Translesion DNA synthesis catalyzed by human pol eta and pol kappa across 1,N6-ethenodeoxyadenosine

1,N(6)-Ethenodeoxyadenosine, a DNA adduct generated by exogenous and endogenous sources, severely blocks DNA synthesis and induces miscoding events in human cells. To probe the mechanism for in vivo translesion DNA synthesis across this adduct, in vitro primer extension studies were conducted using newly identified human DNA polymerases (pol) eta and kappa, which have been shown to catalyze translesion DNA synthesis past several DNA lesions. Steady-state kinetic analyses and analysis of translesion products have revealed that the synthesis is >100-fold more efficient with pol eta than with pol kappa and that both error-free and error-prone syntheses are observed with these enzymes. The miscoding events include both base substitution and frameshift mutations. These results suggest that both polymerases, particularly pol eta, may contribute to the translesion DNA synthesis events observed for 1,N(6)-ethenodeoxyadenosine in human cells.     

人类polⅡ启动子的识别

依据基因启动子区和非启动子区碱基分布的特征,应用基于多样性增量的二次判别分析 (IDQD),对人类polⅡ启动子进行识别,识别精度达到90％以上的水平,优于其他已发表的 (包括SVM分类器等) 识别算法. 使用IDQD算法也能对转录起始位点 (TSS) 进行较准确的预测,10-fold交叉检验结果的敏感性和特异性分别为86％和91％. 这些结果表明IDQD是一个有效的分类器.     

When pol I goes into high gear: processive DNA synthesis by pol I in the cell

Pol I is the most abundant polymerase in E. coli and plays an important role in short patch repair. In accord with this role in the cell, the purified polymerase exhibits low processivity and high fidelity in vitro. Pol I is also the polymerase responsible for leader strand synthesis during ColE1 plasmid replication. In a previous publication, we described the generation of a highly error-prone DNA polymerase I. Expression of this mutant Pol I results in errors during the replication of a ColE1 plasmid. The distribution and spectrum of mutations in the ColE1 plasmid sequence downstream the ori indicates that Pol I is capable of more processive replication in vivo than previously accepted. Here, we review evidence suggesting that Pol I may be recruited into a replisome-like holoenzyme and speculate that processive DNA replication by Pol I may play a role in recombination-dependent DNA replication in the cell.     

DNA binding properties of human pol gammaB

We have recently reported the crystal structure of the accessory subunit of mitochondrial DNA polymerase, pol gammaB, and identified a region of the protein involved in DNA binding. The DNA employed in previous studies was presumed to be single-stranded, because it was generated by single-sided PCR. Further characterization of this DNA indicated that, due to a strand transfer event during synthesis by single-sided PCR, the DNA adopts a double-stranded hairpin conformation under native conditions. We used a series of double- and single-stranded oligonucleotides of different lengths to confirm that human pol gammaB prefers to bind double-stranded DNA longer than 40 bp with little apparent sequence specificity. Site-specific deletion mutagenesis identified clusters of basic residues in two surface loops required for DNA binding located on opposite sides of the symmetrical pol gammaB dimer. A heterodimer of pol gammaB that contains one mutant and one wild-type DNA binding region was shown to be unable to bind double-stranded DNA, suggesting that a single DNA molecule must contact both DNA binding sites in the pol gammaB dimer. The ability to bind double-stranded DNA is not essential for pol gammaB stimulation of pol gammaA activity in vitro, but may play a role in DNA replication or repair.     

Association of DNA polymerase mu (pol mu) with Ku and ligase IV: role for pol mu in end-joining double-strand break repair

Mammalian DNA polymerase mu (pol mu) is related to terminal deoxynucleotidyl transferase, but its biological role is not yet clear. We show here that after exposure of cells to ionizing radiation (IR), levels of pol mu protein increase. pol mu also forms discrete nuclear foci after IR, and these foci are largely coincident with IR-induced foci of gammaH2AX, a previously characterized marker of sites of DNA double-strand breaks. pol mu is thus part of the cellular response to DNA double-strand breaks. pol mu also associates in cell extracts with the nonhomologous end-joining repair factor Ku and requires both Ku and another end-joining factor, XRCC4-ligase IV, to form a stable complex on DNA in vitro. pol mu in turn facilitates both stable recruitment of XRCC4-ligase IV to Ku-bound DNA and ligase IV-dependent end joining. In contrast, the related mammalian DNA polymerase beta does not form a complex with Ku and XRCC4-ligase IV and is less effective than pol mu in facilitating joining mediated by these factors. Our data thus support an important role for pol mu in the end-joining pathway for repair of double-strand breaks.     

