur in young rabbit gut-associated lymphoid tissue and are thought to diversify a primary Ab repertoire that is otherwise limited by preferential VH gene segment utilization. Because somatic gene conversion is rarely found within Ig genes during immune responses in mouse and human, we investigated whether gene conversion in rabbit also occurs during specific immune responses, in a location other than gut-associated lymphoid tissue. We analyzed clonally related VDJ genes from popliteal lymph node B cells responding to primary, secondary, and tertiary immunization with the hapten FITC coupled to a protein carrier. Clonally related VDJ gene sequences were derived from FITC-specific hybridomas, as well as from Ag-induced germinal centers of the popliteal lymph node. By analyzing the nature of mutations within these clonally related VDJ gene sequences, we found evidence not only of ongoing somatic hypermutation, but also of ongoing somatic gene conversion. Thus in rabbit, both somatic gene conversion and somatic hypermutation occur during the course of an immune response.

In vitro induction of the expression of multiple IgA isotype genes in rabbit B cells by TGF-beta and IL-2.

The rabbit genome has 13 different Calpha genes that are expressed at different levels in mucosal tissues. To analyze the factors involved in the differential expression of these Calpha genes, we cloned and sequenced the promoters of the Ialpha regions that control the expression of sterile mRNA. We found that all Calpha genes, including Calpha3 and Calpha8, which are not expressed, and Calpha4, which is expressed at high levels, have similar nucleotide sequences in the Ialpha region, and all contain the recognition elements for TGF-beta in the promoter. B lymphocytes from popliteal lymph nodes or Peyer's patch activated in vitro could be induced by TGF-beta to express sterile IgA transcripts of all IgA isotypes, except Calpha2, Calpha3, and Calpha8. Many single B lymphocytes transcribed sterile mRNA of more than one IgA isotype, which demonstrates that transcription of sterile mRNA alone does not regulate the IgA isotype switch. The addition of IL-2 led to the expression of transcripts of mature IgA of all isotypes, except Calpha2, Calpha3, and Calpha8. The predominantly expressed isotype in these experiments was Calpha4. With the use of an IgA4-specific mAb we found that IgA4+ plasma cells are unevenly distributed throughout the small intestine such that many of the IgA+ plasma cells in the duodenum-jejunum produced IgA4, whereas in the lower part of the ileum IgA4-producing cells were almost absent. Because the microbial flora varies throughout the intestine, we suggest that the microbial flora creates different local environments and thus affects either isotype switching or homing of IgA-expressing cells.

Trans-chromosomal recombination within the Ig heavy chain switch region in B lymphocytes.

Somatic DNA rearrangements in B lymphocytes, including V(D)J gene rearrangements and isotype switching, generally occur in cis, i. e., intrachromosomally. We showed previously, however, that 3 to 7% of IgA heavy chains have the VH and Calpha regions encoded in trans. To determine whether the trans-association of VH and Calpha occurred by trans-chromosomal recombination, by trans-splicing, or by trans-chromosomal gene conversion, we generated and analyzed eight IgA-secreting rabbit hybridomas with trans-associated VH and Calpha heavy chains. By ELISA and by nucleotide sequence analysis we found that the VH and Calpha regions were encoded by genes that were in trans in the germline. We cloned the rearranged VDJ-Calpha gene from a fosmid library of one hybridoma and found that the expressed VH and Calpha genes were juxtaposed. Moreover, the juxtaposed VH and Calpha genes originated from different IgH alleles. From the same hybridoma, we also identified a fosmid clone with the other expected product of a trans-chromosomal recombination. The recombination breakpoint occurred within the Smicro/Salpha region, indicating that the trans-association of VH and Calpha genes occurred by trans-chromosomal recombination during isotype switching. We conclude that trans-chromosomal recombination occurs at an unexpectedly high frequency (7%) within the IgH locus of B lymphocytes in normal animals, which may explain the high incidence of B-cell tumors that arise from oncogene translocation into the IgH locus.

Transchromosomally derived Ig heavy chains.

During an immune response, activated B cells undergo isotype switching and begin to express isotypes other than IgM and IgD. Isotype switching occurs when downstream C gamma, C alpha, or C epsilon genes are rearranged into the S mu chromosomal region, resulting in the deletion of the region in between. These rearrangements usually occur in cis, i.e., intrachromosomally. In previous studies, we analyzed allotypic specificities of rabbit secretory IgA and identified a substantial number of IgA heavy chains with VH and C alpha allotypes that were encoded by VH and C alpha genes in trans. In those studies, however, we could not determine whether the trans association of VH and C alpha occurred during VDJ gene rearrangement or during isotype switching. Here, we cloned rabbit cDNA which encodes these trans IgA heavy chains and determined the chromosomal origin of the VH, JH, and C alpha regions. To determine whether the trans association occurred during VDJ gene rearrangement, we analyzed the nucleotide polymorphism of the JH region and the VH allotype encoded by the cDNA. We found that the VH and JH genes used in the VDJ gene rearrangements were from the same chromosome, indicating that the VH, D, and JH gene rearrangements occurred in cis. Furthermore, we analyzed the DNA polymorphisms of JH and C alpha and showed that the VDJ and C alpha genes encoding the trans IgA molecules were derived from different parental chromosomes. We suggest that the trans association occurred during isotype switching. This study shows that VH and CH can associate transchromosomally as part of a normal immune response.

