Germline antibody V regions as determinants of clonal persistence and malignant growth in the B cell compartment.

Antibody V gene expression was studied in a subpopulation of murine B cells (Ly1 B) which was enriched by cell transfer and had earlier been shown to persist in the immune system over long periods of time. Among 17 hybridomas derived from Ly1 B cells of two different mice, eight were progeny of only three different B cell precursors which apparently had expanded to clones of large size, in the absence of detectable somatic mutation of their antibody V regions. Furthermore, several clonally independent cells expressed identical, unmutated V genes. These data define a novel pathway of B cell development in which cells expressing a selected set of germline antibodies are continuously propagated in the organism. A Ly1 B cell leukemia derived from a similar transfer experiment expressed a VH gene that had been isolated in three independent Ly1 B cell hybridomas, suggesting that the leukemic cells had been equally selected in this pathway.     

High frequency expression of S107 VH genes by peritoneal B cells of B10.H-2aH-4bP/WTS mice

Our previous analyses of peritoneal Ly-1 B cells indicate that a high percentage express VH genes of the VH11 and VH12 families, and that this bias is due to clonal selection. The antibodies encoded by these genes bind the same hapten, phosphatidyl choline (PtC). Twenty-one of 73 hybridomas generated from fusions with peritoneal Ly-1 and Ly-1 sister population B cells of B10.H-2aH-4bp/Wts mice produce anti-PtC specific antibodies. We show here that 19 of these express VH11 and VH12 family genes and two express VH36-60 family genes. To assess whether there is a bias in VH gene use among non-PtC-specific hybridomas we analyzed the remaining 52 hybridomas for VH family expression by using VH family-specific probes in an RNA dot blot assay and by Ig mRNA sequencing. We find a seven-fold increase in the expression of the VHS107 family genes, and only slight differences in the expression of VH genes of other families relative to splenic B cells. We attribute the increase in VHS107 gene expression to clonal selection inasmuch as five of the seven VHS107+ hybridomas express the same VH gene (V11) and VL association is nonrandom. The bias in VH gene use among the entire panel of 73 peritoneal hybridomas is to the extent that approximately one-third express one of three genes: the V11 gene of the S107 family, the CH34 gene of the VH11 family, and the VH12 family gene.     

A single VH gene is utilized predominantly in anti-BrMRBC hybridomas derived from purified Ly-1 B cells. Definition of the VH11 family

By establishing hybridomas from two distinct surface IgM+ splenic B cell populations, Ly-1 B cells and "conventional" (Ly-1-) B cells, we found that the Ly-1 B population includes a 30 to 70 times higher frequency (1 to 2%) of cells with specificity for bromelain treated autologous red blood cells (anti-BrMRBC) when compared with conventional B cells (0.03%). We cloned and sequenced the V genes encoding anti-BrMRBC antibody from two hybridomas made with Ly-1 B cells sorted from the spleen of SM/J mice. The VH sequence (for both) is identical with the previously reported sequence associated with this specificity and belongs to a new VH gene family. This gene family, defined here as VH11, has only two members and is the predominant VH rearranged in a collection of Ly-1 B derived anti-BrMRBC hybridomas, always in association with a single VL gene (a member of the V kappa 9 family). Furthermore, analysis of hybridomas made with Ly-1 B cells sorted from the peritoneum reveals a yet higher increased frequency of VH11-encoded anti-BrMRBC specificity (30%). This variation in frequency of anti-BrMRBC in the Ly-1 population depending on location, together with the repeated association of VH11 with a particular V kappa gene suggest that antigen driven selection is (at least in part) responsible for the biased V gene expression seen in this population. Furthermore, a mechanism that might contribute to biased expression, preferential rearrangement due to close proximity to J (as seen in pre-B lines), is excluded by localization of VH11 5' to several of the more J-proximal families (Q52, 7183).     

