The structural and genetic basis for expression of normal and latent VHa allotypes of the rabbit

Sequencing of VDJ genes in Lepus americanus confirms a correlation between VHn expression and the leporid species continent of origin

Leporid VH genes used in the generation of their primary antibody repertoire exhibit highly divergent lineages. For the European rabbit (Oryctolagus cuniculus) four VHa lineages have been described, the a1, a2, a3 and a4. Hares (Lepus spp.) and cottontail (Sylvilagus floridanus) express one VHa lineage each, the a2L and the a5, respectively, along with a more ancient lineage, the Lepus spp. sL and S. floridanus sS. Both the European rabbit and the Lepus europaeus use a third lineage, VHn, in a low proportion of their VDJ rearrangements. The VHn genes are a conserved ancestral polymorphism that is being maintained in the leporid genome.Their usage in a low proportion of VDJ rearrangements by both European rabbit and L. europaeus but not S. floridanus has been argued to be a remnant of an ancient European leporid immunologic response to pathogens. To address this hypothesis, in this study we sequenced VDJ rearranged genes for another North American leporid, L. americanus. Our results show that L. americanus expressed these genes less frequently and in a highly modified fashion compared to the European Lepus species. Our results suggest that the American leporid species use a different VH repertoire than the European species which may be related with an immune adaptation to different environmental conditions, such as different pathogenic agents.

An overview of the lagomorph immune system and its genetic diversity

Our knowledge of the lagomorph immune system remains largely based upon studies of the European rabbit (Oryctolagus cuniculus), a major model for studies of immunology. Two important and devastating viral diseases, rabbit hemorrhagic disease and myxomatosis, are affecting European rabbit populations. In this context, we discuss the genetic diversity of the European rabbit immune system and extend to available information about other lagomorphs. Regarding innate immunity, we review the most recent advances in identifying interleukins, chemokines and chemokine receptors, Toll-like receptors, antiviral proteins (RIG-I and Trim5), and the genes encoding fucosyltransferases that are utilized by rabbit hemorrhagic disease virus as a portal for invading host respiratory and gut epithelial cells. Evolutionary studies showed that several genes of innate immunity are evolving by strong natural selection. Studies of the leporid CCR5 gene revealed a very dramatic change unique in mammals at the second extracellular loop of CCR5 resulting from a gene conversion event with the paralogous CCR2. For the adaptive immune system, we review genetic diversity at the loci encoding antibody variable and constant regions, the major histocompatibility complex (RLA) and T cells. Studies of IGHV and IGKC genes expressed in leporids are two of the few examples of trans-species polymorphism observed outside of the major histocompatibility complex. In addition, we review some endogenous viruses of lagomorph genomes, the importance of the European rabbit as a model for human disease studies, and the anticipated role of next-generation sequencing in extending knowledge of lagomorph immune systems and their evolution.

Sequencing of Sylvilagus VDJ genes reveals a new VHa allelic lineage and shows that ancient VH lineages were retained differently in leporids

Antigen recognition by immunoglobulins depends upon initial rearrangements of heavy chain V, D, and J genes. In leporids, a unique system exists for the VH genes usage that exhibit highly divergent lineages: the VHa allotypes, the Lepus sL lineage and the VHn genes. For the European rabbit (Oryctolagus cuniculus), four VHa lineages have been described, the a1, a2, a3 and a4. For hares (Lepus sp.), one VHa lineage was described, the a2L, as well as a more ancient sL lineage. Both genera use the VHn genes in a low frequency of their VDJ rearrangements. To address the hypothesis that the VH specificities could be associated with different environments, we sequenced VDJ genes from a third leporid genus, Sylvilagus. We found a fifth and equally divergent VHa lineage, the a5, and an ancient lineage, the sS, related to the hares' sL, but failed to obtain VHn genes. These results show that the studied leporids employ different VH lineages in the generation of the antibody repertoire, suggesting that the leporid VH genes are subject to strong selective pressure likely imposed by specific pathogens.

Sequencing of modern Lepus VDJ genes shows that the usage of VHn genes has been retained in both Oryctolagus and Lepus that diverged 12 million years ago

Among mammals, the European rabbit (Oryctolagus cuniculus) has a unique mechanism of generating the primary antibody repertoire. Despite having over 200 VH genes, the VH1 gene, the most D-proximal VH gene, is used in 80-90 % of VDJ rearrangements, while the remaining 10-20 % is encoded by the VHn genes that map at least 100 Kb upstream of VH1. The maintenance of the VHn genes usage in low frequency in VDJ rearrangements has been suggested to represent a relic of an ancestral immunologic response to pathogens. To address this question, we sequenced VDJ genes for another leporid, genus Lepus, which separated from European rabbit 12 million years ago. Approximately 25 VDJ gene sequences were obtained for each one of three Lepus europaeus individuals. We found that Lepus also uses the VHn genes in 5-10 % of its VDJ rearrangements. Our results show that the VHn genes are a conserved ancestral polymorphism that has been maintained in the leporids genome and is being used for the generation of VDJ rearrangements by both modern Lepus and Oryctolagus.

The solution structure of rabbit IgG accounts for its interactions with the Fc receptor and complement C1q and its conformational stability

Solution structures for antibodies are critical to understand function and therapeutic applications. The stability of the solution structure of rabbit IgG in different buffers and temperatures was determined by analytical ultracentrifugation and X-ray and neutron scattering. Rabbit IgG showed a principally monomeric species, which is well resolved from small amounts of a dimeric species. The proportion of dimer increased with increased concentration, decreased temperature and heavy water from 8% to 25% in all buffers except for high salt (250 mM NaCl). The Guinier X-ray radius of gyration R(G) likewise increased with concentration in 137 mM NaCl buffer but was unchanged in 250 mM NaCl buffer. The Guinier neutron R(G) values increased as the temperature decreased. The X-ray and neutron distance distribution curves P(r) revealed two peaks, M1 and M2, whose positions did not change with concentration to indicate unchanged structures under all these conditions. The maximum dimension increased with concentration because of dimer formation. Constrained scattering modeling reproducibly revealed very similar asymmetric solution structures for monomeric rabbit IgG in different buffers, in which the Fab-Fc and Fab-Fab pairs were separated by maximally extended hinge structures. The dimer was best modeled by two pairs of Fab regions forming tip-to-tip contacts. The intact rabbit IgG structures explained the ability of its two ligands, the Fc receptor and complement C1q, to bind to the top of its Fc region that is fully accessible and unhindered by the Fab regions.

