Immunoglobulin gene conversion: insights from bursal B cells and the DT40 cell line.

Chicken B cells diversify their immunoglobulin (Ig) light and heavy chain genes by pseudogene templated gene conversion within the bursa of Fabricius. Although Ig gene conversion was initially believed to occur only in birds, it is now clear that most farm animals also use this elegant mechanism to develop an immunoglobulin gene repertoire. The best model to study Ig gene conversion remains the chicken Ig light chain locus due to its compact size and the fact that all the pseudogene donors are sequenced. Furthermore, gene conversion continues in the bursa-derived DT40 cell line whose genome can be easily modified by targeted integration of transfected constructs. Disruption of the AID gene, which had been shown to control somatic hypermutation and switch recombination in mammals leads to a complete block of gene conversion in DT40 indicating that all B-cell specific repertoire formation is controlled by the same gene. Here, we review the genetics and the molecular mechanism of Ig gene conversion based on sequence analysis of bursal B cells and gene disruption studies in the DT40 cell line.     

The chicken B cell line DT40: a novel tool for gene disruption experiments

The use of the chicken DT40 B cell line is increasing in popularity due to the ease with which it can be manipulated genetically. It offers a targeted to random DNA integration ratio of more than 1:2, by far exceeding that of any mammalian cell line. The facility with which knockout cell lines can be generated, combined with a short generation time, makes the DT40 cell line attractive for phenotype analysis of single and multiple gene disruptions. Advantage has been taken of this to investigate such diverse fields as B cell antigen receptor (BCR) signaling, cell cycle regulation, gene conversion and apoptosis. In this review, we give a historical introduction and a practical guide to the use of the DT40 cell line, along with an overview of the main topics being researched using the DT40 cell line as a model system. These topics include B cell-specific subjects such as B cell signaling and Ig rearrangement, and subjects common to all cell types such as apoptosis, histones, mRNA modification, chromosomal maintenance and DNA repair. Attention is in each case brought to peculiarities of the DT40 cell line that are of relevance for the subject. Novel applications of the cell line, e.g., as a vector for gene targeting of human chromosomes, are also discussed in this review.     

Karyotype stability of the DT40 chicken B cell line: Macrochromosome variation and cytogenetic mosaicism

The DT40 transformed chicken B-cell line is an important and widely used vertebrate cell line. Knowledge of the 'wild-type' DT40 karyotype is a significant consideration for most research applications and for extrapolation of results to normal cells. Here we present data indicating that (1) modal karyotype differences exist between DT40 cultures from different sources, (2) DT40 cultures are cytogenetically mosaic, and (3) the mosaic features can change over time with media conditions influencing the degree and type of non-modal karyotypes that emerge. In addition to the previously reported trisomy for chromosome 2, a monosomy for chromosome 4 and a variant 4p- are described. The macrochromosomal variation and mosaic nature of the DT40 system should alert researchers using this important cell line to consider whether such variation will impact experimental results and interpretation. The results are discussed in regard to current knowledge of cytogenetic anomalies associated with chicken cancers.     

The CENP-O complex requirement varies among different cell types

CENP-U (CENP-50) is a component of the CENP-O complex, which includes CENP-O, CENP-P, CENP-Q, CENP-R, and CENP-U and is constitutively localized at kinetochores throughout the cell cycle in vertebrates. Although CENP-U deficiency results in some mitotic defects in chicken DT40 cells, CENP-U-deficient chicken DT40 cells are viable. To examine the functional roles of CENP-U in an organism-dependent context, we generated CENP-U-deficient mice. The CENP-U-deficient mice died during early embryogenesis (approximately E7.5). Thus, conditional CENP-U-deficient mouse ES cells were generated to analyze CENP-U-deficient phenotypes at the cell level. When CENP-U was disrupted in the mouse ES cells, all CENP-O complex proteins disappeared from kinetochores. In contrast, other kinetochore proteins were recruited in CENP-U-deficient mouse ES cells as CENP-U-deficient DT40 cells. However, the CENP-U-deficient ES cells died after exhibiting abnormal mitotic behavior. Although CENP-U was essential for cell viability during mouse early embryogenesis, CENP-U-deficient mouse embryonic fibroblast cells were viable, similar to the DT40 cells. Thus, although both DT40 and ES cells with CENP-U deficiency have similar mitotic defects, cellular responses to mitotic defects vary among different cell types.     

Chicken B-cell-activating factor: regulator of B-cell survival in the bursa of fabricius

Previous studies on mammals have demonstrated that a tumour necrosis factor family member, B-cell-activating factor (BAFF) (BlyS, TALL-1), is mainly produced by myeloid and dendritic cells and that BAFF promotes B-cell differentiation and survival in a paracrine fashion. We have recently shown that BAFF is upregulated at the bursal stage of the avian B-cell development. We now show that the avian bursal B cells and B-cell lines, RP-9, RP-13 and DT40, express chicken BAFF (cBAFF). In situ hybridization confirms strong cBAFF expression within the bursal follicles. Like mammals, cBAFF is expressed in the avian myeloblast and myelomonocytic cell lines but not in the peripheral blood alphabeta and gammadelta T cells. The binding of recombinant human BAFF (hBAFF) to the bursal B-cells indicates a conserved receptor-ligand binding. Furthermore, the recombinant hBAFF has a positive effect on bursal cell proliferation and transiently inhibits cell death in vitro. In conclusion, cBAFF is highly conserved structurally, but as a novel observation we suggest cBAFF to function in an autocrine fashion to promote the growth and maturation of follicular B cells in bursa of Fabricius.     

