Complexity, polymorphism, and connectivity of mouse Vk gene families

Vkappa polymorphisms in NOD mice are spread throughout the entire immunoglobulin kappa locus and are shared by other autoimmune strains

The diversity of immunoglobulin (Ig) and T cell receptor (TCR) genes available to form the lymphocyte repertoire has the capacity to produce a broad array of both protective and harmful specificities. In type 1 diabetes (T1D), the presence of antibodies to insulin and other islet antigens predicts disease development in both mice and humans, and demonstrate that immune tolerance is lost early in the disease process. Anti-insulin T cells isolated from T1D-prone non-obese diabetic (NOD) mice use polymorphic TCRalpha chains, suggesting that the available T cell repertoire is altered in these autoimmune mice. To probe whether insulin-binding B cells also possess polymorphic V genes, Ig light chains were isolated and sequenced from NOD mice that harbor an Ig heavy chain transgene. Three insulin-binding Vkappa genes were identified, all of which were polymorphic to the closest germline sequence matches present in the GenBank database. Additional analysis of over 300 light chain sequences from multiple sources, including germline DNA, shows that polymorphisms are spread throughout the entire NOD Igkappa locus, as these polymorphic sequences represent 43 distinct Vkappa genes which belong to 14 Vkappa families. Database searches reveal that a majority of polymorphic Vkappa genes identified in NOD are identical to Vkappa genes isolated from SLE-prone NZBxNZW F1 or MRL strains of mice, suggesting that a shared Igkappa haplotype may be present. Predicted amino acid changes preferentially occur in CDR, and thus could alter antigen recognition by the germline B cell repertoire of autoimmune versus non-autoimmune mouse strains.

Rearrangement and expression of immunoglobulin light chain genes can precede heavy chain expression during normal B cell development in mice

In mouse mutants incapable of expressing mu chains, VkappaJkappa joints are detected in the CD43(+) B cell progenitors. In agreement with these earlier results, we show by a molecular single cell analysis that 4-7% of CD43(+) B cell progenitors in wild-type mice rearrange immunoglobulin (Ig)kappa genes before the assembly of a productive VHDHJH joint. Thus, mu chain expression is not a prerequisite to Igkappa light chain gene rearrangements in normal development. Overall, approximately 15% of the total CD43(+) B cell progenitor population carry Igkappa gene rearrangements in wild-type mice. Together with the results obtained in the mouse mutants, these data fit a model in which CD43(+) progenitors rearrange IgH and Igkappa loci independently, with a seven times higher frequency in the former. In addition, we show that in B cell progenitors VkappaJkappa joining rapidly initiates kappa chain expression, irrespective of the presence of a mu chain.

Editing disease-associated autoantibodies

We have generated site-directed transgenic mice whose transgenes code for anti-DNA antibodies. These antibodies are representative of the lupus-associated anti-DNAs seen in mouse models of autoimmunity and human SLE, and have the usual characteristics of pathogenic autoantibodies. As conventional transgenics in nonautoimmune mice, anti-DNA B cells have been shown to be deleted or inactivated. Autoreactive B cells can also escape negative regulation by a process called receptor editing. Here we describe two combined immunoglobulin H and L chain site-directed transgenic mouse models and characterize their editing phenotypes. One model, 3H9R/Vkappa4R, has a deletion-prone phenotype and undergoes editing, primarily by inactivation of the light chain by leap-frogging events. In the other model, 3H9R/Vkappa8R, B cells are susceptible to anergy and maintain most of their HR and LR chains. These studies clarify the relationship between editing and other mechanisms of tolerance.

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.

Structural diversity of monoclonal CD4 antibodies and their capacity to block the HIV gp120/CD4 interaction

A number of monoclonal antibodies have been raised against CD4, the receptor on T cells for the HIV envelope glycoprotein gp120. In the present paper we describe biological activities and sequence analysis of seven CD4 MAb. Five of these MAb preparations compete with HIV/gp120 for CD4 binding. The sequences of the variable regions for these MAb were determined in order to ascertain any correlation with selective V gene usage. A relationship was found between the expressed variable region genes and the CD4 recognition pattern. The VH genes that are used can be subdivided into two major groups expressing either a VH gene belonging to the J558 family or to the VGam family. The usage of the VL genes varies, indicating that the epitope specificity is predominantly determined by the rearranged VH genes. The distinct cross-reactivity pattern of these MAb also correlates with their capacity to block binding of recombinant gp120 to CD4 in vitro. Although five of these MAb were able to block gp120 binding none of the CDR sequences shows a relevant homology to the gp120 sequence. This indicates a steric hinderence mechanism for blocking gp120 binding and not a direct interaction with the receptor binding site on CD4. The data also confirm the failure of these MAb as a potential target for receptor mimicry.

