Physical linkage of the constant region genes for immunoglobulins lambda I and lambda III

Differences in the function of three conserved E-boxes of the muscle creatine kinase gene in cultured myocytes and in transgenic mouse skeletal and cardiac muscle

The 1256-base pair enhancer-promoter of the mouse muscle creatine kinase gene includes three CAnnTG E-boxes that are conserved among mammals and have flanking and middle sequences conforming to consensus muscle regulatory factor binding sites. This study seeks to determine whether these E-boxes are critical for muscle creatine kinase expression in physiologically distinct muscles. Mutations of the "right" and "left" E-boxes in the enhancer decreased expression in cultured skeletal myocytes approximately 10- and 2-fold, respectively, whereas a "promoter" E-box mutation had little effect. In neonatal myocardiocytes, the left E-box mutation decreased expression approximately 3-fold, whereas right or promoter E-box mutations had no effect. Very different effects were seen in transgenic mice, where the promoter E-box mutation decreased expression in quadriceps, extensor digitorum longus, and soleus approximately 10-fold, and approximately 100-fold in distal tongue, diaphragm, and ventricle. The right E-box mutation, tested in the presence of the other two mutations, caused a significant decrease in distal tongue, but not in quadriceps, extensor digitorum longus, soleus, or ventricle. Mutation of the left E-box actually raised expression in soleus, suggesting a possible repressor role for this control element. The discrepancies between mutation effects in differentiating skeletal muscle cultures, neonatal myocardiocytes, and adult mice suggested that the E-boxes might play different roles during muscle development and adult steady-state function. However, transgenic analysis of embryonic and early postnatal mice indicated no positive role for these three E-boxes in early development, implying that differences in E-box function between adult muscle and cultured cells are the result of physiological signals.

Assembly requirements of PU.1-Pip (IRF-4) activator complexes: inhibiting function in vivo using fused dimers

Gene expression in higher eukaryotes appears to be regulated by specific combinations of transcription factors binding to regulatory sequences. The Ets factor PU.1 and the IRF protein Pip (IRF-4) represent a pair of interacting transcription factors implicated in regulating B cell-specific gene expression. Pip is recruited to its binding site on DNA by phosphorylated PU.1. PU.1-Pip interaction is shown to be template directed and involves two distinct protein-protein interaction surfaces: (i) the ets and IRF DNA-binding domains; and (ii) the phosphorylated PEST region of PU.1 and a lysine-requiring putative alpha-helix in Pip. Thus, a coordinated set of protein-protein and protein-DNA contacts are essential for PU.1-Pip ternary complex assembly. To analyze the function of these factors in vivo, we engineered chimeric repressors containing the ets and IRF DNA-binding domains connected by a flexible POU domain linker. When stably expressed, the wild-type fused dimer strongly repressed the expression of a rearranged immunoglobulin lambda gene, thereby establishing the functional importance of PU.1-Pip complexes in B cell gene expression. Comparative analysis of the wild-type dimer with a series of mutant dimers distinguished a gene regulated by PU.1 and Pip from one regulated by PU.1 alone. This strategy should prove generally useful in analyzing the function of interacting transcription factors in vivo, and for identifying novel genes regulated by such complexes.

The primary antibody repertoire of kappa-deficient mice is characterized by non-stochastic Vlamda1 + V(H) gene family pairings and a higher degree of self-reactivity

We have investigated the primary antibody repertoire of genetically manipulated 129/Sv kappa-deficient (JCkappaD) mice, in order to understand the contributions of the lambda-light chain, in the absence of an otherwise predominant kappa-light chain, to the development of humoral immunity. The expression of Vlambda1 gene (lambda1 and lambda3 subtypes) and the Vlambda1 + V(H) (J558, 36-60, V(H)11 and S107) gene family associations were studied in 7.43 x 10(3) mitogen-activated splenic B-lymphocyte clones of JCkappaD origin. Furthermore, the functional significance of the exclusive expression of the lambda-light chain, in the peripheral B-cell repertoire of JCkappaD mice, was analysed by determining natural autoantibody specificities in the circulating serum immunoglobulin and the frequency of autoreactive B-lymphocyte clones in the peripheral B-lymphocyte repertoire. These experiments revealed that: first, of the three available Vlambda genes at the lambda locus, the Vlambda1 gene is the one that is expressed most frequently (59.9%); second, non-random Vlambda1 + V(H) (J558, 36-60) gene family pairings occur in kappa-deficient mice; and third, a higher degree of self-reactivity is generated as a result of exclusive use of the lambda-light chain, as evidenced by higher levels of serum natural autoantibodies as well as a high frequency of autoreactive B-lymphocyte clones in kappa-deficient (129/Sv JCkappaD) mice. These observations suggest that the high murine kappa/lambda ratio in mice may, apart from high sequence diversity at the kappa-locus, be a result of endogenous selection against the lambda-light chain to restrict self-reactivity within the homeostatic threshold.

A quasi-monoclonal mouse

As a model for studying the generation of antibody diversity, a gene-targeted mouse was produced that is hemizygous for a rearranged V(D)J segment at the immunoglobulin (Ig) heavy chain locus, the other allele being nonfunctional. The mouse also has no functional kappa light chain allele. The heavy chain, when paired with any lambda light chain, is specific for the hapten (4-hydroxy-3-nitrophenyl) acetyl (NP). The primary repertoire of this quasi-monoclonal mouse is monospecific, but somatic hypermutation and secondary rearrangements change the specificity of 20 percent of the antigen receptors on B cells. The serum concentrations of the Ig isotypes are similar to those in nontransgenic littermates, but less than half of the serum IgM binds to NP, and none of the other isotypes do. Thus, neither network interactions nor random activation of a small fraction of the B cell population can account for serum Ig concentrations.

