Adventitious shoot regeneration from seven commercial strawberry cultivars (Fragaria x ananassa Duch.) using a range of explant types.

The parameters for optimal regeneration of seven commercial strawberry cultivars were tested using a range of explants and culture conditions. Efficient levels of regeneration--those needed to carry out transformation experiments--with the cultivars Calypso, Pegasus, Bolero, Tango and Emily were achieved with leaf discs, petioles, roots and stipules. Regeneration from cv. Elsanta proved to be difficult from all explant material, although unpollinated ovaries proved to be a promising explant source, with 12% of the explants regenerating shoots. In cv. Eros, regeneration occurred only from root tissue. A comparison of the genetic background suggests that there is a strong genetic component amongst the different cultivars determining their regeneration capacity. The development of these regeneration systems provides a means to use almost the whole stock plant for the efficient genetic transformation of commercial strawberry varieties.

The role of VL gene structural determinants in the fine specificity of anti-DNA antibodies.

To investigate the structural contribution of the light chain of anti-DNA antibodies to fine specificity, the VKappa genes of two monoclonal anti-DNA antibodies, termed H241 and H102, were cloned and sequenced. H102 and H241 are independently derived from MRL-lpr/lpr mice and differ in their fine specificity: H241 binds dsDNA and normal glomeruli in vitro and deposits in the kidney in vivo, whereas H102 binds only ssDNA and does not deposit in the kidney. Both are encoded by nearly identical VH genes but different N and D regions. Our previous results have demonstrated that the VH gene for H102 and H241 encodes eight other anti-DNA antibodies that also differed in fine specificity. This suggested that the gene product encoded by the VH 102/241 gene, may have intrinsic affinity for DNA, but is unlikely to determine fine specificity or nephritogenicity. In the present study we examined whether the VKappa gene might account for the difference in nephritogenicity. The complete nucleotide and deduced amino acid sequence of VK 102 and VK241 revealed that they are very dissimilar to each other (< 60% homology). VK 241 defined a new member of the VKappa gene family and was moderately homologous to two other VK genes encoding anti-DNA antibodies and to one VK gene encoding an anti-histone antibody all from lupus strains of mice. In addition, sequence diversity in the VK CDR1 region and position 96 of the CDR3 region was observed that may be of significance in determining fine specificity. VK 102 was highly homologous to two other VKappa genes, VKs17.2 and VK C8.5, both encoding anti-DNA antibodies and members of the VK20 gene family. It was striking that all three members of the VK 20 gene family code for DNA reactivity. This suggests that certain VKappa genes may also be used to repeatedly code for anti-DNA reactivity.

Independently derived IgG anti-DNA autoantibodies from two lupus-prone mouse strains express a VH gene that is not present in most murine strains.

The origin and structure of two clonally unrelated IgG anti-DNA autoantibodies from lupus-prone MRL/Ipr mice were examined. One of these antibodies, H241, binds dsDNA and glomeruli and deposits in the kidneys of normal mice, whereas the other, H102, binds only ssDNA and does not deposit in kidneys. The VH genes of these two antibodies were almost identical to each other and were frequently expressed in anti-DNA antibodies derived from lupus-prone mice. Six other clonally unrelated anti-DNA antibodies from the literature or from data banks expressed nearly identical VH genes (< or = 4 nucleotide differences) and eight others had nearly identical protein sequences (< or = 3 amino acid differences). Analysis of the germ line with oligonucleotide probes from the CDR regions suggests that all 10 autoantibodies are derived from a single member of the J558 gene family, which is present only in mice with the j haplotype for the J558 gene family. The amount of somatic mutation in these VH genes appears to be low, suggesting that some V, N, and D gene combinations can generate high affinity IgG anti-DNA auto-antibodies with little or no somatic mutation. Unusual reading frames, D-D fusions, and inversions were common in the IgG antibodies and may have been co-selected. Although the N and D regions of one IgM and all five IgG autoantibodies contained Arg residues, the presence of Arg residues was not correlated with binding to dsDNA or with pathogenicity. These results suggest that differences in the Ag-binding properties and the pathogenicity of these antibodies are determined by the CDR3 region and the L chain.

Molecular analysis of spontaneous nephrotropic anti-laminin antibodies in an autoimmune MRL-lpr/lpr mouse.