Yeast artificial chromosome contigs reveal that distal variable-region genes reside at least 3 megabases from the joining regions in the murine immunoglobulin kappa locus

The immunoglobulin kappa gene locus encodes 95% of the light chains of murine antibody molecules and is thought to contain up to 300 variable (V kappa)-region genes generally considered to comprise 20 families. To delineate the locus we have isolated 29 yeast artificial chromosome genomic clones that form two contigs, span > 3.5 megabases, and contain two known non-immunoglobulin kappa markers. Using PCR primers specific for 19 V kappa gene families and Southern analysis, we have refined the genetically defined order of these V kappa gene families. Of these, V kappa 2 maps at least 3.0 Mb from the joining (J kappa) region and appears to be the most distal V kappa gene segment.

Two kappa immunoglobulin light chains are secreted by an anti-DNA hybridoma: implications for isotypic exclusion

An anti-DNA hybridoma derived from an MRL/lpr mouse secretes two different kappa light chains in combination with a single heavy chain. Multiple single cell clones express and secrete immunoglobulin containing both kappa light chains. The N-terminal protein sequences of the light chains correspond to sequences predicted from functionally rearranged mRNAs subjected to reverse transcription and amplified by polymerase chain reaction (PCR). Karyotype analysis of the hybridoma indicates a clonal line derived from the fusion of two cells. By amino acid sequence comparison and PCR analysis, both functional kappa light chains are derived from the MRL/lpr spleen. The two functional light chain cDNAs were cloned and co-transfected into COS-7 cells with the heavy chain cDNA. Only one of the light chains in combination with mAb 3E10 heavy chain confers anti-DNA reactivity. The presence of two separate kappa light chains and, therefore, two separate antigen receptors on a single B cell may have ramifications for both polyclonal activation and toleration of lupus B cells.

Clustered and interspersed gene families in the mouse immunoglobulin kappa locus

Although numerous solitary germ-line V kappa genes and two small V kappa contiguously cloned gene regions (contigs) are known, no attempts to systematically elucidate the structure of the kappa locus of the mouse have been reported so far. As a first step to this aim we screened a cosmid library of C57BL/6J mouse DNA with 18 probes that are more or less specific for the different V kappa gene families. Ninety-one V kappa gene-containing cosmid clones were characterized by detailed restriction mapping and hybridizations. Several contigs were constructed from overlapping clones. The contigs and the still unlinked cosmid clones cover 1.6 Mb. Many of the cosmid clones were localized on chromosome 6 where the kappa locus is known to reside; no evidence for the existence of dispersed V kappa genes (orphons) was obtained. Eighty-five strong hybridization signals were assigned to distinct V kappa gene families, while for 11 weak signals the assignment was less definite. As to the distribution of gene families within the locus the following situation emerged: there are both, groups of genes which belong to one V kappa gene family ("clusters") and groups in which genes of different families are interspersed. The interspersion of gene families seems to be more pronounced than has been assumed so far. Additional V kappa genes which are known to exist will have to be isolated from other gene libraries of the same mouse Ig kappa haplotype.

Formation and resolution of double-strand break intermediates in V(D)J rearrangement

A recently described pre-B cell line can be induced at high temperature to actively rearrange its immunoglobulin light-chain loci. We used this cell line to determine the fate of double-strand breaks generated by V(D)J rearrangement. After induction, 30%-40% of K loci had broken JK1 signal ends. JK1-coding ends were detectable, but 10- to 100-fold less frequent. Both covalently closed (hairpin) and open, blunt, processed coding ends were observed. Coding junctions involving JK1 accumulated with similar kinetics as JK1 signal ends, arguing that coding ends can be resolved quickly and efficiently to coding junctions, whereas signal ends remain mostly unjoined. Signal ends are then joined rapidly when cells are returned to the low temperature. These results support the model that broken signal ends and hairpin coding ends are authentic intermediates in V(D)J recombination. It appears that hairpin coding ends are rapidly opened, processed, and resolved to coding junctions, whereas joining of signal ends is clearly uncoupled from the joining of coding ends and can be much slower. Efficient formation of signal junctions may require cell cycle progression, or down-regulation of the recombination machinery.

