Non-random features of the repertoire expressed by the members of one V kappa gene family and of the V-J recombination

Skewed primary Igκ repertoire and V-J joining in C57BL/6 mice: implications for recombination accessibility and receptor editing

Previous estimates of the diversity of the mouse Ab repertoire have been based on fragmentary data as a result of many technical limitations, in particular, the many samples necessary to provide adequate coverage. In this study, we used 5'-coding end amplification of Igκ mRNAs from bone marrow, splenic, and lymph node B cells of C57BL/6 mice combined with amplicon pyrosequencing to assess the functional and nonfunctional Vκ repertoire. To evaluate the potential effects of receptor editing, we also compared V/J associations and usage in bone marrows of mouse mutants under constitutive negative selection or an altered ability to undergo secondary recombination. To focus on preimmune B cells, our cell sorting strategy excluded memory B cells and plasma cells. Analysis of ~90 Mbp, representing >250,000 individual transcripts from 59 mice, revealed that 101 distinct functional Vκ genes are used but at frequencies ranging from ~0.001 to ~10%. Usage of seven Vκ genes made up >40% of the repertoire. A small class of transcripts from apparently nonfunctional Vκ genes was found, as were occasional transcripts from several apparently functional genes that carry aberrant recombination signals. Of 404 potential V-J combinations (101 Vκs × 4 Jκs), 398 (98.5%) were found at least once in our sample. For most Vκ transcripts, all Jκs were used, but V-J association biases were common. Usage patterns were remarkably stable in different selective conditions. Overall, the primary κ repertoire is highly skewed by preferred rearrangements, limiting Ab diversity, but potentially facilitating receptor editing.

Violations of the 12/23 rule at the mouse immunoglobulin kappa locus, including V kappa-V kappa rearrangement

Classically, recombination between immunoglobulin gene segments uses a pair of recombination signal sequences (RSSs) with dissimilar spacers (the "12/23 rule"). Using a series of different genotyping assays, four different kinds of atypical rearrangements were identified at the murine kappa locus: (1) V kappa to V kappa, (2) J kappa to J kappa, (3) V kappa to iRS, a heptameric sequence found in the J kappa C kappa intron, and (4) a possible by-product of a rearrangement between a V kappa and the hypothetical 12-RSS side of a pre-existing signal joint. The novel V kappa-V kappa structure prompted further characterization. Sequence analysis of 14 different V kappa-V kappa rearrangements cloned from murine splenocytes and hybridomas revealed a V kappa 4 family member as one participant in 13 rearrangements, but no rearrangements contained two V kappa 4 genes. The V kappa 4 partner in the V kappa-V kappa rearrangement exhibited more trimming of nucleotides at the V kappa-V kappa junction. A signal joint derived from the inversional rearrangement of two neighboring V kappas was also recovered. These data suggest that the V kappa-V kappa structures arise via RAG-mediated, intrachromosomal recombination.

Haplotype exclusion and receptor editing: irreconcilable differences?

Features of antibody genes and their regulation hinder two properties thought to be critical for clonal selection: haplotype exclusion and receptor diversity. These properties include: (1) the retention of multiple independent L-chain isotypes, which compounds the problem of allelic exclusion with one of isotype exclusion; (2) the process of receptor editing, in which recombination continues in cells already expressing antigen receptors; and (3) non-random associations and quasi-ordered rearrangements of the elements that generate light chain genes, which promote editing at the expense of allelic exclusion and receptor diversification. In contrast, heavy chain gene structure seems to promote haplotype exclusion and receptor diversity. It appears that requirements of receptor selection, such as the need for receptor editing as an immune tolerance mechanism and positive selection as a quality control checkpoint for receptor functionality, impose independent selections that shape the organization and regulation of the antibody genes. Despite these features, B cell development still achieves a significant level of phenotypic haplotype exclusion, suggesting that there is indeed significant selection for antibody monospecificity that is accommodated along with receptor editing. Thus, the immune system achieves both receptor selection and clonal selection, despite their partly antagonistic mechanisms.

