Relationship of human variable region heavy chain germ-line genes to genes encoding anti-DNA autoantibodies

In order to identify the V region genes encoding systemic lupus erythematosus (SLE)-derived anti-DNA autoantibodies, we have determined the nucleotide sequence of heavy chain mRNA from several DNA-binding immunoglobulins secreted by human hybridomas. We used the technique of cDNA primer extension for determining sequences of the VH, D, and JH gene segments of anti-DNA autoantibodies from three different primary hybridoma growths from an SLE patient and one hybridoma from a leprosy patient. Immunoglobulins from two of the SLE hybridomas expressed the same idiotype, Id-16/6, which is also expressed on immunoglobulins in sera of patients with active SLE. Their mRNA sequences showed complete homology to each other in the V, D, and J genes and more than 99% homology to the VH26 germ-line gene sequence, a member of the human VHIII gene family. The VH mRNA sequence of the third SLE hybridoma, 21/28, which was idiotypically unrelated to the other two, was 93% homologous to a different VH germ-line gene sequence, HA2, a member of the human VHI gene family. The fourth anti-DNA-producing hybridoma, 8E10, was derived from a leprosy patient of different ethnic origin than the SLE patient. It was idiotypically related to 21/28 and expressed a VH segment gene identical to that of 21/28. Hybridomas 21/28 and 8E10 shared sequence homology with the VH26 anti-DNA antibodies in the first complementarity-determining region. In addition, 21/28 shared sequence homology with the Id-16/6+ group in the region encoded by the D and J gene segments. Our findings indicate that some SLE autoantibodies are encoded by unmodified or scarcely modified VH germ-line genes that are conserved in the human population and identify two distinct VH germ-line genes that can encode segments of anti-DNA immunoglobulins.     

Two induced anti-Z-DNA monoclonal antibodies use VH gene segments related to those of anti-DNA autoantibodies

The cDNA for H and L chain V regions of two anti-Z-DNA mAb, Z22 and Z44, were cloned and sequenced. These are the first experimentally induced anti-nucleic acid antibody sequences available for comparison with autoantibody sequences. Z22 and Z44 are IgG2b and IgG2a antibodies from C57BL/6 mice. They recognize different facets of the Z-DNA structure. They both use VH10 family genes and share 95% sequence base sequence identity in the VH and leader sequences; however, they differ in the 5'-untranslated region of the VH mRNA, indicating they arise from different germline genes. Both use JH4 segments. They differ from each other very extensively in the CDR3 of both H and L chains. The most closely related H chains in the current GenBank/EMBL data base are two mouse IgG anti-DNA autoantibodies, one from an MRL-lpr/lpr mouse (MRL-DNA4) and one from an NZB/NZW mouse (BV04-01). Z22 and Z44 share 95% sequence identity with these antibodies in the VH segment. In addition, Z22 is identical to MRL-DNA4 at 91% of the positions in the 5'-untranslated region of the H chain mRNA. The two antibodies share 95% base sequence identity in the V kappa segment. The most closely related L chains, with 97 to 98% sequence identity, are the V kappa 10b germline gene for Z22 and the V kappa 10a germ line gene, which is associated with A/J anti-arsonate antibodies and BALB/c anti-ABO blood group substance antibodies, for Z44. Z22 and Z44 share several structural features (similarities in VH, JH, and V kappa) but differ very markedly in the L chain CDR1 and both H and L chain CDR3 sequences; these regions may determine the differences in their specific interactions with Z-DNA.     

Variable region sequence analysis of anti-DNA antibodies: evidence for a family of closely related germ-line VH genes encoding lupus autoantibodies.

