Sequence transfers between variable regions in a mouse antibody transgene can occur by gene conversion

Different vertebrate species show widely differing usage of somatic hyperconversion (SHC) as a mechanism for diversifying expressed Ab V genes. The basis for the differing levels of SHC in different species is not known. Although no clear evidence for SHC has been found in normal mouse B cells, transgenic mice carrying high-copy numbers of a gene construct designed to optimize detection of SHC have previously been shown to exhibit sequence transfers that resemble gene conversion events. However, these transgene sequence transfers could reflect multistep or reciprocal DNA recombination events rather than gene conversions. We now find in low-copy number transgenic mice that transgene sequence transfers can exhibit the unidirectional sequence information movement that is a hallmark of gene conversion. This indicates that gene conversion between V region sequences can occur in mouse B cells; we propose that the lack of efficient SHC contributions to Ab diversification in normal mice may be due, at least in part, to the particular pattern of V gene recombinational accessibility that occurs in differentiating mouse B cells.     

Antigen-induced somatic diversification of rabbit IgH genes: gene conversion and point mutation.

During T cell-dependent immune responses in mouse and human, Ig genes diversify by somatic hypermutation within germinal centers. Rabbits, in addition to using somatic hypermutation to diversify their IgH genes, use a somatic gene conversion-like mechanism, which involves homologous recombination between upstream VH gene segments and the rearranged VDJ genes. Somatic gene conversion and somatic hypermutation occur in young rabbit gut-associated lymphoid tissue and are thought to diversify a primary Ab repertoire that is otherwise limited by preferential VH gene segment utilization. Because somatic gene conversion is rarely found within Ig genes during immune responses in mouse and human, we investigated whether gene conversion in rabbit also occurs during specific immune responses, in a location other than gut-associated lymphoid tissue. We analyzed clonally related VDJ genes from popliteal lymph node B cells responding to primary, secondary, and tertiary immunization with the hapten FITC coupled to a protein carrier. Clonally related VDJ gene sequences were derived from FITC-specific hybridomas, as well as from Ag-induced germinal centers of the popliteal lymph node. By analyzing the nature of mutations within these clonally related VDJ gene sequences, we found evidence not only of ongoing somatic hypermutation, but also of ongoing somatic gene conversion. Thus in rabbit, both somatic gene conversion and somatic hypermutation occur during the course of an immune response.     

Isotype switching of an immunoglobulin heavy chain transgene occurs by DNA recombination between different chromosomes

Transgenic mice carrying an immunoglobulin mu heavy chain transgene exhibit isotype switching of the transgene. We have now characterized the mechanism of transgene switching in these mice. The site of mu transgene insertion in one transgenic line has been localized to chromosome 5 using a series of polymorphic endogenous retroviruses as genetic markers in backcross mice. The endogenous immunoglobulin heavy chain locus resides on mouse chromosome 12, which shows that transgene isotype switching can occur between two different chromosomes even though normal antibody gene switching has generally been thought to occur within one chromosome. We find that transgene isotype switching involves interchromosomal DNA recombination, and our data suggest that the same enzymatic mechanisms mediate both normal isotype switch recombination and interchromosomal transgene switching. Our findings also support the notion that the isotype switching mechanism can induce chromosomal translocations such as observed for the c-myc gene in some B cell tumors.     

Brca1 in immunoglobulin gene conversion and somatic hypermutation

Defects in Brca1 confer susceptibility to breast cancer and genomic instability indicative of aberrant repair of DNA breaks. Brca1 was previously implicated in the homologous recombination pathway via effects on the assembly of recombinase Rad51. Activation-induced cytidine deaminase (AID) deaminates C to U in B lymphocyte immunoglobulin (Ig) DNA to initiate programmed DNA breaks. Subsequent uracil-glycosylase mediated U removal, and perhaps further processing, leads to four known classes of mutation: Ig class switch recombination that results in a region-specific genomic deletion, Ig somatic hypermutation that introduces point mutations in Ig V-regions, Ig gene conversion in vertebrates that possess Ig pseudo-V genes, and translocations common to B cell lymphomas. We tested the involvement of Brca1 in AID-dependent Ig diversification in chicken DT40 cells. The DT40 cell line diversifies IgVlambda mainly by gene conversion, and less so by point mutation. Brca1-deficiency caused a shift in Vlambda diversification, significantly reducing the proportion of gene conversions relative to point mutations. Thus, Brca1 regulates AID-dependent DNA lesion repair. Interestingly, while Brca1 is required to recruit ubiquitinated FancD2 to DNA damage, the phenotype of Brca1-deficient DT40 differs from the one of FancD2-deficient DT40, in which both gene conversion and non-templated mutations are impaired.     