Nucleotide and translated amino acid sequences of cDNA coding for the variable regions of the light and heavy chains of mouse hybridoma antibodies to blood group A and B substances

This is the first report of nucleotide and translated amino acid sequences of the variable region light (VL) and heavy (VH) chains of mouse monoclonal hybridoma anti-blood group A and B substances, the combining sites of which have been mapped. Monoclonal hybridoma anti-A and anti-B produced in BALB/c mice by immunization with A or B blood group substances, with A1 erythrocytes, and water-soluble blood group A substance or with synthetic B determinants coupled to bovine serum albumin or to O erythrocytes have been characterized immunochemically. To relate the immunochemical properties of the monoclonals to their primary structures, we have cloned and sequenced cDNAs of variable regions of light and heavy chains of two anti-A and two anti-B. The anti-A hybridomas have very similar combining site specificities and have almost identical VH sequences belonging to the J558 germ-line family, but their VL are from different germ-line VK gene families. The two anti-B hybridomas have different combining site specificities and use the same VL which differs completely from the anti-A VL; their VH are derived from different VH germ-line genes belonging to the J606 family. The results suggest that the heavy chains play a major role in determining the specificities of the antibody combining sites, with only minor contribution of VL. Additional sequence data on monoclonal antibodies of defined specificity for blood group substances are needed for further insights into the genetic and structural basis for their specificities.     

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.     

Diversity in the available repertoire of murine antibodies reactive with bromelain-treated isologous erythrocytes

Antibodies specific for bromelain-treated mouse RBC (BrMRBC) are of interest as models of "natural autoantibodies" and because of their primary source is Ly-1+ (CD5+) B cells. In earlier work by others, anti-BrMRBC hybridomas prepared by using CBA or NZB "spontaneously activating" peritoneal B cells were all found to produce mAb with a single common H chain V region sequence, by using a novel gene (VH11p), and a single common L chain V region sequence, a member of the Vk9 group (VkBrMp). We prepared anti-BrMRBC hybridomas by using LPS-activated B10.A splenic B cells in order to reveal the maximum available diversity in this repertoire. Data based on binding studies, Northern blot analyses with V region-specific probes, and mRNA nucleotide sequence analysis indicated that there is combining-site diversity in the repertoire of anti-BrMRBC hybridomas. There was considerable variation in trimethylammonium (a constituent of phosphatidyl choline) binding efficiency, and one of the anti-BrMRBC mAb showed no detectable binding. Northern blot analyses indicated 6 of 11 mAb to be of the VH11p/VkBrMp type, including one dual reactive anti-[BrMRBC + SRBC] mAb. Sequence analyses of the H chain V regions of four of the non-VH11p mAb revealed utilization of four distinct VH, three of which are very similar to the VH expressed by Ly-1+ B cell clones or lymphomas, as reported by others. However, because the VH11p/VkBrMp-type mAb were all relatively efficient at lysing BrMRBC and binding trimethylammonium, we suggest that affinity considerations may determine the selective predominance of B cells with this V region configuration from an available repertoire of considerable diversity.     

VH sequence of a human anti-Sm autoantibody. Evidence that autoantibodies can be unmutated copies of germline genes

The utilization of germline genes for the synthesis of autoantibodies has been suspected for many years based on the presence of cross-reactive idiotypes among patients as well as in some healthy first-degree relatives of patients with several autoimmune diseases including SLE. One such system of idiotypes involves anti-Sm antibodies, which are highly specific for SLE. To definitively establish the utilization of germline genes in the Sm system, we produced human-human B cell hybridomas from a patient with SLE who had circulating anti-Sm antibodies. One stable hybridoma designated 4B4 secretes an IgM-kappa mAb that binds Sm and shares idiotypic determinants with other anti-Sm antibodies. A second anti-Sm antibody (3C3), isolated from the same patient was also studied. Oligo(dT) priming was used to produce cDNA corresponding to full length IgM. Sequence analysis revealed that the VH gene segment (1-96) of 4B4 is identical to a VH sequence previously detected in a fetal liver cDNA library by Schroeder and his co-workers as well as a germline VH recently described by Berman and his associates. The identity of a lupus mAb and sequences derived from unrelated individuals provides strong evidence that this autoantibody is a direct copy of a germline gene.     

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.     

Repetitive usage of immunoglobulin VH and D gene segments in CD5+ Ly-1 B clones of (NZB x NZW)F1 mice.

