Unusual germline DSP2 gene accounts for all apparent V-D-D-J rearrangements in newborn, but not adult, MRL mice.

Anti-dsDNA autoantibodies in MRL mice contain a higher than average frequency of atypical complementarity-determining regions 3, including those made with D-D rearrangements. It has been reported that MRL mice have an intrinsically high frequency of creating VDDJ rearrangements; however, we show in this study that the majority of these apparent D-D rearrangements in B cell progenitors can be accounted for by a very novel germline D(H) gene in mice of the Igh(j) haplotype. This gene has the appearance of a D to D rearrangement due to the duplication of 9 bp common to most DSP2 genes. Germline DSP2 genes from Igh(j) mice were amplified, cloned, and sequenced, showing the presence of this novel gene as well as a new allele of a conventional DSP2 gene. Sequencing of D-J rearrangements revealed that Igh(j) mice also have a different allele of DFL16.1 and apparently lack DFL16.2. Despite the existence of this new DSP gene, analysis of VDJ rearrangements from adult bone marrow pre-B cells of MRL/lpr mice still revealed the presence of complementarity-determining region 3 containing apparent D-D joinings in 4.6% of the sequences. C3H pre-B cells had 4.2% of sequences with apparent VDDJ rearrangements, and BALB/c pre-B cells had approximately 2%. DDJ intermediates were also observed, but at a lower frequency. However, strikingly, no VDDJ rearrangements were observed in newborn sequences, suggesting the process of assembly of VDJ rearrangements is fundamentally different in newborn mice vs adult mice.

Localized gene-specific induction of accessibility to V(D)J recombination induced by E2A and early B cell factor in nonlymphoid cells.

Accessibility of immunoglobulin (Ig) gene segments to V(D)J recombination is highly regulated and is normally only achieved in B cell precursors. We previously showed that ectopic expression of E2A or early B cell factor (EBF) with recombination activating gene (RAG) induces rearrangement of IgH and IgL genes in nonlymphoid cells. VkappaI genes throughout the locus were induced to rearrange after transfection with E2A, suggesting that the entire Vkappa locus was accessible. However, here we show that Ig loci are not opened globally but that recombination is localized. Gene families are interspersed in the D(H), Vkappa, and Vlambda loci, and we show that certain families and individual genes undergo high levels of recombination after ectopic expression of E2A or EBF, while other families within the same locus are not induced to rearrange. Furthermore, in some families, induction of germline transcription correlates with the level of induced recombination, while in others there is no correlation, suggesting that recombination is not simply initiated by induction of germline transcription. The induced repertoire seen at 24 hours does not change significantly over time indicating the absence of many secondary rearrangements and also suggesting a direct targeting mechanism. We propose that accessibility occurs in a local manner, and that binding sites for factors facilitating accessibility are therefore likely to be associated with individual gene segments.

Terminal deoxynucleotidyl transferase deficiency decreases autoimmune disease in MRL-Fas(lpr) mice.

The neonatal Ab and TCR repertoires are much less diverse, and also very different from, the adult repertoires due to the delayed onset of terminal deoxynucleotidyl transferase (TdT) expression in ontogeny. TdT adds nontemplated N nucleotides to the junctions of Igs and TCRs, and thus its absence removes one of the major components of junctional diversity in complementarity-determining region 3 (CDR3). We have generated TdT-deficient MRL/lpr, Fas-deficient (MRL-Fas(lpr)) mice, and show that they have an increased lifespan, decreased incidence of skin lesions, and much lower serum levels of anti-dsDNA, anti-chromatin, and IgM rheumatoid factors. The generalized hypergammaglobulinemia characteristic of MRL-Fas(lpr) mice is also greatly reduced, as is the percentage of CD4(-)CD8(-)B220(+) (double-negative) T cells. IgG deposits in the kidney are significantly reduced, although evidence of renal disease is present in many mice at 6 mo. CDR3 regions of both IgH and TCR from peripheral lymphocytes of MRL-Fas(lpr) mice are shorter in the absence of TdT, and there is a paucity of arginines in the IgH CDR3 regions of the MRL-Fas(lpr) TdT(-/-) mice. Because the amelioration of symptoms is so widespread, it is likely that the absence of N regions has more of an affect than merely decreasing the precursor frequency of anti-dsDNA B cells. Hence, either the T or B cell repertoires, or more likely both, require N region diversity to produce the full spectrum of autoimmune lupus disease.

Unequal VH gene rearrangement frequency within the large VH7183 gene family is not due to recombination signal sequence variation, and mapping of the genes shows a bias of rearrangement based on chromosomal location.