Differences in the biochemical properties of esterolytic antibodies correlate with structural diversity

A prerequisite to the design and engineering of catalytic antibodies is the knowledge of their structure and in particular which residues are involved in binding and catalysis. We compared the structure and catalytic properties of a series of six monoclonal antibodies which were all raised against a p-nitrophenyl (PNP) phosphonate and which catalyze the hydrolysis of p-nitrophenyl esters. Three of the antibodies (Group I) have similar light and heavy chain variable regions. The other three antibodies have similar VL regions of which two (Group II) have VH regions from the MOPC21 gene family and the remaining one (Group III) a VH from the MC101 gene family making a total of three different groups based on their V region sequences. The structural division into groups is paralleled by the differences in binding constants to hapten analogs, substrate specificity and the susceptibility of the catalytic activity of the antibodies to chemical modification of tryptophan and arginine residues. The relative binding of a transition state analog to the binding of substrate is much higher for the Group I antibodies than for the other groups. Only the Group I antibodies can catalyze the hydrolysis of a carbonate substrate. However all of the antibodies lose catalytic activity upon specific tyrosine modification which highlights the importance of tyrosine in the active site of the antibodies. Thus, antibodies raised against a single hapten can give antibodies with different structures, and correspondingly different specificities and catalytic properties.

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.

Characterization of a V kappa family in Mus musculus castaneus: expansion at the subset level

We have examined the same kappa chain variable (V kappa) region family in several mouse species in order to observe short-term, incremental change at immunoglobulin (Ig) multigene loci. In the present study, the Igk-V24 family has been characterized in a Mus m. castaneus colony derived from individuals originating in Thailand and compared to the same family in Mus m. domesticus (BALB/c) and Mus pahari, representing about 1-2 and about 5-9 million years of evolution, respectively. Southern hybridization of genomic DNA with a probe encoding the prototype Igk-V24 coding region reveals restriction fragment patterns indicative of two distinct M. m. castaneus haplotypes. These haplotypes appear to result from an unequal recombination between similar gene arrays, as their restriction patterns are unique but contain many common fragments. The complexity of these patterns indicates a marked expansion in the Igk-V24 family of M. m. castaneus relative to BALB/c and M. pahari. Additional analyses using probes specific for individual subsets demonstrate that the expansion is not general throughout the entire family, but is restricted to particular subsets and therefore to relatively short chromosomal segments. One subset alone accounts for most of the expansion and comprises over 40% of the entire M. m. castaneus family. The wide range of Igk-V24 family complexity seen among M. m. castaneus, M. m. domesticus, and M. pahari, as well as among the different M. m. castaneus family subsets, suggests a model of random evolution in V kappa family copy number rather than one which is selective.

Combinatorial functions of two chimeric antibodies directed to human CD4 and one directed to the alpha-chain of the human interleukin-2 receptor

The general feasibility of chimerization of monoclonal antibodies (mAbs) has already been shown for a large number of them. In order to evaluate in vitro parameters relevant to immunosuppressive therapy, we have chimerized and synthesized two anti-CD4 mAbs recognizing two different epitopes on the human T-lymphocyte antigen, CD4. The chimerized mAbs are produced at levels corresponding to those of the original hybridoma cell lines. With respect to activation of human complement, the individual Abs are negative; however, when used in combination, complement activation was performed. When applied in combination, they were found to modulate the CD4 antigen, whereas the individual mAb do not display this property. Individually they mediate an up to 60% inhibition of the mixed lymphocyte reaction (MLR). However, by combination of an anti-CD4 mAb with one directed against the alpha-chain of the human IL2 receptor, nearly 100% inhibition of the MLR was achieved, even with reduced dosage of the mAbs. Our data suggest that the combination of an anti-CD4 mAb and an anti-IL2R alpha chain mAb is more effective with respect to immunosuppression than each mAb by itself, indicating that this mAb cocktail could be a new strategy for immunosuppressive therapy.

Linkage of two pseudogenes from V kappa 1 and V kappa 9 murine immunoglobulin families

As an initial step towards the molecular analysis of the murine V kappa locus, a cosmid library from BALB/cJ mouse liver DNA was screened with probes representing 10 V kappa families. Of eight cosmids that were isolated from the initial screen, five contained a single restriction fragment that hybridized to the probes. Two cosmids contained two fragments that hybridized to the same probe, V kappa 4, indicating that some V kappa 4 gene segments are linked. One cosmid had two genes that belonged to different families, V kappa 1 and V kappa 9. The two gene segments were located within 12 kb of each other and lay in the same transcriptional orientation. Linkage of gene segments from the V kappa 1 and V kappa 9 families is consistent with a genetic map of the locus, and provides physical evidence for the first time that two genes from different families are closely linked in the murine kappa locus. Sequence analysis revealed that both genes are pseudogenes: the V kappa psi 1.7 gene segment has eight mutations, including termination codons, insertions, and deletions, and the V kappa psi 9B.8 gene segment has two mutations of an insertion and altered RNA splice site. Both genes have the potential to rearrange based on the sequence of their heptamer-nonamer motifs. The identification of pseudogenes raises the question of how many nonfunctional genes are present in the murine germline repertoire.