Cloning and sequencing of the V regions of the anti-DNA monoclonal antibodies (mAbs), H438 and H130, indicate that H438 is encoded by a J558 VH gene, a single D region nucleotide, and unmutated JH1, V kappa-1C and J kappa 1 genes, and the H130 L chain is encoded by a V kappa-21 subgroup gene J kappa 1 gene. Identification of VH438, which shared VH hybridization pattern with 6% of a panel of 352 MRL/lpr hybridomas, suggests that the frequency of J558 use among spontaneously activated B cells in MRL/lpr mice is greater than previously reported. The VHH438 J558 family gene is identical to VHPAR, which encodes the independently derived MRL/lpr autoantibody, MRP-2, and is highly homologous to the previously reported VHH130, which is identical to a BALB/c germ-line VH gene. Comparison of consensus sequences of homologous autoantibodies and previously reported restriction mapping suggest that a minimum of three highly related J558 germ-line genes encode lupus autoantibodies.     

Cloning and sequence analysis of the VH and VL regions of an anti-myelin/DNA antibody from a patient with peripheral neuropathy and chronic lymphocytic leukemia

We have cloned and determined the nucleotide sequence of the Ig VH and VL region genes of an IgM kappa mAb that binds to denatured DNA and myelin from a patient (POP) with chronic lymphocytic leukemia and peripheral neuropathy. Sequence analysis indicates that the V region of the kappa L chain gene (PopVK) has 99% homology to a V kappa IIIa germ-line gene and the V region of the mu H chain gene (PopVH) has 96% homology to the VH26 germ-line gene that is a member of the VH3 gene family. It is likely the V kappa and VH genes arose from these respective germ-line genes via somatic mutation or from closely related genes. V kappa III genes have frequently been used by other IgMk mAb especially those with rheumatoid factor activity, and the VH26 gene with no somatic mutation has been used by several anti-DNA antibodies, suggesting the possibility of preferential association of these or related germ-line genes with autoantibodies. The minor differences between the sequences of POP's VH and V kappa genes and sequences used by other autoantibodies, may be responsible for this antibody's crossreactivity with myelin and, as a result, the autoimmune neuropathy.     

V region sequences of anti-DNA and anti-RNA autoantibodies from NZB/NZW F1 mice

The V region sequences of two anti-DNA (A52, D42) and two anti-RNA (D44, D444) autoantibodies, derived from lupus prone NZB/NZW F1 female mice, were determined by mRNA sequencing. The sequences had the following features: 1) there was no clear sequence relationship between anti-DNA and anti-RNA antibodies; 2) there were no major similarities between any of the L chain sequences and each VL gene segment belonged to a different mouse VK subgroup; 3) the H chains of the two anti-RNA antibodies showed closely related sequences of VH gene segments and very similar third complementarity determining regions (CDR3); 4) the H chains of the two anti-DNA antibodies had VH segments belonging to different VH gene families but had a unique and similar combination of D segments and junctional sequences, suggesting a common recognition element for Ag and/or for idiotypic regulation in the H chain CDR3; and 5) the VH gene segment of one anti-DNA antibody (D42) was found to be very similar to the VH gene segment of a CBA mouse hybridoma antibody (6G6) which binds to the environmental Ag phosphocholine. The three-dimensional structure of the Fv-region of the anti-DNA antibody (D42) was modeled by computer and a stretch of poly(dT), ssDNA was docked to a cleft in the antibody combining site, formed by the three H chain CDR and by CDR1 and CDR3 of the L chain. The cleft is characterized by a preponderance of arginine and tyrosine residues, lining both the walls and base of the cleft.     

Identification and sequence of the VH gene elements encoding a human anti-DNA antibody

