Activity of error-prone DNA polymerase iota in different periods of house mouse <Emphasis Type="Italic">Mus musculus</Emphasis> ontogeny

Analysis of incorrect activity of error-prone DNA polymerase iota in M. musculus ontogeny demonstrated considerable changes in its activity, which peaks in most organs during prenatal development and decreases in the adult body. We propose that the capacity of error-prone DNA polymerases to synthesize on damaged DNA regions is critical for the realization of rapidly changing genetic program in mammalian embryogenesis, which relieves the replication block and prevents cell death.     

Evolution of DNA polymerase <Emphasis Type="Italic">ι</Emphasis> structure and function in eukaryotes

Analysis of DNA polymerase iota (Pol iota) enzymic activity in different classes of eukaryotes has shown that error-prone activity of this enzyme can be found only in mammals, and that it is completely absent from organisms that are at lower stages of development. It was supposed that the emergence of the error-prone Pol iota activity in mammals is caused by structural alteration of the active center. Possible functions of error-prone Pol iota in higher eukaryotes are discussed.     

Molecular mechanisms of induced mutagenesis: Replication in vivo of bacteriophage φX174 single-stranded,ultraviolet light-irradiated DNA in intact and irradiated host cells

Genetic analysis has revealed that radiation and many chemical mutagens induce in bacteria an error-prone DNA repair process which is responsible for their mutagenic effect. The biochemical mechanism of this inducible error-prone repair has been studied by analysis of the first round of DNA synthesis on ultraviolet light-irradiated φX174 DNA in both intact and ultraviolet light-irradiated host cells. Intracellular φX174 DNA was extracted, subjected to isopycnic CsCl density-gradient analysis, hydroxylapatite chromatography and digestion by single-strand-specific endonuclease S₁. Ultraviolet light-induced photolesions in viral DNA cause a permanent blockage of DNA synthesis in intact Escherichia coli cells. However, when host cells are irradiated and incubated to fully induce the error-prone repair system, a significant fraction of irradiated φX174 DNA molecules can be fully replicated. Thus, inducible error-prone repair in E. coli is manifested by an increased capacity for DNA synthesis on damaged φX174 DNA. Chloramphenicol (100 μg/ml), which is an inhibitor of the inducible error-prone DNA repair, is also an inhibitor of this particular inducible DNA synthesis.     

Kinetics of induction and decay of error-prone DNA repair activity in Escherichia coli after treatment with nalidixic acid

Inducible error-prone DNA repair activity was detected by infecting nalidixic acid-pretreated E. coli cells with UV-irradiated phage phi X174. Induction and decay kinetics of reactivation very much resembled that of mutagenesis of the UV-damaged phage. Repair as well as mutagenic activity increased for about 30 min. The maximal error-prone repair capacity, which was induced in the cell during the 30 min nalidixic acid treatment, rapidly died out during subsequent cell growth in absence of nalidixic acid. Induction of this repair mode was not observed in a recA- mutant. In the presence of nalidixic acid plus rifampicin both repair and mutagenic effects were abolished.     

Directed evolution of alpha-aspartyl dipeptidase from Salmonella typhimurium.

Model-free approaches (error-prone PCR to introduce random mutations, DNA shuffling to combine positive mutations, and screening of the resultant mutant libraries) have been used to enhance the catalytic activity and thermostability of alpha-aspartyl dipeptidase from Salmonella typhimurium, which is uniquely able to hydrolyze Asp-X dipeptides (where X is any amino acid) and one tripeptide (Asp-Gly-Gly). Under double selective pressures of activity and thermostability, through two rounds of error-prone PCR and three sequential generations of DNA shuffling, coupled with screening, a mutant pepEM3074 with approximately 47-fold increased enzyme activity compared with its wild-type parent was obtained. Moreover, the stability of pepEM3074 is increased significantly. Three amino acid substitutions (Asn89His, Gln153Glu, and Leu205Arg), two of them are near the active site and substrate binding pocket, were identified by sequencing the genes encoding this evolved enzyme. The mechanism of the enhancement of activity and stability was analyzed in this paper.     

