Ig VH gene family repertoire of plasma cells derived from lupus-prone MRL/lpr and MRL/++ mice

VH gene family usage was determined in both spontaneous, in vivo activated plasma cells and LPS-induced plasma cells from individual MRL/lpr mice by using in situ hybridization. It was found that VH gene family expression in spontaneous plasma cells varied from mouse to mouse. Some mice expressed VH families in an apparently random manner similar to that obtained with polyclonal activation. Other mice showed an exaggerated expression of particular VH gene families. VH J558 was overrepresented most frequently, but overrepresentation of VH 7183, Q52, and 36-60 was also observed. Importantly, LPS-induced VH gene family expression in these same mice displaying biased VH family usage in spontaneous plasma cells, appeared normal with no evidence for similar biases in the LPS-induced repertoire. Anti-DNA antibody concentrations and the degree of glomerulonephritis were determined for each mouse to measure the severity of disease. The level of expression of the J558 family was positively correlated with disease severity. The results suggest that the initial autoantibody response is highly diverse but becomes more restricted as the disease progresses.     

Neonatal and adult primary B cells use the same germ-line VH and V kappa genes in their (T,G)-A-L-specific repertoire

Although there is a nonrandom usage of VH gene families by primary B cells early in ontogeny, at issue is whether the preferential rearrangement of 3' germ-line VH genes, e.g., VH7183 and VHQ52 family genes, influences the neonatal B cell repertoire that can be expressed in response to Ag. In order to address this issue, and to determine whether neonatal B cells can use the same germ-line VH and V kappa genes as adult B cells in their primary response, we have analyzed at the molecular level the neonatal antibody response to (T,G)-A-L and compared it with the adult primary response. Among the TGB5 Id+, GT+ antibodies, which dominate the neonatal response to (T,G)-A-L, two VH gene families were used: J558 (high frequency) and 36-60 (low frequency). The majority of Id+ neonatal hybridomas used the same germ-line VH gene (H10, from the VHJ558 family), but with enormous diversity in the D region, and one of two germ-line V kappa 1 genes (V kappa 1A, V kappa 1C). These are the same germ-line V-genes used by most primary adult Id+ hybridomas, and the frequency of expression of this germ-line V-gene combination appears equivalent in the neonatal and adult primary repertoires. Therefore, it is clear from this study that as early as day 5, neonatal B cells can use the same germ-line V-genes as adult primary B cells in their Ag-specific repertoire.     

Comparison of V kappa gene family expression in adult and fetal B cells

The functional B cell repertoires from adult and fetal mice were compared by examining V kappa gene family expression in individual cells. In addition, because little is known about the relative use of the various V kappa gene families in an immune response, adult B cells from several different strains of mice were analyzed. This was accomplished by stimulating B cells with the polyclonal activator, LPS. Activated cells were then analyzed for V kappa gene family expression at the single cell level by in situ hybridization using radiolabeled V kappa gene probes. It was found that all V kappa gene families tested were represented in the LPS-induced adult repertoire with V kappa 1, V kappa 4,5 and V kappa 19 being expressed to the largest degree in all strains tested. The LPS-induced adult V kappa gene family repertoire was then compared to the fetal repertoire and some differences were observed. In particular, a lower proportion of fetal B cells expressed V kappa 1 and a higher proportion of fetal B cells expressed V kappa 4,5 and V kappa 10. Importantly, compared with the adult response there was no evidence in the fetal response for an increased expression of V kappa 21, the family that maps closest to J kappa,C kappa. This is in contrast to what has been shown previously with H chain V region exons in which there was a clear preference for the VH gene families that mapped closest to DH.     

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.     

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.     