Neonatal VH, D, and JH gene usage in rabbit B lineage cells.

The neonatal antibody repertoire in both mouse and humans differs from that of the adult repertoire in that the neonatal repertoire uses a limited set of JH-proximal VH genes but the adult repertoires use many different VH genes. Rabbits are unusual in that adults use only three or four VH genes, with approximately 80% of the B cells using VH1, the 3'-most VH gene. To investigate whether the repertoire of neonatal rabbits differs from that of adults, we analyzed VH, D, and JH gene usage in B cells of neonatal rabbits. A total of 68 rearranged VDJ genes was cloned from mRNA and genomic DNA isolated from lymphoid tissues of newborn to 10-day-old rabbits. We found that 74% of the VDJ gene rearrangements utilized VH1 and 15% utilized the genes that we designated VHx or VHy. From the remaining VDJ genes we identified seven novel VH genes, one, VHz, which was found in mRNA. We conclude that the repertoire of utilized VH genes in neonates is limited and is similar to that of adult rabbits. We also found the D1, D2a, D2b, and JH4 gene segments preferentially rearranged. We suggest that the preferential usage of VH, D, and JH gene segments in VDJ genes is caused by preferential rearrangement rather than by selective expansion of B cells that utilize the gene segments.

Limited repertoire of utilized VH gene segments in a VHa3-allotype-suppressed rabbit.

Between 70 and 90% of serum Ig molecules of normal laboratory rabbits bear one of the serologically defined VHa allotypic specificities, a1, a2, or a3, and are termed VHa+ (a-positive) molecules; the remaining 10-30% of Ig molecules that do not have VHa allotypic specificities are designated VHa- (a-negative). The repertoire of utilized VHa(+)-encoding gene segments has been examined extensively, but only limited studies of the repertoire of utilized VHa(-)-encoding gene segments in normal rabbits have been done. To examine the repertoire of utilized VHa- gene segments, we analyzed VH-encoding cDNA clones from mRNA of a VHa-allotype-suppressed rabbit whose serum Ig was primarily VHa-. For VHa suppression a newborn a3/a3 rabbit was injected periodically with anti-VHa3 antiserum; when it was 2 months of age and its serum Ig was greater than 94% VHa-, cDNA clones were generated from splenic RNA. The nucleotide sequences of eight putative VHa(-)-encoding cDNA clones were compared to those of eight cDNA clones generated from RNA of non-suppressed a3/a3 rabbits. The presumed VHa3-encoding cDNA clones from the non-suppressed rabbits appeared to derive from VH1-a3, the 3'-most germline VH gene segment. In contrast, the VHa(-)-encoding cDNA clones from the suppressed rabbit were distinctly different from VH1 and were most probably derived from germline VH segments other than VH1. Because the expressed VHa- gene repertoire was highly restricted, we propose that VHa- molecules in a3/a3 rabbits may be derived from as few as three germline VH gene segments.

VDJ genes in VHa2 allotype-suppressed rabbits. Limited germline VH gene usage and accumulation of somatic mutations in D regions.

In this study we investigate the molecular genetic basis for VHa- Ig. Knowing that the expression of VHa allotype Ig is suppressed by neonatal injection of rabbits with anti-VHa allotype antibody, and that the decreased level of VHa allotype Ig, VHa+, in the suppressed rabbits is compensated for by an increase in VHa- Ig, we determined the nucleotide sequences of 41 VDJ genes from a2/a2 rabbits neonatally suppressed for the expression of a2 Ig. We compared these nucleotide sequences to each other and identified two groups of VH sequences. We predict that the molecules of each group are encoded by one germline VH gene. Inasmuch as VHa+ Ig is encoded predominantly by one germline VH gene, VH1, it appears that more than 95% of the VDJ repertoire of rabbits may be encoded by as few as three germline VH genes. A genomic VDJ gene whose VH sequence was similar to those of group I molecules was expressed in vitro and was shown by ELISA to encode molecules of the VHa- allotype, y33. Analysis of the D regions in the VDJ gene indicated that germline D2b and D3 gene segments were preferentially used in the VDJ gene rearrangement. A comparison of sequences of D regions of the 41 VDJ gene rearrangements in 3-, 6-, and 9-wk-old rabbits to sequences of germline D gene segments showed an accumulation of mutations in the D region. Inasmuch as we have previously shown that V regions of rabbit VDJ genes are diversified, in part, by somatic gene conversion, it appears now that rabbit VDJ genes diversify by a combination of somatic mutation and somatic gene conversion.