Mutation pattern of immunoglobulin transgenes is compatible with a model of somatic hypermutation in which targeting of the mutator is linked to the direction of DNA replication.

We have previously demonstrated that B lymphocyte specific somatic mutations are introduced into the variable regions of immunoglobulin kappa transgenes in two independent transgenic mouse lines. The frequency, distribution and nature of these mutations strongly suggest that they arose as a result of the process of somatic hypermutation, which is responsible, in part, for affinity maturation during an immune response. Unexpectedly, in these multiple copy transgenic lines, many of the transgene copies showed no evidence of somatic mutation. This paradox was addressed by determining the sequence of each transgene copy in several B cell hybridomas derived from a mouse line carrying three copies of the kappa transgene. It was found that the somatic hypermutation process in different B cells from the same mouse preferentially targets one, but not the same, transgene copy. We present a model, based on the pattern of this targeting, which links somatic hypermutation to the orientation of the Ig gene relative to the direction of DNA replication.     

Gene conversion and hypermutation during diversification of VH sequences in developing splenic germinal centers of immunized rabbits

The young rabbit appendix and the chicken bursa of Fabricius are primary lymphoid organs where the B cell Ab repertoire develops in germinal centers (GCs) mainly by a gene conversion-like process. In human and mouse, V-gene diversification by somatic hypermutation in GCs of secondary lymphoid organs leads to affinity maturation. We asked whether gene conversion, somatic hypermutation, or both occur in rabbit splenic GCs during responses to the hapten DNP. We determined DNA sequences of rearranged heavy and light chain V region gene segments in single cells from developing DNP-specific GCs after immunization with DNP-bovine gamma-globulin and conclude that the changes at the DNA level that may lead to affinity maturation occur by both gene conversion and hypermutation. Selection was suggested by finding some recurrent amino acid replacements that may contribute increased affinity for antigen in the complementarity-determining region sequences of independently evolved clones, and a narrower range of complementarity-determining region 3 lengths at day 15. Some of the alterations of sequence may also lead to new members of the B cell repertoire in adult rabbits comparable with those produced in gut associated lymphoid tissues of young rabbits.     

Somatic hypermutation of immunoglobulin kappa may depend on sequences 3'' of C kappa and occurs on passenger transgenes.

We have compared the pattern of somatic mutation in different immunoglobulin kappa transgenes and suggest that an element(s) located between 1 kb and 9 kb 3' of C kappa is necessary for somatic hypermutation of the antibody V gene. The sequences of transgenic and endogenous Ig V regions were determined in antigen-specific B cell hybridomas specific for 2-phenyloxazolone from independent lines of hyperimmunized transgenic mice. We analysed somatic mutation of the transgene both in hybridomas in which the transgenic kappa chain contributes to the antigen combining site as well as in hybridomas in which the transgene is a passenger with the expressed antibody being composed of endogenously-encoded heavy and light chains. In both cases, nucleotide changes in the transgene are correctly targeted to the V region and are absent from the C region. They accumulate at a similar rate to that in the endogenous Ig genes within the same cell and we find that, irrespective of whether or not the transgene kappa is directly selected by antigen, somatic mutation occurs at a similar rate and involves only single base substitutions. Furthermore, the pattern of mutations in passenger transgenes gives information about the intrinsic sequence specificities of the somatic hypermutation mechanism.     

AID is essential for immunoglobulin V gene conversion in a cultured B cell line

Following productive V gene rearrangement, the functional immunoglobulin genes in the B lymphocytes of man and mouse are subjected to two further types of genetic modification. Class-switch recombination, a region-specific but largely nonhomologous recombination process, leads to a change in constant region of the expressed antibody. Somatic hypermutation introduces multiple single nucleotide substitutions in and around the rearranged V gene segments and underpins affinity maturation. However, in chicken and rabbits (but not man or mouse), an additional mechanism, gene conversion, is a major contributor to V gene diversification. It has been demonstrated recently that both switch recombination and hypermutation are ablated in mice and humans lacking AID, a B cell-specific protein of unknown molecular activity. Here we show that disruption of AID in the DT40 chicken B cell lymphoma leads to a failure to perform immunoglobulin V gene conversion. Thus, AID is required for all three immunoglobulin gene modification programs (gene conversion, hypermutation, and switch recombination) and acts in the initiation or execution of these processes rather than in bringing the B cell to an appropriate stage of differentiation.     