Eleven MRL-lpr/lpr anti-DNA autoantibodies are encoded by genes from four VH gene families: a potentially biased usage of VH genes

The genes encoding 11 independently derived anti-DNA autoantibodies from the lupus-prone mouse strain, MRL-lpr/lpr, were examined with VH, D, and JH gene probes. These autoantibodies do not define new VH gene families, since all of the autoantibodies were encoded by VH genes from four of the nine known gene families. A minimum of nine different VH genes encoded this panel of 11 anti-DNA autoantibodies. These results are consistent with the stochastic use of the VH gene repertoire and the expression of multiple VH genes. However, the data is also consistent with a biased usage of the VH gene repertoire. First, two pairs of autoantibodies, one from the J558 family and one from the 7183 family, appear to express identical or closely related VH genes as determined by the position of two restriction enzyme sites 5' of the expressed VH genes. In addition, three autoantibodies that appear to be sister clones might define a third VH gene that is used repeatedly. Secondly, about 45% of the panel is encoded by the Q52 and 7183 families, which are the 3' most families. These families have been shown to be preferentially rearranged early in B cell ontogeny. This suggests that some anti-DNA autoantibodies might originate from a population of B cells that predominate early in ontogeny. An alternative hypothesis is that the potential bias in VH gene and gene family usage could be due to antigen selection. All four JH genes are expressed, although the JH1 gene appears to be underutilized in both expressed and unexpressed rearrangements. Two members of the panel that bind double-stranded DNA were encoded by two different VH gene families, the S107 family and the J558 family.     

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.     

Direct quantitative in situ hybridization studies of Ig VH utilization. A comparison between unstimulated B cells from autoimmune and normal mice

This study examines Ig VH utilization in murine lupus with emphasis on the relative contribution of 3' and 5' gene families. We used in situ hybridization with 35S-labeled ssRNA probes to detect VH expression in individual spleen cells. Cells were taken from unmanipulated animals, and were not stimulated in vitro. This approach allows analysis of VH usage among only those B cells which have undergone activation in vivo, while minimizing the potential for skewing in vitro. We compared usage of the 3' 7183 and Q52 families with the more 5' J558 family in adult NZB, MRL-lpr/lpr, and nonautoimmune NIH Swiss mice. VH utilization in the autoimmune strains was proportionate to VH family size, and was not biased toward the 3' families when compared with the Swiss repertoire. Moreover, 3' skewing did not develop in NZB mice with increasing age. Thus, systemic autoimmunity is not associated with impaired normalization of the adult repertoire away from the 3' bias of early ontogeny. Instead, our data support a stochastic model for VH gene usage in the activated B cells and plasma cells of adult lupus mice.     

Germline V genes encode viable motheaten mouse autoantibodies against thymocytes and red blood cells

Autoantibodies against thymocytes and RBC may contribute to the pathophysiology of homozygous viable motheaten (mev) autoimmune disease. Whether the production of these autoantibodies in mev mouse results from polyclonal nonspecific B cell activation or specific Ag-driven stimulation is not known. To understand the mechanisms involved in the induction of antithymocyte autoantibody response in mev mouse, we have studied the fine antigenic specificity, structure, and origin of three antithymocyte autoantibodies derived from mev splenic B cell hybridomas. Western blot analysis showed that these mAb bind to polypeptides of 33 and 105 kDa present in RBC and thymocytes, respectively. Additional specificities for the epitopes present in other polypeptides distinguished these three autoantibodies. Northern hybridization and flow microfluorimetry analysis indicated that these hybridomas are derived from the Ly1+ B cell subset. These autoreactive Ly-1 B cell hybridomas, chosen on the basis of their specificity, expressed L chain V genes from a single VK family (VK9) and VH genes from J606 and S107 families. Hybridomas UN34.11 and UN42.5 expressed the VK9 gene identical to that used by peritoneal Ly1+ B cells from various mouse strains and malignant B lymphoma cells secreting anti-mouse RBC treated with proteolytic enzyme bromelin and anti-SRBC antibodies. The third hybridoma, S2-14.2, used a VK9 gene identical to that expressed by MOPC41. None of the VK genes encoding these autoantibodies showed any somatic mutations. In the case of VH genes, the two hybridomas UN42.5 and S2-14.2 derived from two separate fusions, used identical VH genes from the J606 family. The third hybridoma UN34.11 used unmutated V11 germline VH gene, a member of the S107 family. Southern hybridizations, using oligonucleotide probes specific for CDR1 and CDR2, showed that the VH genes encoding the J606 autoantibodies were derived from a germline gene found in the 6.7-kb fragment of EcoRI-digested germline DNA. This germline VH gene is distinct from VH22.1 germline gene that codes for antigalactan antibodies. Sequence analysis of this gene showed perfect homology with the rearranged VH genes confirming the lack of somatic mutations. Thus, our data demonstrate that antithymocyte antibody response occurring in mev mouse is polyclonal and it involves Ly-1 B cells expressing unmutated germline VH and VK genes. These results indicate that antigen driven stimulation may not play an important role in the induction of anti-thymocyte antibody response in mev mouse.     

