Flanking nucleotide specificity for DNA mismatch repair-deficient frameshifts within Activin Receptor 2 (ACVR2)

Chung, Heekyung; Chaudhry, Joy; Lai, Jenny; Young, Dennis; Carethers, John M.

doi:10.1016/j.mrfmmm.2011.09.009

Cited by 6 publications

(11 citation statements)

References 21 publications

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“…Individual sequence context and flanking sequences may also contribute to the different outcome of the mutation (e.g. insertion vs. deletion) [11], [12], [24]. At the D20S82 locus, only about one-third of EGFP-positive hMSH3 −/− cells demonstrated one AAAG unit deletion and this could be due to this particular clone containing multiple copies of the construct.…”

Section: Discussionmentioning

confidence: 99%

“…Sense and anti-sense oligos containing D8S321 or D20S82 , surrounding sequences, as well as Pme I and Asc I cloning sites ( Table S1 ) were synthesized (Integrated DNA Technologies, Inc., San Diego, CA) and subjected to T4-polynucleotide kinase reactions to phosphorylate the 5′ ends (Invitrogen). The sense and anti-sense oligos were allowed to anneal and cloned into pIREShyg2-EGFP plasmids via Pme I- Asc I sites immediately after the start codon of the EGFP gene as described previously [10]–[12], [24]. Experimental plasmids were constructed +1 bp out of frame, such that one deletion of a tetranucleotide repeat within D8S321 or D20S82 (−4 bp frameshift mutation) would shift the reading frame into the correct frame to allow EGFP expression.…”

Section: Methodsmentioning

confidence: 99%

“…Mutation rates were calculated by the “method of the mean” developed by Luria and Delbruck [25] as described previously [10]–[12], [24].…”

Section: Methodsmentioning

confidence: 99%

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Oxidative Stress Induces Nuclear-to-Cytosol Shift of hMSH3, a Potential Mechanism for EMAST in Colorectal Cancer Cells

et al. 2012

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BackgroundElevated microsatellite alterations at selected tetranucleotide repeats (EMAST) is a genetic signature observed in 60% of sporadic colorectal cancers (CRCs). Unlike microsatellite unstable CRCs where hypermethylation of the DNA mismatch repair (MMR) gene hMLH1’s promoter is causal, the precise cause of EMAST is not clearly defined but points towards hMSH3 deficiency.AimTo examine if hMSH3 deficiency causes EMAST, and to explore mechanisms for its deficiency.MethodsWe measured −4 bp framshifts at D8S321 and D20S82 loci within EGFP-containing constructs to determine EMAST formation in MMR-proficient, hMLH1−/−, hMSH6−/−, and hMSH3−/− CRC cells. We observed the subcellular location of hMSH3 with oxidative stress.Results D8S321 mutations occurred 31-and 40-fold higher and D20S82 mutations occurred 82-and 49-fold higher in hMLH1−/− and hMSH3−/− cells, respectively, than in hMSH6−/− or MMR-proficient cells. hMSH3 knockdown in MMR-proficient cells caused higher D8S321 mutation rates (18.14 and 11.14×10−4 mutations/cell/generation in two independent clones) than scrambled controls (0 and 0.26×10−4 mutations/cell/generation; p<0.01). DNA sequencing confirmed the expected frameshift mutations with evidence for ongoing mutations of the constructs. Because EMAST-positive tumors are associated with inflammation, we subjected MMR-proficient cells to oxidative stress via H2O2 to examine its effect on hMSH3. A reversible nuclear-to-cytosol shift of hMSH3 was observed upon H2O2 treatment.ConclusionEMAST is dependent upon the MMR background, with hMSH3−/− more prone to frameshift mutations than hMSH6−/−, opposite to frameshift mutations observed for mononucleotide repeats. hMSH3−/− mimics complete MMR failure (hMLH1−/−) in inducing EMAST. Given the observed heterogeneous expression of hMSH3 in CRCs with EMAST, hMSH3-deficiency appears to be the event that commences EMAST. Oxidative stress, which causes a shift of hMSH3’s subcellular location, may contribute to an hMSH3 loss-of-function phenotype by sequestering it to the cytosol.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Oxidative Stress Induces Nuclear-to-Cytosol Shift of hMSH3, a Potential Mechanism for EMAST in Colorectal Cancer Cells

et al. 2012

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“…This fact is believed to be the driver of improved outcome for patients with MSI-H CRCs. The frameshifted genes are transcribed and translated as shorter novel peptides due to the frameshift and new stop codon (Figure 2) [1–3,40–45]. These neopeptides are immunogenic and are recognized by the immune system, which causes the development of subepithelial lymphoid aggregates.…”

