Sergei Malkhosyan scite author profile

Spontaneous errors in DNA replication have been suggested to play a significant role in neoplastic transformation and to explain the chromosomal alterations seen in cancer cells. A defective replication factor could increase the mutation rate in clonal variants arising during tumour progression, but despite intensive efforts, increases in tumour cell mutation rates have not been unambiguously shown. Here we use an unbiased genomic fingerprinting technique to show that 12 per cent of colorectal carcinomas carry somatic deletions in poly(dA.dT) sequences and other simple repeats. We estimate that cells from these tumours can carry more than 100,000 such mutations. Only tumours with affected poly(dA.dT) sequences carry mutations in the other simple repeats examined, and such mutations can be found in all neoplastic regions of multiple tumours from the same patient, including adenomas. Tumours with these mutations show distinctive genotypic and phenotypic features. We conclude that these mutations reflect a previously undescribed form of carcinogenesis in the colon (predisposition to which may be inherited) mediated by a mutation in a DNA replication factor resulting in reduced fidelity for replication or repair (a 'mutator mutation').

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Genomic instability in repeated sequences is an early somatic event in colorectal tumorigenesis that persists after transformation

Shibata

et al. 1994

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Genomic instability at simple repeated sequences (SRS) is a landmark for some sporadic and hereditary cancers of the colon. We have identified several human tumour cell lines with up to 1,000-fold increases in mutation rates for endogenous microsatellite sequences, relative to normal cells or tumour cells without the mutator phenotype and show that they are very early events in tumorigenesis. Our in vivo and in vitro results show that the genomic instability persists after transformation and that microsatellite mutations accumulate as consecutive somatic slippage events of a single or a few repeated units. This mechanism may account for the repeat expansions in triplet hereditary diseases and the same defect in replication fidelity in non-polyposis colon cancer could also contribute to the non-mendelian anticipation in these diseases.

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Frameshift mutator mutations

Malkhosyan

Rampino

Yamamoto

et al. 1996

Nature

280

212

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Isolation and characterization of allelic losses and gains in colorectal tumors by arbitrarily primed polymerase chain reaction.

Peinado

Malkhosyan

Velázquez

et al. 1992

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

224

125

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Transcriptionally driven cruciform formationin vivo

Dayn¹,

Malkhosyan

Mirkin³

1992

Nucl Acids Res

108

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We studied the formation of d(A-T)n cruciforms in E.coli cells by probing intracellular plasmid DNA with chloroacetaldehyde followed by fine analysis of modified DNA bases. d(A-T)16 sequences were inserted into specifically designed plasmids either upstream of a single trc promoter, or between two divergent trc promoters. We found that in both cases, induction of transcription by IPTG leads to the transition of the d(A-T)16 stretch into a cruciform state. In the case of two divergent promoters, we observed cruciform formation even without IPTG. Enhanced cruciform formation correlates with the elevation in promoter activity as defined by the opening of the promoter at the -10 to +2 positions. We conclude that transcriptionally driven negative supercoiling provokes cruciform formation in vivo.

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