Molecular bases of genetic diversity and evolution of the immunoglobulin heavy chain variable region (IGHV) gene locus in leporids

The rabbit has long been a model for studies of the immune system. Work using rabbits contributed both to the battle against infectious diseases such as rabies and syphilis, and to our knowledge, of antibodies' structure, function, and regulated expression. With the description of rabbit Ig allotypes, the discovery of different gene segments encoding immunoglobulins became possible. This challenged the "one gene-one protein" dogma. The observation that rabbit allotypic specificities of the variable regions were present on IgM and IgG molecules also led to the hypothesis of Ig class switching. Rabbit allotypes contributed to the documentation of phenomena such as allelic exclusion and imbalance in production of allelic gene products. During the last 30 years, the rabbit Ig allotypes revealed a number of unique features, setting them apart from mice, humans, and other mammals. Here, we review the most relevant findings concerning the rabbit IGHV. Among these are the preferential usage of one VH gene in VDJ rearrangements, the existence of trans-species polymorphism in the IGHV locus revealed by serology and confirmed by sequencing IGHV genes in Lepus, the unusually large genetic distances between allelic lineages and the fact that the antibody repertoire is diversified in this species only after birth. The whole genome sequence of a rabbit, plus re-sequencing of additional strains and related genera, will allow further evolutionary investigations of antibody variation. Continued research will help define the roles that genetic, allelic, and population diversity at antibody loci may play in host-parasite interactions.

B cell development in GALT: role of bacterial superantigen-like molecules

Intestinal bacteria drive the formation of lymphoid tissues, and in rabbit, bacteria also promote development of the preimmune Ab repertoire and positive selection of B cells in GALT. Previous studies indicated that Bacillus subtilis promotes B cell follicle formation in GALT, and we investigated the mechanism by which B. subtilis stimulates B cells. We found that spores of B. subtilis and other Bacillus species, including Bacillus anthracis, bound rabbit IgM through an unconventional, superantigen-like binding site, and in vivo, surface molecules of B. anthracis spores promoted GALT development. Our study provides direct evidence that B cell development in GALT may be driven by superantigen-like molecules, and furthermore, that bacterial spores modulate host immunity.

Genetic diversity at the hinge region of the unique immunoglobulin heavy gamma (IGHG) gene in leporids (Oryctolagus, Sylvilagus and Lepus)

Unlike other species, European rabbit (Oryctolagus cuniculus) possesses only one immunoglobulin gamma class. Allelic diversity at the Ig (immunoglobulin) gamma constant region encoded by the unique IGHG (immunoglobulin heavy gamma) gene is moreover much reduced. In the European rabbit, the genetic variation at IGGH hinge region is limited to a single nucleotide substitution, which causes a Met-Thr interchange at amino acid position 9 (IMGT hinge numbering). We have analysed the diversity at this region more in-depth by, (1) analysing the allelic variation in 11 breeds of domestic European rabbit (Oryctolagus cuniculus cuniculus), and (2) sequencing the gamma hinge exon in wild specimens of six species of rabbit (Oryctolagus and Sylvilagus) and hares (Lepus), including the two Oryctolagus subspecies (O. cuniculus cuniculus and O. cuniculus algirus). It appeared that among leporid species, amino acid changes occur exclusively at positions 8 and 9. However, while position 8 is occupied by either Pro or Ser residues, four different residues can occur at position 9 (Met, Thr, Pro and Leu). This variation concerns sites of potential O-glycosylation and/or proteolytic cleavage, suggesting that the underlying genetic diversity could be the outcome of selection. Preservation of the gamma hinge polymorphism in domestic stocks could therefore be important. We report here a polymerase chain reaction/restriction fragment length polymorphism protocol that has allowed the monitoring of the heterozygosity levels at the gamma hinge in 11 breeds of domestic European rabbit.

The evolution of the immunoglobulin heavy chain variable region (IgV H ) 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.

Positive selection of the peripheral B cell repertoire in gut-associated lymphoid tissues

Gut-associated lymphoid tissues (GALTs) interact with intestinal microflora to drive GALT development and diversify the primary antibody repertoire; however, the molecular mechanisms that link these events remain elusive. Alicia rabbits provide an excellent model to investigate the relationship between GALT, intestinal microflora, and modulation of the antibody repertoire. Most B cells in neonatal Alicia rabbits express V_Hn allotype immunoglobulin (Ig)M. Within weeks, the number of V_Hn B cells decreases, whereas V_Ha allotype B cells increase in number and become predominant. We hypothesized that the repertoire shift from V_Hn to V_Ha B cells results from interactions between GALT and intestinal microflora. To test this hypothesis, we surgically removed organized GALT from newborn Alicia pups and ligated the appendix to sequester it from intestinal microflora. Flow cytometry and nucleotide sequence analyses revealed that the V_Hn to V_Ha repertoire shift did not occur, demonstrating the requirement for interactions between GALT and intestinal microflora in the selective expansion of V_Ha B cells. By comparing amino acid sequences of V_Hn and V_Ha Ig, we identified a putative V_H ligand binding site for a bacterial or endogenous B cell superantigen. We propose that interaction of such a superantigen with V_Ha B cells results in their selective expansion.

