Switch region content of hybridomas: the two spleen cell Igh loci tend to rearrange to the same isotype

We have examined the switch region content of 25 hybridomas that secret antibodies of various isotypes with specificity for phosphocholine or glycoproteins of herpes simplex virus. These Southern hybridization experiments included probes for the murine JH region as well as probes for the mu, gamma 3, gamma 1, gamma 2b, gamma 2a, and alpha switch regions. For 22 of the hybridomas, the deletion model of the heavy chain switch fits the data well--all switch regions upstream of the rearranged (and expressed) switch regions are deleted and all switch regions downstream remain in the germline configuration. As exceptions to a simple deletion model of the switch recombination, we have observed two, and perhaps three, examples of switch region rearrangements downstream of an expressed heavy chain gene. The 25 hybridoma DNA samples include 28 rearranged gamma switch regions; the sizes of at least 25 of these rearranged fragments are consistent with recombination in the tandemly repeated sequences associated with gamma genes. For those hybridomas with two spleen cell-derived Igh loci, including three mu-expressers, three gamma 3-expressers, four gamma 1-expressers, and one gamma 2b-expresser, the two loci tend to be rearranged to the same switch region, suggesting that the heavy chain switch rearrangement is an isotype-specific event. The exceptions within this group include three hybridomas in which the switch seems to be incomplete--on one chromosome the JH complex is rearranged to the S gamma 3 region, while on the other it remains associated with the S mu region. A second group of hybridomas, which includes four gamma 3-expressers, have both gamma 3 and gamma 1 switch rearrangements. Each of these four hybridomas includes three rearranged JH segments, suggesting that they may be the result of an unusual differentiative pathway or a technical artifact. These experiments suggest that the heavy chain switch rearrangement in normal spleen cells is a deletion event that occurs within tandemly repeated elements. The rearrangement is mediated by factors with partial, or perhaps complete, isotype specificity.     

Abnormal recombination of Igh D and J gene segments in transformed pre-B cells of scid mice

Studies of Ig and TCR genes in transformed lymphocytes of scid mice have revealed aberrant DNA rearrangements. Here we present a more detailed analysis of the Igh gene recombination in nine scid pre-B cell lines transformed by Abelson murine leukemia virus. We found 85% of the rearranged Igh alleles to contain abnormal Dh-Jh deletions of varying size. All of these deletions encompassed Jh elements and extended into the Igh enhancer region, occasionally involving the switch (S) region of the C mu gene. Some of these rearrangements removed most of the Dh elements, but none appeared to extend to the Vh genes. DNA sequence analysis of the two abnormally rearranged Igh alleles in one pre-B cell line showed that no Dh or Jh coding sequences were retained at the recombination sites though heptamer-like (CACTGTG) recognition signal sequences were present in the absence of nonamer (GGTTTTTGT) recognition signal sequences. These results imply that a deregulated recombinase activity may be responsible for the abnormal Dh-Jh deletions and the absence of Vh-Dh joining in established lines of Abelson murine leukemia virus-transformed scid pre-B cells.     

Immunoglobulin V gene replacement is caused by the intramolecular DNA deletion mechanism.

Circular DNA resulting from V gene replacement was studied with an A-MuLV transformed cell line containing ablts. This cell line undergoes V gene replacement at elevated temperatures in the immunoglobulin (Ig) heavy chain (H) gene. Examination of circular DNA revealed that a heptamer-related sequence (TACTGTG) within the coding region of VDJ was joined to the recombination signal sequence (RSS) of a germline VH segment. This provides direct evidence for a intramolecular DNA deletion mechanism for V gene replacement. In the pre-B cell line as well as in in vivo lymphocytes, unusual circular DNAs were found which were structurally similar to the V gene replacement circles. They represented excision products of the deletion type recombination between one complete RSS and a heptamer-like sequence in the Ig H region.     

Products and implied mechanism of H chain switch recombination

The Ig H chain switch is a DNA recombination event. The recombination occurs between two or more switch regions, areas of tandem sequence duplication that lie upstream of the corresponding H chain C region genes. We have determined the DNA sequence at four recombination sites in three molecularly cloned, rearranged switch regions. All eight donor and recipient recombination sites are at the common pentamers GGGGT, GAGCT, and GGTGG. One of the switch recombination events is an inversion of S gamma 3 sequences. Another of the recombinational events is an internal S gamma 1 deletion, which may be switch enzyme mediated. These results, together with other switch recombination site sequences, suggest that switch recombination is mediated by cutting enzymes with modest specificity and religation enzymes with no specificity.     