Loss of splicing factor ASF/SF2 induces G2 cell cycle arrest and apoptosis, but inhibits internucleosomal DNA fragmentation

ASF/SF2 is an SR protein splicing factor that participates in constitutive and alternative pre-mRNA splicing and is essential for cell viability. Using a genetically modified chicken B-cell line, DT40-ASF, we now show that ASF/SF2 inactivation results in a G2-phase cell cycle arrest and subsequent programmed cell death. However, although several hallmarks of apoptosis are apparent, internucleosomal DNA fragmentation was not detected. Furthermore, inactivation of ASF/SF2 also blocks DNA fragmentation normally induced by a variety of apoptotic stimuli. Notably, mRNA encoding the inhibitor of caspase-activated DNase-L (ICAD-L), which acts as an inhibitor as well as a chaperone of caspase-activated DNase (CAD), decreased in abundance, whereas the level of mRNA encoding ICAD-S, which has only inhibitory activity, increased upon ASF/SF2 depletion. Strikingly, expression of appropriate levels of exogenous human ICAD-L restored apoptotic DNA laddering in ASF/SF2-depleted cells. These results not only indicate that loss of an SR protein splicing factor can induce cell cycle arrest and apoptosis, but also illustrate the important role of ICAD and its regulation by alternative splicing in the process of apoptotic DNA fragmentation.     

Rescue of Targeted Regions of Mammalian Chromosomes by in Vivo Recombination in Yeast

In contrast to other animal cell lines, the chicken pre-B cell lymphoma line, DT40, exhibits a high level of homologous recombination, which can be exploited to generate site-specific alterations in defined target genes or regions. In addition, the ability to generate human/chicken monochromosomal hybrids in the DT40 cell line opens a way for specific targeting of human genes. Here we describe a new strategy for direct isolation of a human chromosomal region that is based on targeting of the chromosome with a vector containing a yeast selectable marker, centromere, and an ARS element. This procedure allows rescue of the targeted region by transfection of total genomic DNA into yeast spheroplasts. Selection for the yeast marker results in isolation of chromosome sequences in the form of large circular yeast artificial chromosomes (YACs) up to 170 kb in size containing the targeted region. These YACs are generated by homologous recombination in yeast between common repeated sequences in the targeted chromosomal fragment. Alternatively, the targeted region can be rescued as a linear YACs when a YAC fragmentation vector is included in the yeast transformation mixture. Because the entire isolation procedure of the chromosomal region, once a target insertion is obtained, can be accomplished in ~1 week, the new method greatly expands the utility of the homologous recombinationproficient DT40 chicken cell system.     

FancJ/Brip1 helicase protects against genomic losses and gains in vertebrate cells

Defects in the FANCJ/BRIP1 helicase gene are associated with genome instability disorders such as familial breast cancer or Fanconi anemia (FA). Although FANCJ has an in vitro activity to resolve G-quadruplex (G4) structures, and FANCJ ortholog in C. elegans prevents G4-associated deletions during replication, how FANCJ loss affects genome integrity in higher organisms remains unclear. Here, we report that FANCJ, but not other FA genes FANCD2 or FANCC, protected against large-scale genomic deletion that occurred frequently at the rearranged immunoglobulin heavy chain (IgH) locus in chicken DT40 cell line, suggesting that FancJ protects the genome independently of the FA ubiquitination pathway. In a more unbiased approach using array-comparative genomic hybridization, we identified de novo deletions as well as amplifications in fancj cells kept in culture for 2 months. A cluster of G4 sequence motifs was found near the breakpoint of one amplified region, but G4 sequence motifs were not detected at the breakpoints of two deleted regions. These results collectively suggest that, unlike in C. elegans, actions of vertebrate FANCJ to promote genome stability may not be limited to protection against the G4-mediated gene deletions.     

Naturally occurring Bruton's tyrosine kinase mutations have no dominant negative effect in an X-linked agammaglobulinaemia cellular model

X-linked agammaglobulinaemia (XLA) is characterized by absence of mature B cells because of mutations in the Bruton's tyrosine kinase (Btk) gene. Btk-deficient early B cell precursors experience a block in their differentiation potentially reversible by the addition of an intact Btk gene. Btk expression was measured in 69 XLA patients with 47 different mutations and normal expression was detected in seven. We characterized these Btk mutant forms functionally by transfection into a lymphoma cell line that lacks endogenous Btk expression (Btk-/- DT40 cells) and analysed the calcium flux in response to B cell receptor stimulation. To test whether co-expression of a mutated form could compromise the function of the intact Btk transfection, studies in wild-type (WT) DT40 cells were also performed. Study reveals that none of the seven Btk mutants analysed was able to revert the absence of calcium mobilization upon IgM engagement in Btk-/- DT40 cells, as does intact Btk. In addition, calcium mobilization by anti-IgM stimulation in DT40 Btk+/+ cells was unaffected by co-expression with Btk mutants. These results suggest that gene addition would be feasible not only for patients with XLA and mutations that prevent Btk expression, but for those with expression of a mutant Btk.     