To explore the genetic relationship between anti-laminin and anti-DNA autoantibodies (autoAb), VH gene and gene family expression were determined among autoAb derived from an individual 6-mo-old MRL-lpr/lpr mouse. Whereas 85% of the anti-DNA Ig were identified by one of two VH family probes, 7183 and VHJ558, none of the anti-laminin antibodies (Ab) examined were recognized by these probes. Subsequent V region sequence analysis of three of the anti-laminin Ab revealed that they in fact utilized a J558 VH gene (VH50). Furthermore, FR2 and CDR2 oligonucleotide probes complementary to VH50 recognized multiple anti-laminin Ab by Northern blot analysis; the FR2 probe recognized two control anti-DNA Ab, but neither probe recognized anti-DNA Ab from the same mouse. Polymerase chain reaction amplification of MRL-lpr/lpr genomic liver DNA using primers generated from VH50 and Vk50 sequences indicated that all three anti-laminin Ig have a single replacement mutation in both their VH and Vk genes. Search of the nucleic acid databases revealed that both germline VH and Vk genes are expressed unmutated by murine lupus anti-dsDNA autoAb, previously sequenced in other laboratories. Sequence comparisons suggest that differences in anti-DNA and anti-laminin reactivity may be dependent upon somatically generated differences in the CDR3 regions of the H and L chains. The results indicate that lupus anti-laminin Ab can arise from distinct B cell populations but express the same unmutated germline V region genes as lupus anti-dsDNA autoAb. They further raise the possibility that these distinct B cell populations may be activated and expanded either: independently, by distinct Ig receptor ligands such as the Ag, laminin and DNA; or simultaneously, by a common ligand such as an anti-Id recognizing a common V region epitope.

Identification and complementation of a mutation to constitutive filamentous growth in Ustilago maydis.

Pathogenicity of the corn smut fungus Ustilago maydis involves the formation of a filamentous, infectious dikaryon by fusion of compatible, yeastlike haploid cells. The mating-type loci, a and b, regulate cell fusion and establishment of the dikaryotic cell type, respectively. On solid medium, compatibility at the mating-type loci, in particular heterozygosity at the b locus, is manifested by the formation of aerial hyphae on colonies formed by mating cells. We have employed this "fuzzy" phenotype to identify haploid mutants that constitutively form hyphal filaments and forego cell division by budding. A total of 125 such mutants have been isolated; characterization of one mutant (termed rem1-1) revealed that it can participate in infection of the host plant, although it must be paired with a compatible, wild-type mating partner. That is, mutation to the mycelial phenotype is not sufficient to allow a haploid strain to be pathogenic by itself. A cosmid has been isolated that restores the ability of an rem1-1 mutant to grow with a budding phenotype. Localization of the complementing region on cosmid DNA allowed the construction of an additional mutation by gene disruption. Coinoculation of plants with two compatible strains, each carrying the disruption mutation, gave greatly reduced disease symptoms. The analysis of the rem1 gene should contribute to an understanding of dimorphic growth and pathogenesis in U. maydis.

Anti-DNA antibodies form immune deposits at distinct glomerular and vascular sites.

To investigate the capacity of lupus autoAb to produce glomerular immune deposits (ID) and nephritis, 24 murine monoclonal (m) anti-DNA antibodies (Ab), derived from either MRL-lpr/lpr, SNF1 or NZB lupus-prone mice and selected based on properties shared with nephritogenic Ig, were administered i.p. (as hybridomas) and i.v. (as purified Ig) to normal mice; at least four mice/mAb were evaluated. Three general patterns of immune deposit formation (IDF) were observed: extracellular ID within glomeruli (+/- blood vessels, N = 8); intranuclear ID (N = 5); or minimal or no ID (N = 11). The four MRL m anti-DNA Ab that produced significant extracellular ID demonstrated different disease profiles including: (a) mesangial and subendothelial ID with anti-basement membrane staining, associated with proliferative glomerulonephritis, PMN infiltration, and proteinuria; (b) diffuse fine granular mesangial and extraglomerular vascular ID, associated with proliferative glomerulonephritis and proteinuria; (c) dense intramembranous ID and intraluminal ID, associated with capillary wall thickening, mesangial interposition and expansion, aneurysmal dilatation and intraluminal occlusion of glomerular capillary loops, and heavy proteinuria; and (d) mesangial and extraglomerular vascular ID, associated with mild segmental mesangial expansion, without proteinuria. These MRL mAb were derived from four different mice, and they had variable pIs and isotypes. They all cross reacted with multiple autoantigens (autoAg), however, their autoAg binding profiles were distinguishable. Among the SNF1 derived mAb, four produced histologically and clinically indistinguishable disease characterized by diffuse mesangial and capillary wall ID, associated with cellular proliferation/infiltration and proteinuria. Three of the four mAb were derived from the same mouse and were clonally related; they were: IgG2b with SWR allotype, relatively cationic, highly cross reactive with similar Ag binding patterns, idiotypically related and encoded by identical VH and nearly identical VL sequences. We conclude that both the capacity of lupus autoAb to form ID and the location of IDF are dependent on properties unique to individual Ig. The results also indicate that the Ag binding region of the autoAb is influential in this process, and they suggest that multiple Ab-Ag interactions contribute to IDF in individuals with lupus nephritis. Furthermore, these observations raise the possibility that the pathologic and clinical abnormalities resulting from these interactions are influenced by the location of IDF, and that the dominant interaction, in a given individual, may be highly influential in the phenotypic expression of nephritis.