Mechanism of allergic cross-reactions--III. cDNA cloning and variable-region sequence analysis of two IgE antibodies specific for trinitrophenyl

As a first step toward defining the molecular interactions between ligands and the IgE antigen-combining site, we report here the cDNA cloning and variable (V) region nucleic acid sequences of the heavy (H) and light (L) chains of 2 monoclonal mouse IgE antibodies to trinitrophenyl (ATCC-TIB142 = IGELa2 and ATCC-TIB141 = IGELb4). In all instances, full-length cDNA clones were obtained to facilitate future expression studies. The H chains were encoded by VH genes from the VH3660 and J558 gene families in context with DQ52 and DSP2.2 diversity (D) mini genes, and JH3 and JH4 joining (J) gene segments, respectively. Vk8/Jk2 and Vk1/Jk5 rearrangements encoded the respective L chain V-regions. Both antibodies exhibited considerable conservation of complementarity determining region (CDR) sequences, which will facilitate template-based computer modeling of the three-dimensional structures of complexes formed between various ligands and these antibodies. From sequence comparison between the dinitrophenyl (DNP)-binding myeloma protein MOPC-315 and these IgE antibodies likely candidates for hapten-contact residues within the binding sites of IGELa2 and IGELb4 have been suggested.

Comparative expression of adult and fetal V gene repertoires

A hallmark of the immune system is the extraordinary diversity associated with antibodies. This is made possible by a series of genetic rearrangements involving variable region gene segments. Considerable detail is known about these genetic mechanisms except for the enzymatic machinery involved. An important question in studies of the generation of diversity is whether V genes are selected for rearrangement mainly in a random manner or selected by particular developmental rules. Past studies have indicated that the acquisition of fetal and neonatal specificity repertoires is a nonrandom process. In this report, we review our studies that directly compare the adult and fetal/neonatal V gene repertoires. The evidence suggests that the adult repertoire is more diverse with indications of a random use of VH gene families. However, whether V genes are indeed randomly used in the adult remains to be clarified at the VH gene member level. The fetal repertoire, on the other hand, appears nonrandom in V gene usage. In addition, the fetal repertoire is mostly germline encoded with little evidence of junctional diversity. Taken together, the results indicate different rules for generation of the adult and fetal repertoires, findings most likely explain by distinct B cell subsets and B cell progenitors at early stages in ontogeny.

Fine-structure mapping of the complex locus Odc-rs5 relative to Igk and distal loci

Odc-rs5 was previously identified as a complex locus closely linked to the Igk complex on mouse Chromosome (Chr) 6 and comprising at least five copies of a sequence related to the mRNA encoding ornithine decarboxylase (ODC) in the genomes of mice of some inbred strains and at least seven copies in others (Richards-Smith and Elliott, Mammalian Genome 2: 215, 1992). In the present study, Odc-rs5 was shown to be composed of at least seven copies of the ODC sequence in both the Odc-rs5a and Odc-rs5b haplotypes. Based upon the distribution of DNA restriction fragments (RFs) that had previously been associated with Odc-rs5a or Odc-rs5b among 42 mice of inbred laboratory strains having various haplotypes at Igk and in mice of two congenic strains [B6.PL-Ly-2a, Ly-3a(75NS)/Cy and B6.PL-Ly-2a,Ly-3a(85NS)/Cy] and a backcross-derived stock (NAK) known to be recombinant within Igk, a fine structure map of Odc-rs5 was deduced relative to Igk and more distal loci. Odc-rs5-derived RFs were located to three distinct regions within and/or distal to Igk and to a fourth site between (Ly-3, Ly-2) and Raf-1. Additionally, DNAs from 19 mice of inbred strains and random-bred stocks derived from wild progenitors trapped at various locations were analyzed and found to exhibit an unexpected variety of combinations of RFs associated with the two Odc-rs5 haplotypes most frequently observed among inbred laboratory strains of mice.