Light chain editing in kappa-deficient animals: a potential mechanism of B cell tolerance

The genetic organization of the kappa and lambda light chain loci permits multiple, successive rearrangement attempts at each allele. Multiple rearrangements allow autoreactive B cells to escape clonal deletion by editing their surface receptors. Editing may also facilitate efficient B cell production by salvaging cells with nonproductive light chain (L chain) rearrangements. To study receptor editing of kappa L chains, we have characterized B cells from mice hemizygous for the targeted inactivation of kappa (JCkD/wt) which have an anti-DNA heavy chain transgene, 3H9. Hybridomas from JCkD/wt mice exhibited an increased frequency of rearrangements to downstream Jk segments (such as Jk5) compared with most surveys from normal mice, consistent with receptor editing by sequential kappa locus rearrangements in JCkD/wt. We observed an even higher frequency of rearrangements to Jk5 in 3H9 JCkD/wt animals compared with nontransgenic JCkD/wt, consistent with editing of autoreactive kappa in 3H9 JCkD/wt. We also recovered a large number of 3H9 JCkD/wt lines with Vk12/13-Jk5 rearrangements and could demonstrate by PCR and Southern analysis that up to three quarters of these lines underwent multiple kappa rearrangements. To investigate editing at the lambda locus, we used homozygous kappa-deficient animals (JCkD/JCkD and 3H9 JCkD/JCkD). The frequencies of V lambda 1 and V lambda 2 rearrangements among splenic hybridomas in 3H9 JCkD/JCkD were reduced by 75% whereas V lambda X was increased 5-10-fold, compared with nontransgenic JCkD/JCkD animals. This indicates that V lambda 1 and V lambda 2 are negatively regulated in 3H9 JCkD/JCkD, consistent with earlier studies that showed that the 3H9 heavy chain, in combination with lambda 1 binds DNA. As successive lambda rearrangements to V lambda X do not inactivate V lambda 1, the consequence of lambda editing in 3H9 JCkD/JCkD would be failed allelic exclusion at lambda. However, analysis of 18 3H9 JCkD/JCkD hybridomas with V lambda 1 and V lambda X DNA rearrangements revealed that most of these lines do not have productive lambda 1 rearrangements. In sum, both kappa and lambda loci undergo editing to recover from nonproductive rearrangement, but only kappa locus editing appears to play a substantial role in rescuing autoreactive B cells from deletion.

Somatic mutation in constant regions of mouse lambda 1 light chains

To study the distribution of somatic mutation, we determined nucleotide sequences of rearranged lambda 1-chain genomic DNA from four hybridomas obtained from C57BL/6 mice that had been immunized with (4-hydroxy-3-nitrophenyl)acetyl-conjugated chicken gamma globulin. In total, 114 nucleotide substitutions were observed, with neither insertion nor deletion. Sixty-one mutations occurred in the variable-joining region genes (V lambda 1-J lambda 1) and 49 in joining-constant (J lambda 1-C lambda 1) introns. Although frequency decreased with distance from the V lambda 1-J lambda 1 coding region, somatic mutations occurred in the entire J lambda 1-C lambda 1 intron and even in the C lambda 1 region. We found four nucleotide substitutions in C lambda 1 genes, all of which were replacement mutations. Therefore, the mechanism responsible for somatic mutation is operative into the C lambda 1 exons. Nucleotide sequences of rearranged but inactive lambda 2-chain genes from two hybridomas were also examined and compared with those of lambda 1-chain genes. The clustering of replacement mutations in complementarity-determining regions in the inactive lambda 2-chain genes similar to the active lambda 1-chain genes suggested a mechanism that induces somatic mutation preferentially in this region even in the absence of antigenic selection.

A novel enhancer in the immunoglobulin lambda locus is duplicated and functionally independent of NF kappa B

As a first step toward defining the elements necessary for lambda immunoglobulin gene regulation, DNase I hypersensitive sites were mapped in the mouse lambda locus. A hypersensitive site found 15.5 kb downstream of C lambda 4 was present in all the B-cell but not in the T-cell lines tested. This site coincided with a strong B-cell-specific transcriptional enhancer (E lambda 2-4). This novel enhancer is active in myeloma cells, regardless of the status of endogenous lambda genes, but is inactive in a T-cell line and in fibroblasts. The enhancer E lambda 2-4 functions in the absence of the transcription factor NF kappa B, which is necessary for kappa enhancer function. No evidence could be found for NF kappa B binding by this element. Rearrangement of V lambda 2 to JC lambda 3 or JC lambda genes deletes E lambda 2-4; however, a second strong enhancer was found 35 kb downstream of C lambda 1, which cannot be eliminated by lambda gene rearrangements. The second lambda enhancer (E lambda 3-1) is 90% homologous to the E lambda 2-4 sequence in the region determined to comprise the active enhancer and likewise lacks the consensus binding site for NF kappa B. The data support a model for the independent activation of kappa and lambda gene expression based on locus-specific regulation at the enhancer level.

