The rearranged V(H) domain of a physiologically selected anti-single-stranded DNA antibody as a precursor for formation of IgM and IgG antibodies to diverse antigens.

It has been proposed that autoreactivity of modest affinity contributes to positive selection of a preimmunization B cell repertoire, whereas high-affinity autoreactivity leads to negative selection. This hypothesis predicts that a B cell producing a physiologically selected unmutated ssDNA-binding Ab should be a precursor of cells that respond to diverse exogenous Ags. To test this prediction, we prepared transgenic mice bearing the rearranged V(H) domain of an IgM Ab from a nonautoimmune mouse immunized with a DNA-protein complex, poly(dC)-methylated BSA. The Ab, dC1, binds both poly(dC) and ssDNA. It is encoded by V(H) and V(L) gene segments with no mutations, suggesting that the producing cell may have been selected before and activated during immunization. The dC1V(H) transgene was targeted to the IgH locus. In heterozygous mice, on a nonautoimmune C57BL/6 background, the transgene allotype was expressed on B cell surfaces and in serum Ig, but about one-third of B cells expressed the endogenous allele instead. Total serum Ig concentrations were normal and included both transgene- and endogenous gene-coded IgM and IgG. The transgene V(H) D(H)J(H) was expressed in splenic IgM cDNA with few or no mutations, and in IgG cDNA with multiple mutations. The transgene allotype was also expressed in Abs formed on immunization with thyroglobulin, pneumococcal polysaccharide, and ssDNA-methylated BSA. Consistent with the hypothesis, cells with a rearranged autoreactive V(H) domain selected for reactivity with a form of ssDNA did serve as precursors for cells producing IgM and IgG Abs to diverse Ags.

Adult bone marrow contains precursors for CD5+ B cells.

To determine directly whether B cell precursors of adult origin are capable of generating CD5+ B cells, we reconstituted neonatal C3H. SCID mice with adult C57BL/6 bone marrow and analyzed splenic B cells 10 months later. Surface staining and flow cytometry revealed that the B cells were of donor origin and that 30% were CD5+. This confirms that in vivo generated CD5+ B cells can be adult derived. After anti-IgM (but not lipopolysaccharide) stimulation in vitro, virtually all of the B cells from the bone marrow-reconstituted mice expressed surface CD5. Sequence analysis of expressed VHDJH genes from the CD5+ B cells present after anti-IgM stimulation revealed a high frequency of N nucleotide addition in CDR3 regions. The presence of N nucleotides indicates that these sequences were derived from CD5+ B cells of adult origin rather than from long-lived fetal precursor B cells present in either the adult bone marrow at the time of transfer or adult spleen. These experiments demonstrate conclusively that adult bone marrow contains precursors for CD5+ B cells and that unlike fetal liver-derived precursors these express terminal deoxynucleotidyl transferase.

Endogenous Ig production in mu transgenic mice. I. Allelic exclusion at the level of expression.

Our findings indicate that allelic exclusion is maintained in B cells that successfully rearrange and express and endogenous H chain gene, despite carrying a functionally rearranged H chain transgene (17.2.25 mu a). Cloned hybridomas having a functionally rearranged endogenous H chain gene as well as the transgene produce only endogenous gene products. Some of these hybridoma cultures, upon continuous growth, will secrete transgene as well as endogenous gene products. However, the two H chain polypeptides appear to be made by different cells. In each of three cases of such "double producer" lines examined, further subcloning at this time reveals two types of clones: those that secrete only transgene and those that secrete only endogenous H chains. The clones producing transgene product have lost the functionally rearranged endogenous H chain genes, whereas the clones producing endogenous gene products still contain both transgene and endogenous functionally rearranged H chain genes. These results indicate that hybridomas expressing endogenous Ig have transgene copies that are potentially functional but are reversibly silenced by an unknown mechanism and suggest that inhibition of transgene expression may be mediated by endogenous Ig gene expression.

Endogenous Ig production in mu transgenic mice. II. Anti-Ig reactivity and apparent double allotype expression.

In 17.2.25 mu transgenic mice (M54, M95), many of the expressed Ig, whether encoded by the transgene or endogenous H chain genes, react with Ig. IgM antibodies encoded by the 17.2.25 mu transgene transfected into J558L myeloma cells are also Ig reactive. In addition, anti-Ig reactivity was manifested by antibodies of the IgM, IgG, and IgA isotypes from the transgenic mice, suggesting that this characteristic reactivity is associated with VH and VL domains of these antibodies. These antibodies bind the (Fab')2 fragment of mouse IgG1 mAb known to be directed against C mu allotypic determinants. This finding could account for the so called "double producer" B cells found in mu transgenic mice and previously identified in serologic assays conducted with two different anti-mu allotypic reagents. In transgenic mice, a high frequency of the antibodies encoded by the transgene or endogenous H chain genes react with polyclonal and monoclonal antiidiotypic antibodies raised against the 17.2.25 Id. The idiotypic and/or antiidiotypic reactivity displayed by antibodies derived from these transgenic mice is similar to that of antibodies expressed by neonatal B cells of normal mice. Thus, our data suggest that transgene expression can play an important role in shaping the endogenous repertoire of antibody specificities.