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.

High-specificity in-situ hybridization. Methods and application.

We describe a technique of in-situ hybridization using oligonucleotide probes employing the expression of immunoglobulin VH genes as a model. Optimal conditions for hybridization with the 35S-labeled oligonucleotide probes were established with monoclonal B-cell lines that express VH genes of known nucleic acid sequence. The range of sensitivity and specificity achieved with this technique is documented. Under conditions of high stringency, this method can detect the expression of highly related VH hypervariable regions.

Murine monoclonal anti-DNA antibodies penetrate cells, bind to nuclei, and induce glomerular proliferation and proteinuria in vivo.

The production of relatively high quantities of autoantibodies (autoAb) that react with DNA and other intranuclear antigens is characteristic of individuals with systemic lupus erythematosus and other autoimmune diseases. However, the capacity of these Ab to penetrate cells and induce functional perturbations in vivo is not well appreciated. To address this issue, monoclonal (m) anti-DNA Ab (mAb), derived from MRL-lpr/lpr and (NZB x SWR)F1 mice, were administered to normal mice, and the animals were examined for morphologic and functional abnormalities. A subset of five mAb produced intranuclear immunoglobulin deposits in multiple organs. Intranuclear immunoglobulin deposits were also observed after cross-linking the tissue before direct immunofluorescence and after i.v. injection of F(ab')2 fragments of one anti-DNA Ab. This phenomenon was reproducible and was only associated with this subset of autoAb. Furthermore, intranuclear deposits of anti-DNA Ab within glomeruli were associated with morphologic and functional abnormalities including: hypercellularity, epithelial foot process fusion, new fiber bundle formation within the mesangium suggestive of new collagen synthesis, and proteinuria. These results indicate that a subset of autoAb may penetrate cells in vivo to influence normal cellular and nuclear function and to contribute to functional and pathologic abnormalities in individuals with systemic lupus.

Molecular heterogeneity of auto-anti-idiotypic antibodies in MLR-lpr/lpr mice.

The VH and V kappa gene families expressed by 20 monoclonal auto-anti-idiotypes (Ab2) derived from unmanipulated MLR-lpr/lpr mice were determined by Northern blotting. Complete variable region sequences of six Ab2, along with three additional V kappa-JH Ab2 sequences, were obtained. These auto-anti-idiotypes arose spontaneously in the animals, and they bound specifically to an idiotypic determinant (Id/r) on mAb 28/12, a monoclonal IgG2b MLR-lpr/lpr anti-small nuclear ribonucleoprotein antibody. The 16 Ab2 heavy chains belonged to 7 different VH gene families, and the 10 Ab2 light chains were derived from 8 V kappa families. The light chains of two Ab2 were approximately 99% identical; the remaining variable region sequences were highly heterogeneous. There was no correlation between primary amino acid sequence of either heavy or light chain and idiotypic properties of the auto-anti-idiotypes. Six Ab2 used VH or V kappa genes that are identical to known germ-line genes. A high proportion of the spontaneous auto-anti-idiotypes was shown to have autoantibody activity (anti-DNA, anti-ribonucleoprotein), or specific binding reactions with lipopolysaccharide of Salmonella RE, or both properties. The structural diversity of spontaneous MLR-lpr/lpr auto-anti-idiotypes differs sharply from the structural homogeneity reported for Ab2 induced in normal animals against syngeneic Ab1. Our results suggest that auto-anti-idiotypes might arise independently of an immunogenic stimulus from an Ab1.