Antibodies to DNA similar to those found in patients with systemic lupus erythematosus (SLE) and autoimmune mice can be derived from the lymphocytes of normal individuals. It is not known whether these normal derived anti-DNA antibodies are made from the same VH gene elements as the anti-DNA antibodies made by SLE patients. To begin to answer this question, we examined mu chain cDNA clones from human hybrid clone C6B2 producing anti-DNA antibodies. The sequence of the 500 base pair restriction fragment containing the variable region (5' terminus) was determined and was sequenced. This antibody uses a VHII heavy chain subgroup gene, a J3 joining segment, a hitherto unknown D segment, and a previously reported leader sequence. Significant homology was found to a mouse anti-DNA antibody sequence in the use of VH subgroup in J3, and in the hypervariable regions with a shared Ser-Tyr construction in CDR1 and an identical five amino acid residue stretch in CDR2. Comparison with the limited sequence data of published SLE monoclonal anti-DNA antibodies, both human and mouse, suggests that this shared Ser-Tyr may be important in some but not all antibodies to DNA. Comparison of C6B2 antibody is made with other known antibody sequences with identification of those residues likely to be part of the antigen binding site.     

Autoimmune mice and stimulated normal mice make lambda 1 with increased V region diversity

Previous studies of the genetic bases of murine SLE have defined gene segments that encode the H chain and the kappa L chain of anti-DNA, anti-Sm, and anti-IgG autoantibodies. As a result of these studies, the genetic origins of autoantibody H chains and kappa L chains are better understood, but little remains known about the genetic bases of autoantibody lambda-chains. Thus, we have analyzed serologically the germ-line and somatic origins of lambda 1 L chains in antibodies of normal mice and in both antibodies and autoantibodies of autoimmune mice. This study finds an increased lambda 1 diversity in both Ag-stimulated mice and autoimmune mice. This study also finds that the lambda 1 L chains in antibodies of unstimulated normal mice have the gene segment-encoded variable region, V lambda 1. In contrast, additional genetic processes appear to make the lambda 1 V regions of antibodies in Ag-stimulated normal mice and the lambda 1 V regions of both antibodies and autoantibodies in autoimmune mice. The increased lambda 1 diversity that we found in both Ag-stimulated mice and autoimmune mice might be caused by mutational processes creating antibody diversities. Therefore, the same somatic processes might be able to make both antibody and autoantibody lambda 1 diversities.     

Characteristics of murine monoclonal anti-CD4. Epitope recognition, idiotype expression, and variable region gene sequence.

We have characterized a series of mouse monoclonal anti-CD4 and describe both their CD4 epitope recognition and Id expression. We also determined the V region gene sequences of these antibodies in an attempt to correlate epitope recognition and Id expression with V region sequence. All of these preparations recognize epitopes that cluster around the HIV gp120 binding site on the human CD4 molecule. However, we observed differences in epitope recognition among the anti-CD4 preparations, based on either competitive inhibition assays or functional assays, such as syncytium inhibition. Analysis of Id specificities using a polyclonal anti-Id generated against anti-Leu 3a indicated that five of the seven monoclonal anti-CD4 expressed a shared Id. Based on V region gene sequences, the V region kappa-chain (V[kappa]) from each of the seven antibodies was encoded by the V[kappa]21 gene family and expressed the J[kappa]4 gene segment. Those preparations that expressed the shared Id with anti-Leu 3a have virtually identical V[kappa] sequences, with a high degree of homology in the CDR. The VH region gene sequences of six of the seven antibodies also shared overall homology and appeared to be encoded by the J558 VH gene family. The seventh anti-CD4 VH region is encoded for by the VHGAM gene family. The majority of these antibodies used JH3 gene segment, although the JH2 and JH4 gene segments were also represented. In addition, several of these antibodies share a common sequence organization within their V-D-J joining regions that appears to involve N and P sequences to generate unique D segments. Together, these data suggest that differences in epitope recognition among the monoclonal anti-CD4 may reflect sequence variability primarily within the CDR3 region of both V[kappa] and VH. The basis for the detection of a shared Id most likely reflects the high degree of homology within the V[kappa] region sequences. In addition, these data, which are based on a limited analysis, suggest the possible restricted use of V region germ-line gene families in the secondary antibody response of BALB/c mice to specific epitopes on the human CD4 molecule.     

