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.

The mu switch region tandem repeats are important, but not required, for antibody class switch recombination.

Class switch DNA recombinations change the constant (C) region of the antibody heavy (H) chain expressed by a B cell and thereby change the antibody effector function. Unusual tandemly repeated sequence elements located upstream of H chain gene exons have long been thought to be important in the targeting and/or mechanism of the switch recombination process. We have deleted the entire switch tandem repeat element (S(mu)) from the murine (mu) H chain gene. We find that the S(mu) tandem repeats are not required for class switching in the mouse immunoglobulin H-chain locus, although the efficiency of switching is clearly reduced. Our data demonstrate that sequences outside of the S(mu) tandem repeats must be capable of directing the class switch mechanism. The maintenance of the highly repeated S(mu) element during evolution appears to reflect selection for a highly efficient switching process rather than selection for a required sequence element.

Somatic hypermutation of an immunoglobulin mu heavy chain transgene.

We have analyzed somatic hypermutation of an immunoglobulin (Ig) heavy chain transgene. Hybridomas expressing the transgene were produced from immunized transgenic mice and transgene copies were sequenced to assay for mutation. In two IgM-producing hybridomas, as well as in several IgG-producing hybridomas, mutations were found in the VDJ region of the transgene. In the IgM-producing hybridomas, both mutated and unmutated transgene copies were present and expressed as mRNA. Several mutated transgene copies were present in a single cell and these showed different patterns of mutation. Two IgG-producing hybridomas isolated from a single animal also showed a hierarchical pattern of mutation indicating that transgene mutations can accumulate during B cell proliferation, similar to the mutational process for endogenous antibody genes. Among hybridomas that expressed both IgG and IgM molecules derived from the transgene, the isotype-switched gamma transgene copy exhibited a higher level of mutation than the mu transgene copies. Our results indicate that the 15-kb ARSmu transgene contains all the sequence information required to target the Ig-specific hypermutational machinery, and raise the possibility that sequences associated with the endogenous CH locus might enhance somatic mutation.

Analysis of sequence transfers resembling gene conversion in a mouse antibody transgene.

The role of gene conversion in murine immunoglobulin gene diversification is unclear. An antibody gene construct designed to provide the homologous donor and acceptor sequences required for conversion mechanisms was produced and used to generate transgenic mice. When these transgenic mice were immunized, DNA sequence transfers between tandem transgene VDJ regions were detectable and resembled gene conversion events. There is a strong link between these conversion-like sequence transfers and transgene somatic hypermutation, suggesting that both processes might occur at the same stage of B cell differentiation.

Conformations of A,T-rich DNAs.

DNAs from the genomes of Clostridium perfringens and Cytophaga johnsonii display orthodox A-DNA and B-DNA structures despite their high (A+L) nucleotide content. Unique structures, such as those found for synthetic DNAs having specific special sequences, do therefore not necessarily occur for DNAs having more random base sequence even if these have unusual base compositions. Clostridium perfringens DNA exhibits unusual structural properties only prior to purification by gel filtration.

Somatic mutation of immunoglobulin light-chain variable-region genes.

A single germline immunoglobulin kappa-variable-region gene, VK167, is rearranged and expressed in two myelomas, MOPC167 and MOPC511. Only this single germline gene displays close homology to the expressed genes. Neither of the rearranged, functional genes, however, has a nucleotide sequence that is identical to the germline VK167 gene. Both active genes display several single-base-pair mutations with respect to the germline sequence. The nucleotide sequence data predict the alteration of a restriction-enzyme-recognition site within the VK167 gene between germline cells and cells producing the MOPC167 light-chain protein. Based on this restriction-site alteration, Southern blot analysis proves unambiguously that no gene present in the germline BALB/c mouse genome contains the exact VK167 nucleotide sequence found in cells committed to MOPC167 antibody production. Instead the alterations found in the expressed MOPC167 and MOPC511 V-region genes have apparently arisen by a process of somatic mutation during cellular differentiation. Since nucleotide alterations are found in framework and hypervariable portions of the variable region, the mechanism of somatic mutation is not limited to hypervariable sequences. In addition, Southern blot hybridization indicates that the observed mutations did not arise by recombinational events, but are single-base-pair substitutions. Based on the distribution of mutations that have been found in expressed immunoglobulin variable-region genes, a model that links the introduction of somatic mutations to DNA replication during the V-J joining event is proposed.