VH gene analysis of spontaneously activated B cells in adult MRL-lpr/lpr mice. J558 bias is not limited to classic lupus autoantibodies.

To determine the genetic origins of lupus auto-antibodies, we analyzed the relationship between VH gene usage and auto-Ag-binding properties of 352 B cell hybridomas derived from MRL-lpr/lpr mice. The hybridomas were derived from neonatal, 1-month-old, 3-month-old, and 6-month-old mice. The experimental strategy provided that the hybridomas were monoclonal at initial evaluation, so the Ag binding and V gene frequencies of the entire population could be determined. Initially, 1032 Ig-producing hybridomas were evaluated for binding to six Ag; VH gene family use was determined in 119 anti-DNA and anti-rabbit thymus extract (RTE) antibodies (autoantibodies) and in 233 age-matched Ig that did not bind to any of the six Ag (nonbinders). Neonatal B cells, including cross-reactive IgM autoantibodies and nonbinder IgM, used relatively 3' VH genes. The majority of B cells in adult mice used VH genes of the J558 family. Although J558 use was significantly higher among the autoantibodies (anti-DNA and anti-RTE) than among the nonbinder Ig, this difference was due to a higher frequency of J558 use by 1-month-old mice. At 3 months, J558 use by the nonbinder Ig increased to the same frequency of J558 use as in the autoantibody population. J558 use in both groups of antibodies exceeded a previously reported estimation of J558 expression in the functional B cell repertoire of young adult MRL-lpr/lpr mice. Several subgroups of antibodies that share properties with pathogenic Ig, including IgG, cross-reactive Ig, and anti-dsDNA autoantibodies, demonstrated a marked preferential expression of the J558 family. These results suggest that there is an age-related bias in the activation of B cells using J558 VH genes in MRL-lpr/lpr mice that is under the influence of a selective force distinct from, or in addition to, an ssDNA or RTE auto-Ag-driven response.

Molecular analysis of a germ line-encoded idiotypic marker of pathogenic human lupus autoantibodies.

Id-16/6 is an idiotypic marker found in both IgM and IgG antibodies, as well as in the tissue lesions of patients with SLE. The prototypic Id-16/6+ mAb is 18/2, whose VH3-derived H chain is encoded by an unmutated germ-line gene. We found that the H chains of VH3-derived Id-16/6+ antibodies contain the major determinants of Id-16/6. Moreover, B cell clones from which those antibodies were harvested produce RNA that hybridized under conditions of high stringency to oligonucleotide probes corresponding to the CDR of the VH segment of 18/2. Western blots of Id-16/6+ mAbs with anti-Id confirmed the association of the Id with H chains. Id-16/6 can identify a subgroup of VH3-derived antibodies we have termed the 18/2 CDR family. However, Id-16/6 can also be expressed in some antibodies unrelated to the 18/2 CDR family. No characteristic Ag-binding specificity was found among the members of the 18/2 CDR family. The principal phenotypic feature shared by all known members of the family is Id-16/6.

Individual VH genes detected with oligonucleotide probes from the complementarity-determining regions.

The germ-line and expressed Ig repertoire was examined with three oligonucleotide probes from the CDR regions of VH18/2, a VH gene from the largest human VH gene family, VHIII. Each oligonucleotide probe detected small numbers of germ-line bands (1-5) under conditions in which single base differences can be detected; more than half of these bands were polymorphic. The combined results from pairs of oligonucleotides from CDR1 and CDR2 identified a single band on Southern blots, as did a probe from the 5' end of CDR2. This band contains the 18/2 germ-line gene. The nucleotide sequence of expressed VH genes that hybridized to both CDR probes or to the 5' CDR2 probe were greater than or equal to 97% homologous to 18/2 in both the framework and CDR regions. This group of closely related VH genes, the 18/2 CDR family, appears to be overexpressed. The role of polymorphisms and differential expression of individual V genes in multigenic autoimmune diseases, as well as the organization and expression of individual V genes, can be examined with pairs of oligonucleotides from CDR1 and the 3' end of CDR2, or with probes from the 5' end of CDR2.

