Ubiquitylation of proliferating cell nuclear antigen and recruitment of human DNA polymerase eta.

This study investigated the requirement for ubiquitylation of PCNA at lysine 164 during polymerase eta-dependent translesion synthesis (TLS) of site-specific cis-syn cyclobutane thymine dimers (T (wedge)T). The in vitro assay recapitulated origin-dependent initiation, fork assembly, and semiconservative, bidirectional replication of double-stranded circular DNA substrates. A phosphocellulose column was used to fractionate HeLa cell extracts into two fractions; flow-through column fraction I (CFI) contained endogenous PCNA, RPA, ubiquitin-activating enzyme E1, and ubiquitin conjugase Rad6, and eluted column fraction II (CFII) included pol delta, pol eta, and RFC. CFII supplemented with purified recombinant RPA and PCNA (wild type or K164R, in which lysine was replaced with arginine) was competent for DNA replication and TLS. K164R-PCNA complemented CFII for these activities to the same extent and efficiency as wild-type PCNA. CFII mixed with CFI (endogenous PCNA, E1, Rad6) exhibited enhanced DNA replication activity, but the same TLS efficiency determined with the purified proteins. These results demonstrate that PCNA ubiquitylation at K164 of PCNA is not required in vitro for pol eta to gain access to replication complexes at forks stalled by T (wedge)T and to catalyze TLS across this dimer.

The DEXH protein product of the DHX36 gene is the major source of tetramolecular quadruplex G4-DNA resolving activity in HeLa cell lysates.

G4-DNA is a highly stable alternative DNA structure that can form spontaneously in guanine-rich regions of single-stranded DNA under physiological conditions. Since a number of biological processes create such single-stranded regions, G4-DNA occurrence must be regulated. To date, resolution of tetramolecular G4-DNA into single strands (G4-resolvase activity) has been observed only in recombinant RecQ DNA helicases. We previously reported that human cell lysates possess tetramolecular G4-DNA resolving activity (Harrington, C., Lan, Y., and Akman, S. (1997) J. Biol Chem. 272, 24631-24636). Here we report the first complete purification of a major non-RecQ, NTP-dependent G4-DNA resolving enzyme from human cell lysates. This enzyme is identified as the DEXH helicase product of gene DHX36 (also known as RHAU). G4-DNA resolving activity was captured from HeLa cell lysates on G4-DNA affinity beads and further purified by gel filtration chromatography. The DHX36 gene product was identified by mass spectrometric sequencing of a tryptic digest from the protein band on SDS-PAGE associated with activity. DHX36 was cloned within a His(6)-tagging vector, expressed, and purified from Escherichia coli. Inhibition and substrate resolution assays showed that recombinant DHX36 protein displayed robust, highly specific G4-DNA resolving activity. Immunodepletion of HeLa lysates by a monoclonal antibody to the DHX36 product removed ca. 77% of the enzyme from lysates and reduced G4-DNA resolving activity to 46.0 +/- 0.4% of control, demonstrating that DHX36 protein is responsible for the majority of tetramolecular G4-DNA resolvase activity.

The N2-ethylguanine and the O6-ethyl- and O6-methylguanine lesions in DNA: contrasting responses from the "bypass" DNA polymerase eta and the replicative DNA polymerase alpha.

The effects of N(2)-ethylGua, O(6)-ethylGua, and O(6)-methylGua adducts in template DNA on polymerization by mammalian DNA polymerases alpha and eta have been investigated. The N(2)-ethylGua adduct blocks polymerization by the replicative DNA polymerase alpha to a much greater extent than does the O(6)-ethyl- or the O(6)-methylGua adducts. The DNA polymerase eta efficiently and accurately bypasses the N(2)-ethylGua lesion but like DNA polymerase alpha is similarly blocked by the O(6)-ethyl- or the O(6)-methylGua adducts. A steady state kinetic analysis of nucleotide insertion opposite the N(2)-ethylGua and the O(6)-ethylGua adducts by the DNA polymerases alpha and eta and extension from 3'-termini positioned opposite these adducts was performed to measure the efficiency and the accuracy of DNA synthesis past these lesions. This analysis showed that insertion of Cyt opposite the N(2)-ethylGua adduct by DNA polymerase alpha is approximately 10(4)-fold less efficient than insertion of Cyt opposite an unadducted Gua residue at the same position. Extension from the N(2)-ethylGua:Cyt 3'-terminus by DNA polymerase alpha is approximately 10(3)-fold less efficient than extension from a Cyt opposite the unadducted Gua. Insertion of Cyt opposite the N(2)-ethylGua lesion by the DNA polymerase eta is about 370-fold more efficient than by the DNA polymerase alpha, and extension from the N(2)-ethylGua:Cyt 3'-terminus by the DNA polymerase eta is about 3-fold more efficient than by the DNA polymerase alpha. Furthermore, the DNA polymerase eta preferably inserts the correct nucleotide Cyt opposite the N(2)-ethylGua lesion with nearly the same level of accuracy as opposite an unadducted Gua, thus minimizing the mutagentic potential of this lesion. This result contrasts with the relatively high misincorporation efficiency of Thy opposite the O(6)-ethylGua adduct by the DNA polymerases alpha and eta. In reactions containing both DNA polymerases alpha and eta, synthesis past the N(2)-ethylGua adduct is detected to permit completed replication of the adducted oligonucleotide template. These results suggest that accurate replication past the N(2)-ethylGua adduct might be facilitated in cells by pausing of replication catalyzed by DNA polymerase alpha and lesion bypass catalyzed by DNA polymerase eta.