Production of 17.2.25 mu transgenic and endogenous immunoglobulin in X-linked immune deficient mice.

In M54 mice transgenic for a completely rearranged mu(a) heavy chain there is a decrease in total B cells and the rearrangement of endogenous immunoglobulin genes is partially inhibited. Surprisingly, however, endogenous immunoglobulin gene rearrangement and significant heavy chain polypeptide production does occur. We tested the hypothesis that only CD5+ B cells produce endogenous immunoglobulin by taking advantage of the fact that X-linked immune deficient (xid) mice normally are deficient in CD5+ B cells. We found that the frequency of CD5+ splenic B cells was similar in XxidY transgenic and non-transgenic F1 males, and in XxidX transgenic and non-transgenic F1 females. In both XxidX and XxidY transgenic F1 mice some, but not all, splenic B cells are CD11b+. There was a striking deficit of splenic B cells expressing endogenous immunoglobulin in XxidY transgenic mice, although this was not true for peritoneal cells. Thus, the introduction of the 17.2.25 mu transgene does not prevent the development of CD5- B cells nor does it limit endogenous immunoglobulin gene arrangement and expression solely to CD5+ B cells. However, in mice capable of expressing B cell surface CD5 or CD11 this transgene can lead to expansion of the fraction of B cells positive for these molecules. We conclude that while the introduction of the 17.2.25 mu transgene alters the frequencies of B cell populations, maturation is not limited to one subpopulation.

Cationic residues in pathogenic anti-DNA autoantibodies arise by mutations of a germ-line gene that belongs to a large VH gene subfamily.

The F1 progeny of autoimmune NZB and normal SWR mice uniformly develop severe and accelerated lupus nephritis. The (SWR x NZB)F1 mice produce an oligoclonally expanded population of nephritogenic anti-DNA autoantibodies that share a recurrent cross-reactive idiotype (Id564), use highly homologous VH genes and surprisingly have the CH region allotype of the normal SWR parent. From extensive library analyses, we isolated 15 SWR germ-line genes which are most closely related to the pathogenic autoantibody VH564 gene and which also belong to the NPb subfamily of J558 VH genes. We found that the pathogenic VH genes are probably somatic variants of a SWR germ-line VH gene, SW6-3, and they have several basic amino acid substitutions, in addition to those already present in the SW6-3 germ-line gene. Since these pathogenic autoantibodies are not detectable in the sera of the normal SWR mice despite the presence of the SW6-3 gene, strong selection and expansion of B cells expressing the SW6-3 VH gene is probably occurring in (SWR x NZB)F1 lupus-prone mice. We also isolated eight germ-line genes from the NZB mouse which are homologous to SW6-3. The autoimmune NZB parent that rarely develops nephritis lacks the SW6-3 gene, but has several highly homologous germ-line VH genes that would encode less cationic antibodies. These results establish a correlation between structure and pathogenic potential of VH genes.

The effect of an immunoglobulin mu transgene on B cell maturation.

In mu 17.2.25-transgenic (M54) mice the absolute number of surface IgM (sIgM) B cells in lymphoid organs is drastically reduced compared to normal C57BL/6 mice and a high frequency of B cells express the immunoglobulin (Ig) encoded by the transgene rather than endogenous Ig on the surface. To determine the effect of a mu transgene on B cell development, adoptive cell transfers were performed using mu transgenic (M54) bone marrow and fetal liver cells. The data presented support the following conclusions: (a) adult transgenic bone marrow contains functional B cell precursors able to mature and repopulate the spleen and peritoneum of recipient mice. The relative frequency of transgene (sIgMa) and endogenous (sIgMb) surface sIgM-positive B cells reconstituted by transgenic bone marrow in allotype-matched C57BL/6 recipients is the same as in the M54 donors; (b) serum analysis indicates that transgenic bone marrow donor cells can reconstitute B cells in congenic and severe combined immunodeficient (SCID) recipient mice; (c) transgenic fetal liver cells are not a richer source of precursors for B cells expressing endogeneous Ig; (d) in transgenic mice sIgM+ B cells are not restricted to the CD5+ phenotype, however, the relative frequency of sIgMb B cells that are CD5+ is higher in transgenic than normal mice; and (e) bone marrow cells from adult normal and transgenic mice are able to generate CD5+ B lymphocytes in the spleen and peritoneum of allotype-congenic and neonatal SCID recipient mice. The results indicate that the presence of a complete mu heavy chain transgene does not result in a selective developmental block of "conventional" bone marrow-derived pre-B and B cells.