Comparison of the Escherichia coli umu+-encoded function with plasmid R46-mediated error-prone repair in DNA-damaged cells

Escherichia coli strain TK701 umu+ was more resistant than strain TK702 umu when tested against bleomycin (BLM), cis-platinum(II) diamminodichloride (PDD), ultraviolet light and methyl methanesulphonate (MMS), which produce single-strand DNA damage. However, the umu mutant was no more sensitive to mitomycin C (MTC) or proflavine (PF), which cause double-strand DNA binding. Strain TK702 umu was nonmutable by any of the agents, whereas mutations were induced in the wild-type strain by PDD, UV, MMS and MTC. The E. coli umu+ function therefore mimics plasmid R46-mediated error-prone repair in protecting only against single-strand DNA damage, whilst enhancing mutagenesis by both single- and double-strand damaging agents. Comparison of plasmid R46-mediated protection and mutagenesis in umu+ and umu strains indicated that the plasmid confers a greater error-prone DNA-repair activity in the mutant. Results are discussed in terms of analogy between host umu+ and plasmid muc+ functions.     

Amino acid substitutions at conserved tyrosine 52 alter fidelity and bypass efficiency of human DNA polymerase eta

DNA polymerase eta (Pol eta) is a member of a new class of DNA polymerases that is able to copy DNA containing damaged nucleotides. These polymerases are highly error-prone during copying of unaltered DNA templates. We analyzed the relationship between bypass efficiency and fidelity of DNA synthesis by introducing substitutions for Tyr-52, a highly conserved amino acid, within the human DNA polymerase eta (hPol eta) finger domain. Most substitutions for Tyr-52 caused reduction in bypass of UV-associated damage, measured by the ability to rescue the viability of UV-sensitive yeast cells at a high UV dose. For most mutants, the reduction in bypass ability paralleled the reduction in polymerization activity. Interestingly, the hPol eta Y52E mutant exhibited a greater reduction in bypass efficiency than polymerization activity. The reduction in bypass efficiency was accompanied by an up to 11-fold increase in the incorporation of complementary nucleotides relative to non-complementary nucleotides. The fidelity of DNA synthesis, measured by copying a gapped M13 DNA template in vitro, was also enhanced as much as 15-fold; the enhancement resulted from a decrease in transitions, which were relatively frequent, and a large decrease in transversions. Our demonstration that an amino acid substitution within the active site enhances the fidelity of DNA synthesis by hPol eta, one of the most inaccurate of DNA polymerases, supports the hypothesis that even error-prone DNA polymerases function in base selection.     

Inhibition of Mn2+-induced error-prone DNA synthesis with Cd2+ and Zn2+

Bivalent metal cations are key components in the reaction of DNA synthesis. They are necessary for all DNA polymerases, being involved as cofactors in catalytic mechanisms of nucleotide polymerization. It is also known that in the presence of Mn²⁺ the accuracy of DNA synthesis is considerably decreased. The findings of this work show that Cd²⁺ and Zn²⁺ selectively inhibit the Mn²⁺-induced error-prone DNA polymerase activity in extracts of cells from human and mouse tissues. Moreover, these cations in low concentrations also can efficiently inhibit the activity of homogeneous preparations of DNA polymerase iota (Pol ?), which is mainly responsible for the Mn²⁺-induced error-prone DNA polymerase activity in cell extracts. Using a primary culture of granular cells from postnatal rat cerebellum, we show that low concentrations of Cd²⁺ significantly increase cell survival in the presence of toxic Mn²⁺ doses. Thus, we have shown that in some cases low concentrations of Cd²⁺ can display a positive influence on cells, whereas it is widely acknowledged that this metal is not a necessary microelement and is toxic for organisms.     

DNA Polymerase ζ-Dependent Lesion Bypass in Saccharomyces cerevisiae Is Accompanied by Error-Prone Copying of Long Stretches of Adjacent DNA