Novel V genes encode virtually identical variable regions of six murine monoclonal anti-bromelain-treated red blood cell autoantibodies

The variable (V) region sequences of six immunoglobulin M (IgM, kappa) monoclonal autoantibodies that recognize bromelinized isologous red blood cells, obtained by fusions of peritoneal cells from NZB or CBA/J nonimmunized mice with BALB/c myeloma cells, were determined by direct mRNA sequencing. The V regions of the light chains (VL) are almost identical with one another, as are the V regions of the heavy chains (VH), which, however, differ by six linked-base substitutions, depending on the strain of mice producing the autoantibodies. Such variations may reflect allelic differences. The VH segments determined have no obvious correspondence to any VH genes identified so far. They may belong to the small VH group 4, where 73% homology, at the most, can be calculated at the protein level for codons 1 to 94. Alternatively, the VH regions may be members of a new group of VH sequences not previously found. The V kappa regions appear closely homologous to members of the V kappa-9 subgroup of myeloma proteins of unknown antigen-binding specificity. The joining segments, J kappa and JH, used by the autoantibodies investigated, originate from the J kappa 2 and JH1 germ-line gene segments, respectively. The nine base-long diversity segments, D, derive from one member of the germ-line D gene SP2 family.     

A human systemic lupus erythematosus-related anti-cardiolipin/single-stranded DNA autoantibody is encoded by a somatically mutated variant of the developmentally restricted 51P1 VH gene.

We report the Ig H and L chain V region sequences from the cDNAs encoding a monoclonal human IgG anti-cardiolipin/ssDNA autoantibody (R149) derived from a patient with active SLE. Comparison with the germ-line V-gene repertoire of this patient revealed that R149 likely arose as a consequence of an Ag-driven selection process. The Ag-binding portions of the V regions were characterized by a high number of arginine residues, a property that has been associated with anti-dsDNA autoantibodies from lupus-prone mice and patients with SLE. The VH gene encoding autoantibody R149 was a somatically mutated variant of the 51P1 gene segment, which is frequently associated with the restricted fetal B cell repertoire, malignant CD5 B cells, and natural autoantibodies. These data suggest that in SLE patients a common antigenic stimulus may evoke anti-DNA and anti-cardiolipin autoantibodies and provide further evidence that a small set of developmentally restricted VH genes can give rise to disease-associated autoantibodies through Ag-selected somatic mutations.     

A transgenic mouse that expresses a diversity of human sequence heavy and light chain immunoglobulins.

We have generated transgenic mice that express a diverse repertoire of human sequence immunoglobulins. The expression of this repertoire is directed by light and heavy chain minilocus transgenes comprised of human protein coding sequences in an unrearranged, germ-line configuration. In this paper we describe the construction of these miniloci and the composition of the CDR3 repertoire generated by the transgenic mice. The largest transgene discussed is a heavy chain minilocus that includes human mu and gamma 1 coding sequences together with their respective switch regions. It consists of a single 61 kb DNA fragment propagated in a bacterial plasmid vector. Both human heavy chain classes are expressed in animals that carry the transgene. In light chain transgenic animals the unrearranged minilocus sequences recombine to form VJ joints that use all five human J kappa segments, resulting in a diversity of human-like CDR3 regions. Similarly, in heavy chain transgenics the inserted sequences undergo VDJ joining complete with N region addition to generate a human-like VH CDR3 repertoire. All six human JH segments and at least eight of the ten transgene encoded human D segments are expressed. The transgenic animals described in this paper represent a potential source of human sequence antibodies for in vivo therapeutic applications.     

Human lupus anti-DNA autoantibodies undergo essentially primary V kappa gene rearrangements.