Recombination events near the immunoglobulin Cmu gene join variable and constant region genes, switch heavy-chain expression, or inactivate the locus

Immunoglobulin heavy-chain expression is initiated by recombination between a variable region (VH) gene and one of several joining region (JH) genes located near the mu constant region (Cmu) gene, and the active VH gene can subsequently switch to another CH gene. That the general mechanism for CH switching involves recombination between sites within the JH-Cmu intervening sequence and the 5' flanking region of another CH gene is supported here by Southern blot hybridization analysis of eight IgG- and IgA-secreting plasmacytomas. An alternative model requiring successive VH linkage to similar JH clusters near each CH gene is shown to be very unlikely since the mouse genome appears to contain only one complement of the JH locus and no JH gene was detectable within large cloned sequences flanking germline C gamma 3 and C gamma 1 genes. Thus, VH-JH joining and CH switching are mediated by separate regions of "the joining-switch" or J-S element. In each plasmacytoma examined, the J-S element had undergone recombination within both the JH locus and the switch region and was shown to be linked to the functional CH gene in an IgG3, and IgG1, and three IgA secretors. Both JH joining and CH switching occurred by deletion of DNA. Switch recombination occurred at more than one site within the J-S element in different lines, even for recombination with the same CH gene. Significantly, although heavy-chain expression is restricted to one allele ("allelic exclusion"), all rearranged in each plasmacytoma. Some rearrangements were aberrant, involving, for example, deletion of all JH genes from the allele. Hence, an error-prone recombination machinery may account for allelic exclusion in many plasmacytomas.     

Multiple genomic defects result in an alternative RNA splice creating a human gamma H chain disease protein

Heavy chain diseases (HCD) are human lymphoproliferative disorders in which a clonal B cell population produces Ig molecules made of truncated H chains without associated L chain. We characterized the rearranged H chain gene and its mRNA from the leukemic cells of a patient (RIV) with gamma-HCD. The abnormal RIV serum Ig consisted of shortened, dimeric gamma 1-chains which had an amino terminus within the hinge region. RIV lymphoblasts possessed a foreshortened (1200 bp) gamma 1-mRNA which had sequences for only the leader, hinge, second, and third constant region domains (CH2 + CH3), but lacked variable (VH) and CH1 information. Sequence of the productive gamma 1 allele revealed it had undergone VH-JH and H chain class switch recombinations. However, normal RNA splice sites had been eliminated by a DNA insertion/deletion (VH acceptor site), mutations (JH donor site), or a large deletion (CH1 region). Inserted sequences were of non-Ig and apparently non-genomic origin. These DNA alterations resulted in aberrant mRNA processing in which the leader region was spliced directly to the hinge region, accounting for the HCD protein.     

Complete nucleotide sequence of the murine gamma 3 switch region and analysis of switch recombination sites in two gamma 3-expressing hybridomas

The heavy chain isotype switch is mediated by a DNA rearrangement between a donor switch region (usually mu) and a recipient switch region (gamma, epsilon, or alpha). Switch regions lie upstream of the appropriate heavy chain constant region gene and are composed of simple sequences repeated in tandem. It is not known to what extent the tandemly repeated sequences are important to the heavy chain switch recombination, and to what extent other features of switch region sequences might contribute to the switch process. We studied switches to the gamma 3 isotype by sequencing the entire gamma 3 switch region. This switch region is composed of forty-four 49 base pair units repeated in tandem. These repeated units share modest homology with the mu switch region repeated elements. Evolution of the gamma 3 switch region seems to involve insertions and deletions of the 49mer elements. We also molecularly cloned rearranged switch regions from two gamma 3-expressing hybridomas and determined the DNA sequences at the mu-gamma 3 recombination sites. We located these switch recombination sites within the germ-line gamma 3 switch region, as well as switch recombination sites from two myelomas. All four sites are found in the 5' one-third of the gamma 3 switch region. We discuss some additional trends in the sequence data near these four recombination sites.     

