A. Manheimer-Lory

Molecular characterization of a somatically mutated anti-DNA antibody bearing two systemic lupus erythematosus-related idiotypes.

We report the molecular characterization of 2A4, an IgG, DNA-binding antibody bearing the 3I and F4 idiotypes which are associated with anti-DNA antibodies in serum of patients with systemic lupus erythematosus (SLE). The antibody is produced by an EBV-transformed B cell line derived from a patient with multiple myeloma whose myeloma protein is also an IgG, 3I-reactive, F4-reactive, DNA-binding immunoglobulin, although the 2A4 antibody does not itself represent the myeloma protein. The 2A4 heavy chain is encoded by a VH4 gene, a D-D gene fusion and the JH6 gene; the light chain is derived from a Vk1 gene and the Jk2 gene. This is the first human antibody shown to have a CDR3 encoded by a D-D fusion. DNA sequence analysis of the 2A4 VH gene together with a Southern blot of genomic DNA probed with a 2A4 VH-specific oligonucleotide strongly suggest it to be somatically mutated. The data provide evidence that human autoantibodies can be products of somatically mutated genes and suggest that the 2A4 antibody may reflect the selective pressure of antigen.

Lupus-specific antibodies reveal an altered pattern of somatic mutation.

The F4 idiotype is a heavy chain determinant expressed almost exclusively on IgG immunoglobulins and is highly associated with specificity for double-stranded DNA. Since high-titered F4 expression is present predominantly in sera of patients with systemic lupus erythematosus (SLE), we thought F4+ IgG antibodies might constitute a useful subset of immunoglobulins in which to investigate lupus-specific alterations in variable (V) region gene expression or in the process of somatic mutation. This molecular analysis of F4+ B cell lines generated from lupus patients demonstrates that despite the strong association of F4 reactivity with specificity for native DNA, there is no apparent VH gene restriction. Furthermore, VH gene segments encoding these antibodies are also used in protective immune responses. An examination of the process of somatic mutation in F4+ antibodies showed no abnormality in frequency of somatic mutation nor in the distribution of mutations in complementarity-determining regions or framework regions. However, there was a decrease in targeting of mutations to putative mutational hot spots. This subtle difference in mutations present in these antibodies may reflect an intrinsic defect in mutational machinery or, more likely, altered state of B cell activation that affects the mutational process and perhaps also negative selection.

Pathogenic Anti-DNA Antibodies in SLE: Idiotypic Families and Genetic Origins

We have adopted an idiotypic approach to study the double stranded DNA (dsDNA) binding antibodies of systemic lupus erythematosus (SLE). Three anti-idiotypic reagents, 8.12, 3I, and F4, identify cross reactive idiotypes that are each expressed on anti-dsDNA antibodies in the sera of many patients with SLE. These idiotypic antibodies are implicated in the pathogenesis of SLE as they are present in immune complex deposits in the kidneys of patients with SLE glomerulonephritis. The autoantibody associated idiotypes are also expressed on antibodies that do not bind DNA. We are investigating the origin of the pathogenic anti-dsDNA antibodies of SLE by comparing the autoantibodies, the antibodies to foreign antigens, and the myeloma proteins that express each SLE associated idiotype. In conjunction with serological analysis of these idiotypic systems, molecular genetic studies indicate that both the 8.12 and the 3I autoantibody associated idiotypes may be germline encoded, while the F4 idiotype is generated by somatic mutation. The data further suggest that the antigenic specificity of the pathogenic anti-DNA antibodies of SLE is acquired through somatic mutation of germline immunoglobulin genes. By studying the regulation of genes capable of encoding pathogenic autoantibodies, in both SLE patients and non-autoimmune individuals, we may be able to elucidate the pathogenesis of autoimmune disease and begin to design more effective therapeutic interventions.

Generation and analysis of clonal IgM- and IgG-producing human B cell lines expressing an anti-DNA-associated idiotype.

This study describes a methodology for generating stable, cloned, EBV-transformed IgG- and IgM-producing human B cell lines. Using these lines we have characterized immunoglobulin V gene utilization in an anti-DNA-associated idiotypic system. The 31 anti-DNA-associated idiotype is encoded preferentially by the VK1 gene family, and, in all probability, reflects a germ line gene-encoded framework determinant. Analysis of these lines indicates that the DNA-binding antibodies produced by B cell lines from SLE patients may differ from DNA binding myeloma proteins and from natural autoantibodies.

Analysis of the VKI Family: Germline Genes from an SLE Patient and Expressed Autoantibodies

Our studies of anti-DNA antibodies in systemic lupus erythematosus have demonstrated a preferential use of the VKI family to encode light chains of antibodies that express the anti-DNA associated 31 idiotype. This idiotype is present on a high percentage of anti-DNA antibodies in approximately 80% of SLE patients1,2. In this study, we employed PCR to obtain VKI germline genes from a lupus patient in order to address the following questions: Do the VKI germline genes of an individual with autoimmune disease differ from those of healthy individuals? What VKI genes are used to encode autoantibodies and are they used to encode protective antibodies also? Does the VKI gene family display peculiarities in V gene segment rearrangement or somatic mutation?Our analysis shows that the coding region sequences of germline genes of an autoimmune individual are highly homologous to those of non-autoimmune individuals. In addition, the same germline genes can be utilized to encode antibodies to both exogenous and self a...

Analysis of V kI and VLDII Light Chain Genes in the Expressed B‐Cell Repertoirea

Our previous studies of anti-DNA antibodies in SLE have demonstrated a preferential use of V kappa I and V lambda II gene families to encode light chains of antibodies that express the anti-DNA-associated 3I and 8.12 idiotypes, respectively. In this study, we employed PCR to obtain V kappa I and V lambda II germline genes from lupus patients in order to compare the germline genes to genes encoding expressed V kappa I and V lambda II light chains and to analyze the extent of somatic mutation among autoantibodies that derive from these light chain families. Our analysis shows that the germline repertoire among all persons (autoimmune and healthy) is comparable and that somatic mutation is used to diversify autoantibodies as well as anti-microbial antibodies. We have observed that autoantibodies encoded by V kappa I and V lambda II genes have a higher number of amino acid replacements in CDRs than autoantibodies encoded by other VL gene families. In addition, there may be subtle differences in V gene usage that distinguish the V kappa I-encoded light chains from other expressed V kappa light chains.