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Recombination is responsible for the increased recovery of drug-resistant mutants with hypermutated genomes in resting Yeast Diploids Expressing APOBEC deaminases. / Lada, Artem G.; Stepchenkova, Elena I.; Zhuk, Anna S.; Kliver, Sergei F.; Rogozin, Igor B.; Polev, Dmitrii E.; Dhar, Alok; Pavlov, Youri I.

In: Frontiers in Genetics, Vol. 8, No. DEC, 202, 12.12.2017.

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@article{c9f478be3c4242eaa41f577e43a9a75d,
title = "Recombination is responsible for the increased recovery of drug-resistant mutants with hypermutated genomes in resting Yeast Diploids Expressing APOBEC deaminases",
abstract = "DNA editing deaminases (APOBECs) are implicated in generation of mutations in somatic cells during tumorigenesis. APOBEC-dependent mutagenesis is thought to occur during transient exposure of unprotected single-stranded DNA. Mutations frequently occur in clusters (kataegis). We investigated mechanisms of mutant generation in growing and resting diploid yeast expressing APOBEC from sea lamprey, PmCDA1, whose kataegistic effect was previously shown to be associated with transcription. We have found that the frequency of canavanine-resistant mutants kept raising after growth cessation, while the profile of transcription remained unchanged. Surprisingly, the overall number of mutations in the genomes did not elevate in resting cells. Thus, mutations were accumulated during vigorous growth stage with both intense replication and transcription. We found that the elevated recovery of can1 mutant clones in non-growing cells is the result of loss of heterozygosity (LOH) leading to clusters of homozygous mutations in the chromosomal regions distal to the reporter gene. We confirmed that recombination frequency in resting cells was elevated by orders of magnitude, suggesting that cells were transiently committed to meiotic levels of recombination, a process referred to in yeast genetics as return-to-growth. In its extreme, on day 6 of starvation, a few mutant clones were haploid, likely resulting from completed meiosis. Distribution of mutations along chromosomes indicated that PmCDA1 was active during ongoing recombination events and sometimes produced characteristic kataegis near initial breakpoints. AID and APOBEC1 behaved similar to PmCDA1. We conclude that replication, transcription, and mitotic recombination contribute to the recovered APOBEC-induced mutations in resting diploids. The mechanism is relevant to the initial stages of oncogenic transformation in terminally differentiated cells, when recombination may lead to the LOH exposing recessive mutations induced by APOBECs in cell's history and to acquisition of new mutations near original break.",
keywords = "APOBECs, Kataegis, Mutants in resting diploid yeast, Next generation sequencing, Recombination, Tumorigenesis",
author = "Lada, {Artem G.} and Stepchenkova, {Elena I.} and Zhuk, {Anna S.} and Kliver, {Sergei F.} and Rogozin, {Igor B.} and Polev, {Dmitrii E.} and Alok Dhar and Pavlov, {Youri I.}",
year = "2017",
month = dec,
day = "12",
doi = "10.3389/fgene.2017.00202",
language = "English",
volume = "8",
journal = "Frontiers in Genetics",
issn = "1664-8021",
publisher = "Frontiers Media S.A.",
number = "DEC",

}

RIS

TY - JOUR

T1 - Recombination is responsible for the increased recovery of drug-resistant mutants with hypermutated genomes in resting Yeast Diploids Expressing APOBEC deaminases

AU - Lada, Artem G.

AU - Stepchenkova, Elena I.

AU - Zhuk, Anna S.

AU - Kliver, Sergei F.

AU - Rogozin, Igor B.

AU - Polev, Dmitrii E.

AU - Dhar, Alok

AU - Pavlov, Youri I.