An immunoglobulin heavy chain variable region gene is generated from three segments of DNA: VH, D and JH

We have determined the sequences of separate germline genetic elements which encode two parts of a mouse immunglobulin heavy chain variable region. These elements, termed gene segments, are heavy chain counterparts of the variable (V) and joining (J) gene segments of immunoglobulin light chains. The VH gene segment encodes amino acids 1-101 and the JH gene segment encodes amino acids 107-123 of the S107 phosphorylcholine-binding VH region. This JH gene segment and two other JH gene segments are located 5' to the mu constant region gene (Cmu) in germline DNA. We have also determined the sequence of a rearranged VH gene encoding a complete VH region, M603, which is closely related to S107. In addition, we have partially determined the VH coding sequences of the S107 and M167 heavy chain mRNAs. By comparing these sequences to the germline gene segments, we conclude that the germline VH and JH gene segments do not contain at least 13 nucleotides which are present in the rearranged VH genes. In S107, these nucleotides encode amino acids 102-106, which form part of the third hypervariable region and consequently influence the antigen-binding specificity of the immunoglobulin molecule. This portion of the variable region may be encoded by a separate germline gene segment which can be joined to the VH and JH gene segments. We term this postulated genetic element the D gene segment, referring to its role in the generation of heavy chain diversity. Essentially the same noncoding sequences are found 3' to the VH gene segment and as inverse complements 5' to two JH gene segments. These are the same conserved nucleotides previously found adjacent to light chain V and J gene segments. Each conserved sequence consists of blocks of seven and ten conserved nucleotides which are separated by a spacer of either 11 or 22 nonconserved nucleotides. The highly conserved spacing, corresponding to one or two turns of the DNA helix, maintains precise spatial orientations between blocks of conserved nucleotides. Gene segments which can join to one another (VK and JK, for example) always have spacers of different lengths. Based on these observations, we propose a model for variable region gene rearrangement mediated by proteins which recognize the same conserved sequences adjacent to both light and heavy chain immunoglobulin gene segments.     

Diverse organization of immunoglobulin VH gene loci in a primitive vertebrate.

The immunoglobulin (Ig) heavy chain variable (VH) gene family of Heterodontus francisci (horned shark), a phylogenetically distant vertebrate, is unique in that VH, diversity (DH), joining (JH) and constant region (CH) gene segments are linked closely, in multiple individual clusters. The V regions of 12 genomic (liver and gonad) DNA clones have been sequenced completely and three organization patterns are evident: (i) VH-D1-D2-JH-CH with unique 12/22 and 12/12 spacers in the respective D recombination signal sequences (RSSs); VH and JH segments have 23 nucleotide (nt) spacers, (ii) VHDH-JH-CH, an unusual germline configuration with joined VH and DH segments and (iii) VHDHJH-CH, with all segmental elements being joined. The latter two configurations do not appear to be pseudogenes. Another VH-D1-D2-JH-CH gene possesses a D1 segment that is flanked by RSSs with 12 nt spacers and a D2 segment with 22/12 spacers. Based on the comparison of spleen, VH+ cDNA sequences to a germline consensus, it is evident that both DH segments as well as junctional and N-type diversity account for Ig variability. In this early vertebrate, the Ig genes share unique properties with higher vertebrate T-cell receptor as well as with Ig and may reflect the structure of a common ancestral antigen binding receptor gene.     

(AGCTG) (AGCTG) (AGCTG) (GGGTG) as the primordial sequence of intergenic spacers: the role in immunoglobulin class switch

The means employed for immunoglobulin heavy chain class switch appears to be no different from that by which meiotic intergenic crossing-overs at accomplished. As with other intergenic spacers, the 5' noncoding sequence of each Ig CH (immunoglobulin heavy chain constant region) gene apparently undergoes unconstrained sequence changes due to randomly sustained base substitutions, deletions, and duplications. Yet, there remains sufficient regional sequence homology between the Ig Cmu 5' noncoding sequence and those of its somatic recombination partners, e.g., Ig C gamma 1, Ig C gamma 2b, Ig C alpha, because each of these 5' noncoding sequences is made of multiple copies in various stages of degeneracy of one primordial 20 base pair-long sequence: (AGCTG) (AGCTG) (AGCTG) (GGGTG).     

DNA sequences at immunoglobulin switch region recombination sites.

The immunoglobulin heavy chain switch from synthesis of IgM to IgG, IgA or IgE is mediated by a DNA recombination event. Recombination occurs within switch regions, 2-10 kb segments of DNA that lie upstream of heavy chain constant region genes. A compilation of DNA sequences at more than 150 recombination sites within heavy chain switch regions is presented. Switch recombination does not appear to occur by homologous recombination. An extensive search for a recognition motif failed to find such a sequence, implying that switch recombination is not a site-specific event. A model for switch recombination that involves illegitimate priming of one switch region on another, followed by error-prone DNA synthesis, is proposed.     