Mapping of immunoglobulin variable region genes: relationship to the 'deletion' model of immunoglobulin gene rearrangement.

Five families of variable region genes of mouse kappa chains were analyzed by Southern blot hybridization to determine their relative chromosomal map positions. Map positions were deduced by Vk gene deletion from antibody-producing cells expressing upstream Vk genes and retention in cells expressing downstream genes. The Vk regions expressed in the myelomas M0PC167, MPC11, M0PC21 and ABPC20 are members of Vk families exhibiting one, three, six and six major germline hybridization bands respectively. The gene order of the five families in germline DNA was found to be VM167-VM11-(VM21, VA20)-VABE8-Jk-Ck. As expected in a deletion model of immunoglobulin gene rearrangement, a sequence located just 5' of J1 in germline DNA was found to be absent from some antibody producing cells which had not retained any germline Ck genes. However, other cell lines contained this sequence in rearranged contexts, suggesting that any deletion model of immunoglobulin V-J joining, as well as V gene mapping, must take into account the possibilities of stepwise rearrangements and reintegration of "deleted" DNA.

Polynucleotide block polymers consisting of a DNA.RNA hybrid joined to a DNA.DNA duplex. Synthesis and characterization of dGn.rCidCk duplexes.

The synthesis of several nucleic acid block polymers of the general type dGn.rCidCk is described. The key steps in this procedure were the joining of dCk oligomers, protected at the 3'-OH with an acetyl group, to rCi oligomers by T4 DNA ligase and the purification of the products by RPC-5 column chromatography. The block polymers were characterized by 20% polyacrylamide gel electrophoresis, UV and CD spectra, analytical Cs2SO4 buoyant density analyses, helix-coil transitions and S1 nuclease studies. NMR studies on one member of this series, dGn.rC11dC16, were reported recently (Selsing, E., Wells, R.D., Early, T.A., and Kearns, D.R. (1978) Nature 275, 249-250). The NMR studies and the results described herein indicate that these block polymers are linear duplexes with two adjoining conformations yet are hydrogen-bonded and base-stacked throughout with minimal disruption of the helix at the junction of the two conformations. Computer model building studies described in the following paper (Selsing, E., Wells, R.D., Alden, C.J., and Arnott, S. (1979) J. Biol. Chem. 254, 5417-5422) predict that these nucleic acids contain a bend at the junction region.

Immunoglobulin gene 'remnant' DNA--implications for antibody gene recombination.

Many immunoglobulin (Ig)-producing cells retain the DNA that separates Ig variable (V) and constant (C) region genes in the germline. This "remnant" DNA must be moved during the recombination process that joins V and C genes via a joining (J) segment. We have analyzed remnant DNAs in several Ig-producing cell lines. The nucleotide sequences of kappa (kappa) light chain remnant DNAs indicate close relationships to V-J joining. We find fused V kappa and J kappa recognition sequences in five remnant DNAs, suggesting reciprocal relationships to the fused V kappa and J kappa segments produced by V-J joining. However, of sixteen plasmacytoma remnant DNAs analyzed, all involve only recombination with J kappa l. Thus, in most cell lines, remnant DNAs are not directly reciprocal to recombined kappa-genes. On the other hand, our analyses of some myelomas do indicate indirect relationships between remnant DNAs and kappa-genes. Our results suggest that multiple steps of DNA recombination occur during Ig-gene rearrangement. Because remnant DNA joining sites do not exhibit the flexibility that has been observed in Ig-gene V-J joining, our findings also suggest that the joining mechanism may involve endonuclease, exonuclease and ligase activities.

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.

Preparation of triple-block DNA polymers using recombinant DNA techniques.

The construction of several recombinant plasmid derivatives containing novel triple-block DNA sequence insertions is described. The protocol for these constructions involves synthesis of a heterogenous mixture of block oligomer duplexes, : formula: (see text), using pancreatic deoxyribonuclease and terminal transferase. The synthetic duplexes were mixed with linearized and dG-tailed vectors and the DNA mixture used to transform E. coli. Triple-block sequences of the type dGidAjdCk.dGkdTjdCi, characterized by DNA sequencing, were inserted into the Bam HI site of pBR322 and next to the lac wild-type and UV5 promoter regions in pRW26 and pRW28. Similarly, sequences were inserted into the Sma I site of pACYC189 and could be excised by cleavage with Sma I since the procudure regenerates the recognition site. The approach provides a technique for the synthesis of a large family of defined sequence triple-block polymers in essentially unlimited amounts. Although these inserts contain sequences which have the potential for forming stable hairpin structures, the recombinant plasmids are stable and appear to replicate normally.

