Detection of two allotype-(Ig-1)-linked minor histocompatibility loci by the use ofH-2-restricted cytotoxic lymphocytes in congenic mice

Cytotoxic lymphocytes (CTL) were generated betweenIg-1-congenic strains BALB/c(H-2^d,Ig-1^a) andC.B-17(H-2^d,Ig-1^b) by cross-immunization in both directions and rechallenge in vitro. The effector cell populations specifically lysed target cells sharing both theH-2 haplotype and theIg-1 allele of the sensitizing strain. B- and T-cell blasts were equally good targets, suggesting thatH-2-restricted cytotoxic lymphocytes are not directed against serologically defined conventional allotypic determinants, but probably against minor histocompatibility antigens controlled by genes linked to theIg-1 complex. Competition experiments using cold target cells from a series ofIg-1^b-congenic strains of the BALB/c background (BAB-14, C.B-17, C.B-26) revealed two not yet described minor histocompatibility loci linked to theIg-1 complex: We could demonstrate that BALB/c anti-C.B-17 effector cells recognize at least two distinct antigenic determinants on C.B-17 target cells, but only one on target cells from BAB-14, which carries a recombinantIg-1 complex. From these results we conclude that one of the minor histocompatibility antigens, designated as H(C_H), is encoded by a gene linked to the heavy-chain constant-region (C_H) genes, whereas the second minor histocompatibility antigen, designated as H(V_H), is coded for by a gene linked to the heavy-chain variable-region (V_H) genes. These two new genetic markers may be useful for further analysis of the mouseIg-1 complex because the analysis of the H(C_H) and H(V_H) genes may facilitate the search for recombinants in that chromosomal region.     

MouseV k gene classification by nucleic acid sequence similarity

Analyses of immunoglobulin (Ig) variable (V) region gene usage in the immune response, estimates ofV gene germline complexity, and other nucleic acid hybridization-based studies depend on the extent to which such genes are related (i. e., sequence similarity) and their organization in gene families. While mouseIgh heavy chainV region (V _H ) gene families are relatively well-established, a corresponding systematic classification ofIgk light chainV region (V _k ) genes has not been reported. The present analysis, in the course of which we reviewed the known extent of theV _k germline gene repertoire andV _k gene usage in a variety of responses to foreign and self antigens, provides a classification of mouseV _k genes in gene families composed of members with >80% overall nucleic acid sequence similarity. This classification differed in several aspects from that ofV _H genes: only someV _k gene families were as clearly separated (by >25% sequence dissimilarity) as typicalV _H gene families; mostV _k gene families were closely related and, in several instances, members from different families were very similar (>80%) over large sequence portions; frequently, classification by nucleic acid sequence similarity diverged from existing classifications based on amino-terminal protein sequence similarity. Our data have implications forV _k gene analyses by nucleic acid hybridization and describe potentially important differences in sequence organization betweenV _H andV _k genes.     

Abnormalities in DNA rearrangements of immunoglobulin gene loci in precursor B cells derived from X-linked agammaglobulinemia patient and a severe combined immunodeficiency patient

In an attempt to characterize the genes that cause immunodeficiencies such as X-linked agammaglobulinemia (XLA) and severe combined immunodeficiency (SCID) we established precursor B-cell lines by transforming the patients' bone marrow cells with Epstein-Barr viruses. DNA rearrangements of immunoglobulin J_H gene loci were observed on both chromosomes in pre-B cells derived from an XLA patient. We cloned and characterized both rearranged bands from one cell line. Both of the rearrangements occurred between D _H and J _H gene loci without the V_H DH structure. On the other hand, JH gene loci retained the germline configuration on both chromosomes in almost all the transformants derived from a SCID patient that had been determined according to their surface markers, to be in an early precursor B-cell stage. The implications of the observations are discussed.     