Sequence analysis of 0.5 Mb of the rabbit germline immunoglobulin heavy chain locus

A bacterial artificial chromosome (BAC) library was created using partially digested rabbit chromosomal DNA. Four BAC clones spanning about 0.5 Mb of the rabbit immunoglobulin (Ig) heavy chain locus were isolated and sequenced. Three of the BAC clones were partially overlapping. Thirty-four V elements, 11 D elements, DQ52, six J elements and the coding regions of Cmicro, Cgamma, C and four Calpha genes were identified and characterized. Additionally, the sequence of a fosmid clone spanning Calpha13 and 30 kb 3'enhancer region was determined. The organization of the locus and the potential function of newly identified functional and structural elements are discussed.

Allelic Variation at the VHa Locus in Natural Populations of Rabbit (Oryctolagus cuniculus, L.)

The large interallelic distances between the three rabbit Ig V(H)a lineages, a1, a2 and a3, suggest that the persistence time of the V(H)a polymorphism could amount to 50 million years, which is much longer than that of MHC polymorphisms. Rabbit originated in the Iberian Peninsula where two subspecies coexist, one of which is confined to Southwestern Iberia (Oryctolagus cuniculus algirus). We studied the V(H) loci in the original species range to obtain a better understanding of the evolutionary history of this unusual polymorphism. Serological surveys revealed that sera from the subspecies algirus, when tested with V(H)a locus-specific alloantisera, showed either cross-reactivity ("a-positive" variants) or no reaction at all ("a-blank"). Using RT-PCR, we determined 120 sequences of rearranged V(H) genes expressed in seven algirus rabbits that were typed as either a-positive or a-blank. The data show that the V(H) genes transcribed in a-positive rabbits are closely related to the V(H)1 alleles of domestic rabbits. In contrast, a-blank rabbits were found to preferentially use V(H) genes that, although clearly related to the known V(H)a genes, define a new major allotypic lineage, designated a4. The a4 sequences have hallmark rabbit V(H)a residues together with a number of unprecedented amino acid changes in framework region 2 and 3. The net protein distances between the V(H)a4 and the V(H)a1, a2, and a3 lineages were 20, 29, and 21% respectively. We conclude that at least four distantly related lineages of the rabbit V(H)a locus exist, one of which seems to be endemic in the Iberian range.

Gene-conversion in rabbit B-cell ontogeny and during immune responses in splenic germinal centers

Combinatorial diversity is limited in rabbits because only a few V(H) genes rearrange. Most diversification of the primary repertoire is generated by somatic hypermutation and gene conversion-like changes of rearranged V(H) in B cells that migrate to appendix and other gut associated lymphoid tissues (GALT) of young rabbits. The changes are referred to as gene conversion-like because the non-reciprocal nature of the alterations introduced has not yet been demonstrated. There are many similarities between rabbits and chickens in how their B cells develop and diversify their repertoires. However, although the majority of rabbit B cells may have rearranged and diversified their V genes early in life, some B cells in adult rabbits have rearranged VH sequences that are identical or nearly identical to germline sequences. We found these cells in splenic germinal centers (GC) on days 7 and 10 after immunization of normal adult rabbits with DNP-BGG. By day 15, all rearranged V(H) sequences were diversified. We find an overall pattern of splenic precursor cells whose germline or near germline sequences change both by gene conversion and point mutations during early divisions and mainly by point mutations during later divisions. These events, in parallel with diversification of light chain sequences, may produce the diverse combining sites that serve as substrates for further affinity maturation by selection either within GC or later among emigrant cells in sites such as bone marrow. Some of the sequences altered by gene conversion in splenic germinal centers may also produce new members of the B-cell repertoire in adult rabbits comparable to those produced in GALT of neonatal rabbits.

Immunoglobulin structure and function as revealed by electron microscopy

Electron-microscopic (EM) analysis preceded crystallographic analysis [1,2] of Igs by over a decade and was for a time the only direct way of analyzing their 3-D molecular structure. Once the X-ray structures were deduced, the role of EM gradually shifted from gross structural analysis to the addressing of more sophisticated structural and functional questions. EM remains a vital adjunct to the many physicochemical, biochemical, and serological tools brought to bear on these remarkable molecules as we try to relate form to function. In this review I will highlight some of the many contributions that have been made possible by virtue of being able to 'see' Ig molecules and immune complexes.

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.

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.

B-cell superantigens may play a role in B-cell development and selection in the young rabbit appendix

In order to develop protective antibodies against a wide range of potentially infectious pathogens, the young rabbit must diversify a limited initial repertoire by somatic mechanisms (the high copy number primary repertoire). The majority of rabbit B cells produce heavy chain variable regions by rearranging the VHa allotype-encoding VH1 gene. Thus in normal rabbits the majority of serum immunoglobulins bear VHa allotype (due to VH1 FR1 and FR3 sequences). The young rabbit appendix is a site of diversification of rearranged VH genes by gene-conversion-like and somatic hypermutation mechanisms. The newly generated B cells probably undergo selection processes that involve foreign and self-antigens and superantigens. We find preferential expansion and survival of B cells in normal and VH-mutant ali/ali rabbits based on their heavy chain FR1 and FR3 sequences (VHa allotype). This selection may involve "superantigen"-like interactions with endogenous as well as exogenous ligands.

Somatic diversification of IgH genes in rabbit

Rabbits have helped elucidate one of the major immunologic puzzles, namely the genetic control of antibody diversity. The primary IgH antibody repertoire in rabbits is dominated by B cells that use the same germline VH-gene segment in VDJ gene rearrangements. The VDJ genes of essentially all B lymphocytes undergo somatic diversification within the first few weeks of the rabbit's life. Such diversification occurs both by a somatic gene conversion-like mechanism as well as by somatic hyperpointmutation. The diversification that occurs early in ontogeny takes place in gut-associated lymphoid tissues and potentially depends on external factors such as microbial antigens. Few, if any, new B lymphocytes develop in adult rabbits and we discuss how the antibody repertoire is maintained throughout life. Finally, we discuss the molecular mechanism of somatic gene conversion of Ig genes, including the possibility that this involves the use of RAD51, an enzyme required for gene conversion-mediated mating type switch in yeast.

