Ab class (isotype) switching allows the humoral immune system to adaptively respond to different infectious organisms. Isotype switching occurs by intrachromosomal DNA recombination between switch (S) region sequences associated with C(H) region genes. Although isotype-specific transcription of unrearranged (germline) C(H) genes is required for switching, recent results suggest that isotype specificity is also determined by the sequences of downstream (acceptor) S regions. In the current study, we identify the histone methyltransferase Suv39h1 as a novel Salpha-specific factor that specifically increases IgA switching (Smu-Salpha recombination) in a transiently transfected plasmid S substrate, and demonstrate that this effect requires the histone methyltransferase activity of Suv39h1. Additionally, B cells from Suv39h1-deficient mice have an isotype-specific reduction in IgA switching with no effect on the level of germline Ialpha-Calpha transcripts. Taken together, our results suggest that Suv39h1 activity inhibits the activity of a sequence-specific DNA-binding protein that represses switch recombination to IgA.

Nucleotide substitutions are found in recombined Ig switch (S) regions and also in unrecombined (germline, GL) Smicro segments in activated splenic B cells. Herein we examine whether mutations are also introduced into the downstream acceptor S regions prior to switch recombination, but find very few mutations in GL Sgamma3 and Sgamma1 regions in activated B cells. These data suggest that switch recombination initiates in the Smicro segment and secondarily involves the downstream acceptor S region. Furthermore, the pattern and specificity of mutations in GL and recombined Smicro segments differ, suggesting different repair mechanisms. Mutations in recombined Smicro regions show a strong bias toward G/C base pairs and WRCY/RGYW hotspots, whereas mutations introduced into the GL Smicro do not. Additionally, induction conditions affect mutation specificity within the GL Smicro segment. Mutations are most frequent near the S-S junctions and decrease rapidly with distance from the junction. Finally, we find that mice expressing a transgene for terminal deoxynucleotidyl transferase (TdT) have nucleotide insertions at S-S junctions, indicating that the recombining DNA ends are accessible to end-processing enzyme activities.

Activation-induced deaminase (AID) is expressed only in germinal center B cells. There, it is required for somatic hypermutation, gene conversion and class switch recombination of antibody variable region segments, three processes that diversify antibodies during immune responses. Although AID has homology to RNA-editing enzymes, three recent reports suggest it could initiate the diversification processes by deaminating cytidine residues within the antibody genes themselves.

Ab class switching is induced upon B cell activation in vivo by immunization or infection or in vitro by treatment with mitogens, e. g. LPS, and results in the expression of different heavy chain constant region (CH) genes without a change in the Ab variable region. This DNA recombination event allows Abs to alter their biological activity while maintaining their antigenic specificity. Little is known about the molecular mechanism of switch recombination. To attempt to develop an assay for enzymes, DNA binding proteins, and DNA sequences that mediate switch recombination, we have constructed a plasmid DNA substrate that will undergo switch recombination upon stable transfection into the surface IgM+ B cell line (I.29 mu), a cell line capable of undergoing switch recombination of its endogenous genes. We demonstrate that recombination occurs between the two switch regions of the plasmid, as assayed by PCRs across the integrated plasmid switch regions, followed by Southern blot hybridization. Nucleotide sequence analysis of the PCR products confirmed the occurrence of S mu-S alpha recombination in the plasmid. Recombination of the plasmid in I.29 mu cells does not require treatment with inducers of switch recombination, suggesting that recombinase activity is constitutive in I.29 mu cells. Recombination does not require high levels of transcription across the switch regions of the plasmid. Fewer recombination events are detected in four different B and T cell lines that do not undergo switch recombination of their endogenous genes.