Expression from the transferrin gene promoter in transgenic mice

Transferrin is an iron-binding protein that is expressed as a major product in liver and secreted into the plasma. To study the tissue-specific regulatory regions of this gene, the genomic mouse transferrin (mTf) gene was cloned and characterized by partial sequence analysis and S1 nuclease mapping of the transcriptional start site. Fusion genes containing the transferrin gene promoter and 5'-flanking sequences were ligated to the human growth hormone (hGH) gene and used to produce transgenic mice. A deletion construct containing the -581 to +50 region of the transferrin gene was sufficient to direct a high level of liver-specific expression resembling endogenous transferrin gene expression. Deletion to -139 base pairs of 5'-flanking sequence gave a construct which retained liver specificity, but the magnitude of expression decreased severalfold. These results demonstrate the presence of a liver-specific transcriptional element between -139 and +50 and suggest the presence of a distal element between -581 and -139 that can further increase expression. Surprisingly, fusion constructs containing -3 kilobase pairs (kb) of 5'-flanking sequence gave higher levels of mRNA in nonhepatic tissues than did either the -581 or -139 construct. Further studies indicated that the high levels of circulating hGH in these transgenic mice specifically induced the endogenous transferrin and albumin genes in liver and also stimulated the normally low levels of expression of the endogenous transferrin gene in brain, heart, kidney, and muscle. A mutated hGH gene that does not produce active growth hormone was fused to the -3- to +50-kb transferrin sequences to produce the -3-kb mTf-hGX construct. A liver-specific pattern of expression was observed in transgenic mice harboring the -3-kb mTf-hGX construct, and this mutated transgene was shown to be induced four- to sevenfold by either bovine or human growth hormone. These results demonstrate the presence of a growth hormone-responsive element between -3 and +50 kb in the 5'-flanking region of the mTf gene promoter.

Expression from the transferrin gene promoter in transgenic mice

Transferrin is an iron-binding protein that is expressed as a major product in liver and secreted into the plasma. To study the tissue-specific regulatory regions of this gene, the genomic mouse transferrin (mTf) gene was cloned and characterized by partial sequence analysis and S1 nuclease mapping of the transcriptional start site. Fusion genes containing the transferrin gene promoter and 5'-flanking sequences were ligated to the human growth hormone (hGH) gene and used to produce transgenic mice. A deletion construct containing the -581 to +50 region of the transferrin gene was sufficient to direct a high level of liver-specific expression resembling endogenous transferrin gene expression. Deletion to -139 base pairs of 5'-flanking sequence gave a construct which retained liver specificity, but the magnitude of expression decreased severalfold. These results demonstrate the presence of a liver-specific transcriptional element between -139 and +50 and suggest the presence of a distal element between -581 and -139 that can further increase expression. Surprisingly, fusion constructs containing -3 kilobase pairs (kb) of 5'-flanking sequence gave higher levels of mRNA in nonhepatic tissues than did either the -581 or -139 construct. Further studies indicated that the high levels of circulating hGH in these transgenic mice specifically induced the endogenous transferrin and albumin genes in liver and also stimulated the normally low levels of expression of the endogenous transferrin gene in brain, heart, kidney, and muscle. A mutated hGH gene that does not produce active growth hormone was fused to the -3- to +50-kb transferrin sequences to produce the -3-kb mTf-hGX construct. A liver-specific pattern of expression was observed in transgenic mice harboring the -3-kb mTf-hGX construct, and this mutated transgene was shown to be induced four- to sevenfold by either bovine or human growth hormone. These results demonstrate the presence of a growth hormone-responsive element between -3 and +50 kb in the 5'-flanking region of the mTf gene promoter.

DNase I sensitivity of immunoglobulin light chain genes in Abelson murine leukemia virus transformed pre-B cell lines

We have used Abelson murine leukemia virus (A-MuLV) transformed pre-B cell lines to test the hypothesis that the rearrangement potential of a developing B-lymphocyte is dependent on an "opening" of the chromatin structure surrounding immunoglobulin (Ig) genes, thus allowing accessibility to an Ig gene recombinase. The chromatin structures surrounding heavy (H), kappa (kappa), and lambda (lambda) chain constant-region genes were assessed by DNase I sensitivity in A-MuLV transformed cell lines capable of H, kappa or lambda gene rearrangement. Our results indicate that DNase I-sensitive chromatin structures of these Ig constant-region genes correlate closely with the ability of the genes to undergo recombination. We also find that the chromatin structure of an Ig constant-region locus becomes DNase I sensitive before any DNA rearrangement events occur.

Inhibition of immunoglobulin gene rearrangement by the expression of a lambda 2 transgene

The rearrangement of Ig genes is known to be regulated by the production of H and kappa L chains. To determine whether lambda L chains have a similar effect, transgenic mice were produced with a lambda 2 gene. It was necessary to include the H chain enhancer, since a lambda gene without the added enhancer did not result in transgene expression. The lambda 2 transgene with the H enhancer was expressed in lymphoid cells only. The majority of the B cells of newborn transgenic mice produced lambda, whereas kappa + cells were reduced. Concomitantly, serum levels of kappa and kappa mRNA were diminished. By 2 wk after birth the proportion of kappa-expressing cells was dramatically increased. Adults had reduced proportions of B cells that produced lambda only, but the levels of lambda were still higher than in normal littermates. Also, kappa + cells were still lower than in normal mice. Analysis of hybridomas revealed that reduction of kappa gene rearrangement was the basis for the decreased frequency of kappa + cells. Furthermore, many cells also contained an unrearranged H chain allele. It was concluded that feedback inhibition by the lambda 2 together with endogenous H protein may have inhibited recombinase activity in early pre-B cells, leading to inhibition of both H chain and kappa gene rearrangement. Thus, lambda 2 can replace kappa in a feedback complex. The levels of serum lambda 1 and, to a lesser degree, of spleen lambda 1 mRNA were reduced in the lambda 2 transgenic mice. However, the proportion of hybridomas with endogenous lambda gene rearrangement was at least as high as in normal mice. It was therefore concluded that the suppression of functional lambda 1 may be a consequence of decreased selection of endogenous lambda-producing cells because of the excess of transgenic lambda. The escape of kappa-producing cells from feedback inhibition may be the result of several mechanisms that operate to varying degrees, among them: (a) kappa rearrangement during a period in which the recombinase is still active after appearance of a lambda 2/mu stop signal; (b) a B cell lineage that is not feedback inhibited at the pre-B cell stage; (c) subthreshold levels of transgenic lambda 2 in some pre-B cells; and (d) loss of the lambda 2 transgenes in rare pre-B cells.