Subunit interactions within the Saccharomyces cerevisiae DNA polymerase epsilon (pol epsilon ) complex. Demonstration of a dimeric pol epsilon

Saccharomyces cerevisiae DNA polymerase epsilon (pol epsilon) is essential for chromosomal replication. A major form of pol epsilon purified from yeast consists of at least four subunits: Pol2p, Dpb2p, Dpb3p, and Dpb4p. We have investigated the protein/protein interactions between these polypeptides by using expression of individual subunits in baculovirus-infected Sf9 insect cells and by using the yeast two-hybrid assay. The essential subunits, Pol2p and Dpb2p, interact directly in the absence of the other two subunits, and the C-terminal half of POL2, the only essential portion of Pol2p, is sufficient for interaction with Dpb2p. Dpb3p and Dpb4p, non-essential subunits, also interact directly with each other in the absence of the other two subunits. We propose that Pol2p.Dpb2p and Dpb3p.Dpb4p complexes interact with each other and document several interactions between individual members of the two respective complexes. We present biochemical evidence to support the proposal that pol epsilon may be dimeric in vivo. Gel filtration of the Pol2p.Dpb2p complexes reveals a novel heterotetrameric form, consisting of two heterodimers of Pol2p.Dpb2p. Dpb2p, but not Pol2p, exists as a homodimer, and thus the Pol2p dimerization may be mediated by Dpb2p. The pol2-E and pol2-F mutations that cause replication defects in vivo weaken the interaction between Pol2p and Dpb2p and also reduce dimerization of Pol2p. This suggests, but does not prove, that dimerization may also occur in vivo and be essential for DNA replication.     

Tryptic peptide analysis of avian oncovirus gag and pol gene products.

Tryptic digests of the internal proteins p30, p15, p12, and p10 of mouse xenotropic, ecotropic, and amphotropic type C viruses were subjected to cation-exchange chromatography. Analysis of these maps revealed that the p30 proteins from representative isolates of all three viral subgroups were distinguishable. The p15 proteins were all unique. The p12 proteins of NZB xenotropic and wild-mouse amphotropic viruses were not identical and yielded peptide maps remarkably different from that of the ecotropic virus. The p10 proteins of xenotropic and ecotropic viruses were identical and were dissimilar to that of the wild-mouse amphotropic virus.     

The 3'-5' exonuclease of human DNA polymerase delta (pol delta) is regulated by pol delta accessory factors and deoxyribonucleoside triphosphates.

Human DNA polymerase delta (pol delta) is required for the synthesis of leading strand of simian virus 40 (SV40) DNA replication in vitro. Pol delta requires the accessory factors, proliferating cell nuclear antigen (PCNA), activator 1 (A1; also known as replication factor C [RF-C]), human single-stranded DNA binding protein (HSSB; also known as replication protein A [RP-A]) for the elongation of primed template DNA. Since pol delta has an associated 3'-5' exonuclease activity, the effect of pol delta accessory factors on the exonuclease activity was examined. The 3'-5' exonuclease activity was stimulated 8-10 fold by the addition of HSSB, and this stimulatory effect was preferential to HSSB since other SSBs from E. coli, T4 or adenovirus, had a little or no effect. The stimulatory effect of HSSB was markedly inhibited by the combined action of A1 and PCNA. Furthermore, the addition of deoxyribonucleoside triphosphates (dNTPs) completely abolished the effect of HSSB on the 3'-5' exonuclease activity even in the absence of pol delta accessory factors. These results suggest that accessory factors and dNTPs regulate both the polymerase and the 3'-5' exonuclease activities.     

Translational recoding signals between gag and pol in diverse LTR retrotransposons

Because of their compact genomes, retroelements (including retrotransposons and retroviruses) employ a variety of translational recoding mechanisms to express Gag and Pol. To assess the diversity of recoding strategies, we surveyed gag/pol gene organization among retroelements from diverse host species, including elements exhaustively recovered from the genome sequences of Caenorhabditis elegans, Drosophila melanogaster, Schizosaccharomyces pombe, Candida albicans, and Arabidopsis thaliana. In contrast to the retroviruses, which typically encode pol in the -1 frame relative to gag, nearly half of the retroelements surveyed encode a single gag-pol open reading frame. This was particularly true for the Ty1/copia group retroelements. Most animal Ty3/gypsy retroelements, on the other hand, encode gag and pol in separate reading frames, and likely express Pol through +1 or -1 frameshifting. Conserved sequences conforming to slippery sites that specify viral ribosomal frameshifting were identified among retroelements with pol in the -1 frame. None of the plant retroelements encoded pol in the -1 frame relative to gag; however, two closely related plant Ty3/gypsy elements encode pol in the +1 frame. Interestingly, a group of plant Ty1/copia retroelements encode pol either in a +1 frame relative to gag or in two nonoverlapping reading frames. These retroelements have a conserved stem-loop at the end of gag, and likely express pol either by a novel means of internal ribosomal entry or by a bypass mechanism.