2009
DOI: 10.1084/jem.20082514
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Immunoglobulin switch μ sequence causes RNA polymerase II accumulation and reduces dA hypermutation

Abstract: Repetitive DNA sequences in the immunoglobulin switch μ region form RNA-containing secondary structures and undergo hypermutation by activation-induced deaminase (AID). To examine how DNA structure affects transcription and hypermutation, we mapped the position of RNA polymerase II molecules and mutations across a 5-kb region spanning the intronic enhancer to the constant μ gene. For RNA polymerase II, the distribution was determined by nuclear run-on and chromatin immunoprecipitation assays in B cells from ur… Show more

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Cited by 108 publications
(103 citation statements)
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“…It has been shown in vitro that R-loops block transcription (Canugovi et al ., 2009; Tornaletti et al ., 2008), because the polymerases may have difficulty unwinding the stable RNA-DNA hybrid. A recent study (Rajagopal et al ., 2009) measured the density of polymerases in vivo by nuclear run-on, and found a 5–10 fold increase in polymerases located in close proximity to the Sμ repetitive core. These polymerases appeared to be piling up because they encountered a road-block ahead caused by the RNA-DNA hybrids.…”
Section: The Targeting Enigmamentioning
confidence: 97%
“…It has been shown in vitro that R-loops block transcription (Canugovi et al ., 2009; Tornaletti et al ., 2008), because the polymerases may have difficulty unwinding the stable RNA-DNA hybrid. A recent study (Rajagopal et al ., 2009) measured the density of polymerases in vivo by nuclear run-on, and found a 5–10 fold increase in polymerases located in close proximity to the Sμ repetitive core. These polymerases appeared to be piling up because they encountered a road-block ahead caused by the RNA-DNA hybrids.…”
Section: The Targeting Enigmamentioning
confidence: 97%
“…also had an altered spectrum of substitutions, showing that UNG participates in mutagenesis (Rada et al, 2002;Saribasak et al, 2006;Rajagopal et al, 2009). Thus, UNG is required for both repairing mutations and generating them, which may explain why the mutation frequency was not dramatically increased in UNG-deficient mice.…”
Section: Brief Definitive Reportmentioning
confidence: 99%
“…In the S  region, breaks are frequent as a result of multiple targeting sites for AID activity and prolonged RNA pausing in R-loops (Rajagopal et al, 2009;Wang et al, 2009). UNG and APE1 then produce single-strand breaks, which can be repaired by BER.…”
Section: Increased Double-strand Breaks In S mentioning
confidence: 99%
“…Secondly, RNA polymerase II (RNA Pol II) and its co-factors recruit AID at stalling sites as demonstrated by the striking genome-wide and local correlation between AID occupancy and the density of RNA Pol II and Spt5, a factor preferentially associated with stalled Pol II which binds AID in vitro [7 ,14 ]. Intrinsic properties of S region sequences would cause transcription stalling even at unusual distance from the transcription start (TSS), enabling subsequent recruitment of AID all along S regions via physical interaction with Spt5 [14 ,15,16] (Figure 1a). Of importance, although V regions were excluded from genome-wide analysis because of their high diversity, these results may apply to SHM as well since Spt5 occupancy also correlated with somatic mutations of off-targets [14 ].…”
Section: Aid Targeting Is Not Restricted To the Ig Locusmentioning
confidence: 99%