Physical linkage of mouse lambda genes by pulsed-field gel electrophoresis suggests that the rearrangement process favors proximate target sequences

The first complete map of a mammalian immunoglobulin gene locus is presented. Mouse lambda genes were mapped by pulsed-field gel electrophoresis. The gene order is V2-Vx-C2-C4-V1-C3-C1. The distance between V2 or Vx and the C2-C4 cluster is 74 or 55 kilobases (kb), respectively, whereas that between V1 and C3-C1 is only 19 kb; V2 and C3-C1 are at least 190 kb apart. Thus, the distances between the lambda subloci are inversely proportional to their frequencies of rearrangement. The related gene lambda 5 is not within the 500 kb of the lambda locus mapped here.

Monoclonal antibodies specific for variable and constant domains of murine lambda chains

Rat monoclonal antibodies directed against the BALB/c myeloma protein M315 (alpha,lambda 2) are described. 9A8 (IgG1) binds the V domain of lambda 2 and cross-reacts with lambda 1 and lambda 3 chains. 2B6 (IgG2a) is directed to the C domain of lambda 2 and cross-reacts with C lambda 3. The antibodies bind isolated chains as well as complete immunoglobulins. The monoclonals detect soluble immunoglobulin (radioimmunoassay), immunoglobulin immobilized on polystyrene (enzyme-linked immunosorbent assay), immunoglobulin bound to nitrocellulose (immunoblotting), and surface immunoglobulin intercalated in cell membranes (immunofluorescence). The antibodies are easily purified on protein G immunosorbents and may be biotinylated or conjugated with fluorescein isothiocyanate without loss of capacity to bind. In addition to the anti-lambda antibodies, a C alpha 2/C alpha 3-specific monoclonal antibody, 8D2 (IgG2a) is described.

Physical linkage of mouse lambda genes by pulsed-field gel electrophoresis suggests that the rearrangement process favors proximate target sequences

The first complete map of a mammalian immunoglobulin gene locus is presented. Mouse lambda genes were mapped by pulsed-field gel electrophoresis. The gene order is V2-Vx-C2-C4-V1-C3-C1. The distance between V2 or Vx and the C2-C4 cluster is 74 or 55 kilobases (kb), respectively, whereas that between V1 and C3-C1 is only 19 kb; V2 and C3-C1 are at least 190 kb apart. Thus, the distances between the lambda subloci are inversely proportional to their frequencies of rearrangement. The related gene lambda 5 is not within the 500 kb of the lambda locus mapped here.

Intergenic exchange maintains identity between two human lambda light chain immunoglobulin gene intron sequences

Evidence for gene conversion or unequal double crossover in the human lambda light chain immunoglobulin locus is presented. The high level of J2C2-J3C3 intron cross-hybridization, the identity of the J lambda and J lambda 3 coding and intron sequences, the presence of multiple base differences between the C lambda 2 and C lambda 3 coding regions, and the presence of both the unconverted and converted alleles in the normal gene pool, suggest that a recombinational event has resulted in the conversion of the J lambda 2 coding and intron sequences to those of J lambda 3 and its flanking sequences. Intergenic exchanges, such as the one described here, may provide a mechanism to maintain sequence homogeneity and functionality among the duplicated members of the human lambda gene family.

cDNA clones encoding rabbit immunoglobulin lambda chains. Evidence for length variation of the third hypervariable region and for a novel constant region

Five cDNA clones designated pDH2, pDH8, pDH9, pDH31 and pDH101 encoding rabbit immunoglobulin lambda light chain sequences have been characterized. Comparison of the V lambda sequences suggests that, in addition to an increased divergence in all of the complementarity-determining regions (CDRs), variable-region diversity is amplified by the length heterogeneity of the CDR3, at the V lambda-J lambda junction. An insertion of four codons at positions 48a-d has been noted in three cDNA sequences. This insert, not found in lambda nor kappa light chains of other species, has a variable sequence, suggesting its possible implication in expanding variability of the CDR2. One of the cDNA clones was shown to encode a novel C lambda region which differs by four amino acid substitutions from the C lambda region common to all the other clones. Thus, the rabbit can use two different C lambda genes, which might correlate with the expression of the two known allotypes of lambda chains, C7 and C21. Southern blotting experiments indicate a small number of germ-line V lambda genes and the cDNA nucleotide sequence data reported here suggest that several of these genes can be expressed. The possibility of at least two V-J-C gene clusters is discussed.

Extensive families of constant region genes in a phylogenetically primitive vertebrate indicate an additional level of immunoglobulin complexity

A homologous probe for the constant region of the Heterodontus francisci (horned shark) immunoglobulin heavy chain was used to screen a genomic DNA library constructed in bacteriophage lambda, and a large number of independent clones were recovered. Their hybridization patterns with segment-specific probes are consistent with the close linkage of heavy-chain constant (CH), joining (JH), and variable (VH) gene segments. Differences in the nucleotide sequences of the first CH exon of five genes primarily are localized to 5' positions; extended regions of sequence identity are noted at 3' positions. The predicted amino acid sequences of each gene are different and are related distantly to the corresponding regions of higher vertebrate immunoglobulins. Gene-specific oligodeoxynucleotide probes were used to establish that at least three of the five genes are transcriptionally active. Quantitative gene titration data are consistent with the large numbers of genes suggested by the library screening analyses. In this representative early vertebrate, it appears that (VH-diversity-JH) segments are associated with individual constant region genes that can differ at the predicted protein level.