Much of the nonrandom usage of V, D, and J genes in the Ab repertoire is due to different frequencies with which gene segments undergo V(D)J rearrangement. The recombination signal sequences flanking each segment are seldom identical with consensus sequences, and this natural variation in recombination signal sequence (RSS) accounts for some differences in rearrangement frequencies in vivo. Here, we have sequenced the RSS of 19 individual V(H)7183 genes, revealing that the majority have one of two closely related RSS. One group has a consensus heptamer, and the other has a nonconsensus heptamer. In vitro recombination substrate studies show that the RSS with the nonconsensus heptamer, which include the frequently rearranging 81X, rearrange less well than the RSS with the consensus heptamer. Although 81X differs from the other 7183-I genes at three positions in the spacer, this does not significantly increase its recombination potency in vitro. The rearrangement frequency of all members of the family was determined in microMT mice, and there was no correlation between the in vitro recombination potential and V(H) gene rearrangement frequency in vivo. Furthermore, genes with identical RSS rearrange at different frequencies in vivo. This demonstrates that other factors can override differences in RSS potency in vivo. We have also determined the gene order of all V(H)7183 genes in a bacterial artificial chromosome contig and show that most of the frequently rearranging genes are in the 3' half of the region. This suggests that chromosomal location plays an important role in nonrandom rearrangement of the V(H)7183 genes.

Distribution of human kappa locus IGKV2-29 and IGKV2D-29 alleles in Swedish Caucasians and Hong Kong Chinese.

Polymorphism in the IGKV2-29 gene was shown to decrease the recombination frequency in B cells and to be important for immune responses to Haemophilus influenzae type b polysaccharide. By using the combination of PCR and restriction enzyme mapping, the distribution of IGKV2D-29 and IGKV2-29 gene alleles was estimated in two geographically and ethnically different groups. We found that V2D-29*01 homozygous individuals were most common in Swedish Caucasians (82%), but less common in the Chinese population of Hong Kong (28%). The homozygous V2D-29*02 genotype was found in 19% Chinese, but only in one Caucasian (1%). The frequency of the heterozygous V2D-29*01/V2D-29*02 genotype was also higher in the Chinese population (46%) compared with the Caucasians (7%). V2-29*01 homozygosity was more frequent among Caucasians (85%) than among Chinese (19%). In contrast, homozygous V2-29*02 individuals were over-represented in the Chinese population (18%), whereas only one was found among Caucasians (1%). Heterozygous V2-29*01/V2-29*02 individuals were also more common in the Chinese (63%) than the Caucasian (15%) population. Most Caucasians had the combination of V2D-29*01/V2D-29*01+V2-29*01/V2-29*01 (74%), while the most common genotype for Chinese was V2D-29*01/V2D-29*02+ V2-29*01/V2-29*02 (41%). Analysis of the association of V2D-29*02 and V2-29*02 alleles demonstrated a high degree of linkage, as for V2D-29*01 with V2-29*01. These data show a significant difference in the distribution of IGKV2D-29 and IGKV2-29 alleles among Swedish Caucasians and Hong Kong Chinese. This may help to explain differences in the occurrence of H. influenzae type b infection in the two populations. Evaluated methods for IGKV2D-29 and IGKV2-29 allele detection can be used for the screening allele polymorphisms in other particular patient groups.

B-cell repertoire formation: role of the recombination signal sequence in non-random V segment utilization.

V, D, and J gene segments rearrange at different frequencies in vivo. Each rearranging gene segment is flanked by a recombination signal sequence (RSS), which is composed of a conserved heptamer and nonamer, separated by a spacer of conserved length but not conserved sequence. We summarize data from our lab and other labs showing that in many cases, but not all, the RSS can account for differences in recombination frequencies observed in vivo. Our approach is to determine the initial frequency of rearrangement of the V genes in vivo, and then place the RSSs of two V genes into a competition recombination substrate to determine the relative frequency with which the two RSSs support recombination. In one example, we have shown that a polymorphism in the heptamer of a Vkappa gene can result in a significant reduction in recombination frequency. This particular allele is prevalent in Navajos and absent in other populations. We suggest that this single change may play a major role in the high susceptibility of Navajos to Haemophilus influenzae infection, since this Vkappa gene is important in the antibody response to this bacteria. We also describe experiments showing that the sequence of the spacer of the RSS can play an important role in relative recombination frequencies.

E2A and EBF act in synergy with the V(D)J recombinase to generate a diverse immunoglobulin repertoire in nonlymphoid cells.