Altered selection processes of B lymphocytes in autoimmune NZB/W mice, despite intact central tolerance against DNA

Anti-DNA autoantibodies are the hallmark of systemic lupus erythematosus and the (NZBxNZW)F1 (NZB/W) murine model. To investigate potential defects in B cell tolerance, we followed the development of anti-DNA-specific B cells in 2-5-month-old mice transgenic for an unmutated muH chain in the normal C57BL/6 and in the NZB/W background. When the transgenic H chain was combined with a random kappa L chain repertoire about 60% of the antibodies bound to DNA. The analysis of the B cell repertoire in the spleen showed extensive receptor editing and a deletion of DNA reactivity in the C57BL/6 as well as in the autoimmune NZB/W background. NZB/W compared to C57BL/6 transgenic mice had a higher frequency of anti-DNA B cells among follicular B cells that were not censored by central tolerance mechanisms. Furthermore, positive selection of B cells with a recurrent rearrangement into the marginal zone compartment was more pronounced in NZB/W mice. Serum levels of transgenic IgM and of anti-DNA autoantibodies indicate a polyclonal activation of hyperactive B cells in the transgenic NZB/W mice. We propose different B cell receptor signaling thresholds for the NZB/W compared to C57BL/6 B cells. This could explain the quantitative differences in the B cell repertoire as well as the hyperactivity of B cells from NZB/W mice.

The IgG2a/IgA produced by the murine T560 B lymphoma that arose during a graft-versus-host reaction is polyreactive and somatically mutated

In mice undergoing a graft-versus-host (GVH) reaction, donor T cells responding to the host's MHC antigens induce polyclonal activation of the host's B cells and secretion of their antibodies and autoantibodies. T560, a CD5- B lymphoma that arose in the gut-associated lymphoid tissue (GALT) of a (B10 x B10.H2aH4(b)pWts) F1 hybrid mouse that had been injected with parental B10.H2aH4b splenocytes, is of particular interest because it produces switched, heavily mutated, but, nevertheless, polyreactive immunoglobulin. T560 bears and contains IgG2a but switches to IgA spontaneously. The T560 Ig variable region is encoded by a V186.2-related VH gene, juxtaposed to DFL 16 and J(H)1, and by a Vkappa gene of the Vkappa 4/5 group juxtaposed to Jkappa1. Both VH and VK are heavily mutated. The IgA binds to polystyrene, to p-azophenyl-phosphorylcholine (PC)-conjugated keyhole limpet hemocyanin (KLH) (PC-KLH), to 2,4,6 trinitrophenylated (TNP)-KLH and to human TNF-beta but not to KLH, human TNF-alpha, or any of several other Ags tested. Hapten inhibition experiments indicate that the polystyrene, PC- and TNP-binding sites do not overlap. The switched isotypes and heavy load of somatic mutations found in the T560 IgG2a/IgA suggest that T cell-dependant somatic selection of the T560 precursor B cell may have been superimposed on polyclonal B cell activation originally associated with the GVH.

The variable genes and gene families of the mouse immunoglobulin kappa locus

In this report 118 mouse Vkappa genes are described which, together with the 22 Vkappa genes reported previously (T. Kirschbaum et al., Eur. J. Immunol. 1998. 28: 1458-1466) amount to 140 genes that had been cloned and sequenced in our laboratory. For 73 of them cDNAs are known, i. e. they have to be considered functional genes, although 10 genes of this group have 1-bp deviations from the canonical promoter, splice site or heptanucleotide recombination signal sequences. Twenty Vkappa genes have been defined as only potentially functional since they do not contain any defect, but no cDNAs have been found (yet) for them. Of the 140 Vkappa genes 47 are pseudogenes. There are indications that two to five Vkappa genes or pseudogenes exist in the kappa locus which we have not yet been able to clone. The 140 Vkappa genes and pseudogenes were assigned to 18 gene families, 4 of them being one-member families. This differs from previous enumerations of the families only by the combination of the Vkappa9 and Vkappa10 families and by the addition of the Vkappa dv gene as a new separate family. Sequence identity usually was 80% or above within the gene families and 55-80% between genes of different families. Many of the mouse Vkappa gene families show significant homologies to the human ones, indicating that in evolution Vkappa gene diversification predated the divergence of the primate and rodent clades.