Two closely related kappa variable region pseudogenes pose an evolutionary paradox

Two pseudogenes belonging to the Igk-V1 variable region group have been isolated from BALB/c mice. The genes share greater than 96.5% identity of nucleotide sequence in a 1800 base pair (bp) region surrounding the coding region, but deletions of 221 bp and 84 bp have removed essential sequences from the two genes. As the deletions are different in the two pseudogenes, they must have occurred independently in each gene during or subsequent to the duplication event which gave rise to the genes from a common ancestral gene. Polymerase chain reaction analysis was used to identify the pseudogenes in inbred strains of mice. BALB/c (Igkc) and AKR (Igka), prototype strains representative of the predominant kappa haplotypes, possess both pseudogenes but no intact copy. Only one of the pseudogenes was present in SJL (Igka). Strains C58, c.C58 (Igkd) and NZB (Igkb) possessed an intact version of the gene. This distribution of haplotypes is consistent with a close linkage of the pseudogenes with other Igk-V1 genes on chromosome 6. The translated amino acid sequence of the pseudogenes indicates that prior to their acquiring deletions they encoded typical Igk-V1 variable regions except for an unusual FR2 region, in which the conserved proline at position 44 is replaced by leucine and the normally hydrophobic position 36 was occupied by histidine. Possible mechanisms to explain the occurrence of deletions in both of the pseudogenes in the recent evolution of BALB/c are discussed. One explanation would be that the two genes were already nonfunctional at the time of the duplication so that the subsequent deletions represent neutral events which became fixed in the inbred strains by a process of genetic drift. Alternatively, if the genes were functional at the time of duplication, their rapid loss due to deletion events suggests that negative selection may have acted to eliminate the genes from the V-region repertoire.

Polymorphism in V kappa 10 genes encoding L chains of antibodies bearing the Ars-A and A48 cross-reactive idiotypes

p-azophenylarsonate-specific antibodies of A/J mice which bear the Ars-A crossreactive idiotype utilize the V kappa-Ars-A gene segment, a member of the V kappa 10 family. Southern hybridization of genomic DNA from several inbred strains using a probe from the 5' flanking region of the V kappa-Ars-A gene demonstrated three patterns of restriction fragment length polymorphisms (RFLP). Six genes corresponding to hybridizing bands were obtained from DNA libraries of C.AKR, PERU and A/J mice, and nucleotide sequence comparisons revealed two allelic groups: AKR1 (Igk-V10.1a), AJ1 (Igk-V10.1b) and PERU1 (Igk-V10.1c); AKR2 (Igk-V10.2a), AJ2 (Igk-V10.2b), and PERU2 (Igk-V10.2c). The Igk-V10.1b gene of the A/J strain is the V kappa-Ars-A gene used in Ars-A idiotype-positive antibodies. The product of the C.AKR allele (Igk-V10.1a) contained four amino acid substitutions in CDR3 as compared with Igk-V10.1b. These substitutions probably explain the failure of AKR mice and other strains with the same V kappa 10 RFLP pattern to provide in genetic crosses a L chain which, together with the A/J VH-ArsA gene product, form Ars-A idiotype-positive antibodies. Also, the nucleotide sequence identity between the Igk-V10.1c and Igk-V10.1b alleles and the Igk-V10.2c and Igk-V10.2b alleles is significantly greater than that seen in comparisons with the Igk-V10.1a and Igk-V10.2a alleles, respectively, suggesting an evolutionary pathway similar to that of the linked Igk-J locus. BALB/c antibodies bearing the A48 regulatory idiotype contain L chains encoded by the BALB/c Igk-V10.1b and Igk-V10.2b alleles. Strongly A48 idiotype-positive antibodies utilize the Igk-V10.1b chain, and weakly A48-positive antibodies use the Igk-V10.2b L chain. The possible effects of amino acid substitutions specified by the Igk-V10.1a, Igk-V10.1c, Igk-V10.2a, and Igk-V10.2c alleles on their ability to provide L chains used in A48 idiotype-positive antibodies are discussed.

Antibodies that are specific for a single amino acid interchange in a protein epitope use structurally distinct variable regions

We have analyzed how the immune system generates antibodies that are specific for analogues of an epitope on the influenza virus hemagglutinin (HA) that differ solely by the presence of Asp or Gly at amino acid 225. Most antibodies induced in response to HA(Asp225) use one of a few closely related variable (V) region structures that are encoded by characteristic VH/Vk gene segment combinations. Remarkably, none of these VH/Vk combinations was induced in response to HA(Gly225). Instead of modifying the HA(Asp225)-specific V regions by junctional variation or somatic mutation to recognize the altered epitope, new VH/Vk combinations were used. The expression of unique VH/Vk combinations appears to confer exquisite specificity to the selection of HA-specific B cells from the pre-immune repertoire.