PY - 2017/12/12

Y1 - 2017/12/12

N2 - DNA editing deaminases (APOBECs) are implicated in generation of mutations in somatic cells during tumorigenesis. APOBEC-dependent mutagenesis is thought to occur during transient exposure of unprotected single-stranded DNA. Mutations frequently occur in clusters (kataegis). We investigated mechanisms of mutant generation in growing and resting diploid yeast expressing APOBEC from sea lamprey, PmCDA1, whose kataegistic effect was previously shown to be associated with transcription. We have found that the frequency of canavanine-resistant mutants kept raising after growth cessation, while the profile of transcription remained unchanged. Surprisingly, the overall number of mutations in the genomes did not elevate in resting cells. Thus, mutations were accumulated during vigorous growth stage with both intense replication and transcription. We found that the elevated recovery of can1 mutant clones in non-growing cells is the result of loss of heterozygosity (LOH) leading to clusters of homozygous mutations in the chromosomal regions distal to the reporter gene. We confirmed that recombination frequency in resting cells was elevated by orders of magnitude, suggesting that cells were transiently committed to meiotic levels of recombination, a process referred to in yeast genetics as return-to-growth. In its extreme, on day 6 of starvation, a few mutant clones were haploid, likely resulting from completed meiosis. Distribution of mutations along chromosomes indicated that PmCDA1 was active during ongoing recombination events and sometimes produced characteristic kataegis near initial breakpoints. AID and APOBEC1 behaved similar to PmCDA1. We conclude that replication, transcription, and mitotic recombination contribute to the recovered APOBEC-induced mutations in resting diploids. The mechanism is relevant to the initial stages of oncogenic transformation in terminally differentiated cells, when recombination may lead to the LOH exposing recessive mutations induced by APOBECs in cell's history and to acquisition of new mutations near original break.

AB - DNA editing deaminases (APOBECs) are implicated in generation of mutations in somatic cells during tumorigenesis. APOBEC-dependent mutagenesis is thought to occur during transient exposure of unprotected single-stranded DNA. Mutations frequently occur in clusters (kataegis). We investigated mechanisms of mutant generation in growing and resting diploid yeast expressing APOBEC from sea lamprey, PmCDA1, whose kataegistic effect was previously shown to be associated with transcription. We have found that the frequency of canavanine-resistant mutants kept raising after growth cessation, while the profile of transcription remained unchanged. Surprisingly, the overall number of mutations in the genomes did not elevate in resting cells. Thus, mutations were accumulated during vigorous growth stage with both intense replication and transcription. We found that the elevated recovery of can1 mutant clones in non-growing cells is the result of loss of heterozygosity (LOH) leading to clusters of homozygous mutations in the chromosomal regions distal to the reporter gene. We confirmed that recombination frequency in resting cells was elevated by orders of magnitude, suggesting that cells were transiently committed to meiotic levels of recombination, a process referred to in yeast genetics as return-to-growth. In its extreme, on day 6 of starvation, a few mutant clones were haploid, likely resulting from completed meiosis. Distribution of mutations along chromosomes indicated that PmCDA1 was active during ongoing recombination events and sometimes produced characteristic kataegis near initial breakpoints. AID and APOBEC1 behaved similar to PmCDA1. We conclude that replication, transcription, and mitotic recombination contribute to the recovered APOBEC-induced mutations in resting diploids. The mechanism is relevant to the initial stages of oncogenic transformation in terminally differentiated cells, when recombination may lead to the LOH exposing recessive mutations induced by APOBECs in cell's history and to acquisition of new mutations near original break.

KW - APOBECs

KW - Kataegis

KW - Mutants in resting diploid yeast

KW - Next generation sequencing

KW - Recombination

KW - Tumorigenesis

UR - http://www.scopus.com/inward/record.url?scp=85037985582&partnerID=8YFLogxK

U2 - 10.3389/fgene.2017.00202

DO - 10.3389/fgene.2017.00202

M3 - Article

AN - SCOPUS:85037985582

VL - 8

JO - Frontiers in Genetics

JF - Frontiers in Genetics

SN - 1664-8021

IS - DEC

M1 - 202

ER -

ID: 11937943