Rabbit appendix: a site of development and selection of the B cell repertoire

As early as 1963, it was proposed that the rabbit appendix was a homologue of the chicken bursa of Fabricius (ARCHER et al. 1963). The finding that the young rabbit appendix was thymus independent contributed to the concept of central primary lymphoid tissue. Today we know that appendix is a site that generates the high copy number primary repertoire through diversification of rearranged VH genes by gene conversion-like and somatic hypermutation mechanisms. Thus the appendix of young rabbits functions as a mammalian bursal equivalent. In the appendix, newly generated B cells also undergo selection processes involving self and foreign antigens and superantigens. Preferential expansion and survival of B cells in normal and mutant ali rabbits based on FR1 and FR3 expression may involve "superantigen"-like interactions with endogenous and exogenous ligands. One endogenous ligand appears to be CD5. Additional ligands may be produced by gut flora. Further studies in the rabbit model are needed to determine the fates of emigrants from primary GALT, their sites of postulated self-renewal in the periphery, and the nature of secondary diversification in secondary germinal centers where populations of B lymphocyte memory cells may develop. These data may also be helpful in understanding how the repertoire of human B cells is formed and how this repertoire might be manipulated for clinical benefit.

VH Mutant Rabbits Lacking the VH1a2 Gene Develop a2+ B Cells in the Appendix by Gene Conversion-Like Alteration of a Rearranged VH4 Gene

We investigated the molecular basis for the appearance of VHa2 allotype-bearing B cells in mutant Alicia rabbits. The mutation arose in an a2 rabbit; mutants exhibit altered expression of VH genes because of a small deletion encompassing VH1a2, the 3′-most gene in the VH locus. The VH1 gene is the major source of VHa allotype because this gene is preferentially rearranged in normal rabbits. In young homozygous ali/ali animals, the levels of a2 molecules found in the serum increase with age. In adult ali/ali rabbits, 20 to 50% of serum Igs and B cells bear a2 allotypic determinants. Previous studies suggested that positive selection results in expansion of a2 allotype-bearing B cells in the appendix of young mutant ali/ali rabbits. We separated appendix cells from a 6-wk-old Alicia rabbit by FACS based on the expression of surface IgM and a2 allotype. The VDJ portion of the expressed Ig mRNA was amplified from the IgM+ a2+ and IgM+ a2− populations by reverse transcriptase-PCR. The cDNAs from both populations were cloned and sequenced. Analysis of these sequences suggested that, in a2+ B cells, the first D proximal functional gene in Alicia rabbits, VH4a2, rearranged and was altered further by a gene conversion-like mechanism. Upstream VH genes were identified as potential gene sequence donors; VH9 was found to be the most frequently used gene donor. Among the a2− B cells, y33 was the most frequently rearranged gene.

CD5 is a potential selecting ligand for B cell surface immunoglobulin framework region sequences

In rabbits nearly all B lymphocytes express the glycoprotein CD5, in contrast to mice and humans, where only a small proportion of B cells express this molecule (Raman, C., and K.L. Knight. 1992. J. Immunol. 149:3858-3864). CD5+ B cells appear to develop early in ontogeny and be maintained throughout life by self-renewal. The function of CD5 on B cells is still unknown. We showed earlier that "positive" selection occurs during B lymphocyte development in the rabbit appendix. This selection favors B cell expressing surface immunoglobulins with VHa2 structures in the first and third framework regions (Pospisil, R., G.O. Young-Cooper, and R.G. Mage. 1995. Proc. Natl. Acad. Sci. USA. 92:6961-6965). Here we report that F(ab')2 fragments, especially those bearing VHa2 framework region determinants, specifically interact with the B cell-surface glycoprotein CD5. This interaction can be inhibited by anti-CD5 antibodies. Furthermore, immobilized F(ab')2 fragments selectively bind CD5 molecules in appendix cell lysates. Interactions of VH framework region structures with CD5 may affect maintenance and selective expansion of particular B cells and thus contribute to autostimulatory growth of autoimmune or transformed cells.

Preferential expansion and survival of B lymphocytes based on VH framework 1 and framework 3 expression: "positive" selection in appendix of normal and VH-mutant rabbits

B cells with a rearranged heavy-chain variable region VHa allotype-encoding VH1 gene segment predominate throughout the life of normal rabbits and appear to be the source of the majority of serum immunoglobulins, which thus bear VHa allotypes. The functional role(s) of these VH framework region (FR) allotypic structures has not been defined. We show here that B cells expressing surface immunoglobulin with VHa2 allotypic specificities are preferentially expanded and positively selected in the appendix of young rabbits. By flow cytometry, a higher proportion of a2+ B cells were progressing through the cell cycle (S/G2/M) compared to a2- B cells, most of which were in the G1/G0 phase of the cell cycle. The majority of appendix B cells in dark zones of germinal centers of normal 6-week-old rabbits were proliferating and very little apoptosis were observed. In contrast, in 6-week-old VH-mutant ali/ali rabbits, little cell proliferation and extensive apoptosis were observed. Nonetheless even in the absence of VH1, B cells with a2-like surface immunoglobulin had developed and expanded in the appendix of 11-week-old mutants. The numbers and tissue localization of B cells undergoing apoptosis then appeared similar to those found in 6-week-old normal appendix. Thus, B cells with immunoglobulin receptors lacking the VHa2 allotypic structures were less likely to undergo clonal expansion and maturation. These data suggest that "positive" selection of B lymphocytes through FR1 and FR3 VHa allotypic structures occurs during their development in the appendix.