Translesion synthesis (TLS) helps cells to accomplish chromosomal replication in the presence of unrepaired DNA lesions. In eukaryotes, the bypass of most lesions involves a nucleotide insertion opposite the lesion by either a replicative or a specialized DNA polymerase, followed by extension of the resulting distorted primer terminus by DNA polymerase ζ (Polζ). The subsequent events leading to disengagement of the error-prone Polζ from the primer terminus and its replacement with an accurate replicative DNA polymerase remain largely unknown. As a first step toward understanding these events, we aimed to determine the length of DNA stretches synthesized in an error-prone manner during the Polζ-dependent lesion bypass. We developed new in vivo assays to identify the products of mutagenic TLS through a plasmid-borne tetrahydrofuran lesion and a UV-induced chromosomal lesion. We then surveyed the region downstream of the lesion site (in respect to the direction of TLS) for the presence of mutations indicative of an error-prone polymerase activity. The bypass of both lesions was associated with an approximately 300,000-fold increase in the mutation rate in the adjacent DNA segment, in comparison to the mutation rate during normal replication. The hypermutated tract extended 200 bp from the lesion in the plasmid-based assay and as far as 1 kb from the lesion in the chromosome-based assay. The mutation rate in this region was similar to the rate of errors produced by purified Polζ during copying of undamaged DNA in vitro. Further, no mutations downstream of the lesion were observed in rare TLS products recovered from Polζ-deficient cells. This led us to conclude that error-prone Polζ synthesis continues for several hundred nucleotides after the lesion bypass is completed. These results provide insight into the late steps of TLS and show that error-prone TLS tracts span a substantially larger region than previously appreciated.     

Analysis of the spontaneous mutator phenotype associated with 20S proteasome deficiency in S. cerevisiae

Besides its role as a major recycler of unfolded or otherwise damaged intracellular proteins, the 26S proteasome functions as a regulator of many vital cellular processes and is postulated as a target for antitumor drugs. It has previously been shown that dysfunction of the catalytic core of the 26S proteasome, the 20S proteasome, causes a moderate increase in the frequency of spontaneous mutations in yeast [A. Podlaska, J. McIntyre, A. Skoneczna, E. Sledziewska-Gojska, The link between proteasome activity and postreplication DNA repair in Saccharomyces cerevisiae. Mol. Microbiol. 49 (2003) 1321-1332]. Here we show the results of genetic analysis, which indicate that the mutator phenotype caused by the deletion of UMP1, encoding maturase of 20S proteasome, involves members of the RAD6 epistasis group. The great majority of mutations occurring spontaneously in yeast cells deficient in 20S proteasome function are connected with the unique Rad6/Rad18-dependent error-prone translesion DNA synthesis (TLS) requiring the activities of both TLS polymerases: Pol eta and Pol zeta. Our results suggest the involvement of proteasomal activity in the limitation of this unique error-prone TLS mechanism in wild-type cells. On the other hand, we found that the mutator phenotypes caused by deficiency in Rad18 and Rad6, are largely alleviated by defects in proteasome activities. Since the mutator phenotypes produced by deletion of RAD6 and RAD18 require Pol zeta and Siz1/Ubc9-dependent sumoylation of PCNA, our results suggest that proteasomal dysfunction limits sumoylation-dependent error-prone activity of Pol zeta. Taken together, our findings strongly support the idea that proteolytic activity is involved in modulating the balance between TLS mechanisms functioning during DNA replication in S. cerevisiae.     

Alkyladenine DNA glycosylase (Aag) in somatic hypermutation and class switch recombination

Somatic hypermutation (SHM) and class switch recombination (CSR) of immunoglobulin (Ig) genes require the cytosine deaminase AID, which deaminates cytosine to uracil in Ig gene DNA. Paradoxically, proteins involved normally in error-free base excision repair and mismatch repair, seem to be co-opted to facilitate SHM and CSR, by recruiting error-prone translesion polymerases to DNA sequences containing deoxy-uracils created by AID. Major evidence supports at least one mechanism whereby the uracil glycosylase Ung removes AID-generated uracils creating abasic sites which may be used either as uninformative templates for DNA synthesis, or processed to nicks and gaps that prime error-prone DNA synthesis. We investigated the possibility that deamination at adenines also initiates SHM. Adenosine deamination would generate hypoxanthine (Hx), a substrate for the alkyladenine DNA glycosylase (Aag). Aag would generate abasic sites which then are subject to error-prone repair as above for AID-deaminated cytosine processed by Ung. If the action of an adenosine deaminase followed by Aag were responsible for significant numbers of mutations at A, we would find a preponderance of A:T>G:C transition mutations during SHM in an Aag deleted background. However, this was not observed and we found that the frequencies of SHM and CSR were not significantly altered in Aag-/- mice. Paradoxically, we found that Aag is expressed in B lymphocytes undergoing SHM and CSR and that its activity is upregulated in activated B cells. Moreover, we did find a statistically significant, albeit low increase of T:A>C:G transition mutations in Aag-/- animals, suggesting that Aag may be involved in creating the SHM A>T bias seen in wild type mice.     