The central part of the mouse immunoglobulin kappa locus

At the present state of analysis the central part of the kappa locus comprises four contigs of together 1.2 Mb and contains 55 Vkappa genes. It is flanked by the 3' part of the locus with 22 Vkappa genes in 0.4 Mb (T. Kirschbaum et al., Eur. J. Immunol. 1998. 28: 1458-1466) and the 5' part with 63 Vkappa genes in six contigs of together 1.5 Mb (F. Röschenthaler et al., accompanying report). The 5' and the central regions have one large contig in common. A part of the central region is linked to the 3' region resulting in a 1.1-Mb contig. The structure of the contigs was established mainly by the analysis of overlapping cosmid clones derived from genomic DNA and yeast and bacterial artificial chromosomes (YACs and BACs) and by PCR techniques. Pulsed-field gel electrophoresis of YAC digests indicated that three gaps between the contigs of the central region are 10-40 kb in size, comprising together about 90 kb. Internal duplications in this part of the locus and rearranged YACs were the major problems of the structural work. Structural details are to be found on the Internet at http://www.med.uni-muenchen.de/biochemie/zach au/kappa.htm. In a concluding section of the report the mouse kappa locus is compared to the human one and some aspects of the evolution of the kappa locus are discussed.

Expressed immunoglobulin repertoire of LPS-stimulated splenocytes of unimmunized mice as studied by two-dimensional gel electrophoresis

The repertoire of isolated immunoglobulin polypeptide chains synthesized by LPS-stimulated splenic B cells from unimmunized 6 weeks old mice was studied by two-dimensional gel electrophoresis. These B cells formed mainly mu heavy chains, while only a small amount of gamma chains was detected on two-dimensional electrophoregrams. The number and character of spots corresponding to each class and type of H and L chains were analyzed. Most of the detected 52 spots, which corresponded to L chains, were well resolved with clearly defined round boundaries. Six of them belonged to two isotypes of lambda chains and the rest to the kappa chain. About 25 clusters corresponded to mu chains. They had different appearance from those of L chains and their characteristic elliptic form with prolonged vertical axes indicated the presence of several H chain variants of slightly different length (due probably to the length variations of CDR3 and carbohydrate heterogeneity) in each cluster. The limited number of spots both of H and L chains is explained as being due to restrictions in the expressed repertoire of preimmune splenic B cells, which have no somatic mutations in the immunoglobulin genes. The concept of macrorepertoire (referring to the relatively small number of detected molecular species) and microrepertoire (describing the mutationally altered molecules) is introduced.

Altered spectra of hypermutation in antibodies from mice deficient for the DNA mismatch repair protein PMS2

Mutations are introduced into rearranged Ig variable genes at a frequency of 10(-2) mutations per base pair by an unknown mechanism. Assuming that DNA repair pathways generate or remove mutations, the frequency and pattern of mutation will be different in variable genes from mice defective in repair. Therefore, hypermutation was studied in mice deficient for either the DNA nucleotide excision repair gene Xpa or the mismatch repair gene Pms2. High levels of mutation were found in variable genes from XPA-deficient and PMS2-deficient mice, indicating that neither nucleotide excision repair nor mismatch repair pathways generate hypermutation. However, variable genes from PMS2-deficient mice had significantly more adjacent base substitutions than genes from wild-type or XPA-deficient mice. By using a biochemical assay, we confirmed that tandem mispairs were repaired by wild-type cells but not by Pms2(-/-) human or murine cells. The data indicate that tandem substitutions are produced by the hypermutation mechanism and then processed by a PMS2-dependent pathway.