The usually small Ly-1 B cell population is markedly increased in older mice by expansion of certain clones. This results in a cellular picture very similar to human B chronic lymphocytic leukemia. Here we report a molecular analysis of the immunoglobulin gene rearrangements of the Ly-1 B cell populations in (NZB x NZW)F1 females. We find that (i) the number of clones found in the peritoneum (a major tissue source of Ly-1 B cells) decreases with age till mono- or biclonality is common by approximately 6 months, (ii) many clones from different mice show the same size rearrangements at both the Ig heavy and light chain loci and (iii) the IgH rearrangements found in a clone isolated from the spleen of one mouse are a subset of those found in the peritoneum of the same mouse, implying migration occurs from the peritoneum to the spleen. Molecular cloning and sequencing of the IgH rearrangements from the peritoneal clones of one B/W mouse revealed that all productive rearrangements used the identical unmutated VH and D elements joined to different JHS. Indeed, two VDJH4 rearrangements were recovered which were identical but for six junctional (N region) nucleotides. The conservation of VH and D segment usage in the rearrangements of these Ly-1 B cell clones could indicate some strong selective pressure for clonal expansion (for example antigen selection) operates via the immunoglobulin molecules of these cells. Southern analyses of other (NZB x NZW)F1 mice with this cloned VH and the usage of the same or similar VH genes among a number of Ly-1 B origin tumors in other mouse strains indicate the generality of this repetitive VH gene usage in individual mice.     

A set of closely related antibodies dominates the primary antibody response to the antigenic site CB of the A/PR/8/34 influenza virus hemagglutinin

Approximately 50% of the primary antibody response of BALB/c mice to the A/PR/8/34 influenza virus hemagglutinin is directed to the Cb site, one of the four major antigenic regions of the molecule. To determine the structural basis of the anti-Cb site response, we have examined the paratypic and genetic diversity exhibited by a panel of 24 primary and 4 secondary response mAb specific for this antigenic region. Reactivity pattern analysis demonstrated 20 distinct fine specificities among these antibodies, and V region gene sequence analysis showed that they are encoded by 17 different VH gene segments from 6 VH gene families and 14 different VK gene segments from 6 VK gene groups. Despite this overall diversity, many of the antibodies can be placed in a limited number of sets based on the shared expression of VH and/or VK genes. One set contains antibodies encoded by a single gene of the VK4/5 group in combination with one of two closely related genes from the J558 VH family. This set accounts for half of the Cb site-specific primary response hybridomas, indicating that the representation of the various anti-Cb site B cell specificities during the primary response to A/PR/8/34 influenza virus is not uniform. The preferential participation of B cells expressing this VH/VK combination is largely responsible for the dominance of anti-Cb site antibodies in the primary anti-hemagglutinin response.     

Restriction in V kappa gene use and antigen selection in anti-myeloperoxidase response in mice

Anti-neutrophil cytoplasmic Abs, directed primarily toward myeloperoxidase (MPO) and proteinase 3, are detected in the majority of patients with distinct forms of small vessel vasculitides and pauci-immune necrotizing glomerulonephritis. However, the origin of these autoantibodies remains unknown. We studied the V region gene use in murine anti-MPO Abs derived from Spontaneous Crescentic Glomerulonephritis/Kinjoh mice. A total of 13 anti-MPO-producing hybridomas were generated from four unimmunized mice. Ten of the 13 hybridomas (corresponding to 3 of 4 clones) expressed Vkappa1C but differed in their use of VH genes. The remaining three hybridomas expressed a Vkappa5 gene. Anti-MPO hybridomas from individual mice were derived from single clones as deduced by sequence similarity and splice-site identity. We found a statistically significant bias of amino acid replacement mutations to the complementarity-determining regions (CDR) in the Vkappa1C-expressing hybridomas. Intriguingly, all 10 Vkappa1C hybridomas share a lysine to glutamate mutation in the CDR1. To determine the effects of somatic V gene mutations on binding to MPO, we generated an anti-MPO Ab with an unmutated Vkappa1C L chain and compared its ability to bind MPO with its mutated counterpart. The mutated hybridoma-derived Ab has a 4.75-fold higher avidity for MPO than the unmutated Ab. These results suggest that: 1) the L chain plays a dominant role in determining Ab specificity to MPO, 2) the anti-MPO Ab response is oligoclonal, consistent with Ag selection, and 3) MPO is a driving Ag in the murine anti-MPO Ab response.     

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.     

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.     

A pathogenic monoclonal antibody, G8, is characteristic of antierythrocyte autoantibodies from Coombs'-positive NZB mice.

