Activation-induced cytidine deaminase (AID), which is specific to B lymphocytes, is required for class switch recombination (CSR)--a process mediating isotype switching of immunoglobulin--and somatic hypermutation--the introduction of many point mutations into the immunoglobulin variable region genes. It has been suggested that AID may function as an RNA-editing enzyme or as a cytidine deaminase on DNA. However, the precise enzymatic activity of AID has not been assessed in previous studies. Similarly, although transcription of the target immunoglobulin locus sequences is required for both CSR and somatic hypermutation, the precise role of transcription has remained speculative. Here we use two different assays to demonstrate that AID can deaminate specifically cytidines on single-stranded (ss)DNA but not double-stranded (ds)DNA substrates in vitro. However, dsDNA can be deaminated by AID in vitro when the reaction is coupled to transcription. Moreover, a synthetic dsDNA sequence, which targets CSR in vivo in a manner dependent on transcriptional orientation, was deaminated by AID in vitro with the same transcriptional-orientation-dependence as observed for endogenous CSR. We conclude that transcription targets the DNA deamination activity of AID to dsDNA by generating secondary structures that provide ssDNA substrates.
Activation-induced cytidine deaminase (AID) is a single-stranded (ss) DNA deaminase required for somatic hypermutation (SHM) and class switch recombination of immunoglobulin genes. Class switch recombination involves transcription through switch regions, which generates ssDNA within R loops. However, although transcription through immunoglobulin variable region exons is required for SHM, it does not generate stable ssDNA, which leaves the mechanism of AID targeting unresolved. Here we characterize the mechanism of AID targeting to in-vitro-transcribed substrates harbouring SHM motifs. We show that the targeting activity of AID is due to replication protein A (RPA), a ssDNA-binding protein involved in replication, recombination and repair. The 32-kDa subunit of RPA interacts specifically with AID from activated B cells in a manner that seems to be dependent on post-translational AID modification. Thus, our study implicates RPA as a novel factor involved in immunoglobulin diversification. We propose that B-cell-specific AID-RPA complexes preferentially bind to ssDNA of small transcription bubbles at SHM 'hotspots', leading to AID-mediated deamination and RPA-mediated recruitment of DNA repair proteins.
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