We have recently characterized the heavy chain variable region (VH) genes expressed by a panel of human anti-DNA antibodies derived from four patients with systemic lupus erythematosus and expressing an idiotypic marker representative of a subset of pathogenic autoantibodies. Here, we have cloned and sequenced the kappa chain variable region genes (V kappa) of the clones whose VH genes had been previously analysed. All the V kappa genes utilized map to the 280 kb portion of the 3' end of the locus, suggesting that they represent essentially the products of primary rearrangements. This proximal clustering of the V kappa genes used contrasts with the broad distribution of immunization-induced human antibody V kappa genes over 1400 kb of the locus. In addition, lupus autoantibodies show no tendency to express the downstream junctional (J kappa) exons--another indication of infrequent secondary variable gene assembly. Since successive rearrangements may extinguish high-affinity recognition of self antigens, we propose that this bias in V kappa and J kappa expression reflects a low rate of secondary light chain rearrangements among lupus autoantibodies. We also postulate that the corrective mechanism capable of editing potentially aggressive, self-reactive antibodies in these patients may be deficient--a deficit that could be genetically determined and/or somatically acquired.     

Active site structure and antigen binding properties of idiotypically cross-reactive anti-fluorescein monoclonal antibodies

This report includes complete VH and V kappa nucleotide and deduced amino acid sequences of idiotypically cross-reactive monoclonal anti-fluorescein antibodies that differed greater than 10(5)-fold in affinity. High affinity monoclonal antibody 4-4-20 and intermediate affinity antibodies 10-25, 5-14, 9-40, 12-40, and 3-24 utilized greater than or equal to 90% homologous VHIIIC germ-line genes. Extensive D segment length and sequence variability were observed; however, compensatory germ-line JH4 (4-4-20 and 3-24) or JH3 (10-25, 5-14, 9-40, and 12-40) sequence lengths resulted in H chain CDR3 + FR4 to be a constant 18 amino acids. In addition, each antibody and low affinity 3-13 rearranged greater than or equal to 96% homologous V kappa II genes to J kappa 1, except for 10-25 (J kappa 5) and 3-13 (J kappa 4). Resolved crystal structure of complexed fluorescein and 4-4-20 Fab fragments revealed residues HisL27d, TyrL32, ArgL34, SerL91, TrpL96, and TrpH33 acted as hapten contact residues. Antibodies 5-14, 9-40, 12-40, and 3-24 primary structures possessed identical contact residues as 4-4-20 except for the substitution of HisL34 for ArgL34. Thus, ArgL34 was implicated in the increased affinity of monoclonal antibody 4-4-20. Finally, it was difficult to correlate extensive H chain CDR3 residue heterogeneity directly with fluorescein binding and idiotypy.     

High Affinity Antibodies against Influenza Characterize the Plasmablast Response in SLE Patients After Vaccination

Breakdown of B cell tolerance is a cardinal feature of systemic lupus erythematosus (SLE). Increased numbers of autoreactive mature naïve B cells have been described in SLE patients and autoantibodies have been shown to arise from autoreactive and non-autoreactive precursors. How these defects, in the regulation of B cell tolerance and selection, influence germinal center (GC) reactions that are directed towards foreign antigens has yet to be investigated. Here, we examined the characteristics of post-GC foreign antigen-specific B cells from SLE patients and healthy controls by analyzing monoclonal antibodies generated from plasmablasts induced specifically by influenza vaccination. We report that many of the SLE patients had anti-influenza antibodies with higher binding affinity and neutralization capacity than those from controls. Although overall frequencies of autoreactivity in the influenza-specific plasmablasts were similar for SLE patients and controls, the variable gene repertoire of influenza-specific plasmablasts from SLE patients was altered, with increased usage of JH6 and long heavy chain CDR3 segments. We found that high affinity anti-influenza antibodies generally characterize the plasmablast responses of SLE patients with low levels of autoreactivity; however, certain exceptions were noted. The high-avidity antibody responses in SLE patients may also be correlated with cytokines that are abnormally expressed in lupus. These findings provide insights into the effects of dysregulated immunity on the quality of antibody responses following influenza vaccination and further our understanding of the underlying abnormalities of lupus.     