Section: Msi the Biomarkermentioning

confidence: 99%

Microsatellite Instability Pathway and EMAST in Colorectal Cancer

Carethers

2017

Curr Colorectal Cancer Rep

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Microsatellite instability (MSI) refers to the biochemical detection of frameshifted microsatellite sequences from genomic DNA. Genesis of MSI is due to defective DNA mismatch repair (MMR) that fails to correct post DNA replicative slippage mistakes at microsatellites. Most of the estimated 100,000 genomic microsatellites are non-coding; however, ~150–300 microsatellites are coding such that, when frameshifted during the pathogenesis of an MSI tumor, can generate immunogenic neopeptide antigens that limit the growth of tumor and prolong patient survival. In addition to the immune reaction and longer survival, patients with MSI colorectal cancers tend to have poorly differentiated tumors with mucinous features that are located in the right colon. Patients with MSI tumors are more resistant to 5-fluorouracil-based adjuvant chemotherapy but may be responsive to PD-1 immune checkpoint blockade. Specific defects of MMR function not only drive MSI but also elevate microsatellite alterations at selected tetranucleotide repeats that may further modify patient outcome.

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“…5 We and others previously have shown that mononucleotide and dinucleotide microsatellites in the absence of MMR consistently and uniformly frameshift to shorter microsatellite lengths. [35][36][37][38][39][40] For this to occur, the insertion/deletion loop needs to occur on the template DNA strand, allowing the newly synthesized DNA strand to anneal a shortened complementary microsatellite sequence. [35][36][37][38][39] In the absence of MLH1 or with knockdown of MSH3, we initially observed both deletions and insertion length changes at tetranucleotide sequences, suggesting that insertion/deletion loops form at these longer microsatellites on both the template and newly synthesized DNA strand.…”

Section: Methodsmentioning

confidence: 99%

Tetranucleotide Microsatellite Mutational Behavior Assessed in Real Time: Implications for Future Microsatellite Panels

Raeker

Pierre-Charles

Carethers

2020

Cellular and Molecular Gastroenterology and Hepatology

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RESULTS: Frameshift mutation rates were 31.6 to 71.1 Â 10-4 mutations/cell/generation and correlated with microsatellite length (r 2 ¼ 0.986, P ¼ .0375). Longer repeats showed modestly higher deletion over insertion rates, with both equivalent for shorter repeats. Accumulation of more deletion frameshifts contributed to a distinct mutational bias for each length (overall: 77.8% deletions vs 22.2% insertions), likely owing to continual deletional mutation of insertions. Approximately 78.9% of observed frameshifts were 1 AAAG repeat, 16.1% were 2 repeats, and 5.1% were 3 or more repeats, consistent with a slipped strand mispairing mutation model. CONCLUSIONS: Tetranucleotide frameshifts show a deletion bias and undergo more than 1 deletion event via intermediates, with insertions converted into deletions. Tetranucleotide markers added to traditional microsatellite instability panels will be able to determine both EMAST and classic microsatellite instability, but needs to be assessed by multiple markers to account for mutational behavior and intermediates.

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Flanking nucleotide specificity for DNA mismatch repair-deficient frameshifts within Activin Receptor 2 (ACVR2)

Cited by 6 publications

References 21 publications

Oxidative Stress Induces Nuclear-to-Cytosol Shift of hMSH3, a Potential Mechanism for EMAST in Colorectal Cancer Cells

Oxidative Stress Induces Nuclear-to-Cytosol Shift of hMSH3, a Potential Mechanism for EMAST in Colorectal Cancer Cells

Microsatellite Instability Pathway and EMAST in Colorectal Cancer

Tetranucleotide Microsatellite Mutational Behavior Assessed in Real Time: Implications for Future Microsatellite Panels

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