I.29 lymphoma cells express a nonmutated VH gene before and after H chain switch

The I.29 B cell lymphoma consists of IgM+ and IgA+ cells which express the same germ-line VH gene. IgA+ cells of the I.29 lymphoma were derived from the IgM+ cells by a typical H chain switch recombination event. The IgM+ cells can be induced with LPS to undergo H chain switching in culture. It has been proposed that the somatic hypermutation process is activated during H chain switch, since V genes expressed in IgG+ and IgA+ cells have more frequently undergone mutation than those expressed in IgM+ cells. We have investigated this question by sequencing VH genes expressed before and after H chain switch in the I.29 lymphoma. We have also sequenced the germ-line VH gene corresponding to the gene expressed by I.29 cells to determine whether the VH gene expressed in the IgM+ cells had already undergone somatic mutation. Our results indicate that somatic mutation was not activated in the precursor cell for the I.29 lymphoma, nor during isotype switch in I.29 cells. It is possible that cells of the I.29 lymphoma, or their precursor, have not received the signal which induces somatic mutation, or that I.29 cells belong to a subset of B cells that cannot be induced to undergo any (or much) somatic mutation.     

The block in immunoglobulin class switch recombination caused by activation-induced cytidine deaminase deficiency occurs prior to the generation of DNA double strand breaks in switch mu region

Affinity maturation of the Ab repertoire in germinal centers leads to the selection of high affinity Abs with selected heavy chain constant regions. Ab maturation involves two modifications of the Ig genes, i.e., somatic hypermutation and class switch recombination. The mechanisms of these two processes are not fully understood. As shown by the somatic hypermutation and class switch recombination-deficient phenotype of activation-induced cytidine deaminase (AID)-deficient patients (hyperIgM type 2 syndrome) and mice, both processes require the AID molecule. Somatic DNA modifications require DNA breaks, which, at least for class switch recombination, lead to dsDNA breaks. By using a ligation-mediated PCR, it was found that class switch recombination-induced dsDNA breaks in S mu switch regions were less frequent in AID-deficient B cells than in AID-proficient B cells, thus indicating that AID acts upstream of DNA break induction.     

Checkpoint kinase 1 negatively regulates somatic hypermutation

Immunoglobulin (Ig) diversification by somatic hypermutation in germinal center B cells is instrumental for maturation of the humoral immune response, but also bears the risk of excessive or aberrant genetic changes. Thus, introduction of DNA damage by activation-induced cytidine deaminase as well as DNA repair by multiple pathways need to be tightly regulated during the germinal center response to prevent lymphomagenesis. In the present study, we show that DNA damage checkpoint signaling via checkpoint kinase 1 (Chk1) negatively regulates somatic hypermutation. Chk1 inhibition in human B cell lymphoma lines as well as inactivation of Chk1 alleles by gene targeting in DT40 B cells leads to increased somatic hypermutation. This is apparently due to changes in DNA repair pathways regulated by Chk1, such as a decreased homologous recombination efficiency that also leads to decreased Ig gene conversion in DT40. Our data show that Chk1 signaling plays a crucial role in regulation of Ig diversification and sheds unexpected light on potential origins of aberrant somatic hypermutation in B cell lymphomagenesis.     

Variable-region-identical antibodies differing in isotype demonstrate differences in fine specificity and idiotype

A central tenet of the current understanding of the relationship between Ab structure and function is that the variable region domain is solely responsible for Ag specificity. However, this view was recently challenged by the observation that families of mouse-human chimeric Abs with identical V regions demonstrate differences in fine specificity and by reports of changes in Ab Id structure with isotype switching. Here we revisited this question by evaluating the reactivity of two families of murine IgG switch variants that differed in V region usage for Cryptococcus neoformans glucuronoxylomannan, glucuronoxylomannan peptide mimetics, and anti-Id mAbs. The results reveal isotype-related differences in fine specificities and Id for two mAb isotype switched families, thus establishing the validity of this observation with sets of homologous Abs. The results suggest that the C region affects V region protein conformation, leading to differences in fine specificity and Id. The finding that isotype can affect fine specificity has major implications for current concepts of the generation of secondary responses, idiotypic network regulation, and isotype function. Given that isotype class switching and Ig gene somatic hypermutation share molecular mechanisms, these observations unify these processes in the sense that both can alter specificity and affinity.     