Rapid cloning of any rearranged mouse immunoglobulin variable genes

Immunoglobulins (Ig) have been the focus of extensive study for several decades and have become an important research area for immunologists and molecular biologist. The use of polymerase chain reaction (PCR) technology has accelerated the cloning, sequencing, and characterization of genes of the immune system. However, cloning and sequencing the Ig variable (V) genes using the PCR technology has been a challenging task, primarily due to the very diverse nature of Ig V region genes. We have developed a simple, rapid, and reproducible PCR-based technique to clone any rearranged mouse Ig heavy or light chain genes. A close examination of all Ig heavy and light chain V gene families has resulted in the design of 5 and 3 universal primers from regions that are highly conserved across all heavy or light chain V gene families, and the joining or constant regions, respectively. We present our strategy for designing universal primers for Ig V gene families. These primers were able to rapidly amplify the rearranged Ig V genes, belonging to diverse Ig V gene families from very different cell lines, i.e., J558, MOPC-21, 36–60, and a chicken ovalbumin specific B-cell hybridoma. In addition, the present study provides the complete alignment of nucleotide sequences of all heavy and light chain variable gene families. This powerful method of cloning Ig V genes, therefore, allows rapid and precise analysis of B-cell hybridomas, B-cell repertoire, and B-cell ontogeny.The nucloetide sequence data reported in this paper have been submitted to the EMBL/GenBank nucleotide sequence database and have been assigned the accession number U32111     

A cross-over chromosome combiningIg heavy chain genes of two mouse strains

Two congenic strains of mice were bred in Konstanz that bear theIg heavy chain allotype gene of the C57BL/6 (Ig-1 ^b ) in a BALB/c background genome. One line (CB-8K) underwent eight backcross generations to BALB/c before sister-brother mating was initiated. For the other line (CB-16KN) backcrossing was continued for eight further generations, then a homozygousIg-1 ^b /Ig-1 ^b strain was produced by sister-brother mating. Both lines were tested for four V_H markers of the BALB/c and one of the C57BL parent. The CB-16KN strain expressed the C57BL marker V_HNP^b together with the C57BL allotype marker, and failed to express the three BALB/c markers, V_HDEX, V_HS117, V_HphOx and V_HNP^a. It thus resembled the CB-20 strain.Strain CB-8K expressed the V_HNP^b marker of C57BL but also all the four BALB/c markers that were tested. The strain appeared more heterogeneous than the CB-16KN strain, and a subline was bred from two exceptional mice that did not express the V_HNP^b marker. This subline (CB-8KN) expressed the BALB/c marker V_HNP^a regularly, and was negative for the V_HNP^b marker. It thus resembles the BAB-14 line.The crossing over event thus must have happened in one of the two meioses, which led to the CB-8K line. As BAB-14 is derived in an analogous manner to a branch of the backcross of Potter and Lieberman, which ended up in CB-20, the unexpected finding is discussed that two independent crossing over events (in CB-8KN and BAB 14) within theIg heavy chain gene region have taken place at approximately the same stage of two breeding programs.Recipient of an EMBO fellowship during part of the study.     

Immunoglobulin light chain class multiplicity and alternative organizational forms in early vertebrate phylogeny

The prototypic chondrichthyan immunoglobulin (Ig) light chain type (type I) isolated from Heterodontus francisci (horned shark) has a clustered organization in which variable (V), joining (J), and constant (C) elements are in relatively close linkage (V-J-C). Using a polymerase chain reaction-based approach on a light chain peptide sequence from the holocephalan, Hydrolagus colliei (spotted ratfish), it was possible to isolate members of a second light chain gene family. A probe to this light chain (type II) detects homologs in two orders of elasmobranchs, Heterodontus, a galeomorph and Raja erinacea (little skate), a batoid, suggesting that this light chain type may be present throughout the cartilaginous fishes. In all cases, V, J, and C regions of the type II gene are arranged in closely linked clusters typical of all known Ig genes in cartilaginous fishes. All representatives of this type II gene family are joined in the germline. A third (kappa-like) light chain type from Heterodontus is described. These findings establish that a degree of light chain class complexity comparable to that of the mammals is present in the most phylogenetically distant extant jawed vertebrates and that the phenomenon of germline-joined (pre-rearranged) genes, described originally in the heavy chain genes of cartilaginous fishes, extends to light chain genes.     