Immunomopharmacological effects of polysaccharides from Acanthopanax senticosus on experimental animals.

Polysaccharides PES isolated from a common Oriental herb Acanthopanax senticosus were found to have a wide spectrum of immunomodulatory activities on experimental animals. The potential usefulness of these polysaccharides is suggested in the observations that PES inhibited transplanted tumor growths and ameliorated toxicities of the toxic substances in experimental animals. Of most interest is the observations that they suppressed human TB propagation in mice and guinea pigs, as evaluated by lymph node responses and OT skin tests in the guinea pig model, and the quantitation of the TB in the lungs in the mouse model.

Limited number of immunoglobulin VH regions expressed in the mutant rabbit "Alicia".

A unique feature of rabbit Ig is the presence of VH region allotypic specificities. In normal rabbits, more than 80% of circulating immunoglobulin molecules bear the VHa allotypic specificities, al, a2 or a3; the remaining 10% to 20% of immunoglobulin molecules lack VHa allotypic specificities and are designated VHa-. A mutant rabbit designated Alicia, in contrast, has predominantly serum immunoglobulin molecules that lack the VHa allotypic specificities (Kelus and Weiss, Proc. Natl. Acad. Sci. USA 1986. 83: 4883). To study the nature and molecular complexity of VHa- molecules, we cloned and determined the nucleotide sequence of seven cDNA prepared from splenic RNA of an Alicia rabbit. Six of the clones appeared to encode VHa- molecules; the framework regions encoded by these clones were remarkably similar to each other, each having an unusual insertion of four amino acids at position 10. This insertion of four amino acids has been seen in only 2 of 54 sequenced rabbit VH genes. The similarity of the sequences of the six VHa- clones to each other and their dissimilarity to most other VH genes leads us to suggest that the VHa- molecules in Alicia rabbits are derived predominantly from one or a small number of very similar VH genes. Such preferential utilization of a small number of VH genes may explain the allelic inheritance of VH allotypes.

The IgA heavy-chain gene family in rabbit: cloning and sequence analysis of 13 C alpha genes.

Southern analysis has previously shown that the rabbit genome contains multiple genes coding for the constant regions of IgA heavy chains. In the present study, clones containing these C alpha genes have been isolated from cosmid and phage libraries. Restriction mapping and Southern analysis of the clones identified 13 non-allelic C alpha genes; 11 of the genes were clustered in individual or overlapping clones. The clustered genes are separated by 8-18 kb, and in total, the C alpha genes span a minimum of 160 kb of DNA. Southern analysis has shown that all genes within a cluster have the same transcriptional orientation, and that switch sequences are present 5' of at least 12 of the 13 genes. The nucleotide sequence of each C alpha gene was determined, and it appears that all genes are functional; thus, rabbit may have as many as 13 IgA isotypes. Comparisons of the protein sequences encoded by the 13 C alpha genes showed that the CH2 and CH3 domains of the alpha-chains are highly conserved, whereas the CH1 and hinge regions are highly diverse. Southern analysis of genomic DNA samples from other species within the order Lagomorpha showed that all samples had multiple C alpha hybridizing fragments. Thus, it is likely that all lagomorphs have multiple IgA isotypes and hence complex secretory immune systems.

Ig VH, DH, and JH germ-line gene segments linked by overlapping cosmid clones of rabbit DNA.

Overlapping cosmid clones of rabbit germ-line DNA containing VH, DH and JH gene segments were isolated. The map of this cluster of cosmid clones indicated that the rabbit VH and JH regions were separated by 63 kb. Hybridization of Southern blots of these cosmid clones with two different DH segment probes identified a total of six DH segments within the region between the VH and JH regions. The nucleotide sequences of the JH region and one of the DH segments have been determined. The DH segment has conserved heptamer and nonamer sequences separated by 12 and 11 bp at the 3' and 5' sides, respectively, of the coding region and hence, appears to be a functional gene. The nucleotide sequence of the JH region revealed four functional JH gene segments and one JH pseudogene. Inasmuch as the JH region had previously been linked by contiguous overlapping clones with C mu, C gamma, C epsilon, and one C alpha gene, this VH-DH-JH cluster and the clones containing the Ig H chain C region genes represent 190 kb of contiguous germ-line DNA of the Ig H chain locus.