To better understand the structural basis for rheumatoid factor [RF] activity and the origin of autoantibodies in human autoimmune diseases, we isolated the RF producing B cells from the peripheral blood and from the synovial fluid of a patient suffering from rheumatoid arthritis [RA]. We previously demonstrated that a significant fraction of these RF were derived from three V kappa III genes known to encode most of the monoclonal RF light chain variable regions. To get more insight into the actual repertoire of RF-V kappa genes during RA, we analyzed the nucleotide sequences of RF light chain variable regions of other V kappa families. Using two sets of polymerase chain reactions in order to amplify the cDNA derived from RF producing cells from the same patient KRA, we isolated only three different rearranged V kappa-J kappa complexes: slkv5, slkv7 and bkv42, all derived from V kappa I germ-line genes not previously known to be associated with RF activity; this suggests that the repertoire of VL genes coding for RF during RA is more diverse than the one involved in the generation of paraprotein RF during monoclonal lymphoid proliferations, although there remains a possible bias in favor of the V kappa III family. Moreover, each of these genes is somatically mutated with a pattern suggesting a selective pressure of the antigen. Particularly interesting is the additional proline residue at the V kappa-J kappa junction of bkv42, an unorthodox feature that we found previously in more than 50% of RF V kappa III-J kappa gene complexes. Finally, the homogeneity of some non conservative mutations suggests the existence of a restricted set of pathogenic epitopes driving the production of RF during RA.
The variable regions of the immunoglobulin ( Ig ) expressed on the surface of a malignant B cell can be considered tumor -specific antigens and, as such, could be targets for immunotherapeutic approaches. However, because until now the immunization procedures have been complex and have given only partial protection, it was necessary to find new methods of immunotherapy.Here, we present a successful method of vaccination against B -cell tumors in a murine model. We produced recombinant vaccinia viruses ( rVV ) expressing the heavy and the light chain of surface Ig of a patient's malignant B cells and we tested the ability of these rVV to protect immunized mice against tumor growth of transfectomas producing the same human Ig. The protection of the mice was complete and specific to the variable region of the immunizing heavy chain although specific lymphoproliferative and cytotoxic responses were not detectable in vitro. The protection was strictly dependent on the presence of CD4 T cells and asialo GM1 + cells. Furthermore, tumor protection clearly required -interferon and was partially inhibited by blocking the Fas -Fas ligand interaction. We also show, in a murine syngeneic model, that rVV expressing a poorly mutated Ig protects against the growth of Ig -producing tumor. Cancer Gene Therapy ( 2001 ) 8, 815 -826
Monoreactive high affinity pathologic autoantibodies were supposed previously to derive through somatic mutation from polyreactive low affinity autoantibodies that are encoded by a small set of unmutated V region genes in fetal and neonatal B cells. However, recent data exploring the physiologically expressed Ab repertoire and the importance of the stochastically generated heavy chain CDR3 (H-CDR3) in autoreactivity suggest that this scheme is incomplete. Here we analyzed via gene-swapping experiments and site-directed mutagenesis the relative contributions of the mutations in the light chain variable region (VL) and the heavy chain variable region (VH) domains and of the H-CDR3 in the autoreactivity of two IgM rheumatoid factors (RF), one a polyreactive low affinity Ab, the other a monoreactive high affinity Ab. These two RFs derived from the same V kappa III (humkv325) and VH1 (51p1) genes, but differed from each other by a few mutations and by the structure of the H-CDR3. The analysis of the reactivity patterns of different combinations of wild-type and in vitro engineered hybrid gene products clearly demonstrates the main influence of the H-CDR3 in the autoAb activity profiles. The results directly demonstrate the previously proposed hypothesis, namely, that the H-CDR3 plays a critical role in distinguishing poly- from monospecific RF. However, the data also indicate that self polyreactivity is a very fragile property and is dependent upon the primary structure of the VH segment.
SMI is a previously characterized IgM kappa polyreactive (natural) autoantibody. The variable regions of the heavy and light chains of SMI are respectively encoded by a nonmutated VH1 gene, designated 51p1, and a conserved nonmutated V kappa gene, designated Humkv325. These V genes seem to be over-represented in the autoimmune and fetal B cell repertoires, and to be frequently expressed in malignant B cells during certain lymphoid proliferations such as chronic lymphocytic leukemia. Polyreactive natural autoantibodies are thought to rely mainly on the use of such V genes in germ-line configuration. However, this model underestimates the contribution of the somatically generated heavy chain third complementarity-determining region (HCDR3) to autoantibody specificity. We used oligonucleotide site-directed mutagenesis to permute the sequence of the SMI-HCDR3 to generate a family of mutant proteins, each of which differed from the original SMI-IgM kappa by one amino acid residue. This allowed us to examine the relative contribution of selected amino acid residues in this region to the binding affinity of SMI against a panel of self-Ags. We found that a single amino acid substitution within the HCDR3 could dramatically alter the specificity of this autoantibody. Some substitutions abrogated the reactivity with all the tested Ags, whereas others changed the affinity or spectrum of reactivity for certain self-Ags. These results demonstrate that the autoantibody-binding activity of these conserved autoantibody-associated germ-line V genes is dependent upon heavy chain junctional sequences that are generated somatically during Ig gene rearrangement.
Mixed cryoglobulinemia is usually considered to be a nonmalignant human B cell proliferation that produces a monoclonal IgM rheumatoid factor (RF). Important immunologic similarities and differences were described between the monoclonal B cells during mixed cryoglobulinemia and during malignant chronic lymphocytic leukemia (CLL):high frequency of the same VH and V kappa gene usage by both types of monoclonal B cells producing IgM with RF activity, apparent intraclonal homogeneity, but different expression of the pan T cell CD5 Ag. The description of an unusual CD5-negative B cell CLL case secreting a mutated IgM RF led the authors to suggest that the usage of non-mutated germline Ig genes is a property of cells derived from the CD5 lineage or stage of differentiation, rather than an intrinsic property of CLL or of IgM RF-producing cells in general. Because mixed cryoglobulinemia cells are usually CD5-negative, it was of interest to test for the existence of mutations in the VH and V kappa regions, as well as for the intraclonal homogeneity of the expressed Ig genes. In this study, we used the PCR technique to analyze the monoclonal rheumatoid factor (mRF) V genes from a patient with mixed cryoglobulinemia. We show that the CD5-negative monoclonal B cells express a slightly mutated V kappa 3 gene, but a more mutated VH1 gene whose genomic counterpart was shown to be the 51p1 germline gene. The sequence analysis of several independent clones shows some degree of intraclonal diversity, suggesting the existence of a clonal filiation. These results are discussed in terms of the origin of the monoclonal B cell during mixed cryoglobulinemia and CLL.
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