Sequences of the VH and VL regions of murine monoclonal antibodies against 3-fucosyllactosamine

Many mAb that bind the carbohydrate antigenic determinant 3-fucosyl-lactosamine (3-FL), Gal beta 1-4[Fuc alpha-3]GlcNAc-R have been raised in BALB/c mice, and we are studying the structure and regulation of these antibodies. In this report, we present the first information about their amino acid sequences and the Ig gene segments used to encode them. V regions of the H and L chains of three anti-3-FL antibodies, PMN6, PMN29, and PM81, were sequenced by a combination of mRNA and amino acid sequencing. The L chain sequences of PMN6 and PM81 antibodies indicate that their VK and JK regions are encoded by VK24B and JK1 germ-line genes, respectively. The nucleotide and amino acid sequences of the H chains suggest that the three anti-3-FL antibodies are encoded by the VH441 gene segment of the X24 VH family, and this conclusion was supported by Southern filter hybridization with VH441 and JH3-JH4 probes. PMN29 has at least 11 amino acid substitutions, which is an unusually large amount of somatic mutation for an IgM antibody. Previous analyses of BALB/c genomic libraries with VHX24 and VH441 probes make it unlikely that this VH family contains additional germ-line genes, but this possibility cannot be excluded. All three antibodies use the DQ52 and JH4 gene segments. The single VH and VL gene segments used to encode the anti-3-FL antibodies is in contrast to the multiple VH and VL segments used by antibodies against other carbohydrate Ag such as alpha 1-6 dextran and group A streptococcal carbohydrate. VH441 also encodes the VH regions of antibodies against galactan and levan (beta 2-6 fructosan). The similarities among VH segments of antibodies against 3-FL, levan, and galactan, and the striking differences in their CDR3 sequences, suggest that CDR3 plays an important role in the formation of the Ag binding site. The use of a single VH segment from the smallest VH gene family by antibodies against at least three different carbohydrate determinants is noteworthy. It raises the possibility that the amino acid sequence encoded by VH441 has some general structural features that make it particularly well adapted for binding to carbohydrate sequences.     

V region sequences of an idiotypically connected family of pathogenic anti-DNA autoantibodies

The H and L chain V region sequences of nine anti-DNA mAb that are representative of a pathogenic population of autoantibodies produced by the nephritis prone (SWR x NZB)F1 (SNF1) mice, were determined. These nine anti-DNA autoantibodies were idiotypically connected members of a cross-reactive Id family called the Id564 cluster. Moreover, these autoantibodies were all cationic in charge, IgG2b in isotype, and their H chain C regions had the normal SWR parent's allotype. Although derived from two different SNF1 animals, these pathogenic autoantibodies possessed highly homologous Leader-VH sequences that could account for their idiotypic cross-reactivity. Furthermore, the VH region sequences of these anti-DNA antibodies contained numerous basic residues that could impart their cationic charge. The Leader-VH sequences of these autoantibodies were also highly homologous to that of an anti-NP antibody-related germ-line gene of C57BL/6 mice, called VH-23. Among these nine pathogenic autoantibodies, three sets of clonally related anti-DNA antibodies could be identified. Thus the Id564 cluster of cationic anti-DNA autoantibodies of SNF1 mice are encoded by highly related VH genes, and this idiotypically connected population of pathogenic autoantibodies are selected to undergo an oligoclonal expansion in the lupus-prone SNF1 mice.     

Variable region cDNA sequences and antigen binding specificity of mouse monoclonal antibodies to isomaltosyl oligosaccharides coupled to proteins. T-dependent analogues of alpha(1----6)dextran