CD40 ligand supports the long-term maintenance and differentiation of chicken B cells in culture

TNF family members play crucial roles in mammalian B-cell differentiation and function, many of which have not been demonstrated in other species. To investigate the avian CD40/CD40L system, a chicken CD40 cDNA, obtained by expression screening, was used to raise monoclonal antibodies showing that CD40 was expressed on chicken B cells, monocytes and macrophages, like mammalian CD40. CD40 ligand fusion protein supported the proliferation of B cells in culture for up to 3 weeks, during which they differentiated towards a plasma cell phenotype. CD40L-activated B cells from immunised birds secreted antigen-specific IgM and IgG. These results showed important conserved functions of CD40 and its ligand in mammals and birds. CD40L provides a means for maintenance and differentiation of untransformed chicken B cells in culture, for the first time, allowing new approaches to study of post-bursal B cell biology and host–pathogen interactions with B cell tropic viruses.     

Immunoglobulin gene conversion in chicken DT40 cells largely proceeds through an abasic site intermediate generated by excision of the uracil produced by AID-mediated deoxycytidine deamination

Diversification of the primary antibody repertoire in chickens is achieved by a gene conversion process that uses a set of immunoglobulin variable (IgV) pseudogenes as templates. Studies usingthe chicken DT40 B lymphoma cell line have shown that this gene conversion is dependent on activation-induced deaminase, which deaminates deoxycytidine to deoxyuridine in the IgV gene. The mechanism by which the resultant deoxyuridine/deoxyguanosine (dU/dG) mismatch acts to initiate the gene conversion process is unknown but likely involves either (i) recognition of the dU/dG pair by the mismatch repair complex or (ii) recognition of the dU itself by uracil-DNA glycosylase. To discriminate these possibilities, we have investigated the effects on IgV gene conversion of inhibiting uracil-DNA glycosylase. We find that such inhibition diminishes gene conversion, biasing instead towards point mutations. These results demonstrate that IgV gene conversion in DT40 cells is substantially dependent on uracil excision and implies that it proceeds by a pathway involving an abasic site, which could be acted upon by an apyrimidinic endonuclease to generate a DNA strand break facilitating the conversion process.     

Critical role for chicken Rad17 and Rad9 in the cellular response to DNA damage and stalled DNA replication

The Rad17-replication factor C (Rad17-RFC) and Rad9-Rad1-Hus1 complexes are thought to function in the early phase of cell-cycle checkpoint control as sensors for genome damage and genome replication errors. However, genetic analysis of the functions of these complexes in vertebrates is complicated by the lethality of these gene disruptions in embryonic mouse cells. We disrupted the Rad17 and Rad9 loci by gene targeting in the chicken B lymphocyte line DT40. Rad17-/- and Rad9-/- DT40 cells are viable, and are highly sensitive to UV irradiation, alkylating agents, and DNA replication inhibitors, such as hydroxyurea. We further found that Rad17-/- and Rad9-/- but not ATM-/- cells are defective in S-phase DNA damage checkpoint controls and in the cellular response to stalled DNA replication. These results indicate a critical role for chicken Rad17 and Rad9 in the cellular response to stalled DNA replication and DNA damage.     

Protein kinase D isoforms are dispensable for integrin-mediated lymphocyte adhesion and homing to lymphoid tissues

Leukocyte function-associated antigen-1 (LFA-1) and very late antigen-4 (VLA-4) integrins are essential for lymphocyte adhesion, trafficking and effector functions. Protein kinase D (PKD) has previously been implicated in lymphocyte integrin regulation through regulation of Rap1 activity. However, the true role of PKD in integrin regulation in primary lymphocytes has not previously been investigated. The major PKD isoform in lymphocytes is PKD2. Here we employed PKD2-deficient mice, a specific PKD kinase inhibitor, as well as PKD-null DT40 B cells to investigate the role of PKD in integrin regulation in lymphocytes. We report that PKD2-deficient lymphocytes bound normally to integrin ligands in static and shear flow adhesion assays. They also homed normally to lymphoid organs after adoptive transfer into wild-type mice. DT40 B cells devoid of any PKD isoforms and primary lymphocytes pretreated with a specific PKD inhibitor bound normally to integrin ligands, indicating that multiple PKD isoforms do not redundantly regulate lymphocyte integrins. In addition, PKD2-deficient lymphocytes, as well as DT40 cells devoid of any PKD isoforms, could activate Rap1 in response to B-cell receptor ligation or phorbol ester treatment. Together, these results show that the PKD family does not play a critical role in lymphocyte integrin-mediated cell adhesion or lymphocyte trafficking in vivo.