The endogenous Mtv-8 provirus resides within the V kappa locus

The endogenous Mtv-8 provirus previously has been mapped within approximately 0.52 centimorgan from several V kappa markers on mouse chromosome 6. Using Southern blotting and DNA from a recombinant backcross mouse from the C57BL/6 (Mtv-8 positive) and C58 (Mtv-8 negative) strains, Mtv-8 was localized to the same side of the crossover point as immunoglobulin kappa (Ig kappa)-V24 but on the opposite side of the crossover from Ig kappa-V10 and Ig kappa-V21. Molecular cloning and characterization of cellular DNA adjacent to Mtv-8 revealed a functional V kappa 9 gene approximately 4.6 kb downstream and in the same transcriptional orientation as the provirus. These data suggest that Mtv-8 is within the centromere-proximal portion of the V kappa locus.

Specificity and variable region cDNA sequence of an isogeneic monoclonal antiidiotype to an anti-alpha(1----6)dextran

We have characterized a monoclonal isogeneic antiidiotype, IdB5.7, from a BALB/c mouse immunized with the anti-alpha(1----6)dextran C57BL/6 45.21.1. It defined a hapten-inhibitable idiotope expressed on four of the 2 myeloma and 37 hybridoma anti-alpha(1----6)dextrans tested. Sequence comparison of Id+ and Id- anti-alpha(1----6)dextrans suggested that two extra amino acids at VH 100A and 100B and different residues at VH 101 abolish the expression of the idiotope in the Id- anti-alpha(1----6)dextrans. Sequence analysis of the VH of IdB5.7 showed a CDR1 longer than usual and a D segment in CDR3 formed by the fusion of two D minigenes. The IdB5.7 V kappa uses the V kappa 1 germline gene K5.1 with a few substitutions. The D-D fusion in VH CDR3 is a feature which has been reported in several other antiidiotypic antibodies.

Contribution of the VH11 gene family to mitogen-responsive B cell repertoire in C57BL/6 mice

The contribution of VH11 gene family to the development of the primary B cell repertoire has been studied by analyzing 1.8 x 10(4) mitogen induced B lymphocyte colonies. The data demonstrate that VH11 family is predominantly expressed among neonatal splenic as well as adult peritoneal B cell colonies, both rich in Ly-1+ B cells. VH11 gene family expression among B splenocytes decreases during ontogeny and VH11 family pairs stochastically with different V kappa families among mitogen-activated neonatal B cell colonies, which are representative of an antigen unselected B cell repertoire. Thus, an increased VH11 expression among peritoneal and neonatal B cells points towards its biased expression among Ly-1+ B lymphocytes. The restricted V gene rearrangements and VH11-V kappa 9 pairing observed among anti-bromelain-treated mouse red blood cells autoantibodies are likely to be an outcome of both intrinsic gene recombination processes per se as well as selection by an autoantigen and/or local selective environmental factors.

Lack of feedback inhibition of V kappa gene rearrangement by productively rearranged alleles

Circular DNAs excised by immunoglobulin kappa chain gene rearrangements were cloned and characterized. 16 of 17 clones examined were double recombination products containing a V kappa-J kappa rearrangement (coding joint) as well as the reciprocal element (signal joint) of another V kappa-J kappa rearrangement. These products suggested multiple recombination, primary inversion, and secondary excision. In primary events, 5 of 16 translational reading frames were in-phase. Thus, V kappa gene rearrangement may not be inhibited by the presence of a productively rearranged allele. An unusually large trinucleotide (P) insertion forming a palindrome of 12 nucleotides was also observed in one of the coding joints.

Autoimmune syndrome after neonatal induction of tolerance to alloantigens: analysis of the specificity and of the cellular and genetic origin of autoantibodies