Four mouse hybridomas specific for alpha(1----6)dextran, 16.4.12E (IgA kappa, C57BL/6), 28.4.10A (IgM kappa, BALB/c), 35.8.2H (IgG1 kappa, BALB/c), and 36.1.2D (IgM kappa, BALB/c) were obtained by immunization with the T-dependent Ag isomaltohexaose or isomaltotriose coupled to keyhole limpet hemocyanin or to BSA. Immunochemical characterization of the hybridoma antibodies showed that 16.4.12E and 36.1.2D had cavity-type combining sites, recognizing the terminal non-reducing end of alpha(1----6)dextran, whereas 28.4.10A and 35.8.2H had groove-type sites, recognizing internal linear segments of the dextran. The V region cDNA of the H and L chains of the antibodies were cloned and sequenced. VH of 16.4.12E and VH of 36.1.2D belonged to the X24 and Q52 germ-line gene families, respectively. The VH and V kappa sequences of 16.4.12E and V kappa sequence of 36.1.2D were highly homologous to those of W3129, the only anti-alpha(1----6)dextran mAb with a cavity-type site thus far sequenced; 16.4.12E differed from W3129 in the D, JH, and J kappa. VH genes of 28.4.10A and 35.8.2H were homologous to those of several anti-alpha(1----6)dextrans with groove-type sites, but belonged to the J558 germ-line gene family, differed from the other J558 anti-alpha(1----6)dextrans, probably representing a different germ-line subfamily. The L chain sequence of 28.4.10A encoded by V kappa-Ars and J kappa 2 was almost identical to other groove-type anti-alpha(1----6)dextrans obtained by immunizing with the T-independent glycolipid Ag, stearyl-isomaltotetraose. Use of T-dependent Ag such as isomaltosyl oligosaccharide-protein conjugates provides an additional parameter for probing the fine structure of antibody combining sites and evaluating the V-gene repertoire of anti-alpha(1----6)dextrans.     

Detection of cross reactive anti-DNA antibody idiotypes on tissue-bound immunoglobulins from skin biopsies of lupus patients

Cross-reactive anti-DNA antibody idiotypes have been identified on tissue-bound immunoglobulins from skin biopsies of patients with systemic lupus erythematosus (SLE) and discoid lupus erythematosus (DLE). Four polyclonal and two monoclonal anti-idiotypic reagents were used to screen biopsies from 24 patients with SLE, 23 patients with DLE, and 15 other patients with IgM-positive skin biopsies. Up to 46% of the SLE patients and 30% of the DLE patients were found to share idiotypes present on immunoglobulins deposited at the dermal-epidermal junction. Inhibition studies in four patients indicated that the idiotypes were on anti-DNA antibodies. In contrast, none of the anti-idiotypic antibodies bound to any of the control biopsies. These findings imply that some tissue-bound autoantibodies are derived from related families of high-frequency germ-line genes that are expressed in both SLE and DLE.     

Functional analogues of the VKOx1 gene in different strains of mice: evolutionary conservation but diversity based on V-J joining

Monoclonal antibodies to the hapten phenyloxazolone were raised 7 days after immunization in mice of six strains (BALB/c, C57BL-Igha, DBA2, RF, A/J, and CE). Hybridomas were selected that produced 260 idiotype-positive antibodies, and their light chain mRNA were partially sequenced. (RF is an idiotype-negative strain, and sequencing was done without this selection.) All newly sequenced BALB/c, C57BL-Igha, DBA/2, A/J, or CE VK segments had a 100% nucleotide homology with the VKOx1 (H3) germline gene. This gene codes for one third of early BALB/c phenyloxazolone antibodies, and according to our results the same gene has a significant role in the early response of at least five strains of mice. Four RF hybridomas had identical nucleotide sequences, suggesting that they express a non-mutated nucleotide sequence of a new VK germ-line gene (VKOx2). This gene codes for a CDR1 which is two amino acids longer than the CDR1 coded by the VKOx1 gene, but otherwise the two genes are related (94.5% sequence homology). All but one of the 16 kappa chains studied had the J5 segment; this segment had the same sequence in all six strains. One RF antibody had the J4 segment the nucleotide sequence of which differs from the BALB/c J4 segment in two places. Three of the kappa chains had an extra long CDR3. Long and "normal" kappa chains were probably coded by the same pair of germ-line genes (VKOx1 and J5, or VKOx2 and J5). The length heterogeneity was probably caused by a lack of precision in VK-JK joining.