Interplay between Target Sequences and Repair Pathways Determines Distinct Outcomes of AID-Initiated Lesions

Chen, Zhangguo; Eder, Maxwell; Elos, Mihret; Viboolsittiseri, Sawanee S.; Chen, Xiaomi; Wang, Jing H.

doi:10.4049/jimmunol.1502184

Cited by 6 publications

(12 citation statements)

References 54 publications

(77 reference statements)

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“…In remarkable convergence with this footprint size, Woodrick et al (46) showed that LP-BER produces excision patches centered on the excised AP site that are ≤20 nucleotides long; they further showed that LP-BER predominates over single-nucleotide BER in living cells. AGCW motifs are the only hotspots where AID can deaminate either DNA strand with comparable efficiency in vivo (8,9,47). This leads us to update the Ig hypermutation model and propose that MMR-independent C/G transversions occur via simultaneous G 1 -phase LP-BER of deaminations that have accumulated in Fig.…”

Section: Discussionmentioning

confidence: 98%

“…S1), presumably by the U:G mismatches deamination induces. Processing via BER or MMR predominantly restores C in place of U (6)(7)(8)(9) but is also error-prone. Error-prone BER converts deamination sites into transition or transversion mutations at C/G and occasionally produces mutations at bases flanking deamination sites, including A/T bases (1).…”

mentioning

confidence: 99%

“…Only G 1 -phase activities of AID or UNG2 are mutagenic in mouse B cells (5,6,23). Strong evidence for mutagenic interaction between BER and MMR implies that mutagenic MMR also occurs in G 1 phase (2,3,8,9,12,21). dNTP levels were reported to be lowest in G 1 phase, especially in the nucleus (24).…”

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confidence: 99%

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SAMHD1 enhances immunoglobulin hypermutation by promoting transversion mutation

Thientosapol

Bosnjak

Durack

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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Activation-induced deaminase (AID) initiates hypermutation of genes in activated B cells by converting C:G into U:G base pairs. G-phase variants of uracil base excision repair (BER) and mismatch repair (MMR) then deploy translesion polymerases including REV1 and Pol η, which exacerbates mutation. dNTP paucity may contribute to hypermutation, because dNTP levels are reduced in G phase to inhibit viral replication. To derestrict G-phase dNTP supply, we CRISPR-inactivated SAMHD1 (which degrades dNTPs) in germinal center B cells. inactivation increased B cell virus susceptibility, increased transition mutations at C:G base pairs, and substantially decreased transversion mutations at A:T and C:G base pairs in both strands. We conclude that SAMHD1's restriction of dNTP supply enhances AID's mutagenicity and that the evolution of hypermutation included the repurposing of antiviral mechanisms based on dNTP starvation.

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Section: Discussionmentioning

confidence: 98%

mentioning

confidence: 99%

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SAMHD1 enhances immunoglobulin hypermutation by promoting transversion mutation

Thientosapol

Bosnjak

Durack

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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“…Loss of UNG2 activity can also increase the frequency of C:G to T:A transition mutations, presumably as a result of increased uracil replication. This suggests that high fidelity uracil BER does occur in hypermutating B cells ( 9 , 11 , 19 , 21 ).…”

Section: Introductionmentioning

confidence: 99%

Proximity to AGCT sequences dictates MMR-independent versus MMR-dependent mechanisms for AID-induced mutationviaUNG2

et al. 2016

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AID deaminates C to U in either strand of Ig genes, exclusively producing C:G/G:C to T:A/A:T transition mutations if U is left unrepaired. Error-prone processing by UNG2 or mismatch repair diversifies mutation, predominantly at C:G or A:T base pairs, respectively. Here, we show that transversions at C:G base pairs occur by two distinct processing pathways that are dictated by sequence context. Within and near AGCT mutation hotspots, transversion mutation at C:G was driven by UNG2 without requirement for mismatch repair. Deaminations in AGCT were refractive both to processing by UNG2 and to high-fidelity base excision repair (BER) downstream of UNG2, regardless of mismatch repair activity. We propose that AGCT sequences resist faithful BER because they bind BER-inhibitory protein(s) and/or because hemi-deaminated AGCT motifs innately form a BER-resistant DNA structure. Distal to AGCT sequences, transversions at G were largely co-dependent on UNG2 and mismatch repair. We propose that AGCT-distal transversions are produced when apyrimidinic sites are exposed in mismatch excision patches, because completion of mismatch repair would require bypass of these sites.

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“…While the mouse Sμ switch region contains a high density of AGCT hotspots, this density varies within the switch region, which led the authors to define sub-regions reflecting sparse, intermediate and dense AGCT densities. Interestingly, across the sub-regions mutation frequency did not correlate with AGCT density, suggesting that AID targeting is efficient once a threshold density is reached, and that higher densities do not necessarily increase the mutation targeting frequency [ 42 ].…”

Section: Discussionmentioning

confidence: 99%

The Number of Overlapping AID Hotspots in Germline IGHV Genes Is Inversely Correlated with Mutation Frequency in Chronic Lymphocytic Leukemia

et al. 2017

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The targeting of mutations by Activation-Induced Deaminase (AID) is a key step in generating antibody diversity at the Immunoglobulin (Ig) loci but is also implicated in B-cell malignancies such as chronic lymphocytic leukemia (CLL). AID has previously been shown to preferentially deaminate WRC (W = A/T, R = A/G) hotspots. WGCW sites, which contain an overlapping WRC hotspot on both DNA strands, mutate at much higher frequency than single hotspots. Human Ig heavy chain (IGHV) genes differ in terms of WGCW numbers, ranging from 4 for IGHV3-48*03 to as many as 12 in IGHV1-69*01. An absence of V-region mutations in CLL patients (“IGHV unmutated”, or U-CLL) is associated with a poorer prognosis compared to “IGHV mutated” (M-CLL) patients. The reasons for this difference are still unclear, but it has been noted that particular IGHV genes associate with U-CLL vs M-CLL. For example, patients with IGHV1-69 clones tend to be U-CLL with a poor prognosis, whereas patients with IGHV3-30 tend to be M-CLL and have a better prognosis. Another distinctive feature of CLL is that ~30% of (mostly poor prognosis) patients can be classified into “stereotyped” subsets, each defined by HCDR3 similarity, suggesting selection, possibly for a self-antigen. We analyzed >1000 IGHV genes from CLL patients and found a highly significant statistical relationship between the number of WGCW hotspots in the germline V-region and the observed mutation frequency in patients. However, paradoxically, this correlation was inverse, with V-regions with more WGCW hotspots being less likely to be mutated, i.e., more likely to be U-CLL. The number of WGCW hotspots in particular, are more strongly correlated with mutation frequency than either non-overlapping (WRC) hotspots or more general models of mutability derived from somatic hypermutation data. Furthermore, this correlation is not observed in sequences from the B cell repertoires of normal individuals and those with autoimmune diseases.

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Interplay between Target Sequences and Repair Pathways Determines Distinct Outcomes of AID-Initiated Lesions

Cited by 6 publications

References 54 publications

SAMHD1 enhances immunoglobulin hypermutation by promoting transversion mutation

SAMHD1 enhances immunoglobulin hypermutation by promoting transversion mutation

Proximity to AGCT sequences dictates MMR-independent versus MMR-dependent mechanisms for AID-induced mutationviaUNG2

The Number of Overlapping AID Hotspots in Germline IGHV Genes Is Inversely Correlated with Mutation Frequency in Chronic Lymphocytic Leukemia

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