Active lambda and kappa antibody gene rearrangement in Abelson murine leukemia virus-transformed pre-B cell lines

The two Abelson murine leukemia virus (A-MuLV)-transformed cell lines, BM18-4 and ABC-1, undergo immunoglobulin L-chain gene recombination during passage in tissue culture. BM18-4 cells are capable of kappa gene recombination, whereas ABC-1 cells are capable of both kappa and lambda gene recombination. The expression of H chains is apparently not necessary for continuing L chain gene recombination in either of these cells, although H-chain expression may have been involved in the initiation of L-chain gene recombination. All ABC-1 cells that have lambda gene rearrangements also display recombined kappa alleles, supporting the hypothesis that kappa and lambda gene recombination are initiated in an ordered, developmentally regulated manner in maturing B cells. However, analyses of the ABC-1 line indicate that pre-B cells that have initiated lambda gene recombination do not terminate kappa gene rearrangement. The lambda gene recombinations that occur in the ABC-1 cell line indicate that the germline order of lambda gene segments is: 5' ... V lambda 2 ... J lambda 2C lambda 2-J lambda 4C lambda 4 ... V lambda 1 ... J lambda 3C lambda 3-J lambda 1C lambda 1 ... 3'. In addition, the frequencies of lambda 1, lambda 2, and lambda 3 gene recombinations among ABC-1 cells are quite different than the frequencies of B cells producing lambda 1, lambda 2, and lambda 3 L-chains in the mouse. RS DNA recombinations also occur in the BM18-4 and ABC-1 cell lines, supporting the notion that Ig gene recombinases are involved in RS rearrangement. Recombined RS segments are infrequent among BM 18-4 cells but common among ABC-1 cells, suggesting that RS recombinational events often occur in maturing pre-B cells just before initiation of lambda gene rearrangements. This developmental timing is consistent with the hypothesis that RS recombination may be involved in the initiation of lambda gene assembly.

A new V gene expressed in lambda-2 light chains of the mouse

We have partially sequenced the light chain variable regions expressed in three IgM-producing hybridomas generated from newborn mice or from manipulated animals suppressed for IgM production. In these lines a new V gene (V-lambda-X), exhibiting less than 60% homology to any known lambda or kappa V gene, is rearranged to J-lambda-2. The light chains produced by these cells contain the lambda-2 constant domain, but are not recognized by goat antisera raised against conventional mouse lambda light chains.

Transcriptional regulation of the muscle creatine kinase gene and regulated expression in transfected mouse myoblasts

The muscle-specific form of creatine kinase (MCK) is induced in differentiating myoblast cultures, and a dramatic increase in mRNA levels precedes and parallels the increase in MCK protein. To study this induction, the complete MCK gene was cloned and characterized. The transcription unit was shown to span 11 kilobases and to contain seven introns. The splice junctions were identified and shown to conform to the appropriate consensus sequences. Close homology with branchpoint consensuses was found upstream of the 3' splice sites in six of seven cases. Transcriptional regulation of the gene in differentiating myoblast cultures was demonstrated by nuclear run-on experiments; increases in transcription accounted for a major part of the increased mRNA levels. Regulated expression of a transfected MCK gene containing the entire transcription unit with 3.3 kilobases of 5'-flanking sequence was also demonstrated during differentiation of the MM14 mouse myoblast cell line. The MCK 5'-flanking region was sufficient to confer transcriptional regulation to a heterologous structural gene, since chloramphenicol acetyl transferase activity was induced during differentiation of cultures transfected with an MCK-chloramphenicol acetyl transferase fusion construct. Examination of the DNA sequence immediately upstream of the transcription start site revealed a 17-nucleotide element which occurred three times. Comparisons with other muscle-specific genes which are also transcriptionally regulated during myogenesis revealed upstream homologies in the alpha-actin and myosin heavy chain genes, but not in the myosin light-chain genes, with the regions containing these repeats. We suggest that coordinate control of a subset of muscle genes may occur via recognition of these common sequences.

Human lambda light chain locus: organization and DNA sequences of three genomic J regions

Evidence for the genomic organization of human lambda light chain joining (J) region gene segments is presented. A mouse J lambda probe was used in Southern hybridizations to localize joining region sequences in a cosmid clone containing the genomic cluster of six human lambda constant (C) region gene segments. The results of these hybridizations suggest the presence of at least one J gene segment upstream from each constant region gene segment. The DNA sequences indicate that the human J lambda 1, J lambda 2, and J lambda 3 gene segments have consensus nonamer and heptamer sequences, proposed to be involved in V-J joining, are capable of encoding the known amino acid sequences for the respective J peptides, and have a sequence which could give a functional RNA splice site at the end of their coding regions. Our data show that a single functional J is located 1.3 or 1.6 kb upstream of each of the C lambda gene segments known to encode the Mcg, Kern- Oz-, and Kern- Oz+ isotypes. Therefore, the gene organization of this region of the human lambda locus is J1C1-J2C2-J3C3. The DNA sequences of J lambda 1, J lambda 2, and J lambda 3 presented in this paper establish that a single J lambda gene segment precedes each expressed C lambda gene segment, and support a model for the evolution of the human lambda JC clusters where J1C1 and J2C2-J3C3 arose from different ancestral JC units.