A single VH gene segment encodes the immune response to phosphorylcholine: Somatic mutation is correlated with the class of the antibody

The immune response in BALB/c mice to phosphorylcholine is highly restricted in its heterogeneity. Of the 19 immunoglobulins binding phosphorylcholine for which complete V_H-segment amino acid sequences have been determined, 10 employ a single sequence, denoted T15 after the prototype V_H sequence of this group of antibodies. The remaining 9 of these V_H segments are variants differing by 1 to 8 residues from the T15 sequence. Using a cloned V_H cDNA probe complementary to the T15 sequence, we isolated from a mouse sperm genomic library clones corresponding to four V_H gene segments that by DNA sequence analysis are >85% homologous to one another. These four V_H gene segments have been denoted the T15 V_H gene family. These V_H gene segments are most, if not all, of the germline V_H gene segments that could encode the V_H sequences of antibodies that bind phosphorylcholine. One of these four genes contains the T15-V_H-coding sequence. When the T15-family V_H gene segments were compared with the complete V_H protein sequences of 19 hybridoma and myeloma immunoglobulins that bind phosphorylcholine, several striking conclusions could be drawn. First, all of these V_H regions must have arisen from the germline T15 V_H gene segment. Thus virtually the entire immune response to phosphorylcholine is derived from a single V_H-coding sequence. Nine of the 19 V_H regions were variants differing from the T15-V_H-coding sequence and, accordingly, must have arisen by a mechanism of somatic diversification. Second, the variants appear to be generated by a somatic mutation mechanism. They cannot be explained by recombination or gene conversion among members of the T15 gene family. Third, somatic mutation is correlated with the class of the antibody. All of the somatic variation is found in the V_H regions derived from antibodies of the IgA and IgG classes. The IgM molecules express the germline T15 V_H gene segment exclusively.     

The V<Subscript>H</Subscript> gene repertoire of splenic B cells and somatic hypermutation in systemic lupus erythematosus

In systemic lupus erythematosus (SLE) it has been hypothesized that self-reactive B cells arise from virgin B cells that express low-affinity, nonpathogenic germline V genes that are cross-reactive for self and microbial antigens, which convert to high-affinity autoantibodies via somatic hypermutation. The aim of the present study was to determine whether the V_H family repertoire and pattern of somatic hypermutation in germinal centre (GC) B cells deviates from normal in SLE. Rearranged immunoglobulin V_H genes were cloned and sequenced from GCs of a SLE patient's spleen. From these data the GC V gene repertoire and the pattern of somatic mutation during the proliferation of B-cell clones were determined. The results highlighted a bias in V_H5 gene family usage, previously unreported in SLE, and under-representation of the V_H1 family, which is expressed in 20–30% of IgM⁺ B cells of healthy adults and confirmed a defect in negative selection. This is the first study of the splenic GC response in human SLE.     

Human Vκ immunoglobulin gene number: Implications for the origin of antibody diversity

To assess the relative contributions of germline versus somatically mutated genes in the human immune system, we have examined the size of the kappa light-chain variable region (V_κ) gene pool. Two cloned kappa subgroup 1 (V_κ1) gene probes detected the same family of 15 to 20 crosshybridizing restriction fragments in human DNA, whereas flanking region probes detected fewer hybridizing fragments. Most of the hybridizing bands represent single-copy genes, as judged by a “gene titration” experiment. Furthermore, the number of hybridization bands is a good estimate of the haploid gene number, since we observed little polymorphism of restriction sites in the V_κ locus of eight unrelated people. A cloned V_κ3 probe hybridized to essentially the same 15–20 genes in human DNA as the V_κ1 probes. These results strongly suggest that a discrete family of 15–20 genes constitutes a large proportion of the V genes from three of the four V_κ subgroups. The small number of V_κ genes in the human genome supports the idea that somatic mutation plays a major role in the origin of antibody diversity in man.     