A genetic marker of rabbit immunoglobulin VHa region: a109

A "new" rabbit immunoglobulin allotype belonging to the VHa series (a109) that seems particular to the Iberian O. cuniculus has been detected in a Portuguese wild rabbit population. This allotype was found in the wild population of Spain but not in those of France and Zembra island (Tunisia). Using antisera and monoclonal antibodies raised against already known VHa allotypes, we found that a 109 presents cross-reactivity with a1, a3, a100, a101, a107 and a108 allotypes. On the basis of studies of these cross-reactivities, we show that a109 is constituted of at least three variants (or subfamilies of variants) possessing determinants common with either a1 and a109, a3 and a109 or a1, a3 and a109 allotypes. These results are discussed according to recent data relative to generation of antibody diversity in rabbit.

Rabbit IgH sequences in appendix germinal centers: VH diversification by gene conversion-like and hypermutation mechanisms

Although the rabbit IgH locus contains approximately 100 VH genes, the majority of B cells rearrange VH1. To produce a primary repertoire containing a sufficient number of protective antibodies, rearranged VH1-DH-JH sequences may diversify within rabbit B cells in an organ that functions like a chicken bursa, sheep ileal Peyer's patch, or both. It was suggested many years ago that the rabbit appendix could be a bursal equivalent. To reexamine this possibility, we analyzed rearranged heavy chain variable region sequences in B cells from light and dark zones of appendix germinal centers from 6-week-old rabbits. Our findings indicate that antibody diversification occurs by gene conversion-like and somatic hypermutation mechanisms in appendix germinal centers of young rabbits.

Cell surface recognition and the immunoglobulin superfamily

Immunoglobulins serve as humoral recognition and effector molecules and as antigen-specific cell surface receptors on B and T cells. These molecules are constructed according to a characteristic domain pattern. Variable and constant domains diverged from one another early in vertebrate evolution, and they are joined by a "switch peptide" specified by the joining gene segments. Peptides specified by J-gene segments are strongly conserved in evolution in comparison among Ig light chains and T-cell receptors. Molecules less strongly related to Ig domains have been assembled into an Ig "superfamily" where the identities to classical IgC or V domains are < or = 20%. Among these are cell surface adhesion molecules, receptors for cytokines, and Fc receptors. Moreover, MHC antigens have an Ig-like membrane-proximal domain significantly related to IgC regions. We will analyze putative evolutionary relationships among canonical Igs and members of the Ig superfamily using highly conserved sequences from light and heavy chains of primitive vertebrates (e.g., the sandbar shark) as prototypes to ascertain similarities between Ig-related molecules of vertebrates and invertebrates.

Generating the antibody repertoire in rabbit

We describe a model for B cell development and generation of the antibody repertoire in rabbits. In this model, B cells develop early in ontogeny, migrate to GALT, and undergo the first round of diversification by a somatic gene conversion-like process and by somatic mutation. We designate the repertoire developed by this mechanism as the primary antibody repertoire and it is this repertoire that makes the rabbit immunocompetent. We invoke GALT as the site for development of the primary repertoire because (1) surgical removal of GALT from neonatal rabbits results in highly immunocompromised animals, (2) in germfree rabbits essentially no lymphoid development occurs in GALT and the rabbits are immunoincompetent, and (3) the follicular development of rabbit GALT is highly similar to that of the chicken bursa, the site in which the primary antibody repertoire develops by somatic gene conversion in chicken. We suggest that once the primary antibody repertoire is formed, it is maintained by self-renewing CD5+ B cells and is expanded to a secondary antibody repertoire after the B cells encounter antigen.

Autoreactive sites of human lambda light chain mapped by comprehensive peptide synthesis

Autoantibodies reactive against immunoglobulins are associated with autoimmune disorders as well as with immunization and infection. Moreover, recent interest is focused on auto-antidiotypes because of their possible role in immunoregulation. In this study, we used a set of overlapping synthetic peptides duplicating the structure of the monoclonal human lambda light chain Mcg to map autoreactive determinants recognized by natural antibodies present in normal polyclonal human IgG. We found that autoantibodies in human IgG react strongly with two distinct V lambda determinants corresponding to the first complementarity determining region (CDR1) and the third framework (Fr3). Antibodies showing weak reactivities against three regions of the constant domain also occur in the preparations. The antibodies directed against light chain peptides comprise less than 0.1% of the IgG pool. Analysis by direct binding and by competitive ELISA inhibition established that affinity purified antibodies specific for CDR1 and Fr3 peptide determinants react with the intact light chain Mcg as well as with the corresponding peptide. Competitive inhibition studies comparing total IgG and affinity-purified antibodies indicate that natural antibodies showing a wide range of affinities are present. The polyclonal nature of the natural antibodies is further shown by the presence of both kappa and lambda light chains in the purified antibodies. Although the role of such natural antibodies remains to be determined, the cross-reactivity between V lambda peptides and the intact chain suggest that they can function in regulation of antibody formation.

Recombination activating genes-1 and -2 of the rabbit: cloning and characterization of germline and expressed genes