Transcriptional regulation of the muscle creatine kinase gene and regulated expression in transfected mouse myoblasts

The muscle-specific form of creatine kinase (MCK) is induced in differentiating myoblast cultures, and a dramatic increase in mRNA levels precedes and parallels the increase in MCK protein. To study this induction, the complete MCK gene was cloned and characterized. The transcription unit was shown to span 11 kilobases and to contain seven introns. The splice junctions were identified and shown to conform to the appropriate consensus sequences. Close homology with branchpoint consensuses was found upstream of the 3' splice sites in six of seven cases. Transcriptional regulation of the gene in differentiating myoblast cultures was demonstrated by nuclear run-on experiments; increases in transcription accounted for a major part of the increased mRNA levels. Regulated expression of a transfected MCK gene containing the entire transcription unit with 3.3 kilobases of 5'-flanking sequence was also demonstrated during differentiation of the MM14 mouse myoblast cell line. The MCK 5'-flanking region was sufficient to confer transcriptional regulation to a heterologous structural gene, since chloramphenicol acetyl transferase activity was induced during differentiation of cultures transfected with an MCK-chloramphenicol acetyl transferase fusion construct. Examination of the DNA sequence immediately upstream of the transcription start site revealed a 17-nucleotide element which occurred three times. Comparisons with other muscle-specific genes which are also transcriptionally regulated during myogenesis revealed upstream homologies in the alpha-actin and myosin heavy chain genes, but not in the myosin light-chain genes, with the regions containing these repeats. We suggest that coordinate control of a subset of muscle genes may occur via recognition of these common sequences.

A functional gamma gene formed from known gamma-gene segments is not necessary for antigen-specific responses of murine cytotoxic T lymphocytes

Structural similarities between surface immunoglobulins (s Ig) on B cells and antigen-specific receptors on T cells suggest that a T cell, like a B cell, should express only two immunoglobulin-like genes, one for each subunit of the disulphide-linked, heterodimeric, antigen-specific (alpha beta) T-cell receptor. However, cytotoxic T lymphocytes (Tc cells) and immature thymocytes also contain RNA transcripts of a third immunoglobulin-like gene, called gamma (refs 1-4). A polypeptide corresponding to the gamma gene has not yet been identified and the function of this gene remains an enigma. Judging from its nucleotide sequence, the rearranged gamma gene is expected to encode an integral membrane polypeptide chain, and gamma complementary DNAs from two cloned Tc cell lines have previously been found to have different sequences around the V-J (variable region-joining region) junction, suggesting that, in these cells, the gamma-gene product is a clonally diverse surface structure that may form part of an as yet unidentified, antigen-specific receptor. To analyse further the extent of diversity of the gamma-gene product, we have determined the partial sequences of 11 gamma cDNA clones from three other cloned Tc cell lines, and report here that the sequences are indeed clonally diverse, but in all instances they are out-of-phase in the region of the V-J junction. This finding and the pattern of gamma-gene rearrangements in these cell lines indicate that a polypeptide product of the previously reported gamma gene, V2J2-C2, is not expressed in them and is, therefore, not necessary for the antigen-specific cytotoxic and proliferative responses of these mature T cells.

Frequent lambda light chain gene rearrangement and expression in a Ly-1 B lymphoma with a productive kappa chain allele

We describe here a murine Ly-1-bearing pre-B-cell tumor that, when induced for kappa light chain expression with bacterial lipopolysaccharide, also gives rise spontaneously to a few percent of cells expressing surface lambda light chains. These lambda-positive cells have undergone DNA rearrangements involving either V lambda 1 or V lambda 2 genes. Nearly all clones of lambda-bearing cells express mu and lambda on their surface (but not kappa). However, all these lambda-positive clones continue to transcribe kappa mRNA and synthesize internal kappa chains. Further, surface lambda-positive clones show JH rearrangements on one or both heavy chain chromosomes.

Position of Igl-1, md, and Bst loci on chromosome 16 of the mouse

The experiments described here delineate the position of the chromosome 16 markers Igl-1 (immunoglobulin lambda 1, light chain), md (mahoganoid), and Bst (belly spot and tail), and suggest their location relative to the endogenous proviral locus Akv-2, which is linked within 5.9 centimorgans to Igl-1 (Epstein et al. 1984). The data from an intercross and a three-point backcross detailed herein show the order of these three genes and distances between them to be: centromere-md-10.4 +/- 1.6-Igl-1-15.6 +/- 2.6-Bst. Using a recombinant chromosome recovered in the intercross, we have constructed a stock homozygous for md and Igl-1b (KpnI-), that will aid in mapping other genes on chromosome 16.

Deletions of kappa chain constant region genes in mouse lambda chain-producing B cells involve intrachromosomal DNA recombinations similar to V-J joining

We isolated and characterized the germ-line counterpart of a DNA segment designated RS (for recombining sequence), that is frequently recombined in mouse lambda light chain-producing B lymphocytes. Using Southern blot analyses of myelomas and mouse-Chinese hamster fusion cell lines, we found that RS DNA sequences are located on mouse chromosome 6, evidently more than 15 kilobases downstream of the kappa light-chain locus. We find that a typical recognition site for Ig gene recombination is situated within germ-line RS sequences near the recombination points observed in at least two lambda chain-producing cell lines. This represents a complete and functional Ig recognition site that is not directly associated with Ig genes. We also characterized a recombined RS segment isolated from the cell line BM18-4.13.9. This recombined segment has a variable region kappa light chain gene (V kappa) joined directly to RS sequences. Our results suggest that the deletion of the kappa light chain constant region (C kappa) exon in many lambda chain-producing B cells is the result of RS recombination and that C kappa deletion may be mediated by the same processes as antibody gene V-J joining (J = joining segment gene). We discuss the potential biological significance of RS DNA recombination in B-cell maturation.

V lambda 2 rearranges with all functional J lambda segments in the mouse

We have analyzed 210 lambda-producing hybridomas derived from lipopolysaccharide-stimulated spleen cells from a single kappa-suppressed mouse. All were classified as lambda 1, lambda 2 or lambda 3 with the exception of four unusual lines. Two of these were due to V lambda 2 J lambda 1 and the other two to V lambda 2 J lambda 3 rearrangements. The lines were clonally independent since the point of VJ recombination in each one was different. Southern blot analysis of the V lambda 2 C lambda 1-producing lines showed no evidence for an inversion. Under the assumption of a simple deletion model of rearrangement these findings place the V lambda 2 cluster upstream of the V lambda 1 cluster oriented in the same direction.