Endogenous immunoglobulin expression in mu transgenic mice.

Transgenic mice (M54) containing a functional mu heavy chain were examined to determine the effects of the transgene on rearrangement and expression of endogenous immunoglobulin genes. Two major novel findings are presented. (i) In transgenic mice, the expressed endogenous VH repertoire in LPS-generated B cell blasts and hybridomas is skewed toward expression of JH-proximal VH families (VH7183 and Q52). (ii) There is an increase in the frequency of B cells expressing lambda light chain genes in transgenic mice. Furthermore, in Abelson-MuLV transformed pre-B cells, VH to DJH is inhibited more than the D to JH rearrangement. The results presented indicate that the transgene skews the expressed VH repertoire by inhibiting the VH to DJH rearrangement while permitting an expansion of B cells expressing limited VH and lambda light chain genes.

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.

Selective strain distribution pattern of a germline VH gene for a pathogenic anti-DNA autoantibody family.

Autoimmune NZB mice rarely develop nephritis, but the SNF1, progeny of Crosses between NZB and the normal SWR strain uniformly develop severe lupus nephritis, indicating that the normal SWR strain makes a genetic contribution to the development of nephritis. The SNF1 mice produce a select population of cationic IgG anti-DNA autoantibodies that share a recurrent cross-reactive idiotype called Id564 and these autoantibodies play a prominent role in the development of nephritis. These pathogenic autoantibodies of SNF1 possess the IgCH allotype of the SWR, indicating their origin from the normal parent. The leader-VH sequences of these Id564+ pathogenic anti-DNA autoantibodies are highly homologous and they are also related by 95% homology to a germline gene of normal C57BL/6 mice, called VH-23, that is a member of an anti-NP antibody gene family. Herein, we cloned the flanking and coding regions of the expressed VHDJH genes of the anti-DNA mAb 564, the prototype member of the pathogenic Id564 family. By restriction analysis and partial sequencing, we found that the VH564 gene is related but distinct in its 5' flanking region from all of the known anti-NP VH genes of C57BL/6 and BALB/c mice. Hybridization with four probes complementary to different segments of the flanking and coding regions of the expressed VH564 gene indicated that the germline gene for VH564 is contained in an approximately 5.2 kb EcoRI fragment of SWR genomic DNA. Moreover, high stringency hybridization with oligonucleotide probes complementary to unique CDR2 and 5' flanking sequences of the expressed VH564 gene revealed that the 'approximately 5.2 kb' germline allele for VH564 that is possessed by the normal SWR parental strain is lacking in the NZB parental strain. C57BL/6 mice also lack this allele of the anti-DNA VH564 germline gene, although this strain possesses the highly homologous, anti-NP-related VH-23 germline gene. Thus germline VH genes for certain pathogenic autoantibodies may have a selective strain distribution pattern.

Genetic basis for altered idiotype expression in the hyperimmune response to (4-hydroxy-3-nitrophenyl)acetyl hapten.

To assess the significance of somatic point mutation in the hyperimmune response to the hapten NP, an in vivo enrichment procedure was followed. Mice that expressed high titers of B1-8 idiotopic determinants were selected as donors for serial transfer of small numbers of immune spleen cells into syngeneic irradiated recipient mice. Cells expressing B1-8 idiotopic determinants were chosen for enrichment because B1-8 cross-reactive determinants constitute a significant portion of the primary response. Furthermore, B1-8 is a monoclonal antibody derived from a primary response to NP, and its heavy and light chains are unmutated products of the germ-line genes VH186.2 and VL lambda 1, respectively. The germ-line sequence is thus available for comparison with the somatic mutants that arise during enrichment and hyperimmunization. The data show that serial transfer of spleen cells from mice with a high titer of idiotypic determinants results in a dramatic decrease in the titers of antibodies that bind antigen. Three lines of evidence indicate that progeny cells from the initial lambda-positive, idiotype-bearing, antigen-binding cells are successfully transferred and expanded during successive adoptive transfers. First, the proportion of lambda-bearing antibodies relative to NP-specific lambda-bearing antibodies increases with transfer, which is consistent with mutation away from antigen binding. Second, analysis of serum antibodies and hybridoma proteins derived from transfer-recipient mice confirm the presence of idiotype-positive antibodies that do not bind antigen. Third, RNA dot blot analysis of hybridomas constructed from a recipient mouse in the fourth transfer indicates a high frequency of expression of the VH gene predominantly used in the NP response. Many of the antibodies expressed by these hybridomas not only do not bind antigen, but have also lost the determinants recognized by the anti-idiotypic reagents. Most of these VH-positive hybridomas express lambda L chain. The most likely interpretation of the data is that somatic mutation is occurring during the hyperimmune response. Because we selected donor mice that expressed a high titer of idiotype-positive, antigen-specific antibody and immunized the recipient mice, we expected to observe a selective expansion of somatic variants that bound antigen. This was not the case. The observed loss of antigen binding suggests that the majority of mutations arising result in antibodies with lower affinity for the immunizing antigen.