Analysis of human V H gene repertoire expression in peripheral CD19+ B cells

Using CD19 B-cell selection and polymerase chain reaction-amplified cDNA libraries, we analyzed the peripheral immunoglobulin heavy chain variable repertoire of three healthy adult donors. Here we report that most of the CD19+ circulating B cells expressed unmutated V _H-D-J_H rearrangements. By specific V _H family hybridization, we show that V _H gene family utilization in the periphery roughly corresponds to the complexity of these families in the germline and appears to be relatively constant among the analyzed subjects. However, sequence data of clones picked at random from one IgM cDNA library reveals that in spite of this random utilization, the V _H gene expression in naive circulating B cells is highly biased towards the expression of a limited set of V _H genes. As previously reported by others, this restricted mechanism is also found for the D and J _H segments.The nucleotide sequence data reported in this paper have been submitted to the GenBank/EMBL nucleotide sequence database and have been assigned the accession numbers Z47213-Z47243 and Z47349     

Idiotypic diversity and variable region gene usage by mouse anti-HLA-DQ3 mAb

The anti-HLA-DQ3 monoclonal antibodies (mAb) KS13, SO1, SO2, SO3, SO4, and SO5 recognize spatially close but distinct antigenic determinants, since they crossinhibit each other in their binding to HLA-DQ3 antigens, but do not share idiotopes recognized in their antigen combining site by syngeneic and anti-id antisera and mAb. Furthermore, mAb SO1, SO3, SO4, and SO5 react also with HLA-DQ allospecificities other than HLA-DQ3. Sequence analysis of the heavy (V _H ) and light (V _L ) chain variable region of the six mAb revealed preferential usage of V _H 36–60 and V _K 12/13 gene families. However, the individual V _H and V _L germline gene usage by the six mAb is diverse and the utilization of D, J _H , and J _L gene segments is heterogeneous. The diverse usage of V _H and V _L gene segments and heterogeneous amino acid sequences of V _H and V _L CDR, together with the heterogeneous idiotypic profile, may reflect the complexity of the determinants recognized by the six mAb on HLA-DQ3 antigens. The results we have presented provide for the first time information about the structural basis of the diversity of antibodies recognizing human histocompatibility antigens.The nucleotide sequence data reported in this Papershave been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers L20499, L20957, L20961, L24557, L24558 and L20962, respectively, for V _H region genes, and L20956, L20958, L24555, L24556, L20959, and L20960, respectively, for V _L region genes     

Analysis of the expressed heavy chain variable-region genes of Macaca fascicularis and isolation of monoclonal antibodies specific for the Ebola virus' soluble glycoprotein

The cynomolgus macaque, Macaca fascicularis, is frequently used in immunological and other biomedical research as a model for man; understanding it's antibody repertoire is, therefore, of fundamental interest. The expressed variable-region gene repertoire of a single M. fascicularis, which was immune to the Ebola virus, was studied. Using 5′ rapid amplification of cDNA ends with immunoglobulin (Ig)G-specific primers, we obtained 30 clones encoding full-length variable, diversity, and joining domains. Similar to the human V_H repertoire, the M. fascicularis repertoire utilized numerous immunoglobulin heavy variable (IGHV) gene fragments, with the V_H3 (41%), V_H4 (39%), and V_H1 (14%) subgroups used more frequently than the V_H5 (3.9%) or V_H7 (1.7%) subgroups. Diverse immunoglobulin heavy joining (IGHJ) fragments also appeared to be utilized, including a putative homolog of JH5β gene segment identified in the related species Macaca mulatta, Rhesus macaque, but not in humans. Although the diverse V region genes in the IgG antibody repertoire of M. fascicularis had likely undergone somatic hypermutations (SHMs), they nevertheless showed high nucleotide identity with the corresponding human germline genes, 80–89% for IGHV and 72–92% for IGHJ. M. fascicularis and human V_H genes were also similar in other aspects: length of complementarity-determining regions and framework regions, and distribution of consensus sites for SHMs. Finally, we demonstrated that monoclonal antibodies (mAbs) specific for an Ebola protein could be obtained from M. fascicularis tissue samples by phage display technology. In summary, the study provides new insight into the M. fascicularis V region gene repertoire and further supports the idea that macaque-derived mAbs may be of therapeutic value to humans.     