Evolution and organization of the fibrinogen locus on chromosome 4: gene duplication accompanied by transposition and inversion

Human fibrinogen cDNA probes for the alpha-, beta-, and gamma-polypeptide chains have been used to isolate the corresponding genes from human genomic libraries. There is a single copy of each gene. Restriction endonuclease analysis of isolated genomic clones and human genomic DNA indicates that the human alpha-, beta-, and gamma-fibrinogen genes are closely linked in a 50-kilobase region of a single human chromosome: the alpha-gene in the middle flanked by the beta-gene on one side and the gamma-gene on the other. The alpha- and gamma-chain genes are oriented in tandem and transcribed toward the beta-chain gene. The beta-chain gene is transcribed from the opposite DNA strand toward the gamma- and alpha-chain genes. The three genes have been localized to the distal third of the long arm of chromosome 4, bands q23-q32, by in situ hybridization with fibrinogen cDNAs and by examination of DNA from multiple rodent-human somatic cell hybrids. Alternative explanations for the present arrangement of the three fibrinogen genes involve either a three-step mechanism with inversion of the alpha/gamma-region or a two-step mechanism involving remote transposition and inversion. The second more simple mechanism has a precedent in the origin of repeated regions of the fibrinogen and immunoglobulin genes.

Molecular cloning of a human immunoglobulin lambda chain variable sequence

We have cloned a human V lambda cDNA sequence from an Ig lambda-producing human Burkitt lymphoma cell line (BL2) by taking advantage of a cloned constant region gene as a primer for cDNA synthesis instead of an oligo(dT) primer. The amino acid sequence deduced from the nucleotide sequence of V lambda clones is highly related to that of the NEW V lambda protein of subgroup I. Southern blot hybridization of human DNAs with the V lambda I probe showed at least 12 hybridizing V lambda fragments. These fragments are amplified in K562 cells which derive from a case of chronic myelogenous leukemia and contain an amplified c-abl oncogene and amplified C lambda sequences.

Restricted association of V and J-C gene segments for mouse lambda chains

The frequencies of diverse rearrangements of variable (V)lambda to joining (J)lambda gene segments were examined by Southern blot hybridization in 30 murine B-cell lines, each producing an immunoglobulin lambda light chain of known subtype (lambda 1, lambda 2, or lambda 3). For 11 out of 12 lambda 1 chains, the rearrangement was V lambda 1----J lambda 1; for 9 out of 9 lambda 2 chains, it was V lambda 2----J lambda 2; and for 8 out of 9 lambda 3 chains, it was V lambda 1----J lambda 3. Similar results were obtained by considering the partial or complete sequences at the amino acid or cDNA level of 44 other lambda chains (24 previously described): for 43 of these chains the rearranged V-J gene segments were evidently V lambda 1-J lambda 1 for 28 lambda 1 chains, V lambda 2-J lambda 2 for 10 lambda 2 chains, and V lambda 1-J lambda 3 for 5 lambda 3 chains. Of the combined total of 74 chains there were 3 with unusual V lambda rearrangements, all involving the V lambda 2 gene segment: for 2 of these unusual chains, the encoding segments were V lambda 2-J lambda 1-C lambda 1 and for one they were V lambda 2-J lambda 3-C lambda 3. Thus, the results for all 74 lambda chains show that, in contrast to the apparently unrestricted V kappa----J kappa rearrangements for kappa chains, for each of the 3 murine lambda-chain subtypes V-J recombination is severely restricted: the V lambda gene segment expressed in lambda 1 and lambda 3 chains was nearly always V lambda 1 (95% and 93%, respectively), whereas in lambda 2 chains it was without exception V lambda 2 (19 out of 19 chains). Therefore V lambda-J lambda combinatorial variation is not a significant source of amino acid sequence diversity of lambda chains of inbred mice. If the order of the lambda gene segments is 5' V lambda 2-J lambda 2C lambda 2J lambda 4C lambda 4-V lambda 1-J lambda 3C lambda 3J lambda 1C lambda 1 3', as suggested previously and by the present findings, it appears that (i) when a V lambda gene segment rearranges in a developing B cell it ordinarily recombines with a J lambda gene segment in the nearest downstream (3') cluster of J lambda C lambda segments, and (ii) V lambda rearrangement to the upstream (5') cluster is very rare and possibly may not take place at all.

Methylation patterns of immunoglobulin genes in lymphoid cells: correlation of expression and differentiation with undermethylation

Different states of eukaryotic gene expression are often correlated with different levels of methylation of DNA sequences containing structural genes and their flanking regions. To assess the potential role of DNA methylation in the expression of immunoglobulin genes, which require complex rearrangements prior to expression, methylation patterns were examined in cell lines representing different stages of lymphocyte maturation. Methylation of the second cytosine in the sequence 5' C-C-G-G 3' was determined by using Hpa II/Msp I endonuclease digestion. Four CH genes (C mu, C delta, C gamma 2b, and C alpha), C kappa, V kappa, C lambda, and V lambda genes were analyzed. The results lead to the following conclusions: (i) transcribed immunoglobulin genes are undermethylated; (ii) the C gene allelic to an expressed C gene is always also undermethylated; and (iii) all immunoglobulin loci tend to become increasingly undermethylated as B cells mature.