Altered repertoire of endogenous immunoglobulin gene expression in transgenic mice containing a rearranged mu heavy chain gene.

C57BL/6 mice transgenic for a mu heavy chain gene, the VDJ region of which came from the BALB/c hybridoma 17.2.25, expressed high levels of antibody carrying determinants specific for the transgene (idiotypes). The individual antibodies made by hybridomas from transgenic mice, however, were generally encoded by endogenous genes; in most cases the transgene was present but not expressed. The endogenous, idiotype-positive antibodies had heavy chains that were notable for the high frequencies of JH4 (as in the transgene) and VH segments from the VH81X family (unrelated to the transgene). The expression of endogenous genes mimicking the idiotype of the transgene suggests that a rearranged gene introduced into the germ line can activate powerful cellular regulatory influences.

Shared idiotopes among antibodies encoded by heavy-chain variable region (VH) gene members of the J558 VH family as basis for cross-reactive regulation of clones with different antigen specificity.

A wide idiotype cross-reactivity was observed among six groups of monoclonal antibodies specific for arsonate and nitrophenyl haptens, hemagglutinin of PR8 and X31 influenza viruses, dextran, A48-idiotype, and a set of six monoclonal antibodies with unknown antigenic specificity. All of these antibodies are encoded by heavy-chain variable region (VH) genes belonging to the J558 VH family. This idiotypic cross-reactivity was determined by studying the binding of these antibodies to a panel of six monoclonal anti-idiotype antibodies, each one raised against a member of the six groups of monoclonal antibodies. The administration at birth of two such monoclonal anti-idiotype antibodies induced a long-lasting suppression not only of the corresponding idiotype but also of VH-related idiotypes with different antigenic specificities. These results suggest that the idiotypes encoded by VH genes that belong to the same VH gene family are interactive one with another. The possible physiological consequences of this immunochemical cross-reactivity are discussed.

A transgenic immunoglobulin mu gene prevents rearrangement of endogenous genes.

Transgenic mice containing a microinjected rearranged immunoglobulin (Ig) mu heavy chain gene were examined for the effects on DNA rearrangement of the endogenous Ig genes. Abelson murine leukemia virus (A-MuLV) cell lines were isolated from pre-B cells of transgenic mice and of normal littermates. Microinjected mu gene RNA and a mu heavy chain protein were synthesized in every transgenic A-MuLV cell line. Only 10% of normal mouse A-MuLV transformants synthesized mu protein. A germ-line JH allele was observed in 40% of the transgenic lines, demonstrating that the block to endogenous Ig DNA rearrangement occurred at the first step of heavy chain DNA joining. All alleles were rearranged in normal mouse A-MuLV lines. Germline JH alleles were also detected in 10% of the transgenic hybridomas derived from proliferating B cells. Our results support a model of active prevention of rearrangement by the product of successfully rearranged mu genes.

Heavy chain variable region. Multiple gene segments encode anti-4-(hydroxy-3-nitro-phenyl)acetyl idiotypic antibodies.

The hapten (4-hydroxy-3-nitrophenyl)acetyl (NP), when conjugated to carrier proteins, elicits a characteristic idiotypic response (NPb) in C57BL/6 mice. The response can be divided serologically into two distinct NPb-positive groups of antibodies. The first group consists of four crossreacting subgroups (I-IV), the second of two subgroups (V, VI). Some antibodies of subgroups I and II have been shown to express the unmutated heavy chain variable region (VH) germline gene 186.2. Antibodies of subgroups V and VI crossreact extensively with the NPa-positive antibodies of BALB/c mice. We sequenced heavy chain complementary DNA from eight hybridomas producing anti-NP antibodies. Six of these belong to subgroups V and VI, and two were NPa-positive hybridomas of BALB/c origin. All sequences were homologous to each other, and differed by approximately 80 basepairs from the 186.2 C57BL/6 germline VH gene. From our sequence and Southern blot analyses we suggest: (a) the NPb idiotypic response is the product of several VH germline genes, (b) some of these genes are very homologous to the gene coding for the BALB/c NPa idiotype, and might represent the C57BL/6 allelic forms of this gene, (c) the diversity regions of NPb and NPa-positive antibodies are diverse in length and amino acid composition, except for the first residue, which is always tyrosine, (d) all four heavy chain joining region gene segments are expressed without mutation. We discuss our data in terms of diversity in the germline VH gene repertoire, as well as diversity created by gene segment-joining events and somatic mutation.