An immunoglobulin light chain from a lupus-prone mouse induces autoantibodies in normal mice.

Autoantibodies against the 70-kD U1 RNP nucleoprotein autoantigen and DNA were elicited in normal BALB/c mice with a purified Ig light chain. This light chain, derived from a lupus-prone MRL-lpr/lpr mouse, has two distinctive properties: it contains an idiotypic marker recognized by a monoclonal MRL-lpr/lpr anti-snRNP autoantibody, and the amino acid sequence of its third hypervariable region (CDR3) is homologous to a sequence in an antigenic region of the 70-kD U1 RNP polypeptide. The results demonstrate that an Ig idiotype that mimics an autoantigen can induce autoimmunization.

Polymorphisms in human H chain V region genes from the VHIII gene family.

Polymorphisms of the Ig H chain V region (VH) genes were examined with probes from the coding and flanking regions of a gene from the largest VH gene family, VHIII. The 5'-flanking probe gave the simplest pattern and revealed the largest number of polymorphic fragments. Analysis of unrelated individuals and of families identified five polymorphic loci. Two alleles were detected for each of two of the loci, whereas a polymorphic band was scored as present or absent for the other three loci. The polymorphic fragments segregated in the expected Mendelian fashion and parental haplotypes could be assigned in all cases. Comparison of the patterns obtained with the flanking and coding region probes suggests that the human VHIII gene family is highly polymorphic and may contain several hundred V genes. This method, as well as the polymorphism detected, can be used to investigate the organization and germ-line variation of H chain V genes and their inheritance in normal individuals and in individuals with immunologic disorders.

Anti-DNA antibodies, autoimmunity and the immunoglobulin repertoire.

The advent of hybridoma and recombinant DNA technology about a decade ago has allowed a detailed analysis the structure, properties and molecular genetics of antibodies. These techniques, combined with studies of idiotypes and of Abelson-transformed and other cell lines, have resulted in major findings which are of particular importance to both the normal immune system and to autoimmunity. The rearrangement and expression of antibody genes in the normal immune system are discussed first, as a background for an appreciation of the significance of the molecular genetics of autoantibodies. We then turn to autoantibody genes, with an emphasis on anti-DNA antibodies and their role in the autoimmune disease, systemic lupus erythematosus. A model for the genetics of lupus which includes a possible role for Ig genes is considered.

The heavy chain genes of a lupus anti-DNA autoantibody are encoded in the germ line of a nonautoimmune strain of mouse and conserved in strains of mice polymorphic for this gene locus.

The variable region of the heavy chain of a prototypic anti-DNA autoantibody from the lupus-prone mouse, MRL-lpr/lpr, was cloned and sequenced. The VH and JH genes expressed by this antoantibody were found to be identical to germ line genes from the nonautoimmune mouse strain, BALB/c. The D gene of this autoantibody differed by one nucleotide from several members of the germ line SP2 family, but has been found in expressed D genes from several strains of mice. These results show that a normal mouse strain contains all of the structural information necessary for the expression of the heavy chain variable region of a lupus autoantibody. A fragment that is present in both BALB/c and MRL mice is highly homologous in both coding and flanking sequences to the autoantibody VH gene (VH130) and is the same size as the BALB/c germ line gene. This suggests that these two strains may share the same allele of this VH gene, despite the fact that they are polymorphic for this VH gene family. Other mouse strains that are polymorphic for this locus contained one to three VH genes that were highly related to VH130 in both coding and flanking regions. Thus, VH genes that may be allelic to the antibody VH gene or that may have arisen by gene conversion, unequal crossing over or gene duplication, are conserved in many mouse strains.

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.

Human ferritin H and L sequences lie on ten different chromosomes.

In humans, the H (heavy) and L (light) chains of the iron-storage protein ferritin, are derived from multigene families. We have examined the chromosomal distribution of these H and L sequences by Southern analysis of hybrid cell DNA and by chromosomal in situ hybridization. Our results show that human ferritin H genes and related sequences are found on at least seven different chromosomes while L genes and related sequences are on at least three different chromosomes. Further, we have mapped the chromosomal location of expressed genes for human H and L ferritin chains and have found an H sequence which may be a useful marker for idiopathic hemochromatosis.

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.