Gene conversion and homologous recombination in murine B cells.

Gene conversion has been found to be important in the diversification of antibody genes in chickens and in rabbits. In other species, however, it is not clear whether gene conversion plays any role in antibody diversity. Analysis of an H-chain antibody gene construct that was designed to optimize the detection of gene conversion events in transgenic mice has shown that sequence transfers that resemble gene conversion events can occur in murine B cells and are associated with somatic hypermutation. This raises the possibility that an error-prone gene conversion mechanism might play a role in murine somatic hypermutation.

Novel kappa light-chain gene rearrangements in mouse lambda light chain-producing B lymphocytes.

The genes that encode the immunoglobulin proteins made by B lymphocytes are made up of segments that are separately encoded in the germ-line genome and brought together by recombination during B-cell ontogeny. There are two types of immunoglobulin light chain, kappa and lambda, but only a single type is expressed in individual B cells. It is thought that kappa gene recombination precedes lambda gene recombination during B-cell ontogeny. We describe here unusual recombinations that have occurred in two lambda-producing B-cell lines and suggest that they are involved in the developmental switch from kappa to lambda gene expression in maturing B cells. These recombinations involve the J kappa-C kappa introns of V-J joined but nonfunctional kappa genes and a sequence that in the germ line occurs downstream of the C kappa exon (called RS, for recombining sequence).

Misalignment of V and J gene segments resulting in a nonfunctional immunoglobulin gene.

The myeloma variant NS-1n has lost the functional immunoglobulin kappa gene which is present in its parent, myeloma MOPC-21. The variant retains a nonfunctional rearranged gene, M.21N, which undergoes RNA transcription and processing to yield a mature size kmRNA. This kRNA, however, is not translated into kappa polypeptide chains. The nonfunctional gene was cloned into Charon 4A to determine the basis for its inactivity. Nucleotide sequence analysis of a DNA fragment overlapping the V-J recombination site in the M.21N gene indicated that a misalignment had taken place during somatic recombination. This misalignment results in a deletion of four nucleotides at the 3' end of the V gene and, thus, a translational reading frame shift. In other respects the M.21n V gene, which corresponds to a different VK subgroup than the functional gene of MOPC-21, appears normal.

Rearranged and germline immunoglobulin kappa genes: different states of DNase I sensitivity of constant kappa genes in immunocompetent and nonimmune cells.

The rearrangement of a variable (V) and a constant (C) gene appears to be a necessary prerequisite for immunoglobulin gene expression. Multiple different rearranged kappa genes were found in several mouse myelomas, although these cells produce only one type of kappa chain [Wilson, R., Miller, J., & Storb, U. (1979) Biochemistry 18, 5013--5021]. It is therefore of interest to understand how only one allele within a lymphoid cell becomes expressed, while the other allele remains nonfunctional ("allelic exclusion"). We have studied the chromatin conformation of kappa genes by making use of the preferential digestion of potentially active genes by DNase I described, for example, for globin genes [Weintraub, H., & Groudine, M. (1976) Science (Washington, D.C.) 193, 848--856]. The DNase I sensitivity of kappa genes in myeloma tumors, in a B cell lymphoma, and in liver was determined by hybridization with DNA on Southern blots. It was found that rearranged C kappa genes are DNase I sensitive in myelomas in which several kappa genes are rearranged, regardless of whether the rearranged genes code for the kappa chains synthesized by the cell. Furthermore, the C kappa gene in germline configuration is also DNase I sensitive in a B cell lymphoma; i.e., it is in the same chromatin state as the rearranged C kappa gene which probably codes for the kappa chains produced by the cell. The altered chromatin state appears to be localized: V kappa genes in germline context are not DNase I sensitive in myeloma or B lymphoma cells while C kappa genes present in a kappa gene cluster on the same chromosomes are sensitive. When rearranged, however, the V kappa genes are as sensitive to DNase I as are rearranged C kappa genes. V lambda and C lambda genes are not DNase I sensitive in kappa myelomas. Thus, commitment to kappa gene expression is apparently correlated with a chromatin conformation which confers increased DNase I sensitivity to the DNA in the vicinity of all C kappa genes in the cell. "Allelic exclusion" does not operate on the level of chromatin conformation which can be detected by altered DNase I sensitivity.