Reevaluation of 3'Ekappa function in stage- and lineage-specific rearrangement and somatic hypermutation

Transgenic studies have led to the conclusion that the 3'Ekappa enhancer functions to suppress kappa variable region gene assembly in T lineage cells and in progenitor B cells and have also implicated 3'Ekappa as a critical element in promoting somatic hypermutation of kappa variable region genes. To assess the role of the endogenous 3'Ekappa, we assayed these processes in mice homozygous for mutations in which the 3'Ekappa sequences were deleted by the loxP/Cre method (3'Ekappa delta/delta mice). In contrast to transgenic findings, we found that deletion of the endogenous 3'Ekappa did not deregulate kappa gene rearrangement in T lineage cells or in pro-B cells. Furthermore, immunization of the 3'Ekappa delta/delta mice led to the generation of specific antibodies with mutation patterns typical of affinity maturation, showing that there is no absolute requirement for the 3'Ekappa with respect to somatic mutation of endogenous kappa genes.

Rearrangement and Selection in the Developing Vκ Repertoire of the Mouse: An Analysis of the Usage of Two Vκ Gene Segments

Detailed analysis of the rearrangement and expression of two mouse Vκ genes has been used to examine B cell repertoire development. The Vκ1-A gene is used by a large proportion (9.6%) of splenic B cells in the adult primary repertoire, whereas the Vκ22 gene is used at a much lower frequency (0.16%). Consistent with these results, quantitative PCR (Q-PCR) assays revealed that the number of splenic B cells with rearranged Vκ1-A genes is much greater than the number with rearranged Vκ22 genes. Q-PCR was also performed on both normal bone marrow pre-B cells and transformed pre-B cells induced to rearrange their κ loci at high frequency. In contrast to splenic B cell rearrangements, the numbers of Vκ1-A and Vκ22 rearrangements in pre-B cells differ by only two- or threefold, suggesting that the intrinsic rearrangement frequencies of these two Vκ genes are not significantly different. Further evidence of disproportionate selection was obtained by comparing the percentages of productive rearrangements amplified from genomic splenic DNA. Sequence analysis showed 84% (37 of 44) of the Vκ1-A rearrangements but only 57% (29 of 51) of the Vκ22 rearrangements to be in-frame. Together these results suggest that B cells expressing Vκ1-A-encoded light chains are preferentially selected either in the periphery or in the transition from pre-B to B cell. Sequence data also reveal a surprisingly restricted diversity of VJ junctions, apparently due to biases introduced by the rearrangement mechanism.

Molecular modeling study of the multidrug resistance modifiers cis- and trans-flupentixol

Recent drug-membrane interaction and quantitative structure-activity relationship studies of thioxanthenes and related compounds acting as multidrug resistance (MDR) modifiers pointed to the importance of the stereoisomery for their MDR reversing activity. Therefore a molecular modeling study of trans-(T) and cis-flupentixol (C) was performed in order to elucidate the observed discrepancy between equal binding potency to P-glycoprotein and different MDR reversing activity of the two stereoisomers. The results show that the 2 to 3-fold difference in MDR reversing activity of T compared to C might be related to a different orientation of the molecules in the membrane lipid environment. From the conformations generated by the SYBYL systematic search procedure those comprising local energy minima were selected and further optimized with semiempirical quantum chemistry methods. From the optimized conformations those that corresponded to 1H NMR results on drug conformations in lipid environment were selected for further molecular modeling studies. The electrostatic and lipophilic fields of T and C were compared in order to identify molecular properties related to the activity difference. The results show that the electrostatic fields of the drugs when similar in shape are dissimilar and that the lipophilic and hydrophilic regions are clearer separated in T in comparison with C. This imposes a better fitting of T compared to C to membrane lipid environment in accordance with the observed higher interaction strength of T with phospholipids.