Activation-induced cytidine deaminase initiates immunoglobulin gene conversion and hypermutation by a common intermediate

Depending on the species and the lymphoid organ, activation-induced cytidine deaminase (AID) expression triggers diversification of the rearranged immunoglobulin (Ig) genes by pseudo V (ψV) gene- templated gene conversion or somatic hypermutation. To investigate how AID can alternatively induce recombination or hypermutation, ψV gene deletions were introduced into the rearranged light chain locus of the DT40 B-cell line. We show that the stepwise removal of the ψV donors not only reduces and eventually abolishes Ig gene conversion, but also activates AID-dependent Ig hypermutation. This strongly supports a model in which AID induces a common modification in the rearranged V(D)J segment, leading to a conversion tract in the presence of nearby donor sequences and to a point mutation in their absence.     

Checkpoint kinase 2 is required for efficient immunoglobulin diversification

Maintenance of genome integrity relies on multiple DNA repair pathways as well as on checkpoint regulation. Activation of the checkpoint kinases Chk1 and Chk2 by DNA damage triggers cell cycle arrest and improved DNA repair, or apoptosis in case of excessive damage. Chk1 and Chk2 have been reported to act in a complementary or redundant fashion, depending on the physiological context. During secondary immunoglobulin (Ig) diversification in B lymphocytes, DNA damage is abundantly introduced by activation-induced cytidine deaminase (AID) and processed to mutations in a locus-specific manner by several error-prone DNA repair pathways. We have previously shown that Chk1 negatively regulates Ig somatic hypermutation by promoting error-free homologous recombination and Ig gene conversion. We now report that Chk2 shows opposite effects to Chk1 in the regulation of these processes. Chk2 inactivation in B cells leads to decreased Ig hypermutation and Ig class switching, and increased Ig gene conversion activity. This is linked to defects in non-homologous end joining and increased Chk1 activation upon interference with Chk2 function. Intriguingly, in the context of physiological introduction of substantial DNA damage into the genome during Ig diversification, the 2 checkpoint kinases thus function in an opposing manner, rather than redundantly or cooperatively.     

B cells

B cells are an important component of adaptive immunity. They produce and secrete millions of different antibody molecules, each of which recognizes a different (foreign) antigen. The fact that humans express a very large repertoire of antibodies is due to the complex mechanism of V(D)J recombination of immunoglobulin (Ig) genes as well as other processes including somatic hypermutation, gene conversion and class switching. The B cell receptor (BCR) is an integral membrane protein complex that is composed of two Ig heavy chains, two Ig light chains and two heterodimers of Igalpha and Igbeta. To eliminate foreign antigens, B cells cooperate with other cells of the immune system including macrophages, dendritic cells and T cells. B cell development is a tightly controlled process in which over 75% of the developing cells become apoptotic because of inappropriate immunoglobulin gene rearrangements or recognition of self antigens by Igs. Hence, the majority of B cell-associated disorders are caused by the incorrect function of genes/proteins involved in B cell development.     

Rad9 Is Required for B Cell Proliferation and Immunoglobulin Class Switch Recombination

B cell maturation and B cell-mediated antibody response require programmed DNA modifications such as the V(D)J recombination, the immunoglobulin (Ig) class switch recombination, and the somatic hypermutation to generate functional Igs. Many protein factors involved in DNA damage repair have been shown to be critical for the maturation and activation of B cells. Rad9 plays an important role in both DNA repair and cell cycle checkpoint control. However, its role in Ig generation has not been reported. In this study, we generated a conditional knock-out mouse line in which Rad9 is deleted specifically in B cells and investigated the function of Rad9 in B cells. The Rad9^−/− B cells isolated from the conditional knock-out mice displayed impaired growth response and enhanced DNA lesions. Impaired Ig production in response to immunization in Rad9^−/− mice was also detected. In addition, the Ig class switch recombination is deficient in Rad9^−/− B cells. Taken together, Rad9 plays dual roles in generating functional antibodies and in maintaining the integrity of the whole genome in B cells.