With age, NZB mice develop anti-RBC autoantibodies resulting in the development of autoimmune hemolytic anemia. We now have evidence that this spontaneous autoantibody response consists of antibodies that are similar in specificity and Id expression to a pathogenic autoantibody (G8) that was cloned from an autoimmune NZB mouse. Similar to autoantibodies eluted from Coombs'-positive mouse E (MRBC), the G8 mAb recognizes native (unmodified) MRBC but not RBC from other species. Interestingly, G8 and four additional mAb bind with a higher titer to bromelain-treated MRBC than to native MRBC. Nucleotide sequence analysis reveals, however, that unlike "natural" antibodies that react solely with bromelain-MRBC, G8 is encoded by a J558 VH gene and a V kappa 12,13 L-chain gene. Thus G8 is clearly distinct from antibodies to bromelain-MRBC which are encoded by unrelated V genes. Instead, the sequence of the G8 VH chain was found to be nearly identical to that of an anti-DNA mAb derived from an MRL-lpr/lpr mouse. The results suggest Coombs'-positive autoantibodies from NZB mice are not derived from "natural" antibodies, but rather, consist of a restricted set of autoantibodies expressing the G8 IdX.     

Restricted Ig variable region gene expression among Ly-1+ B cell lymphomas

The majority of the characterized Ly-1+ B cell lymphomas of B10.H-2aH-4bp/Wts origin (the CH series) bear surface Ig related by Ag specificity or idiotype or both. To determine the genetic basis for these structural similarities, we have sequenced the VH and VL region genes expressed by 10 CH lymphomas, and have compared their VH and V kappa gene rearrangements by Southern blot analysis to one another and to those of four other CH lymphomas. Sequence analysis identified only five different VH, and seven different VL genes, and indicated that these V genes are essentially unmutated. CH lymphomas which express the identical VH gene share at least one idiotope. Thus, the basis for shared idiotype and specificity is due in most cases to the use of the same V gene. This restriction in V gene expression is not due to the preferential use of V genes of any particular VH family or VL group, as the expressed V genes belong to four different VH families and four V kappa groups, and include V lambda 1 and V lambda 2. We hypothesize that Ag selection accounts for the restriction in V gene usage among CH lymphomas.     

Origin of the autoreactive anti-type II collagen response. II. Specificities, antibody isotypes and usage of V gene families of anti-type II collagen B cells

Autoantibodies play an important role in the pathogenesis of type II collagen-induced arthritis in mice. We have earlier reported a high frequency of cells producing anti-CII autoantibodies and a low frequency of cells producing multispecific antibodies, in regional lymph nodes 9 to 11 days after primary immunization with CII. It is shown here that anti-CII antibodies produced during primary immune response are IgG-antibodies mainly of IgG2a, IgG1 and IgG2b subclasses while IgM antibodies dominate primary responses elicited by OVA and denatured CII as analyzed with a large panel of hybridomas. Anti-CII antibodies generated during the primary response recognize at least five different epitopes on the CII molecule. The specificities of these antibodies for various epitopes result from combinational association of products encoded by genes derived from various VH and VK families and/or by the occurrence of somatic mutations. It is suggested that the primary anti-CII autoantibody response involves activation of memory B cells and is in this aspect different from the origin of "natural" autoantibodies.     

Nucleotide sequence analysis of the V regions of two IgM cold agglutinins. Evidence that the VH4-21 gene segment is responsible for the major cross-reactive idiotype.

Cold agglutinins are human autoantibodies, usually of the IgM class, which agglutinate RBC at low temperature. The major subset recognizes the I/i carbohydrate Ag, and many of these antibodies bear cross-reacting idiotypic determinants. An anti-idiotypic mAb that is specific for one of the idiotopes largely confined to cold agglutinins has been used to identify and monitor tumor cells that secrete these molecules in two patients. The tumor cells were immortalized with EBV and the idiotope-positive lines used to investigate the utilization of the VH and VL genes by these antibodies. Nucleotide sequence analysis of the two cold agglutinins (FS-1 and FS-2) revealed the utilization of a single common gene segment, VH4-21. Serologic analysis documented that only human antibodies utilizing the VH4-21 gene segment were reactive in the idiotope assay, other VHIV antibodies as well as a panel of antibodies derived from other VH families being negative. The DH, JH, VK, and JK gene segments of FS-1 and FS-2 were structurally distinct. These data suggest that the structural basis for the cross-reactive idiotope as well as cold agglutinin activity is the VH4-21 gene segment. A nucleotide change in H chain CDR1 of both cold agglutinins results in the substitution of an aspartic acid residue for glycine at position 31, suggesting that this amino acid might be critical to recognition of the red cell Ag.     

