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.

Induction of an HPV 6bL1-specific mucosal IgA response by DNA immunization.

Human papillomavirus (HPV) plays a crucial role in the development of human anogenital dysplasia. To prevent infection, it is important to induce an HPV-specific mucosal immune response. We investigated whether DNA vaccination would induce an intravaginal mucosal antibody response against HPV 6bL1. New Zealand White rabbits were immunized with an HPV 6bL1 DNA vaccine by one of the three routes: muscular, vaginal, or rectal. We found that vaginal immunization of rabbits with HPV 6bL1 DNA induced 6bL1 virus-like particle-specific lgA antibodies in vaginal secretions. They were detectable until at least 14 weeks after the first immunization. The antibodies also showed neutralizing activity in a hemagglutination inhibition assay. No mucosal immune response was detected in vaginal secretions of rabbits immunized intramuscularly or intrarectally. Our data suggest that vaginal immunization with HPV 6bL1 DNA induces long-lasting IgA responses with neutralizing activity in vaginal secretions of rabbits.

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.

Dependence of antibody somatic diversification on gut-associated lymphoid tissue in rabbits.

By approximately 4 to 8 wk of age, the IgH VDJ genes of essentially all rabbit B lymphocytes have undergone somatic diversification. Some of this diversification occurs in the appendix, which is a gut-associated lymphoid tissue (GALT). To determine whether GALT is essential for somatic diversification, we surgically removed the appendix, sacculus rotundus, and Peyer's patches from neonatal rabbits (designated GALT-less) and examined the extent to which VDJ genes were somatically diversified. We found that the IgM VDJ genes of peripheral B cells from 2- to 5-mo-old GALT-less rabbits had undergone considerably less somatic diversification than those of control rabbits. Further, the percentage of peripheral B cells in the GALT-less rabbits was generally less than that of controls. Our data suggest that, in rabbits, the primary Ab repertoire develops in GALT, and B cell expansion also occurs there. Hence, GALT may function as a mammalian bursal homologue.

Rabbit monoclonal antibodies: generating a fusion partner to produce rabbit-rabbit hybridomas.

During the last 15 years several laboratories have attempted to generate rabbit monoclonal antibodies, mainly because rabbits recognize antigens and epitopes that are not immunogenic in mice or rats, two species from which monoclonal antibodies are usually generated. Monoclonal antibodies from rabbits could not be generated, however, because a plasmacytoma fusion partner was not available. To obtain a rabbit plasmacytoma cell line that could be used as a fusion partner we generated transgenic rabbits carrying two transgenes, c-myc and v-abl. These rabbits developed plasmacytomas, and we obtained several plasmacytoma cell lines from which we isolated hypoxanthine/aminopterin/thymidine-sensitive clones. One of these clones, when fused with spleen cells of immunized rabbits, produced stable hybridomas that secreted antibodies specific for the immunogen. The hybridomas can be cloned and propagated in nude mice, and they can be frozen without change in their ability to secrete specific monoclonal antibodies. These rabbit-rabbit hybridomas will be useful not only for production of monoclonal antibodies but also for studies of immunoglobulin gene rearrangements and isotype switching.

Lymphoid and non-lymphoid tumors in E kappa-myc transgenic rabbits.

We developed transgenic rabbits with a DNA construct containing the proto-oncogene c-myc conjugated to the Ig kappa-chain enhancer gene, E kappa. One of four transgenic rabbits was mated to a normal rabbit and we used the offspring to develop a colony of rabbits carrying the E kappa-myc transgene in their germline. Of a total of 19 E kappa-myc transgenic rabbits, eight developed tumors. The tumors were characterized histologically and four were diagnosed as lymphoma, and one each was diagnosed as embryonic carcinoma, hepatoma, ovarian carcinoma and basal cell carcinoma. By Southern analysis, we showed the four lymphomas were of B-lymphoid lineage and by nucleotide sequence analysis we found three of them most likely used VH1 in their VDJ gene rearrangements. Cells from the embryonic carcinoma, the hepatoma and two of the B-lymphomas were adapted to tissue culture. We discuss the possibility that tumors of non-lymphoid origin develop in the E kappa-myc transgenic rabbits because of the potential for NF-kappa B to activate the kappa-enhancer in cells other than B-lymphoid lineage cells.

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.