Nonspecificity in a nonimmune human scFv repertoire

Efforts to develop effective antibody therapeutics are frequently hampered by issues such as aggregation and nonspecificity, often only detected in late stages of the development process. In this study, we used a high throughput cross-reactivity assay to select nonspecific clones from a naïve human repertoire scFv library displayed on the surface of yeast. Most antibody families were de-enriched; however, the rarely expressed VH6 family was highly enriched among nonspecific clones, representing almost 90% of isolated clones. Mutational analysis of this family reveals a dominant role of CDRH2 in driving nonspecific binding. Homology modeling of a panel of VH6 antibodies shows a constrained β-sheet structure in CDRH2 that is not present in other families, potentially contributing to nonspecificity of the family. These findings confirm the common decision to exclude VH6 from synthetic antibody libraries, and support VH6 polyreactivity as a possible important role for the family in early ontogeny and cause for its overabundance in cases of some forms of autoimmunity.     

VH gene family repertoire of resting B cells. Preferential use of D-proximal families early in development may be due to distinct B cell subsets

The fetal VH gene repertoire was shown previously to be characterized by overrepresentation of D-proximal families, VH 7183 and VH Q52, compared with adult bone marrow B cells in which VH genes were expressed in a more stochastic fashion. To determine the underlying mechanisms of these findings, adult vs fetal progenitors were placed in the same supportive microenvironment and the resulting B lineage cells analyzed for VH gene family expression. The supportive microenvironment was provided by established adult bone marrow stromal cell layers. In this way the relative importance of environmental vs genetic influences could be determined. The fetal B cells and pre-B cells that developed on adult stromal cells maintained a fetal-like VH gene family repertoire with preference for D-proximal families VH 7183 and Q52. In contrast, adult cultured B cells maintained the adult-like repertoire with predominance of the largest family VH J558. Only after long-term incubation was there a change in the expression of particular VH gene families. These findings suggest that the D-proximal VH gene family preference observed early in ontogeny is associated more with the inherent genetic potential of B cell progenitors that predominate during fetal life and less with environmental influences.     

Heavy chain variable region gene families evolved early in phylogeny. Ig complexity in fish

The V regions of channel catfish H chain cDNA clones have been analyzed. Based upon sequence relationships and hybridization analyses, five different groups of VH genes are identified whose definition is consistent with that of five different VH families. Genomic Southern blots indicate that as many as 100 different germ-line VH genes are likely represented by these families. The sequence diversity between identified members of these different families is similar in magnitude to the divergence represented between members of different human or mouse VH families. The FR regions are the most conserved regions when members of different catfish VH families are compared; specific amino acid positions appear to be highly conserved in phylogeny. Equally important is that diversity is represented in complementarity-determining regions CDR1 and CDR2 in members of the different families as well as in members of the same VH family. These results suggest that an extensive repertoire of VH genes can contribute to antibody diversity in this lower vertebrate. Sequence comparisons indicate that one of the catfish VH families shares considerable structural similarity to several higher vertebrate VH gene families--a relationship which suggests that this VH family may be ancestral to some VH gene families of higher vertebrates. Characteristic of the genomic organization of higher vertebrate H chains, catfish appear to have different VH families wherein a VH gene likely undergoes functional recombination with putative DH gene segments and one of apparently several different JH segments. The recombined V region is expressed with the same C region gene. These combined results suggest that bony fishes are the earliest known phylogenetic representatives to have evolved extensive V region gene families.     