Immunoglobulin (Ig) and T cell receptor (TCR) genes are assembled during lymphocyte maturation through site-specific V(D)J recombination events. Here we show that E2A proteins act in concert with RAG1 and RAG2 to activate Ig VK1J but not Iglambda VlambdaIII-Jlambda1 rearrangement in an embryonic kidney cell line. In contrast, EBF, but not E2A, promotes VlambdaIII-Jlambda1 recombination. Either E2A or EBF activate IgH DH4J recombination but not V(D)J rearrangement. The Ig coding joints are diverse, contain nucleotide deletions, and lack N nucleotide additions. IgK VJ recombination requires the presence of the E2A transactivation domains. These observations indicate that in nonlymphoid cells a diverse Ig repertoire can be generated by the mere expression of the V(D)J recombinase and a transcriptional regulator.

Factors that influence formation of B cell repertoire.

V, D, and J gene segments rearrange at different frequencies in vivo. In my laboratory, we are interested in determining the reasons for this unequal rearrangement of V genes during B cell development, and also in gaining insights into the mechanisms that control recombination. Every V, D, and J gene segment is flanked on its recombining side(s) by a recombination signal sequence (RSS), which is composed of a conserved heptamer and nonamer, separated by a spacer of conserved length. In this article, we summarize data showing that in many cases the RSS can account for differences in recombination frequencies observed in vivo. The approach that we use is to determine the frequency of initial rearrangement of the V genes in vivo. The RSSs of two V genes are then placed into a competition recombination substrate to determine the relative frequency with which the two RSSs recombine. In one example, we have shown that a single base pair polymorphism in the RSS of a Vkappa gene may play a major role in susceptibility to Haemophilus influenzae type b infection.

Individual V(H) promoters vary in strength, but the frequency of rearrangement of those V(H) genes does not correlate with promoter strength nor enhancer-independence.

The process of V(D)J recombination is highly regulated. Germline transcription of unrearranged gene segments precedes V(D)J rearrangement, and the correlation between germline transcription and accessibility for recombination is strong; thus it has been suggested that germline transcription may be required for rearrangement. If germline transcription is essential for rearrangement, then the level of transcription of individual gene segments might affect the relative frequency of recombination of those genes. Also, since the intronic enhancer, E(mu), is very distant from V(H) genes before they rearrange, then any promoters which were enhancer dependent might have a transcriptional advantage. Here we study in luciferase vectors the promoters of three functional genes of the V(H)S107 family, and compare them to that of the most frequently rearranging gene in the mouse I(g)H locus, V(H)81X, and to a V(H)J558 gene. Within the V(H)S107 family, the three V(H) genes rearrange with very different relative frequencies, with V1 rearranging the most, and V13 seldom rearranging. We show that only the strong V(H)J558 promoter has significant luciferase reporter gene activity in the absence of E(mu). V1 has only 20% as much activity as J558 in the absence of E(mu), and the other promoters have less than 8% of the activity of J558. Notably, the 81X promoter has essentially no enhancer-independent activity. In the presence of E(mu), V1 has equivalent activity to J558, while the other promoters show much less activity. Again, 81X is the weakest promoter of all, despite being the most frequently rearranging gene. Finally, we show that the steady state level of V(H)S107 and V(H)7183 germline transcripts in vivo is very low. Thus, these data show little correlation between the strength or enhancer-independence of these V(H) promoters and the relative frequency of recombination of the corresponding V(H) genes. In addition, the data show that individual V(H) promoters have different strengths even in the presence of E(mu), demonstrating that even promoters within a single V(H) family can be quite heterogeneous.

Decreased frequency of rearrangement due to the synergistic effect of nucleotide changes in the heptamer and nonamer of the recombination signal sequence of the V kappa gene A2b, which is associated with increased susceptibility of Navajos to Haemophilus influenzae type b disease.

Navajos and genetically related populations have a 10-fold increased incidence of Haemophilus influenzae type b (Hib) disease compared with control populations. The Vkappa gene A2 is used to encode the majority of anti-Hib Abs, and these are the highest affinity anti-Hib Abs. Navajos carry a different allele of the A2 gene segment (A2b) that is defective in its ability to undergo V-J recombination. The A2b allele has only three nucleotide changes from the commonly occurring A2a allele, two of which could potentially affect its ability to recombine. In this study we used two independent in vitro assays to test whether the nucleotide change found in the A2b promoter and/or in the A2b recombination signal sequence (RSS) might be responsible for the decrease in recombination frequency observed in vivo. Using a luciferase reporter gene assay, we found no significant difference between A2a and A2b promoter activities. However, the competition recombination substrate assay showed a 4.5-fold reduction in the relative frequency of recombination of the A2b RSS compared with A2a. We show that this decreased frequency is due to a synergistic effect of the unique nucleotide change present in the heptamer of the A2b RSS and the shared nucleotide change present in the nonamer of both A2b and A2a. This in vitro relative frequency of rearrangement is not significantly different from that observed in vivo; therefore, the A2b RSS is probably the factor associated with the increased susceptibility to Hib disease among individuals carrying the A2b allele.

