Abstract
RecQ helicases are believed to function in repairing replication forks stalled by DNA damage and may also play a role in the intra-S-phase checkpoint, which delays the replication of damaged DNA, thus permitting repair to occur. Since little is known regarding the effects of DNA damage on RecQ helicases, and because the replication and recombination defects in Werner syndrome cells may reflect abnormal processing of damaged DNA associated with the replication fork, we examined the effects of specific bulky, covalent adducts at N(6) of deoxyadenosine (dA) or N(2) of deoxyguanosine (dG) on Werner (WRN) syndrome helicase activity. The adducts are derived from the optically active 7,8-diol 9,10-epoxide (DE) metabolites of the carcinogen benzo[a]pyrene (BaP). The results demonstrate that WRN helicase activity is inhibited in a strand-specific manner by BaP DE-dG adducts only when on the translocating strand. These adducts either occupy the minor groove without significant perturbation of DNA structure (trans adducts) or cause base displacement at the adduct site (cis adducts). In contrast, helicase activity is only mildly affected by intercalating BaP DE-dA adducts that locally perturb DNA double helical structure. This differs from our previous observation that intercalating dA adducts derived from benzo[c]phenanthrene (BcPh) DEs inhibit WRN activity in a strand- and stereospecific manner. Partial unwinding of the DNA helix at BaP DE-dA adduct sites may make such adducted DNAs more susceptible to the action of helicase than DNA containing the corresponding BcPh DE-dA adducts, which cause little or no destabilization of duplex DNA. The single-stranded DNA binding protein RPA, an auxiliary factor for WRN helicase, enabled the DNA unwinding enzyme to overcome inhibition by either the trans-R or cis-R BaP DE-dG adduct, suggesting that WRN and RPA may function together to unwind duplex DNA harboring specific covalent adducts that otherwise block WRN helicase acting alone.
Highlights
DNA damage evokes a cellular response by a genome surveillance system that senses DNA structural perturbation at the site of the lesion and elicits an appropriate response that may involve direct repair of the lesion, stabilization of the replication fork, or induction of apoptosis [1]
Since little is known regarding the effects of DNA damage on RecQ helicases, and because the replication and recombination defects in Werner syndrome cells may reflect abnormal processing of damaged DNA associated with the replication fork, we examined the effects of specific bulky, covalent adducts at N6 of deoxyadenosine or N2 of deoxyguanosine on Werner (WRN) syndrome helicase activity
These results suggest that the effects of BaP DE adducts on WRN helicase activity are related to the base to which the adduct is covalently attached and dependent on the structure of the BaP DE DNA adduct, such that WRN helicase activity is sensitive to BaP DE dG adducts, which cause flipped out bases or occupy the minor groove
Summary
DNA damage evokes a cellular response by a genome surveillance system that senses DNA structural perturbation at the site of the lesion and elicits an appropriate response that may involve direct repair of the lesion, stabilization of the replication fork, or induction of apoptosis [1]. A single BaP DE-dG adduct with either cis or trans, R or S stereochemistry inhibited WRN in a strand-specific manner, whereas either a cis or trans, R or S BaP DE-dA adduct had little effect These results suggest that the effects of BaP DE adducts on WRN helicase activity are related to the base to which the adduct is covalently attached and dependent on the structure of the BaP DE DNA adduct, such that WRN helicase activity is sensitive to BaP DE dG adducts, which cause flipped out bases or occupy the minor groove. The singlestranded DNA-binding protein RPA, which serves as an auxiliary factor for the WRN helicase, enabled WRN to overcome the inhibition exerted by either the cis or trans BaP DE-dG adduct, suggesting that WRN and RPA may function together to unwind duplex DNA harboring specific covalent DNA adducts that otherwise block WRN helicase acting alone
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