The mouse immunoglobulin kappa locus contains about 140 variable gene segments

In continuation of our efforts to elucidate the immunoglobulin kappa locus of the mouse we analyzed 46 yeast artificial chromosomes (YACs) containing V kappa, J kappa and C kappa genes. The YACs, which were derived from DNA of C57BL/6 and C3H mice, ranged from 0.3-1.9 Mb in size. On the basis of hybridization with probes specific for the V kappa gene families a group of 13 YACs was selected for detailed analysis. The V kappa genes of the YACs were then characterized by hybridization to the family-specific probes and by the sizes of the EcoRI fragments on which they were found. This way evidence was obtained for 140 different V kappa gene signals on the YACs. Of these 63 had been characterized before on clones from a cosmid library of total mouse DNA (I. Zocher et al., Eur. J. Immunol. 1995. 25: 3326-3331) and 22 others were found now on cosmid clones derived from the YACs. Six V kappa genes of the previous study which were not found on the YACs are probably located outside of the kappa locus. The YACs were arrayed in a unique order establishing a YACs panel which most likely contains the whole kappa locus. The cosmid contigs and solitary cosmid clones which contain the 63 plus 22 V kappa gene signals mentioned above comprise about 2.0 Mb. Assuming that the remaining 55 V kappa genes are spaced at the same average distance of 24 kb, one may extrapolate to a locus size of 3.3 Mb.

Somatic hypermutation

For the generation of secondary response antibodies, immunoglobulin genes are subjected to hypermutation. Cells expressing antibodies with higher affinity are then selected by antigen. Recent clues to the mechanism of hypermutation come from experiments using transgenic mice enabling analysis of the controlling cis-acting elements and the intrinsic features of the hypermutation, dissociated from the effects of antigenic selection.

Hypothesis: a memory lymphocyte-specific soma-to-germline genetic feedback loop

Analysis of recently published DNA sequence data obtained for related germline Ig variable (IgV) genetic elements of several vertebrate species revealed the presence of a number of extremely non-random patterns of sequence variability among these genes. Strikingly, the patterns were also observed in two sets of chicken IgV pseudogenes. Since the observed patterns are clearly incompatible with existing theories of multigene family evolution, a new model that can account for all of the data is presented in this paper. The model is a modification and extension of an earlier proposed mechanism whereby somatically expressed genes can be returned to the germline by endogenous retroviruses that may act as soma-to-germline genetic vectors. The mechanism described proposes that the interactions that may result in the soma-to-germline transfer of somatically selected IgV genes occur in the epididymis of the male reproductive tract and are restricted to memory lymphocytes. This mechanism makes a number of predictions that are amenable to experimental testing. From the data presently available in the literature it is not possible to extend the mechanism to the female reproductive tract.

Breakdown of B cell tolerance in a mouse model of systemic lupus erythematosus

Anti-DNA antibodies, specifically those that stain nuclei in a homogenous nuclear (HN) fashion, are diagnostic of systemic lupus erythematosus (SLE) and the MRL-lpr/lpr SLE murine model. We have used a heavy chain transgene that increases the frequency of anti-HN antibodies to address whether their production in SLE is the consequence of a defect in B cell tolerance. Anti-HN B cells were undetectable in nonautoimmune-prone transgenic mice, but in MRL-lpr/lpr transgenic mice their Ig was evident in the sera and they were readily retrievable as hybridomas. We conclude that nonautoimmune animals actively delete anti-HN-specific B cells, and that MRL-lpr/lpr mice are defective in this process possibly because of the lpr defect in the fas gene.

Analysis of patterns of DNA sequence variation in flanking and coding regions of murine germ-line immunoglobulin heavy-chain variable genes: evolutionary implications

We analyzed the DNA sequence structure of the 5' flanking and coding regions of 52 VH186.2-related germ-line genes isolated by PCR from C57BL/6J and BALB/c mice. The aligned coding regions display hypervariable and conserved regions corresponding to some of the complementarity-determining regions (CDRs) and framework regions (FRs) found in somatically mutated rearranged immunoglobulin variable genes. Most of the coding regions (88.5%) display open reading frames, strongly suggesting positive selection by antigen. Phylogenetic comparisons of putative transcribed regions versus 5' nontranscribed regions show that they have evolved very differently. Inspection of the 52 murine VH186.2-related DNA sequences (as well as other vertebrate germ-line V sequences reported in the literature) reveals clusters of insertion and deletion events bracketing the transcription/coding unit. These data strongly suggest hyperrecombination events targeting the putative transcription/coding sequence. Given that the DNA of unrearranged germ-line V elements cannot be the direct target for "natural-selection" antigen-binding forces (since V elements are only expressed somatically when rearranged in a mature lymphocyte), it is difficult to explain how these nonrandom sequence variations appear in the germ-line DNA. A number of molecular genetic processes are considered, including antigen-driven soma-to-germ-line gene feedback operative during vertebrate germ-line V gene evolution.