The recombination activating genes RAG-1 and RAG-2 appear to be necessary components of the machinery needed for the Ig or TCR gene rearrangements that occur in developing B and T lymphocytes. In addition RAG-2 has been implicated in the process of V-gene diversification by somatic gene conversion in the chicken. Because gene conversion may be an important mechanism for V-gene diversification in the rabbit, we cloned the rabbit RAG locus and characterized the coding regions of the genomic RAG-1 and RAG-2. In addition, we sequenced cDNAs encompassing the RAG-2 coding region, part of the RAG-2 5' untranslated region and a 967 bp fragment of cDNA from the RAG-1 coding region. Northern analysis revealed a RAG-1 mRNA of 6.6 kb which is similar in size to the RAG-1 mRNA reported previously for other species, and a major species of RAG-2 mRNA of 4.4 kb, which is larger than that from the mouse (2.2 kb). Analysis of the genomic clones showed that, as in other species, the RAG-1 and RAG-2 genes are oriented so as to be convergently transcribed. The DNA sequence analysis showed that the rabbit RAG-1 coding region is 91, 85 and 72% identical to human, mouse and chicken, respectively. The deduced RAG-1 protein sequence for rabbit is 93, 90 and 78% identical to human, mouse and chicken. Comparison of the rabbit RAG-2 coding region revealed 90, 87 and 71% identity to human, mouse and chicken, respectively, at the nucleotide level, and 91, 90 and 72% at the protein level. Although there is considerable conservation of sequence between species, we obtained evidence for allelic forms of the rabbit RAG locus both by Southern analyses and by sequencing. A remarkable degree of polymorphism was found in our rabbit colonies, particularly in the region 3' of the rabbit RAG-2 coding region. A 5' cDNA probe hybridized with one or more additional fragments that are not detected with the coding region probes, suggesting that the 5' cDNA sequence results from splicing of one or more upstream exons.

Shared antigenic determinants of immunoglobulins in phylogeny and in comparison with T-cell receptors

1. Immunoglobulins are a complex multigene family of proteins specified by genes encoding variable (V), sometimes diversity (D), joining (J), and constant (C) domains. 2. Cross-reactions involving conformational determinants related to the VHa system of rabbits occur on heavy chains of vertebrate species ranging from elasmobranchs to man. 3. Serological markers characteristic of mu chains, the heavy chain of the IgM macroglobulins, occur on homologous heavy chains of species representing all vertebrate classes. 4. Serological markers characteristic of gamma type heavy chains, the major isotype in man, are restricted to the mammals, but are found on representatives of even the most primitive mammals, the egg-laying monotremes. 5. Variable region markers characteristic of lambda light chains are shared by light chains of shark and man. 6. Certain idiotypic markers defined by combining site V region sequences are broadly distributed in evolution. 7. Use of synthetic peptides as antigens and in epitope mapping show that amino acid sequences from the third framework region of the variable domain are broadly shared among light chain in phylogeny and between light chains and T-cell receptor beta chains. 8. The "switch peptides" linking the V and C domains of light chains and T-cell receptors, specified by the C-terminal portion of the J segment and the N-terminus of the constant region, are exposed in the three-dimensional structure of immunoglobulin or Tcrs, show striking homology, and form broadly shared antigenic determinants characteristic of immunoglobulins. 9. Although the multigene nature of the immunoglobulins and the complexity of antigenic determinants expressed by these large proteins renders comparison among molecules difficult, serum immunoglobulins and the closely related T-cell receptors express numerous shared determinants defined on the basis of amino acid sequence homology and three-dimensional conformations.

Human autoantibodies reactive with synthetic autoantigens from T-cell receptor beta chain

We used mapping with synthetic overlapping peptides in combination with molecular modeling to analyze the IgG antibodies that humans naturally produce against human T-cell receptor beta chains and to localize the recognized peptide autoantigens in the three-dimensional structure of the molecule. Healthy individuals produce low levels of antibodies against T-cell receptor peptides, and these can be increased in autoimmune diseases. We characterized the reactivities in detail because IgG molecules reactive with self peptides occur in preparations of intravenous immunoglobulin and can be isolated by immunoaffinity chromatography. Natural IgG antibodies were directed against three major peptides. One corresponds to the first complementarity-determining region of the variable region. A second corresponds to the third framework of the variable region. The third is located in the constant region and is predicted to be a loop that extends out of the beta-barrel structure. This peptide is one that would give a characteristic structural distinction between the beta-chain constant region and the constant regions of immunoglobulin light chains to which beta chains are homologous. The capacity to bind these peptides is found in small fractions of normal polyclonal IgG, which contains both kappa chains and lambda chains. The activity is antibody-like in being confined to the Fab fragment and in its capacity to discriminate among homologous synthetic peptides corresponding to distinct beta-chain variable-region genes. We propose that a recognition and regulatory process naturally occurs that parallels the immune network for the regulation of the production of antibodies.

Molecular analysis of recombination sites within the immunoglobulin heavy chain locus of the rabbit

Previously, recombinations involving genes of the rabbit immunoglobulin heavy chain locus have been documented serologically. These data indicated that the sites at which the causative recombination events occurred could have been anywhere from within the VH gene cluster up to, or 3' of, C mu. Since these sites could not be localized further by serological methods, we attempted to do this using techniques of molecular biology. DNAs from homozygous recombinant rabbits and from the appropriate non-recombinant parental haplotypes were characterized using Southern blots hybridized with a panel of probes derived from cloned regions of the rabbit immunoglobulin heavy chain gene complex. In all three recombinants, the site was downstream of the entire VH cluster and upstream of the JH cluster within an approximately 50 kilobase (kb) region containing expanses of repetitive-sequence DNA as well as DH genes. DH-specific probes further showed that in two of the recombinants, the recombination appears to have occurred within or 5' of DH1 and 5' of DH2 genes; in the third it occurred 3' of the DH2 genes but at least approximately 5 kb 5' of the JH region.

