Abstract
N3-Methyladenine (3-MeA) is formed in DNA by reaction with S-adenosylmethionine, the reactive methyl donor, and by reaction with alkylating agents. 3-MeA protrudes into the DNA minor groove and strongly blocks synthesis by replicative DNA polymerases (Pols). However, the mechanisms for replicating through this lesion in human cells remain unidentified. Here we analyzed the roles of translesion synthesis (TLS) Pols in the replication of 3-MeA-damaged DNA in human cells. Because 3-MeA has a short half-life in vitro, we used the stable 3-deaza analog, 3-deaza-3-methyladenine (3-dMeA), which blocks the DNA minor groove similarly to 3-MeA. We found that replication through the 3-dMeA adduct is mediated via three different pathways, dependent upon Polι/Polκ, Polθ, and Polζ. As inferred from biochemical studies, in the Polι/Polκ pathway, Polι inserts a nucleotide (nt) opposite 3-dMeA and Polκ extends synthesis from the inserted nt. In the Polθ pathway, Polθ carries out both the insertion and extension steps of TLS opposite 3-dMeA, and in the Polζ pathway, Polζ extends synthesis following nt insertion by an as yet unidentified Pol. Steady-state kinetic analyses indicated that Polι and Polθ insert the correct nt T opposite 3-dMeA with a much reduced catalytic efficiency and that both Pols exhibit a high propensity for inserting a wrong nt opposite this adduct. However, despite their low fidelity of synthesis opposite 3-dMeA, TLS opposite this lesion replicates DNA in a highly error-free manner in human cells. We discuss the implications of these observations for TLS mechanisms in human cells.
Highlights
N3-Methyladenine (3-MeA)2 is formed in DNA by reaction with alkylating agents and by reaction with S-adenosylmethionine, the reactive methyl donor in most cellular reactions [1, 2]
To identify the translesion synthesis (TLS) pols required for replicating through the 3-dMeA lesion, we examined the effects of siRNA depletion of various TLS Pols, including Pols , , , and
The TLS data we obtained from independent TLS assays in human cells are highly reproducible as evidenced from the high repeatability of data for TLS opposite UV-induced lesions, cis-syn TT dimer, and the (6 – 4)-TT photoproduct reported in different studies [10, 12, 13]
Summary
3-MeA, N3-methyladenine; 3-dMeA, 3-deaza-3methyladenine; Pol, polymerase; TLS, translesion synthesis; nt, nucleotide; Kan, kanamycin. An infringement of the minor groove at the N3 position of a purine would be highly blocking to replication by Pol␦, necessitating the requirement of translesion synthesis (TLS) DNA Pols for inserting a nucleotide (nt) opposite 3-MeA and extending synthesis from the inserted nt for a distance of at least 4 –5 nts before Pol␦ could take over. Structural studies with Pol have indicated that its active site can accommodate lesions that protrude into the minor groove at the templateprimer junction, whereby it could proficiently extend synthesis from the 3-MeA1⁄7T base pair at the template-primer junction [9]. Even though Pols and incorporate nts opposite 3-dMeA with a low fidelity, replication through the lesion occurs in an error-free manner in human cells. We discuss the implications of these and other observations for the role of TLS in promoting proficient and predominantly error-free replication through DNA lesions in human cells
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