Rat immunoglobulin E heavy chain locus

A 2100 base-pair long sequence has been established which covers all four constant domains of the rat epsilon-chain. An analysis of messenger RNA from an immunoglobulin E producing rat immunocytoma revealed two separate epsilon-chain mRNA species, 2.3 X 10(3) and 2.8 X 10(3) base-pairs long. The latter mRNA encodes the membrane binding form of the epsilon-chain. The membrane exons which are located approximately 2 X 10(3) base-pairs away from the 3'-side of the CH4 exon were also sequenced. A comparison between the rat and mouse epsilon-chains at the protein sequence level revealed an overall homology of 80% which, as expected, is considerably higher than the homology found between rat and human epsilon-chains. The fourth constant domain together with the two membrane exons exhibited the highest degree of homology, 81 to 89%. Only two differences were found when the epsilon-chains from LOU and Sprague Dawley rats were compared. The most striking difference at the nucleotide sequence level between the rat, mouse, and human epsilon genes was found within the first intron. The mouse genome contains a unique 366 base-pair long sequence in this region. The inserted sequence is repetitive and present in approximately 100 copies in the mouse genome. It is flanked by 22 base-pair long direct repeats and contains also 14 base-pair long inverted repeats, thus having properties in common with transposable elements.     

Consequences of frameshift mutations at the immunoglobulin heavy chain locus of the mouse.

From an IgM secreting hybridoma line we have isolated 16 spontaneous mutants that produce truncated IgM polypeptides. The size of the mu-mRNAs produced by these mutants is normal, but they express 3- to 100-fold less mu-mRNA and mutant mu-protein than the parental cell line. Nucleotide sequence analysis of cloned mu-genes and/or their mRNAs show frameshift mutations that generate in-phase chain termination codons. The extent of the reduction in mu-mRNA levels depends on the position of the nonsense codon within the gene.     

An enhancer at the 3'' end of the mouse immunoglobulin heavy chain locus.

A tissue-specific enhancer (E mu) lies between the joining (JH) and mu constant region (C mu) gene segments of the immunoglobulin heavy chain (IgH) locus. Since mouse endogenous IgH genes are efficiently transcribed in its absence, the normal function of this enhancer remains ill-defined. Recently, another lymphoid-specific enhancer of equal strength has been identified 3' of the rat IgH locus. We have isolated an analogous sequence from mouse and have mapped it 12.5 kb 3' of the 3'-most constant region gene (C alpha-membrane) of the BALB/c mouse locus. The mouse and rat sequences are 82% homologous and share with other enhancers several DNA sequence motifs capable of binding protein. However, in transient transfection assays, the mouse sequence behaves as a weaker enhancer. The role of this distant element in the expression of endogenous IgH genes, both in E mu-deficient, Ig-producing cell lines and during normal B cell development, is discussed.     

Stepwise activation of the immunoglobulin mu heavy chain gene locus.

The immunoglobulin heavy chain (IgH) gene locus spans several megabases. We show that IgH activation during B-cell differentiation, as measured by histone acetylation, occurs in discrete, independently regulated domains. Initially, a 120 kb domain of germline DNA is hyperacetylated, that extends from D(FL16.1), the 5'-most D(H) gene segment, to the intergenic region between Cmu and Cdelta. Germline V(H) genes were not hyperacetylated at this stage, which accounts for D(H) to J(H) recombination occurring first during B-cell development. Subsequent activation of the V(H) locus happens in at least three differentially regulated domains: an interleukin-7-regulated domain consisting of the 5' J558 family, an intermediate domain and the 3' V(H) genes, which are hyperacetylated in response to DJ(H) recombination. These observations lead to mechanisms for two well-documented phenomena in B-cell ontogeny: the sequential rearrangement of D(H) followed by V(H) gene segments, and the preferential recombination of D(H)-proximal V(H) genes in pro-B cells. We suggest that stepwise activation may be a general mechanism by which large segments of the genome are prepared for expression.     

Intraclass diversification of immunoglobulin heavy chain genes in the African lungfish

Lungfish (Dipnoi) are the closest living relatives to tetrapods, and they represent the transition from water to land during vertebrate evolution. Lungfish are armed with immunoglobulins (Igs), one of the hallmarks of the adaptive immune system of jawed vertebrates, but only three Ig forms have been characterized in Dipnoi to date. We report here a new diversity of Ig molecules in two African lungfish species (Protopterus dolloi and Protopterus annectens). The African lungfish Igs consist of three IgMs, two IgWs, three IgNs, and an IgQ, where both IgN and IgQ originated evidently from the IgW lineage. Our data also suggest that the IgH genes in the lungfish are organized in a transiting form from clusters (IgH loci in cartilaginous fish) to a translocon configuration (IgH locus in tetrapods). We propose that the intraclass diversification of the two primordial gnathostome Ig classes (IgM and IgW) as well as acquisition of new isotypes (IgN and IgQ) has allowed lungfish to acquire a complex and functionally diverse Ig repertoire to fight a variety of microorganisms. Furthermore, our results support the idea that “tetrapod-specific” Ig classes did not evolve until the vertebrate adaptation to land was completed ~360 million years ago.     