Deletion mapping of the mouse ornithine decarboxylase-related locus Odc-rs8 within Igh-V

The Odc-rs8 locus belongs to a family of mouse DNA sequences related to the gene encoding ornithine decarboxylase (ODC). Odc-rs8 was mapped by recombinant inbred (RI) strain analysis to the region of Chromosome (Chr) 12 occupied by the variable region genes of the immunoglobulin heavy chain (Igh) complex. In the present study, alleles at Odc-rs8 were shown to cosegregate with those for Igh variable region (Igh-V or V _H) genes among 37 inbred mouse strains that had been characterized previously for their haplotypes at Igh. For a more precise definition of the location of Odc-rs8 relative to Igh-V, DNAs from 17 Abelson murine leukemia virus (A-MuLV)-transformed pre-B cell lines cultured from mice heterozygous at Igh and Odc-rs8 were analyzed for the presence of DNA restriction fragments (RFs) derived from each parental Odc-rs8 allele. These cell lines, each of which has rearranged one or both Igh genes, previously were employed in mapping members of nine V _H gene families by deletion analysis (Brodeur et al. 1988). Comparing the deletion profiles of the cell lines for Odc-rs8 with those for the V _H gene families has located Odc-rs8 ^b within the V_HJ558/V_H3609 gene cluster and Odc-rs8 ^c either within or upstream of the 5-most 9% of V_HJ558, identifying Odc-rs8 as a potentially useful marker for the 5 end of the Igh complex.     

Development and characterization of a recombinant chicken single-chain Fv antibody detecting <Emphasis Type="Italic">Eimeria acervulina</Emphasis> sporozoite antigen

Chicken monoclonal antibody (mAb), 8C3, which is reactive with a sporozoite antigen of Eimeria acervulina, is a potential therapeutic agent against avian coccidiosis caused by Eimeria spp. However, production of large amounts of 8C3 mAb in cell culture system is labor intensive and not cost-effective. Accordingly, recombinant single chain variable fragment (ScFv) antibody was constructed by amplification of the V_H and V_L genes from chicken hybridoma, 8C3 and when expressed in E. coli gave 5 mg l^–1. The expressed protein showed antigen binding activity equivalent to that of the parental mAb. In addition, nucleotide sequence comparison of 8C3 gene to the germline chicken V_L genes suggested that the gene conversion with V pseudogenes might contribute to the diversification of V_L genes in chickens.     

Evolution of pseudogenes in the immunoglobulin V H-gene family of the mouse

A quantitative analysis of the complexity of the J558 V _H -gene family in the mouse immunoglobulin heavy chain (Igh) gene locus has been performed. Considerable variations in the degree of complexity are observed in various Igh haplotypes derived from laboratory mice and wild mice. The BALB/c strain shows the highest degree of complexity of the J558 V _H -gene family when all mice are compared. Multiple gene duplications seem to have occurred in the BALB/c-derived J558 V_H-gene family less than 1–2 million years ago. This dating is supported by the divergence in coding and flanking regions of three strongly homologous V _H -region genes. Two of these genes were generated by the duplication of a pseudogene about 1.5 × 10⁵ years ago. A recent expansion of the J558 V _H -gene family and therefore little time for evolutionary drift may explain why most of the pseudogenes in this family exhibit a largely intact structure. We also describe two V _H -region genes which represent older pseudogenes in states of progressive disintegration.