Preferrential rearrangement in normal rabbits of the 3' VHa allotype gene that is deleted in Alicia mutants; somatic hypermutation/conversion may play a major role in generating the heterogeneity of rabbit heavy chain variable region sequences

The rabbit is unique in having well-defined allotypes in the variable region of the heavy chain. Products of the VHa locus, (with alleles a1, a2, and a3), account for the majority of the serum immunoglobulins. A small percentage of the serum immunoglobulins are a-negative. In 1986, Kelus and Weiss described a mutation that depressed the expression of the Ig VH a2 genes in an a1/a2 rabbit. From this animal the Alicia rabbit strain was developed and the mutation was termed ali. We previously showed, using Southern analysis and the transverse alternating field electrophoresis technique, that the difference between the ali rabbit and normal is a relatively small deletion including some of the most 3' VH genes. The most JH proximal 3' VH1 genes in DNA from normal rabbits of a1, a2 and a3 haplotypes encode a1, a2 and a3 molecules respectively, and it has been suggested that these genes are responsible for allelic inheritance of VHa allotypes. The present study suggests that the 3' end of the VH locus probably plays a key role in regulation of VH gene expression in rabbits because VH gene(s) in this region are the target(s) of preferential VDJ rearrangements. This raises the possibility that mechanisms such as somatic gene conversion and hypermutation are at work to generate the antibody repertoire in this species. Our data support the view that the 3' VH1 gene may be the preferred target for rearrangement in normal rabbits, and for the normal chromosome in heterozygous ali animals. However, homozygous ali rabbits with a deletion that removed the a2-encoding VH1 on both chromosomes do survive, rearrange other VH genes and produce normal levels of immunoglobulins as well as a significant percentage of B cells which bear the a2 allotype. This challenges the view that one VH gene, VH1, is solely responsible for the inheritance pattern of VHa allotypes.

Restricted utilization of germ-line VH genes in rabbits: implications for inheritance of VH allotypes and generation of antibody diversity

The presence of inherited VH region allotypic specificities, a1, a2 or a3, on nearly all rabbit immunoglobulins has presented a paradox. We know the germline contains hundreds of VH genes, and if we assume that most of these are used in the generation of antibody diversity, then we must ask how have the a allotype-encoding regions been maintained over time? On the other hand, if we assume that only one (or a small number) of these VH gene(s) is (are) used in VDJ gene rearrangements, then, how is antibody diversity generated? To address these questions, we have cloned and determined the nucleotide sequence of the 3'-most germline VH genes from the a1, a2 and a3 chromosomes and shown in each case that the 3'-most H gene, VH1-a1, VH1-a2, or VH1-a3, encodes an a1, a2 or a3 VH region, respectively. Analysis of rearranged VDJ genes from leukemic B cells showed that VH1 was utilized in these rearrangements. Based on these data, we propose that the allelic inheritance of the VH allotypes is explained by the preferential usage of the VH1 gene in VDJ rearrangements. Support for this hypothesis was obtained from analysis of the mutant rabbit Alicia in which most serum Ig molecules do not have VHa allotypic specificities, but instead have so-called VHa-negative Ig molecules. In this rabbit, VH1 is not expressed as it has been deleted. Analysis of cDNA clones from spleen of Alicia rabbits suggests that the expressed VHa-negative molecules also are encoded by a single germline VH gene. Thus, we suggest that nearly all rabbit VH regions are encoded by one to two germline VH genes and that antibody diversity is generated primarily by somatic hypermutation and gene conversion.

Altered phenotypic expression of immunoglobulin heavy-chain variable-region (VH) genes in Alicia rabbits probably reflects a small deletion in the VH genes closest to the joining region

Rabbits of the Alicia strain have a mutation (ali) that segregates with the immunoglobulin heavy-chain (lgh) locus and has a cis effect upon the expression of heavy-chain variable-region (VH) genes encoding the a2 allotype. In heterozygous a1/ali or a3/ali rabbits, serum immunoglobulins are almost entirely the products of the normal a1 or a3 allele and only traces of a2 immunoglobulin are detectable. Adult homozygous ali/ali rabbits likewise have normal immunoglobulin levels resulting from increased production of a-negative immunoglobulins and some residual ability to produce the a2 allotype. By contrast, the majority of the immunoglobulins of wild-type a2 rabbits are a2-positive and only a small percentage are a-negative. Genomic DNAs from homozygous mutant and wild-type animals were indistinguishable by Southern analyses using a variety of restriction enzyme digests and lgh probes. However, when digests with infrequently cutting enzymes were analyzed by transverse alternating-field electrophoresis, the ali DNA fragments were 10-15 kilobases smaller than the wild type. These fragments hybridized to probes both for VH and for a region of DNA a few kilobases downstream of the VH genes nearest the joining region. We suggest that this relatively small deletion affects a segment containing 3' VH genes with important regulatory functions, the loss of which leads to the ali phenotype. These results, and the fact that the 3' VH genes rearrange early in B-cell development, indicate that the 3' end of the VH locus probably plays a key role in regulation of VH gene expression.

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.

Restricted utilization of VH and DH genes in leukemic rabbit B cells

Polyclonal B cell leukemias have been generated in 17- to 20-day old Emu-myc transgenic rabbits. To analyze the repertoire of VH genes utilized in early B cells, eight VDJ genes were cloned from these leukemic cells. The nucleotide sequences of these genes indicated that seven of the eight VDJ genes encoded prototype VHa1, VHa2 or VHa3 allotypes. The two VDJ genes encoding VHa1 molecules had VH segments with identical nucleotide sequences; similarly, the VH segments of the four VDJ genes encoding VHa2 molecules were identical, with the exception of a single base pair. These data suggest that a limited repertoire of VH genes were utilized in the generation of these VDJ genes. The DH segments of these genes were limited to two DH families, D1 and D2, indicating that a restricted repertoire of DH genes also had been utilized. Since these leukemic cells probably developed early in ontogeny, we suggest that this restricted utilization of VH and DH genes is representative of B cells from developmentally immature rabbits.