Autoantibodies to thyroglobulin are encoded by diverse V-gene segments and recognize restricted epitopes.

Murine experimental autoimmune thyroiditis has been used as a model for human autoimmune thyroiditis. Experimental autoimmune thyroiditis is induced in mice by immunization with mouse thyroglobulin (Tg) in CFA. To characterize the antibodies to this autoantigen, we have studied the binding specificities and determined the nucleotide sequences of monoclonal anti-Tg antibodies. The specificities of the mAb for determinants on Tg varied extensively. Seven of 16 mAb showed reactivity to only mTg, 4 reacted to Tg from more than one species and four reacted to a variety of Ag. Many of the mAb were competitively inhibited by thyroid hormones, suggesting that they recognize the hormonogenic sites on the Tg molecule. The mAb could be divided into at least seven reactivity patterns based on reciprocal competitive inhibition studies, indicating that mTg contains at least seven antigenic regions. DNA sequence analysis of the mAb showed that a large number of V region gene segments encoded the H and L chains. No evidence for preferential use of any V region family or gene segment was found. Gene segments from the VH 7183, Q52, J558, and VH10 families were used by heavy chains, and the V kappa 1, 4, 8, 9, 19, and 21 families were used by kappa-chains. The results indicate that the antigenic epitopes on mTg elicit a very diverse autoantibody response that is derived from a large number of V region gene segments. Many of these autoantibodies show specific reactivity with mTg indicating they recognize species specific epitopes. The results suggest that clonal deletion of autoreactive Ab to certain self-epitopes may not occur.     

Identification of a new V kappa gene family that is highly expressed in hybridomas from an autoimmune mouse strain

We have identified a new murine V kappa family that contains five to seven members, one member of which encodes the L chain V region of an anti-dsDNA antibody produced by a BALB/c hybridoma, C8.5. The cloned C8.5 V kappa gene exhibits highest homology with a human V kappa gene that was cloned from a nonproductive rearrangement but has never been seen in an expressed repertoire. Because this family was first identified in an autoantibody, we studied its expression in an autoimmune mouse strain. This V kappa family is expressed in 20% of hybridomas from NZB mice.     

Specificity and molecular characteristics of monoclonal IgM rheumatoid factors from arthritic and non-arthritic mice

Two-hundred twenty-four hybridomas secreting monoclonal IgM rheumatoid factor (hIgMRF) derived from MRL-lpr/lpr, MRL-+/+ and C57BL/6-lpr/lpr autoimmune mice were analyzed with regard to IgG subclass and domain specificity, and some for VH gene expression patterns. Among these mice, only MRL-lpr/lpr develop arthritis. Clonotypes specific for each of the four mouse IgG subclasses and clonotypes reacting with more than one IgG subclass were identified. Although each panel contained several clonotypes, the predominant one differed in each strain (MRL-lpr/lpr, anti-IgG2a; MRL-+/+, combined anti-IgG2a and 2b; C57BL/6-lpr/lpr, anti-IgG1 or combined anti-IgG1, 2a, and 3). The IgG domains recognized by these monoclonals were defined with mutant Ig carrying IgG1 heavy chains that lacked either the CH1 or CH3 domains, variant Ig carrying hybrid IgG2b-2a heavy chains, and IgG fragments. Inhibition of hIgMRF binding to IgG substrates by protein A was also assessed. Most determinants were assigned to the CH3 domain, but determinants in the hinge region, CH2 domain, and in some instances, even in the Fab portion, could also be identified. Hybridization of cytoplasmic RNA from 35 classes of diverse IgG subclass specificity with VH gene probes representing seven of the approximately 10 VH families (7183, S107, Q52, J558, J606, 36-60, X24) indicated that approximately 90% of these clones expressed VH genes belonging to the large J558 gene family. The results indicate that murine IgMRF are extremely heterogeneous in IgG subclass and domain specificities; the genetic background influences RF specificity characteristics that may relate to pathogenicity; and considering the complexity of the J558 VH gene family and reported RF heavy chain assignments to additional VH gene families, it appears that VH genes encoding RF are diverse.     