Ig repertoire of human polyspecific antibodies and B cell ontogeny.

A total of 463 EBV Ig-secreting clones were derived from embryonic tissues, cord blood, and adult peripheral blood. Subcloning and analysis of the H and K loci (germline vs rearranged DNA status) of 44 primary clones insured clonality in at least 92% of cases. Whatever the cell origin, a somewhat constant proportion of clones (i.e., 11 to 16%) expressed polyspecific antibodies when tested on a panel of nine Ag, including self-Ag. The VH and VK repertoires have been studied using VH1-VH6 and VK1-VK4 family-specific probes. For all EBV clones the VH and VK utilization was similar to that of the normal untransformed population. A correlation was observed between the level of expression and the gene number for VH, whereas a clear distortion appeared for VK. Moreover, the usage pattern of VH and VK families of the polyspecific clones did not significantly differ from that of clones of unknown specificity, suggesting that polyspecificity was not linked to a restricted repertoire.     

Simultaneously arising Ly-1(CD5) B cell lymphomas have identical expressed IgH and kappa-genes but different nonproductive heavy chain rearrangements.

A group of CD5(Ly-1) B cell lymphomas are described. They were derived from mice which received a common pool of syngeneic mouse spleen cells. Southern blot analysis revealed that the lymphomas exhibited an unusual set of Ig gene rearrangements. Six lymphomas analyzed had either of two rearrangement patterns. EcoRI restriction digests of tumor DNA probed for rearrangements in the JH region, resulted in restriction fragments of 4.7 and 5.6 kb or of 4.7 and 8.5 kb. Each had an identical HindIII restriction fragment identified when probed for kappa gene rearrangements. Inasmuch as several B cell lymphomas from mice receiving a common pool of spleen cells had identical kappa-rearrangements and one identical IgH rearrangement, it was important to determine the DNA sequence of expressed IgH and kappa-genes. Each tumor was found to have identical nucleotide sequences of VH-DH-JH and VK-JK. The nonproductive IgH rearrangements each consisted of incomplete DH-JH rearrangements. The 8.5-kb EcoRI fragment was generated from a DFL16 gene segment rearranged into JH3, and the 5.6-kb fragment was generated from DQ52 rearranged into JH)1. We conclude that these Ly-1 B tumors are most likely derived from a single clone of cells which underwent a secondary rearrangement on the nonproductive allele after kappa-rearrangement had occurred. The alternate possibility of independently arising lymphomas with identical expressed VH and VK sequences is discussed.     

Self-reactive repertoire of tight skin (TSK/+) mouse: immunochemical and molecular characterization of anti-cellular autoantibodies.

The tight skin (TSK/+) mouse has been proposed as an experimental model for progressive systemic sclerosis because of the biochemical alterations in collagen synthesis and pathological similarities to the human disease. Here, we report the analysis of tight skin mice sera for the presence of anti-cytoplasmic and anti-nuclear autoantibodies and determination of the frequency of hybridomas producing anti-cellular autoantibodies. The binding specificity of TSK mAbs to nuclear and cytoplasmic antigens such as keratin, actin, vimentin, and mitochondria was determined. Of 71 monoclonal antibodies that we have studied, only 3 appear to bind to foreign as well as self-antigens, indicating that the majority of these antibodies do not belong to the class of natural autoantibodies. Our results also showed that the frequency of hybridomas producing anti-nuclear and anti-cytoplasmic antibodies was higher in TSK mice than in C57BL/6 pa/pa, the control mouse strain, used in these studies. The results of the analysis of V gene usage showed that the majority of anti-cytoplasmic and anti-nuclear antibodies are encoded by genes from a restricted number of VH and VK genes families. In the sera of TSK mice we have detected the presence autoantibodies specific for cytoplasmic antigens in addition to anti-nuclear and anti-topoisomerase I antibodies which are characteristic of scleroderma. Since the presence of anti-cytoplasmic antibodies has not been described in scleroderma, the significance of their production in tight skin mice is not clear. However, the presence of such autoantibodies in the animal model provides a basis for investigation of this type of antibodies in human disease.