V(H) replacement is unlikely to contribute significantly to receptor editing due to an ineffectual embedded recombination signal sequence.

Receptor editing is a process consisting of replacement of pre-existing H or L chain rearrangements by secondary rearrangements. This process could serve to remove autoreactive specificities, or to rescue loci with non-functional rearrangements. At the H chain locus, functional replacement of a V(H)DJ(H) rearrangement by an upstream V(H) requires the presence of an embedded RSS located in reverse orientation near the 3' end of the V(H) segment. Although most V(H) genes contain a fairly consensus embedded heptamer, the nonamer sequence bears little resemblance to the consensus RSS nonamer. Therefore, the physiologic rate of H chain editing by V(H) replacement is yet unknown. In this study, we used both conventional and sensitive competition recombination substrate assays to determine the recombination frequency of the V(H)1X embedded RSS relative to consensus and non-consensus RSS's. Results show no detectable recombination of the 81X embedded RSS in a recombination substrate, and the competition substrate allows us to estimate that the 81X embedded RSS recombines at least 1300 fold less often than a consensus RSS. This suggests that V(H) gene replacement is not responsible for the decrease in representation of the 81X gene during differentiation. Furthermore, since the sequence of the embedded RSS is very similar for many V(H) genes, our results suggest that receptor editing of the H chain will be an infrequent event, leaving L chain editing as the main mode of avoiding autoreactive specificities in vivo.

Sequence of the spacer in the recombination signal sequence affects V(D)J rearrangement frequency and correlates with nonrandom Vkappa usage in vivo.

Functional variable (V), diversity (D), and joining (J) gene segments contribute unequally to the primary repertoire. One factor contributing to this nonrandom usage is the relative frequency with which the different gene segments rearrange. Variation from the consensus sequence in the heptamer and nonamer of the recombination signal sequence (RSS) is therefore considered a major factor affecting the relative representation of gene segments in the primary repertoire. In this study, we show that the sequence of the spacer is also a determinant factor contributing to the frequency of rearrangement. Moreover, the effect of the spacer on recombination rates of various human Vkappa gene segments in vitro correlates with their frequency of rearrangement in vivo in pre-B cells and with their representation in the peripheral repertoire.

Nucleotide deletion and P addition in V(D)J recombination: a determinant role of the coding-end sequence.

During V(D)J recombination, the coding ends to be joined are extensively modified. Those modifications, termed coding-end processing, consist of removal and addition of various numbers of nucleotides. We previously showed in vivo that coding-end processing is specific for each coding end, suggesting that specific motifs in a coding-end sequence influence nucleotide deletion and P-region formation. In this study, we created a panel of recombination substrates containing actual immunoglobulin and T-cell receptor coding-end sequences and dissected the role of each motif by comparing its processing pattern with those of variants containing minimal nucleotide changes from the original sequence. Our results demonstrate the determinant role of specific sequence motifs on coding-end processing and also the importance of the context in which they are found. We show that minimal nucleotide changes in key positions of a coding-end sequence can result in dramatic changes in the processing pattern. We propose that each coding-end sequence dictates a unique hairpin structure, the result of a particular energy conformation between nucleotides organizing the loop and the stem, and that the interplay between this structure and specific sequence motifs influences the frequency and location of nicks which open the coding-end hairpin. These findings indicate that the sequences of the coding ends determine their own processing and have a profound impact on the development of the primary B- and T-cell repertoires.

Human cord blood kappa repertoire.

To determine the Vkappa gene utilization in cord blood, we made libraries of Igkappa sequences from two cord blood cDNA samples. The rearranged sequences were amplified using random amplification of cDNA ends PCR, ensuring unbiased amplification of all Vkappa genes. Although the human kappa locus contains approximately 38 potentially functional V genes, we observed that approximately 75% of the 146 sequences from our two samples used only nine Vkappa genes. Using leader-specific primers, we also amplified VkappaI and VkappaIII rearrangements from genomic DNA from one of these individuals. Nonproductive rearrangements give an approximation of the relative frequency of gene rearrangement. Some of the genes that were overused in the cDNA libraries were also observed to rearrange frequently, but others did not show high rearrangement frequencies, suggesting that cellular selection caused their increase in the periphery. Surprisingly, we observed a high frequency of rearrangements using L9, which has been reported to be a defective Vkappa gene. Sequence analysis of the unrearranged gene revealed two new functional alleles of this gene. We observed that N nucleotides were present in 29% of the productive sequences from cord blood DNA and RNA. To determine the actual rate of N region addition, we analyzed V-J junctions of rearrangements of two nonfunctional V genes. Forty-six percent of those cord blood sequences contained N regions. In comparison, 57% of junctions of the rearranged nonfunctional gene from adult PBMC contained N regions. Finally, we observed that CDR3 length heterogeneity was more pronounced for VkappaIII genes than for all of the other Vkappa families.