BALB/c mice neonatally injected with 10(8) semiallogeneic (C57BL/6 x BALB/c)F1 spleen cells become tolerant to the H-2b alloantigens, but also develop a wide range of autoimmune manifestations characteristic of systemic lupus erythematosus (SLE). Indeed, in these mice, the presence of a hypergammaglobulinaemia, autoantibodies--including anti-ssDNA, anti-platelet, thymocytotoxic and rheumatoid factor antibodies--circulating immune complexes, cryoglobulins as well as renal glomerular deposition of immunoglobulins have been observed. In this study, we have shown that the allogenic effect and B cell chimaerism which characterize these F1 cell-injected mice is associated with the expression of a large spectrum of autoantibodies, including anti-ssDNA and anti-cytoskeleton antibodies, and that these autoantibodies are not multispecific. We took advantage of the fact that, in this model, autoantibodies are exclusively produced by F1 donor B cells to inject newborn BALB/c mice with F1 Xid spleen cells lacking the CD5+ B cell subset. Injection of 2 x 10(8) F1 Xid spleen cells triggers the production of anti-ssDNA as well as anti-BrMRBC antibodies, and these mice developed tissue lesions. Finally, analysis of the VH gene family expressed by monoclonal autoantibodies derived from F1 cell-injected mice showed that they used the 2 largest families J558 and 7183. These results suggest that the allogenic effect and B cell chimerism which characterize the neonatal induction of tolerance to MHC alloantigens is associated with the selective triggering of autoreactive B cells producing monospecific IgG autoantibodies. They also imply that upon stimulation by persisting alloreactive CD4+ T cells, either CD5- B cells are able to produce autoantibodies or autoantibody-producing CD5+ B cells can differentiate from Xid spleen cells.

Structure of extrachromosomal circular DNAs generated by immunoglobulin light chain gene rearrangements

Recombination at the immunoglobulin kappa or lambda light chain locus generates extrachromosomal circular DNAs. We have isolated circular DNAs from adult mouse spleen cells and prepared a circular DNA clone library. We characterized four J kappa-positive and one J lambda 1-positive clones. The J kappa-clones contained both coding and signal joints of V kappa-J kappa joining, and the J lambda 1-clone contained a signal joint of V lambda 1-J lambda 1 joining. Genomic organization of the V kappa gene families used in these joints suggested the excision of circular DNA preceded by inversion. A specific dinucleotide (P) insertion in the coding joint was observed in two clones. Three coding joints were out of frame and one clone had an in-frame coding joint, although possibly combined with a pseudo-V kappa gene. These kappa-positive circular DNAs are possibly excised from the chromosome by secondary recombinations which replace non-productive primary rearrangements.

The mouse immunoglobulin kappa light-chain genes are located in early- and late-replicating regions of chromosome 6

The murine immunoglobulin kappa (kappa) light-chain multigene family includes the constant region (C kappa), joining-region genes, and approximately 30 kappa-variable (V kappa) region families. The entire region occupies an estimated 1,000 to 3,000 kilobases, and some V kappa families have been linked by recombinant inbred mapping. The C kappa gene and 14 V kappa families replicated differently among cell lines of lymphoid and nonlymphoid origin. In nonlymphoid cells, the C kappa gene replicated earlier than the V kappa families. A transition from replication during the second third of S phase for the C kappa gene to later replication during S for V kappa families was observed. The V kappa family (V kappa 21) that maps closest to the C kappa gene, replicated during the first half of the S phase; most of the other V kappa families replicated during the second half of S, and some replicated during the last quarter of the S phase. In lymphoid cells, the kappa locus replicated earlier in the pre-B than in the B-cell lines. In one pre-B-cell line, 22D6, the kappa genes examined replicated at the beginning of the S phase. In the B-cell lines, the EcoRI segment containing the transcribed gene replicated near the beginning of the S phase. Other V kappa families replicated within the first two-thirds of S phase. Some linked V kappa families replicated at similar times. In the B-cell lines, a transition from replication at the beginning of S for the transcribed C kappa and V kappa genes and surrounding DNA sequences to later replication for the other V kappa families was observed. However, in contrast to the non-lymphoid cell lines, the replication of this locus occurred predominantly during the first half of S. The kappa locus contains both early- and late-replicating genes, and early replication is usually associated with transcriptional activity. The results are discussed with respect to the organization of transcriptionally active chromatin domains.

Preferential rearrangement of V kappa 4 gene segments in pre-B cell lines

Examination of the in vitro V kappa gene rearrangements of murine adult bone marrow-derived pre-B cell lines reveals that 21 of 25 (84%) cell lines have rearranged a member of the V kappa 4 family. In contrast, analysis of two V kappa cDNA libraries prepared from LPS-stimulated adult spleen cells indicates that only 17% of the Ig kappa cDNAs contain sequences belonging to the V kappa 4 gene family. Half of the pre-B cell lines examined also share an 8-kbp BamHI reciprocal product (rp). However, these rp do not involve the same V kappa gene, indicating that conserved BamHI sites exist 3' of some V kappa genes. This rp is also readily detected in DNA from normal adult spleen cells, suggesting that the in vitro rearrangements examined in this study are representative of kappa rearrangements that occur in vivo. We suggest that, unlike the diverse V kappa repertoire expressed by mature B cells, the germline V kappa segments involved in initial rearrangements of the Ig kappa locus are highly restricted, and that an initial V kappa 4 rearrangement is probably followed by other, more random recombination events.