Heavy chain diversity region segments of the channel catfish: structure, organization, expression and phylogenetic implications

Circular DNA, derived from lymphocytes of juvenile channel catfish, was used to construct lambda libraries that were screened to identify the products of immunoglobulin DH-JH excision events. Clones were characterized that contained DH to JH recombination signal joints. The signal joints represented 23-bp recombination signal sequences (RSS) identical to germline JH segments that were adjacent to DH 12-bp RSS elements. DH flanking regions within the clones were used to probe a genomic library. Three germline DH gene segments containing 11-19 bp coding regions flanked by 12-bp RSS elements with conserved heptamers and nonamers were identified. The DH locus is closely linked to the JH locus, and Southern blots indicate that the DH segments represent different single member gene families. Analysis of H chain cDNA shows that each germline DH segment was expressed in functional VDJ recombination events involving different JH segments and members of different VH families. Several aspects of CDR3 junctional diversity were evident, including deletion of coding region nucleotides, N- and P-region nucleotide additions, alternate DH reading frame utilization, and point mutations. Coding region motifs of catfish DH segments are phylogenetically conserved in some DH segments of higher vertebrates. These studies indicate that the structure, genomic organization, and recombination patterns of DH segments typically associated with higher vertebrates evolved early in vertebrate phylogeny at the level of the bony fish.     

Isotype switching in human B lymphocyte malignancies occurs by DNA deletion: evidence for nonspecific switch recombination

The mechanism and specificity of isotype switching operative in human B lymphocytes was investigated by a determination of immunophenotype and immunoglobulin heavy and light chain gene status in a panel of human Ig-, IgM, IgG, and IgA B cell malignancies. Regardless of specific tumor type or switched immunophenotype, isotype switching was accompanied by the rearrangement of the expressed CH gene downstream of VDJH, with concomitant deletion of upstream CH genes in all cases. On the allelically excluded chromosome, 25% of the IgG or IgA tumors have retained C mu, and 75% have deleted C mu. The 5' recombination breakpoints for both productive and excluded alleles lie within or near S mu, 3' of the enhancer. No correlation between the extent of allelically excluded CH deletions and the isotype produced by the tumor was observed. Excluded chromosome deletion endpoints were found 5', equal to, or 3' of productive chromosome deletion endpoints. Furthermore, we have identified at least one IgM+ tumor that has undergone abortive CH gene deletions and have observed several unanticipated switch region deletions and potential translocations. The data suggest that isotype switching in human B cells occurs by a nonsubclass- and nonclass-specific switch recombinase.     

Unique sequences are interspersed among tandemly repeated elements in the murine gamma 1 switch segment.

Early in its differentiative pathway, a given B lymphocyte expresses immunoglobulin of the mu heavy chain class (IgM). Subsequent differentiative processes may involve rearrangement within the immunoglobulin heavy chain chromosomal locus to enable cells of the same lineage to synthesize immunoglobulins of other heavy chain classes (e. g. IgG, IgE or IgA), but with specificity for the same antigen as the original IgM molecule. Switch recombination, the molecular event which facilitates this chromosomal rearrangement, has been shown to occur between segments of DNA consisting of tandemly repeated unit sequences. These DNA segments have been functionally defined as switch regions. We have cloned the gamma 1 switch region from the BALB/c germline, and have demonstrated that significantly divergent sequence elements are interspersed among the tandemly repeated units characteristic of this switch region. We show that these unique elements exist in at least three copies within the switch segment, and discuss the implications of this novel and previously unreported primary structure.     

Mutations, duplication, and deletion of recombined switch regions suggest a role for DNA replication in the immunoglobulin heavy-chain switch.

The heavy-chain switch from immunoglobulin M (IgM) expression to IgA expression is mediated by a recombination event between segments of DNA called switch regions. The switch regions lie two to six kilobases upstream of the mu and alpha constant region coding segments. Switch recombination to IgA expression results in a recombinant mu-alpha switch region upstream of the expressed alpha constant region gene. We have characterized the products of switch recombination by a lymphoma cell line, I.29. Two sets of molecular clones represent the expected products of simple mu to alpha switches. Five members of a third set of molecular clones share the same recombination site in both the mu and the alpha switch regions, implying that the five molecular clones were derived from a single switch recombination event. Surprisingly, the five clones fall into two sets of sequences, which differ from each other by several point mutations and small deletions. Duplication of switch region sequences are also found in these five molecular clones. An explanation for these data is that switch recombination involves DNA synthesis, which results in nucleotide substitutions, small deletions, and duplications.