Antibodies to synthetic peptides corresponding to variable-region first-framework segments of T cell receptor. Detection of T cell products and cross-reactions with classical immunoglobulins

Recent studies at the gene level have shown that T cells express rearranged genes for four types of T cell receptors that are strongly homologous to classical immunoglobulins in the joining region and in the framework 1 (Fr1) and 3 segments of the variable region. Based upon the homologies in gene sequence, it follows that the gene products would show similarities in amino acid sequence and in the folding of the proteins so that cross-reactivities in antigenic determinants would be expected between variable regions of the T cell receptors and classical immunoglobulins. We have synthesized peptides corresponding to predicted protein sequences of the Fr1 residues of T cell receptor alpha, beta- and gamma-chains and have produced antibodies in rabbits against these synthetic peptides. Use of antisera and affinity-purified antipeptide antibodies indicated that high-titer antibodies could be raised that were specific for individual Fr1 peptides. Cross-reactions among Fr1 peptides of T cell receptors and immunoglobulin light chains were observed. In addition, some rabbit antisera raised against classical polyclonal immunoglobulins or affinity-purified immunoglobulin-like T cell receptors were found to exhibit binding activity against Fr1 peptides of T cell receptor beta- and gamma-chains. The sequence homology, although real among the Fr1 of T cell receptors and immunoglobulin light chains, is moderate and the antigenic cross-reaction must reflect the configuration and types of amino acids present. The development of antipeptide antibodies holds promise for the characterization of T cell receptors of various T cell sources and also offers a new means for the identification of molecules related to rearranging immunoglobulins.

Anti-HV3 peptide antibodies as probes for conformational changes in immunoglobulins

Recent studies have shown that monoclonal anti-alprenolol antibody 37A4 could mimic the beta-adrenergic receptor with respect to binding properties and alprenolol-induced changes in intrinsic fluorescence. We prepared and characterized polyclonal antibodies against a synthetic tetradecapeptide corresponding to residues 92-105 of the 37A4 VH domain. In ELISA and immunoblotting assays, the anti-peptide antibodies bound to the intact IgG molecule as well as to the isolated heavy chain. They failed to interact with the native IgG protein but recognized with high specificity the conformationally modified Ig molecule; as a consequence, their reactivity to the entire protein was found to vary with the conditions of the assay. This study illustrates that anti-peptide antibodies might be used as probes for the detection of conformational changes occurring in the Ig hypervariable regions.

Immunoglobulin epitopes defined by synthetic peptides corresponding to joining region sequence: conservation of determinants and dependence upon the presence of an arginyl or lysyl residue for cross-reaction between light chains and T-cell receptor chains

Joining or J region sequences of rearranging immunoglobulins and T-cell receptors show considerable sequence homology, particularly in their C-terminal portion corresponding to the fourth framework region of immunoglobulin variable regions. In order to test the question of whether serological cross-reactions between immunoglobulin variable regions and T-cell receptors were due to antigenic similarities in their J regions, we synthesized synthetic peptides corresponding to immunoglobulin J regions and to J regions predicted from gene sequence of the T-cell receptor beta chain. We found that antibodies produced against a synthetic 16-mer J beta sequence reacted with T-cell receptor chains and also with immunoglobulin light chains. The cross-reactivity was dependent upon the J signature sequence FG()GT(R or K)L where the presence of a positively charged lysyl or arginyl residue was essential for cross-reactivity. We were able to classify J region determinants into two distinct antigenic sets; one corresponding to JH and the other corresponding to J kappa, J lambda, J beta and J alpha. Although considerable homology occurs between JH and JL (or J beta) sequences, little cross-reactivity was observed between these two J subsets. Antibodies raised against polyclonal murine IgG immunoglobulins contained antibody subpopulations specifically reactive with either JH or J beta peptides. The serological data derived here using antipeptide antibodies are consistent with computer modeling studies that indicate that the conformations of T-cell receptor variable regions resemble those of classical immunoglobulins. Our data comparing cross-reactivities restricted to the J region indicate that the expression of the J region by intact T-cell receptor beta chains is probably more similar to that of light chains than it is to the corresponding region of heavy chains.

Do antibodies recognize amino acid side chains of protein antigens independently of the carbon backbone?

In an effort to understand the structural basis for antigen mimicry by internal image antibodies, we determined the variable (V) region sequences of two mouse mAbs that mimic the rabbit Ig a1 allotype. The results showed that while the mAb light chains did not contain any allotype-related residues, both heavy chain V regions contained within complementarity-determining region 2 an unusual sequence homologous to the nominal antigen but in opposite orientation with respect to the carbon backbone. The ability of the internal image reversed sequence to express an a1-like determinant was tested directly by producing synthetic peptides that corresponded to the presumed antigenic regions of rabbit Ig and the mAb internal images, respectively. Although the two peptides presented the homologous residues in opposite orientations, they both completely inhibited at similar concentrations the binding of rabbit Ig to anti-a1 antibody. Conservative substitutions in the peptide sequence identified a paired Thr and Glu as being critical for expression of the a1 epitope. These findings indicate that antibodies can recognize the molecular environments created by amino acid side chains independently from the orientation of the protein carbon backbone.

Allotype-specific probes. A molecular approach to the study of serologically defined determinants

A new approach to the study of serologically defined immunoglobulin determinants is described. We designed DNA probes which distinguished between the rabbit kappa light chain allotypic sequences in Northern analyses of mRNAs and Southern analyses of genomic DNAs. S1 nuclease protection experiments are described which detect allotype-specific sequences in as little as 100 pg of total RNA. The use of molecular biological techniques overcomes many of the problems inherent in using serological reagents and techniques. In addition, the sensitivity of the assays described here allows the detection of low level expression of the allotypic genes. This work was extended to include the discrimination of the VHa allotypes.

Heating of immunoglobulins for immunoblot analysis destroys variable region antigenicity

The antigenicity of rabbit immunoglobulin heavy chain variable region allotypes was examined by immunoblotting after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The standard method of sample preparation resulted in a total loss of immunoreactivity with anti-allotype antibody due to heating of the samples prior to their electrophoresis. Thus, caution is warranted in interpreting results obtained from analysis of Ig when such proteins are heated before or during separation. In addition, we describe a method that permits not only separation of Ig heavy and light chains in SDS-PAGE but also preserves V region antigenicity.