Utilization of V kappa families and V kappa exons. Implications for the available B cell repertoire

A molecular cloning approach was used to determine the relative utilization of 2 individual V kappa 21 genes, 13 V kappa gene families, and the 4 functional J kappa gene segments among splenic B cells of nonimmunized BALB/c mice. Based on the observed frequency of individual V kappa gene expression, we estimate that the mouse genome encodes 150 to 180 functional V kappa genes, and we suggest that most functional V kappa exons are expressed at comparable frequencies in the preimmune antibody repertoire. In contrast, clear differences in J kappa segment utilization were observed, J kappa 4 being consistently underrepresented with respect to the other J kappa segments.     

Strain-dependent expression of VH gene families

The tremendous diversity of the antibody specificity repertoire stems from the ability of each developing B cell to select one out of many possible variable, diversity, and joining gene segments by specific rearrangement of the DNA. The mechanism by which V region gene segments is selected is not known. Moreover, evidence for both random and nonrandom expression of VH genes in mature B cells has been presented previously. In this report, the technique of in situ hybridization is used to accurately measure at the single cell level VH gene family expression in LPS-induced cells from several strains. In this way, at least one-third of the B cells are stimulated and a large sampling of activated splenocytes from each strain analyzed. The use of in situ hybridization eliminates any potential biases resulting from transformation protocols. In addition, because all populations of cells are analyzed by both in situ hybridization and immunocytochemical staining with anti-IgM, the proportion of cells detected by in situ hybridization could be compared with the proportion of B cells, blasts, and plasma cells in the population. It was concluded from these comparisons that the cells being detected by in situ hybridization under the conditions described are plasmablasts and plasma cells. Therefore, an accurate measure of the functional and expressed VH gene repertoire could be made. The results clearly demonstrate strain-dependent variation in VH gene family expression, particularly VH 7183 and VH J558 with up to three-fold differences observed. Thus, either there is considerable strain variation in the number of functional VH gene family segments or the expression of VH genes is not entirely random.     

Sequences of variable regions of hybridoma antibodies to alpha (1----6) dextran in BALB/c and C57BL/6 mice

The variable region sequences of light and heavy chains of three hybridoma antibodies to alpha (1----6) dextran, two from BALB/c and one from C57BL/6 mice, were determined by cloning and sequencing their cDNA. The three kappa-light chains are identical in nucleotide and amino acid sequences, except for the use of different J by BALB/c and C57BL/6; all three had the germ-line sequence of antibodies to 2-phenyloxazolone (20). Nevertheless, 2-phenyloxazolone BSA did not cross-react in gel with antidextrans, nor did dextran react with anti-2-phenyloxazolone ascitic fluids. The heavy chains differed, the BALB/c hybridomas having only three amino acid differences in CDR2 and two in CDR3; the C57BL/6 hybridoma differed throughout the variable region. All three VH are members of the J558 family. The three identical V kappa sequences suggest a significant role in dextran binding, with the differences in CDR of VH and the various J mini-genes of VL and VH being responsible for only fine differences in specificity. Alternatively, the role of V kappa might be minor, with most of the complementarity ascribable to VH. Additional sequences are needed to evaluate whether these data are typical of the repertoire of anti-alpha (1----6) dextran-combining sites.