Localization of the rat immunoglobulin heavy chain locus to chromosome 6

We have previously used rat/mouse somatic cell hybrids to localize the rat c-myc gene to chromosome 7 (Sümegi et al. 1983) and the rat immunoglobulin kappa locus to chromosome 4 (Perlmann et al. 1985). We now report that by utilizing rat/mouse somatic cell hybrids, we have localized the rat immunoglobulin heavy chain locus to chromosome 6.     

Physical mapping of the bovine immunoglobulin heavy chain constant region gene locus

Bovine antibodies have recently attracted increasing attention, as they have been shown to exhibit prophylactic and therapeutic properties in selected infectious diseases in humans. In the present study, we have isolated bacterial artificial chromosomes and cosmid clones containing the bovine JH, mu, delta, gamma 1, gamma 2, gamma 3, epsilon, and alpha genes, which allowed us to make a contig of the genes within the bovine IGHC locus. The genes are arranged in a 5'-JH-7 kb-mu-5 kb-delta-33 kb-gamma 3-20 kb-gamma 1-34 kb-gamma 2-20 kb-epsilon- 13 kb-alpha-3' order, spanning approximately 150 kb DNA. Examination of the bovine germline JH locus revealed six JH segments, two of which, JH1 and JH2, were shown to be functional although there was a strong preference for expression of the former. Sequence alignment of the bovine 5' E mu enhancer core region with those of other mammals, demonstrated an absence of the mu E3 motif and a shortened spacer between the mu A and mu B sites within the bovine E mu enhancer core region. Furthermore, the essential sequence element for class switching, switch mu, spanning approximately 3-kb repetitive sequence and abundant in the switch region motifs CTGGG (187 repeats) and CTGAG (127 repeats), was identified immediately upstream of the mu gene. A further sequence comparison revealed that the bovine IGHC genes display an extensive polymorphism leading to expression of multiple antibody allotypes.     

Influence of the immunoglobulin heavy chain locus on expression of the VK1GAC light chain

The VK1GAC light chain represents the dominant V kappa structure employed in the antibody response of A/J mice to streptococcal group A carbohydrate ( GAC ). Two anti-idiotypic antisera, anti- Id5 and anti- Id20 , with specificity for the VK1GAC light chain were used to examine anti- GAC antibody responses in a series of inbred mouse strains that differ at the heavy chain constant region ( IgCH ) allotype locus. Both idiotypes were expressed in normal and immune sera from mice of most IgCH allotypes, except IgCHb (C57BL/6J) and IgCHf (CE/J). C57BL/6J mice expressed Id5 , but not Id20 , whereas CE/J mice did not express either idiotype. Testing of recombinant inbred strains between BALB/c and C57BL/6 indicated that the pattern of idiotype expression did not correlate with IgCH allotype. The C X B recombinants expressed all three idiotype patterns that were observed in the panel of inbred strains. Testing of allotype congenic mice between BALB/c and C57BL/6 showed that CB.20 and BC.8 mice were Id20 -, whereas BAB-14 mice were Id20 +, indicating that both VH and background (V kappa or regulatory) loci must be derived from BALB/c to obtain Id20 expression. The difference in the frequency of idiotype expression observed between BALB/c and BAB-14 mice indicates that the IgCH locus may exert a quantitative influence on the expression of this light chain. To examine the Id20 -, Id5 + antibodies of C57BL/6 mice, anti- GAC hybridomas were prepared. Of 16 C57BL/6-derived anti- GAC monoclonal antibodies, six were reactive with anti- Id5 and not with anti- Id20 . Isoelectric focusing of the purified kappa light chains from three of these antibodies revealed two distinct spectrotypes that co-migrated with the two known VK1GAC spectrotypes observed with A/J anti- GAC light chains. Idiotypic analysis of in vitro recombinants between the heavy and light chains of A/J and C57BL/6 monoclonal antibodies demonstrated that the C57BL/6 light chains were idiotypically similar to A/J light chains when they were free in solution or paired with A/J heavy chains. These results demonstrate that C57BL/6 mice can express a light chain that is very similar, if not identical, to the VK1GAC light chain, although the light chain is expressed in lower frequency and is paired with a distinct VH structure, which can mask expression of one of the VK1GAC idiotypes. These effects on V kappa expression map to at least three genetic loci: VH, CH, and an unlinked locus.     