Development of antibody diversity in single germinal centers: selective expansion of high-affinity variants

In a T cell-dependent immune response the microenvironment of the germinal center plays a crucial role in the affinity maturation of the antigen-specific, immunoglobulins. In order to look at the development of antibody diversity we have isolated single germinal centers and sequenced light chains characteristic of 2-phenyl-oxazolone (phOx)-specific antibodies. Fourteen days after immunization we can demonstrate various stages of intraclonal diversity. There are germinal centers where B cells are practically unmutated, suggesting that in these cases a substantial clonal expansion has taken place prior to the activation of the hypermutation mechanism. In other germinal centers, sequences with a low number of randomly distributed somatic mutations were observed, indicating that these changes have been introduced recently and/or that they fail to generate high-affinity variants and hence provide no basis for affinity selection. Finally, germinal centers are found in which practically all sequences carry the amino acid substitutions characteristic of the high affinity phOx antibodies. In these latter cases the high-affinity variants have been preferentially expanded. We conclude that affinity selection is a process that operates right from the beginning of germinal center development. Those B cells with a relative high affinity for the antigen gain a proliferative advantage over other cells and will dominate the response and these are the cells which will be selected to differentiate into memory cells.

The 5' boundary of somatic hypermutation in a V kappa gene is in the leader intron

The maturation of the immune response involves the hypermutation of antibody genes and the selection of B cells expressing receptors with improved antigen binding properties. Somatic hypermutation of antibody genes is targeted to a small region approximately 1 kb surrounding the rearranged V gene. The precise definition of the 5' limit is not yet clear since the data base of somatic mutations upstream of the V region is very restricted. The available data suggest that it lies close to the promoter region and this has been used to implicate transcription in the mechanism leading to hypermutation. Here we present an extensive analysis of mutations in the 5' region of a single kappa light chain gene. A large data base from highly mutated sequences was obtained from anti-oxazolone hybridomas expressing the V kappa Ox1-J kappa 5 light chain and from polymerase chain reaction-derived clones from splenic and Peyer's patches of transgenic mice expressing the same V kappa Ox1-J kappa 5 gene combination. Although mutations were found in the 5'-flanking segment, the rate of mutation in the V-J segment was about 20-fold higher. A sharp decline between those two mutation rates is evident but the boundary was found in the leader intron of the V kappa Ox1 gene, about 150 bases downstream of the initiation of transcription site.

Conservation of sequence in recombination signal sequence spacers

The variable domains of immunoglobulins and T cell receptors are assembled through the somatic, site specific recombination of multiple germline segments (V, D, and J segments) or V(D)J rearrangement. The recombination signal sequence (RSS) is necessary and sufficient for cell type specific targeting of the V(D)J rearrangement machinery to these germline segments. Previously, the RSS has been described as possessing both a conserved heptamer and a conserved nonamer motif. The heptamer and nonamer motifs are separated by a 'spacer' that was not thought to possess significant sequence conservation, however the length of the spacer could be either 12 +/- 1 bp or 23 +/- 1 bp long. In this report we have assembled and analyzed an extensive data base of published RSS. We have derived, through extensive consensus comparison, a more detailed description of the RSS than has previously been reported. Our analysis indicates that RSS spacers possess significant conservation of sequence, and that the conserved sequence in 12 bp spacers is similar to the conserved sequence in the first half of 23 bp spacers.