Variable amplification of immunoglobulin lambda light-chain genes in human populations

The human lambda immunoglobulin locus displays a series of restriction fragment length polymorphisms that are readily detected in small populations of normal individuals. Similar polymorphisms appear in populations of wild mice, suggesting that the lambda locus is subject to rapid variation within a single species. Here we show that the polymorphisms seen in the human lambda locus seem to have arisen from unequal meiotic crossing over, altering the number of lambda from as few as six to as many as nine per haploid genome. This expansion and contraction in the number of human lambda genes is significant in that it may affect an individual's capacity to produce variation among lambda light chain genes.

Association of two different repetitive DNA elements near immunoglobulin light chain genes

Sequence studies of repetitive DNA elements approximately 6 kb 3' of the mouse immunoglobulin CK region gene show that the R element located there (Gebhard et al. (1982) J. Mol. Biol. 157, 453-471) is adjacent to a 500 base pair long element which shows 80% homology to the BAM5 element sequenced by Fanning (Nuc. Acids Res. (1982), 10, 5003-5013). Neither the BAM5 element nor the R element itself is surrounded by a direct repeat, but the composite element (BAM5 + R) is surrounded by a 15 base pair direct repeat (with one mismatch). Direct repeats, consisting of target site sequences that surround a repetitive DNA element, are thought to arise during the insertion of the element at that site. It therefore appears that the BAM5 and R elements interacted and inserted as a linked entity. The existence of other BAM5/R composites throughout the mouse lambda chain locus indicates that BAM5-R cooperation is not a rare event.

Amplification of immunoglobulin lambda constant genes in populations of wild mice

The lambda immunoglobulin light chain (Ig lambda) locus of BALB/c inbred mice consists of two variable region gene segments (V lambda)1-3, and four constant region gene segments (C lambda)1,2,4,5. Each C lambda gene segment is associated with a unique joining segment (J lambda)2,4-7, and they are organized in two paired units, J3C3-J1C1 and J2C2-J4C4 (refs 4, 8). Using cDNA probes specific for C lambda 1 and C lambda 2 (ref. 9) we have analysed the genomic organization of the C lambda gene segments in wild-derived and inbred strains of mice. Although Southern blots of the genomic DNA of inbred mice show a constant pattern of hybridization, wild-derived mice show a high degree of variation in the number, size and intensity of hybridizing fragments. We have now found that, per haploid genome, mice of a Mus musculus musculus stock isolated from Sladeckovce, Czechoslovakia (CzII) have at least 12 C lambda segments, and mice of a Mus musculus domesticus stock 'Centreville Lights' from Centreville, Maryland (CL) have at least 8 C lambda segments. There appears to have been relatively recent amplifications of the C lambda gene segments in wild mice.

Evolution of mouse immunoglobulin lambda genes

The mouse has four C lambda and two V lambda genes. We have isolated Charon 4A clones that contain all six lambda genes from a BALB/c germ-line library. We present here the DNA sequences of the C lambda 2, C lambda 3, and C lambda 4 genes and also correct what are apparently errors in previous reports of C lambda 1 protein and DNA sequences. In addition, we have analyzed cloned DNAs by restriction mapping and electron microscopy to determine the relationships among the various lambda genes. By heteroduplex analysis, two gene clusters containing JC lambda 3--JC lambda 1 and JC lambda 2--JC lambda 4 show homology extending from the J regions 5' of C lambda 3/C lambda 2 to just 3' of C lambda 1/C lambda 4. Other than the region between the genes, very little homology exists in the C lambda flanking regions. In contrast, V lambda 1 and V lambda 2 genes show considerable homology extending into the 5' flanking regions. Large inverted repeats are found in the 5' flanking regions of V lambda 1 and C lambda 3, as well as in the 3' flanking regions of both C lambda gene clusters. DNA sequence divergences between the C lambda genes indicate that an ancestral JC lambda x--JC lambda g gene cluster arose at about the time of the first mammals by duplication of a primordial JC lambda gene. The data further suggest that the JC lambda x--JC lambda gene cluster duplicated after the speciation of mouse and man and subsequently diverged into the present day JC lambda 3--JC lambda 1 and JC lambda 2--JC lambda 4 gene clusters. C lambda 4, a pseudogene, became inactive at about the time of duplication of the ancestral JC lambda x--JC lambda y cluster. Comparison of DNA sequence divergence between the V lambda 1 and V lambda 2 genes demonstrates an anomaly. The percentage of amino acid replacement changes is approximately the same for V lambda 1/V lambda 2 as for C lambda 3/C lambda 2, implying that the ancestral V lambda gene was duplicated at the same time, and possibly together with, the JC lambda x--JC lambda y cluster. However, there are fewer silent changes than amino acid replacement changes between the V lambda 1/V lambda 2 genes, suggesting either that a selective pressure acted on the silent sites or that V lambda genes have only recently been duplicated. We also consider the possibility of a gene conversion event subsequent ot a more ancient duplication.

DNA sequences of the joining regions of mouse lambda light chain immunoglobulin genes

The joining (J) segments of mouse immunoglobulin lambda light chain genes, lambda 2, lambda 3, and a presumptive lambda 4, were cloned, and their sequences were determined and compared with that of lambda 1. Although all the lambda J segments share sequence homology, the J1 and J4 segments and the J2 and J3 segments, respectively, are more homologous. These sequence data, together with the fact that present day lambda genes occur in two clusters, 5' J3C3J1C1 3' and 5' J2C2J4C4 3', further substantiates a probable evolutionary duplication unit, JIICIIJICI, with II the precursor of lambda 3 and lambda 2 and I the precursor of lambda I and lambda 4. From the J4 sequence, we conclude that the lambda 4 gene is most likely nonfunctional (i.e., a pseudogene). The signal nonamer sequence 5' to J3 differs from that of J1 in two consecutive base pairs. This difference could account in part for the lower level of expression of lambda 3 as compared with lambda 1 in mouse serum.