Variability of the immunoglobulin heavy chain constant region locus: a population study

The Immunoglobulin Heavy chain Constant region (IGHC) locus is a multigene family composed of highly homologous segments often involved in unequal crossings over that lead to deleted and duplicated haplotypes. The frequencies of these haplotypes in 558 individuals from Lombardy, Veneto, Puglia and Sardinia were determined by Pulsed Field Gel Electrophoresis (PFGE), followed by Southern blotting with four IGHC probes, and compared with those observed in 110 subjects from Piedmont. Twenty deletions and 60 duplications were characterized, all in heterozygous individuals except for 2 homozygous deletions. The differences in frequency between the five populations were not significant. The deletions/duplications involved one or more genes: GP-A2, A1-E and G4 duplications, and A1-E and GP-A2 deletions were the most common. Four new duplications are described: three, involving the genes from GP to A2, from G2 to G4, and G4, are counterparts of known deletions. The fourth duplication spans from GP to G2. A G1 deleted heterozygous individual never previously described in Italy is reported. All the rearranged haplotypes seem to be the result of unequal crossing over. The difference between the number of duplications and deletions was significant in Sardinia, Lombardy, Puglia and in the total of 668 subjects (P < 0.001). This may be due to selection or genetic drift.     

The immunoglobulin heavy chain class switch

Conclusions While much has been learned concerning the molecular structural basis for the heavy chain class switch, many questions relating to the regulation of the switch remain unanswered, or at least controversial. Identification of the enzyme system which mediates the class switch, as well as other regulatory, possibly X-linked, genes should provide the necessary key to our understanding of this unique process.AbbreviationsB cell lymphocyte derived from the bone marrow in adult mammals or the bursa of Fabricius in chickens - bp base pair - C immunoglobulin constant region - CDR complementarity-determining region of the immunoglobulin variable region - D diversity gene segment of the immunoglobulin heavy chain variable region gene - H immunoglobulin heavy chain - Ig immunoglobulin - J joining region gene segment of the immunoglobulin variable region gene - kb kilobase - L immunoglobulin light chain - LPS lipopolysaccharide - Pyr pyrimidine - S-, s-site, s-region switch rearrangement site - SCE sister chromatid exchange - sIg surface immunoglobulin - T cell lymphocyte derived from the thymus - USCE unequal sister chromatid exchange - V immunoglobulin variable region     

Molecular analysis of recombination sites within the immunoglobulin heavy chain locus of the rabbit

Previously, recombinations involving genes of the rabbit immunoglobulin heavy chain locus have been documented serologically. These data indicated that the sites at which the causative recombination events occurred could have been anywhere from within the V _H gene cluster up to, or 3 of, C. Since these sites could not be localized further by serological methods, we attempted to do this using techniques of molecular biology. DNAs from homozygous recombinant rabbits and from the appropriate non-recombinant parental haplotypes were characterized using Southern blots hybridized with a panel of probes derived from cloned regions of the rabbit immunoglobulin heavy chain gene complex. In all three recombinants, the site was downstream of the entireV _H cluster and upstream of the J _Hcluster within an 50 kilobase (kb) egion containing expanses of repetitive-sequence DNA as well as D _H genes. D _H-specific probes further showed that in two of the recombinants, the recombination appears to have occurred within or 5 of D _H1 and 5 of D _H2 genes; in the third it occurred 3 of the D _H2 genes but at least 5 kb 5 of the J _H region. Address for correspondence and offprint request to: R. G. Mage.     

Evolution of the immunoglobulin heavy chain variable region (Igh-V) locus in the genusMus

The evolution of the mouse immunoglobulin heavy chain variable region (Igh-V) locus was investigated by the comprehensive analysis of variable region (Vh) gene family content and restriction fragment polymorphism in the genusMus. The examination of naturalMus domesticus populations suggests an important role for recombination in the generation of the considerable restriction fragment polymorphism found at theIgh-V locus. Although the sizes of individualVh gene families vary widely both within and between differentMus species, evolutionary trends ofVh gene family copy number are revealed by the analysis of homologues of mouseVh gene families inRattus andPeromyscus. Processes of duplication, deletion, and sequence divergence all contribute to the evolution ofVh gene copy number. CertainVh gene families have expanded or contracted differently in the various muroid lineages examined. Collectively, these findings suggest that the evolution of individualVh family size is not driven by strong selective pressure but is relatively neutral, and that gene flow, rather than selection, serves to maintain the high level of restriction fragment polymorphism seen inM. domesticus.