Analysis of somatic hypermutation in mouse Peyer's patches using immunoglobulin kappa light-chain transgenes

We have exploited mice transgenic for an immunoglobulin kappa light chain in order to show that immunoglobulin genes in the B cells of Peyer's patches in unimmunized mice carry a high level of somatic mutations. Most of the mutations are found in the subpopulation of B cells which, based on peanut agglutinin binding, derive from the germinal centers. The number of mutations per clone and their distribution along the variable gene segment (indicative of untemplated point mutations) are very similar to those found in antigen-specific splenic B cells of normal mice after secondary immunization. The mutations accumulate mainly in complementarity-determining region 1, in particular in some specific codons (Ser-26, Ser-31, and Ser-77) which have been previously recognized as intrinsic hypermutational hotspots. These results suggest that, as in the spleen, somatic mutation occurs in B cells which have migrated to the germinal centers, probably as a consequence of stimulation by antigens present in the gut environment. Transgenic animals are increasingly being used to define the signals involved in hypermutation. However, their subsequent study is very time-consuming because it is based on immunization and analysis of hybridomas or antigen-selected cells. We propose that the use of Peyer's patches of unimmunized adult mice offers a reliable and simple approach to analyze hypermutation of transgenes.

Affinity maturation leads to differential expression of multiple copies of a kappa light-chain transgene

Transgenic animals containing rearranged heavy or light chains are used to study the process of hypermutation, which characterizes the maturation of the antibody response. LK6 mice contain five copies of a transgene coding for a light chain produced in response to the hapten 2-phenyloxazolone. We have selected hybridomas from secondary responses that express the transgene as the only light chain. Some of these hybridomas contain transgene copies carrying mutations known to improve antibody affinity. We have analysed the expression of the five transgene copies in those hybridomas. We report here that the somatic hypermutation process can affect the successful expression of antibody light-chain transgenes. When mutations that improve the antibody affinity appear in one transgene copy, antigenic selection favours cells that downregulate the other copies at multiple levels of gene expression, including examples where nonsense mutations correlate with a drop in messenger RNA level.

Restricted kappa chain expression in early ontogeny: biased utilization of V kappa exons and preferential V kappa-J kappa recombinations

To determine the extent of kappa chain diversity in the preimmune repertoire early in development, kappa cDNA libraries were analyzed from 15-d old fetal omentum, 18-d-old fetal liver, and 3-wk old bone marrow. An anchored polymerase chain reaction approach was used to avoid bias for particular V kappa families. From the sequence analysis of 27 bone marrow clones, 10 different families and 20 unique V kappa genes were identified. In contrast, the V kappa expression in the fetus is highly restricted and clearly differs from the broader distribution see in 3-wk-old bone marrow. Although several V kappa families were represented in the fetal library including V kappa 9, V kappa 10, V kappa 4,5, V kappa 8, and V kappa 1, one or two members of individual families were observed repeatedly. The fetal liver and omentum libraries were found to be largely overlapping. Given the V kappa families/exons identified in the fetal sequences, the mechanism of kappa rearrangements in the early repertoire appears to occur predominantly by inversion. Importantly, the fetal repertoire was further restricted by dominant V kappa-J kappa combinations such as V kappa 4,5-J kappa 5, V kappa 9-J kappa 4, and V kappa 10-J kappa 1. Since in some cases independent rearrangements could be established, the results indicate a bias for particular V kappa-J kappa joins. The results also suggest that clonal expansion/selection in the fetal repertoire takes place after light chain rearrangement as opposed to at the pre-B cell level in the bone marrow. The restriction observed in kappa light chain expression together with known restrictions in gene usage and junctional diversity at the heavy chain level indicate a remarkably conserved fetal repertoire.

B lymphocytes may escape tolerance by revising their antigen receptors

To explore mechanisms that prevent autoreactivity in nonautoimmune mice, endogenous immunoglobulin (Ig) light (L) chains that associate with a transgenic anti-DNA heavy chain were analyzed. The antibodies from splenic B cell hybridomas of such mice did not bind double-stranded DNA (dsDNA) and their L chain sequences showed a biased use of V kappa and J kappa gene segments. The 44 L chains in this survey were coded for by just 18 germline genes. Six of the genes, each belonging to a different V kappa group, were used more than once and accounted for three fourths of all sequences. Based on the distribution of V kappa genes, the L chain repertoire in this line of transgenic mice was estimated at 37 V kappa genes. The most frequently observed gene, a member of the V kappa 12/13 group, was identified in 16 hybrids. In addition, the majority of V kappa genes used J kappa 5. We interpret the skewed representation of V kappa and J kappa gene segments to result from negative selection. Based on the data, we suggest that V kappa rearrangements giving rise to anti-dsDNA reactivity are removed from the repertoire by a corrective mechanism capable of editing self-reactive Ig.