The mouse immunoglobulin kappa light-chain genes are located in early- and late-replicating regions of chromosome 6

The murine immunoglobulin kappa (kappa) light-chain multigene family includes the constant region (C kappa), joining-region genes, and approximately 30 kappa-variable (V kappa) region families. The entire region occupies an estimated 1,000 to 3,000 kilobases, and some V kappa families have been linked by recombinant inbred mapping. The C kappa gene and 14 V kappa families replicated differently among cell lines of lymphoid and nonlymphoid origin. In nonlymphoid cells, the C kappa gene replicated earlier than the V kappa families. A transition from replication during the second third of S phase for the C kappa gene to later replication during S for V kappa families was observed. The V kappa family (V kappa 21) that maps closest to the C kappa gene, replicated during the first half of the S phase; most of the other V kappa families replicated during the second half of S, and some replicated during the last quarter of the S phase. In lymphoid cells, the kappa locus replicated earlier in the pre-B than in the B-cell lines. In one pre-B-cell line, 22D6, the kappa genes examined replicated at the beginning of the S phase. In the B-cell lines, the EcoRI segment containing the transcribed gene replicated near the beginning of the S phase. Other V kappa families replicated within the first two-thirds of S phase. Some linked V kappa families replicated at similar times. In the B-cell lines, a transition from replication at the beginning of S for the transcribed C kappa and V kappa genes and surrounding DNA sequences to later replication for the other V kappa families was observed. However, in contrast to the non-lymphoid cell lines, the replication of this locus occurred predominantly during the first half of S. The kappa locus contains both early- and late-replicating genes, and early replication is usually associated with transcriptional activity. The results are discussed with respect to the organization of transcriptionally active chromatin domains.

Stochastic pairing of heavy-chain and kappa light-chain variable gene families occurs in polyclonally activated B cells

Frequencies of 25 immunoglobulin heavy-chain and kappa light-chain variable (VH + V kappa) gene-family pairings expressed in splenic B-cell populations were determined by hybridization of VH- and V kappa-family-specific DNA probes to mitogen-induced B-cell colonies from C57BL/6 mice or hybridomas derived from BALB/c and NZB mice. Both analyses support the conclusion that VH and V kappa gene families pair without bias; as would be expected for random association, the frequencies of specific VH + V kappa pairs may be estimated by the product of the independent VH and V kappa frequencies. Based upon the frequencies at which 9 VH and 12 V kappa gene families are expressed, we calculated the expected usage for approximately 100 VH + V kappa family pairings in neonatal and adult C57BL/6 mice. Variability in the expression of such VH + V kappa pairings is considerable; pairs representing greater than 10% to less than 0.01% of the splenic B-cell population occur. This variability is most pronounced in the neonate, where 6 VH + V kappa family pairs account for nearly 40% of all mitogen-reactive B cells. As the neonate matures, the distribution of frequencies for VH + V kappa pairings becomes more nearly uniform. This process may underlie the patterned acquisition of humoral immune responsiveness.

Mouse Vk gene classification by nucleic acid sequence similarity

Analyses of immunoglobulin (Ig) variable (V) region gene usage in the immune response, estimates of V gene germline complexity, and other nucleic acid hybridization-based studies depend on the extent to which such genes are related (i.e., sequence similarity) and their organization in gene families. While mouse Igh heavy chain V region (VH) gene families are relatively well-established, a corresponding systematic classification of Igk light chain V region (Vk) genes has not been reported. The present analysis, in the course of which we reviewed the known extent of the Vk germline gene repertoire and Vk gene usage in a variety of responses to foreign and self antigens, provides a classification of mouse Vk genes in gene families composed of members with greater than 80% overall nucleic acid sequence similarity. This classification differed in several aspects from that of VH genes: only some Vk gene families were as clearly separated (by greater than 25% sequence dissimilarity) as typical VH gene families; most Vk gene families were closely related and, in several instances, members from different families were very similar (greater than 80%) over large sequence portions; frequently, classification by nucleic acid sequence similarity diverged from existing classifications based on amino-terminal protein sequence similarity. Our data have implications for Vk gene analyses by nucleic acid hybridization and describe potentially important differences in sequence organization between VH and Vk genes.