Lack of detectable somatic hypermutation in the V region of the Ig H chain gene of a human chronic B lymphocytic leukemia

Monoclonal human B cell tumors are a model system for the study of somatic hypermutation of the Ig genes of humans. It was previously shown that a number of B cell lymphomas exhibited striking V region point mutation, hypothesized to result from the somatic hypermutation mechanism. In this study we have extended the analysis to chronic lymphocytic leukemia. We have cloned and sequenced the productive Vh representing five different cells from a monoclonal chronic lymphocytic leukemia. All five Vh sequences were identical. Therefore, the Vh region in this leukemia was not the subject of detectable somatic mutation. These data suggest that chronic lymphocytic leukemia might lack the mechanism for somatic hypermutation and represent a stage of normal B lymphocyte differentiation in which the somatic hypermutation mechanism is not active.     

Somatic hypermutation and the three R's: repair, replication and recombination

Somatic hypermutation introduces single base changes into the rearranged variable (V) regions of antigen activated B cells at a rate of approximately 1 mutation per kilobase per generation. This is nearly a million-fold higher than the typical mutation rate in a mammalian somatic cell. Rampant mutation at this level could have a devastating effect, but somatic hypermutation is accurately targeted and tightly regulated. Here, we provide an overview of immunoglobulin gene somatic hypermutation; discuss mechanisms of mutation in model organisms that may be relevant to the hypermutation mechanism; and review recent advances toward understanding the possible role(s) of DNA repair, replication, and recombination in this fascinating process.     

A new model of sheep Ig diversification: shifting the emphasis toward combinatorial mechanisms and away from hypermutation

The current model of Ig repertoire development in sheep focuses on the rearrangement of a small number (approximately 20) of Vlambda gene segments. It is believed that this limited combinatorial repertoire is then further diversified through postrearrangement somatic hypermutation. This process has been reported to introduce as many as 110 mutations/1000 nucleotides. In contrast, our data have that indicated somatic hypermutation may diversify the preimmune repertoire to a much lesser extent. We have identified 64 new Vlambda gene segments within the rearranged Ig repertoire. As a result, many of the unique nucleotide patterns thought to be the product of somatic hypermutation are actually hard-coded within the germline. We suggest that combinatorial rearrangement makes a much larger contribution, and somatic hypermutation makes a much smaller contribution to the generation of diversity within the sheep Ig repertoire than is currently acknowledged.     

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.     

Inferring processes underlying B-cell repertoire diversity

We quantify the VDJ recombination and somatic hypermutation processes in human B cells using probabilistic inference methods on high-throughput DNA sequence repertoires of human B-cell receptor heavy chains. Our analysis captures the statistical properties of the naive repertoire, first after its initial generation via VDJ recombination and then after selection for functionality. We also infer statistical properties of the somatic hypermutation machinery (exclusive of subsequent effects of selection). Our main results are the following: the B-cell repertoire is substantially more diverse than T-cell repertoires, owing to longer junctional insertions; sequences that pass initial selection are distinguished by having a higher probability of being generated in a VDJ recombination event; somatic hypermutations have a non-uniform distribution along the V gene that is well explained by an independent site model for the sequence context around the hypermutation site.     

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.     

应用mTR-/-鼠模型系统研究肿瘤发生机制的进展

端粒酶是真核细胞体内的一种核糖核酸蛋白质复合体,是一种特殊的DNA聚合酶,具有延伸DNA末端的功能,能够维持端粒长度和功能,TERT具有反转录酶活性。在大多数体细胞和原代细胞中,端粒酶活性很低,通常检测不到,但在肿瘤细胞中,端粒酶则被广泛激活,因此认为端粒酶与肿瘤的发生具有密切的关系,本介绍了应用端粒酶阴性鼠研究端粒酶与G链悬垂和P53在肿瘤的发生过程中的相互关系。     

A/T-targeted somatic hypermutation: critique of the mainstream model

The "affinity maturation" of the humoral immune response is driven by antigen-activated somatic hypermutation (SHM) of the genes that encode antibody variable regions and the subsequent antigenic selection of mutant clones. The molecular mechanism of SHM is yet to be completely elucidated. SHM affects cytosine-guanine (C/G) and adenine-thymine (A/T) pairs with approximately equal frequency in vivo. The proposition that error-prone DNA-dependent DNA synthesis explains A/T-targeted hypermutagenesis seems to have mainstream support within the hypermutation research community at present. A major feature of SHM in vivo is that C/G hypermutation is strand unbiased, whereas A/T hypermutation is strand biased. We show that the "DNA-based polymerase error" model of A/T-targeted hypermutagenesis does not explain this important aspect of SHM.     

T cells can induce somatic mutation in B cell receptor-engaged BL2 Burkitt's lymphoma cells independently of CD40-CD40 ligand interactions

The B cell surface trigger(s) and the molecular mechanism(s) of somatic hypermutation remain unknown, partly because of the lack of amendable in vitro models. Recently, however, we reported that upon B cell receptor cross-linking and coculture with activated T cells, the Burkitt's lymphoma cell line BL2 introduces mutations in its IgVH gene in vitro. We now confirm the relevance of our culture model by establishing that the entire spectrum of somatic mutations observed in vivo, including insertions and deletions, could be found in the DNA of BL2 cells. Additionally, we show that among four human B cell lines, only two with a centroblast-like phenotype can be induced to mutate. Triggering of somatic mutations in BL2 cells requires intimate T-B cell contacts and is independent of CD40-CD40-ligand (CD40L) interactions as shown by 1) the lack of effect of anti-CD40 and/or anti-CD40L blocking Abs on somatic mutation and 2) the ability of a CD40L-deficient T cell clone (isolated from an X-linked hyper-IgM syndrome patient) to induce somatic mutation in B cell receptor-engaged BL2 cells. Thus, our in vitro model reveals that T-B cell membrane interactions through surface molecules different from CD40-CD40L can trigger somatic hypermutation.     

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.