Passenger transgenes reveal intrinsic specificity of the antibody hypermutation mechanism: clustering, polarity, and specific hot spots

We have analyzed somatic hypermutation in mice carrying an immunoglobulin kappa transgene in order to discriminate mutations that reflect the intrinsic specificity of the hypermutation mechanism from those highlighted by antigenic selection. We have immunized animals with three different immunogens. With one immunogen, the antigen-specific B cells express a transgenic kappa chain, which does not form part of the antibody; the transgene is a passenger free to accumulate unselected mutations. With the other two immunogens, the transgenic kappa chain constitutes the light chain of the expressed antibody. A comparison of the transgene mutations obtained under these different circumstances allows us to identify common features that we attribute to the intrinsic specificity of the hypermutation process. In particular, it yields only base substitutions and leads to hot spots occurring in individual positions (e.g., the second base of the Ser-31 codon). The mutations preferentially accumulate around the first complementarity-determining region. The process exhibits specific base substitution preferences with transitions being favored over transversions. We propose that these substitution preferences can be used to discriminate intrinsic from antigen-selected hot spots. We also note that hypermutation distinguishes between the coding and noncoding strands since pyrimidines (particularly thymidines) mutate less frequently than purines.

P nucleotides in V(D)J recombination: a fine-structure analysis

Antigen receptor genes acquire junctional inserts upon assembly from their component, germ line-encoded V, D, and J segments. Inserts are generally of random sequence, but a small number of V-D, D-J, or V-J junctions are exceptional. In such junctions, one or two added base pairs inversely repeat the sequence of the abutting germ line DNA. (For example, a gene segment ending AG might acquire an insert beginning with the residues CT upon joining). It has been proposed that the nonrandom residues, termed "P nucleotides," are a consequence of an obligatory end-modification step in V(D)J recombination. P insertion in normal, unselected V(D)J joining products, however, has not been rigorously established. Here, we use an experimentally manipulable system, isolated from immune selection of any kind, to examine the fine structure of V(D)J junctions formed in wild-type lymphoid cells. Our results, according to statistical tests, show the following, (i) The frequency of P insertion is influenced by the DNA sequence of the joined ends. (ii) P inserts may be longer than two residues in length. (iii) P inserts are associated with coding ends only. Additionally, a systematic survey of published P nucleotide data shows no evidence for variation in P insertion as a function of genetic locus and ontogeny. Together, these analyses establish the generality of the P nucleotide pattern within inserts but do not fully support previous conjectures as to their origin and centrality in the joining reaction.

P nucleotides in V(D)J recombination: a fine-structure analysis

Antigen receptor genes acquire junctional inserts upon assembly from their component, germ line-encoded V, D, and J segments. Inserts are generally of random sequence, but a small number of V-D, D-J, or V-J junctions are exceptional. In such junctions, one or two added base pairs inversely repeat the sequence of the abutting germ line DNA. (For example, a gene segment ending AG might acquire an insert beginning with the residues CT upon joining). It has been proposed that the nonrandom residues, termed "P nucleotides," are a consequence of an obligatory end-modification step in V(D)J recombination. P insertion in normal, unselected V(D)J joining products, however, has not been rigorously established. Here, we use an experimentally manipulable system, isolated from immune selection of any kind, to examine the fine structure of V(D)J junctions formed in wild-type lymphoid cells. Our results, according to statistical tests, show the following, (i) The frequency of P insertion is influenced by the DNA sequence of the joined ends. (ii) P inserts may be longer than two residues in length. (iii) P inserts are associated with coding ends only. Additionally, a systematic survey of published P nucleotide data shows no evidence for variation in P insertion as a function of genetic locus and ontogeny. Together, these analyses establish the generality of the P nucleotide pattern within inserts but do not fully support previous conjectures as to their origin and centrality in the joining reaction.