Both E12 and E47 allow commitment to the B cell lineage.

The E2A gene products, E12 and E47, are required for proper B cell development. Mice lacking the E2A gene products generate only a very small number of B220+ cells, which lack immunoglobulin DJ(H) rearrangements. We have now generated mice expressing either E12 or E47. B cell development in mice expressing E12 but lacking E47 is perturbed at the pro-B cell stage, and these mice lack IgM+B220+ B cells in both bone marrow and spleen. IgM+B220+ B cells can be detected, albeit at significantly reduced levels, in the bone marrow and spleen of mice lacking E12. Ectopic expression of both E12 and E47 in a null mutant background shows that E12 and E47 act in concert to promote B lineage development. Taken together, the data indicate that both E12 and E47 allow commitment to the B cell lineage and act synergistically to promote B lymphocyte maturation.

Targeted disruption of the PU.1 gene results in multiple hematopoietic abnormalities.

PU.1 is a member of the ets family of transcription factors and is expressed exclusively in cells of the hematopoietic lineage. Mice homozygous for a disruption in the PU.1 DNA binding domain are born alive but die of severe septicemia within 48 h. The analysis of these neonates revealed a lack of mature macrophages, neutrophils, B cells and T cells, although erythrocytes and megakaryocytes were present. The absence of lymphoid commitment and development in null mice was not absolute, since mice maintained on antibiotics began to develop normal appearing T cells 3-5 days after birth. In contrast, mature B cells remained undetectable in these older mice. Within the myeloid lineage, despite a lack of macrophages in the older antibiotic-treated animals, a few cells with the characteristics of neutrophils began to appear by day 3. While the PU.1 protein appears not to be essential for myeloid and lymphoid lineage commitment, it is absolutely required for the normal differentiation of B cells and macrophages.

A defective Vkappa A2 allele in Navajos which may play a role in increased susceptibility to haemophilus influenzae type b disease.

The antibody response to H. influenzae type b (Hib) is pauciclonal, and is dominated by antibodies using the VkappaA2 gene. Navajos have a 5-10-fold increased incidence of Hib disease compared with control populations. We hypothesized that a polymorphism in one of the genes in this oligoclonal response may lead to increased disease susceptibility. Since the predominant A2+ anti-Hib antibodies have high avidity for Hib and can be unmutated, the A2 Vkappa gene was analyzed. Over half of the Navajos studied, but only one control individual, had a new allele of A2, termed A2b, with three changes from the published A2 germline sequence. One of the changes was in the recombination signal sequence, suggesting that the A2b allele might not undergo V-J rearrangement very frequently. This possibility was confirmed by analyzing the relative frequency of non-productive A2 rearrangements in A2a/b heterozygous Navajos. Many fewer A2b rearrangements were observed, showing that the A2b allele is defective in its ability to undergo rearrangement. The prevalence of this allele in Navajos may play a role in their increased susceptibility to invasive Hib disease. If so, it would underscore the importance of the germline Ig repertoire for protective antibody responses to pathogenic bacteria in unimmunized children.

New alleles of IGKV genes A2 and A18 suggest significant human IGKV locus polymorphism.

The human kappa light chain consists of approximately 35 potentially functional IGKV genes. However, an estimation of the diversity in the IGKV repertoire of an individual will be affected by the extent of polymorphisms for the different IGKV genes and their patterns of inheritance. To date, little information is available to indicate the extent of allelic variation of the IGKV genes. We examined the extent of allelism for one IGKV gene pair, the distal region A2 gene and its closely related proximal region duplicate A18. We found two new alleles for A2 and one new allele for A18, and sequenced approximately 1 kilobase flanking each gene. The new A18 allele, unlike the originally described allele, appears to be functional. All these alleles were found at relatively high frequencies in the four ethnic populations studied, with the exception of the defective A2b allele which was highly represented only in Navajos. The originally described A2a allele encodes for the predominant protective antibody against Haemophilus influenzae. Therefore, the patterns of allelic inheritance described for this IGKV gene pair indicate that allelism in the IGKV locus is likely to have a significant impact on immune responses.