Random mutagenesis and recombination of sam1 gene by integrating error-prone PCR with staggered extension process

An efficient method for creating a DNA library is presented in which gene mutagenesis and recombination can be introduced by integrating error-prone PCR with a staggered extension process in one test tube. In this process, less than 15 cycles of error-prone PCR are used to introduce random mutations. After precipitated and washed with ethanol solution, the error-prone PCR product is directly used both as template and primers in the following staggered extension process to introduce DNA recombination. The method was validated by using adenosyl-methionine (AdoMet) synthetase gene, sam1, as a model. The full-length target DNA fragment was available after a single round. After being selected with a competitive inhibitor, ethionine, a mutated gene was obtained that increased AdoMet accumulation in vivo by 56%.     

Nucleotide excision repair DNA synthesis by excess DNA polymerase beta: a potential source of genetic instability in cancer cells.

The nucleotide excision repair pathway contributes to genetic stability by removing a wide range of DNA damage through an error-free reaction. When the lesion is located, the altered strand is incised on both sides of the lesion and a damaged oligonucleotide excised. A repair patch is then synthesized and the repaired strand is ligated. It is assumed that only DNA polymerases delta and/or epsilon participate to the repair DNA synthesis step. Using UV and cisplatin-modified DNA templates, we measured in vitro that extracts from cells overexpressing the error-prone DNA polymerase beta exhibited a five- to sixfold increase of the ultimate DNA synthesis activity compared with control extracts and demonstrated the specific involvement of Pol beta in this step. By using a 28 nt gapped, double-stranded DNA substrate mimicking the product of the incision step, we showed that Pol beta is able to catalyze strand displacement downstream of the gap. We discuss these data within the scope of a hypothesis previously presented proposing that excess error-prone Pol beta in cancer cells could perturb the well-defined specific functions of DNA polymerases during error-free DNA transactions.     

分段DNA shuffling: 一种大分子海藻糖合酶有效的定向进化方法

[目的]红色亚栖热菌(Meiothermus ruber)海藻糖合酶(Trehalose synthase,M-TreS)将麦芽糖转化生成海藻糖只需一步反应,且具有很好的热稳定性及pH耐受性,是潜在的工业生产海藻糖的酶源.为了提高该酶的性能,有必要对其进行定向进化.[方法]M-TreS基因(M-treS)大小为2 889bp.该蛋白质分子本身具有很大的进化空间,但是却不宜进行全长基因Shuffling.分段DNA shuffling是为大分子蛋白质(基因≥2 000 bp)的进化而设计的一种方法.该方法分为三步:(1)用两对引物分别扩增目的基因的上游片段和下游片段;(2)上下游片段各自进行Shuffling; (3)利用重叠延伸PCR连接上下游突变群,建立完整基因的突变文库.[结果]结合易错PCR,通过该方法经一轮进化获得一株酶活力是野生型1.6倍、催化效率是野生型2倍的突变株.序列分析表明,该突变株共有6个位点发生了氨基酸的替代,其中一个来自易错突变,2个来自同源重组,3个为随机突变.[结论]分段DNA shuffling是进化大分子蛋白质的有效方法.     

Lyase activities intrinsic to Escherichia coli polymerases IV and V

Escherichia coli DNA polymerase IV and V (pol IV and pol V) are error-prone DNA polymerases that are induced as part of the SOS regulon in response to DNA damage. Both are members of the Y-family of DNA polymerases. Their principal biological roles appear to involve translesion synthesis (TLS) and the generation of mutational diversity to cope with stress. Although neither enzyme is known to be involved in base excision repair (BER), we have nevertheless observed apurinic/apyrimidinic 5'-deoxyribose phosphate (AP/5'-dRP) lyase activities intrinsic to each polymerase. Pols IV and V catalyze cleavage of the phosphodiester backbone at the 3'-side of an apurinic/apyrimidinic (AP) site as well as the removal of a 5'-deoxyribose phosphate (dRP) at a preincised AP site. The specific activities of the two error-prone polymerase-associated lyases are approximately 80-fold less than the associated lyase activity of human DNA polymerase beta, which is a key enzyme used in short patch BER. Pol IV forms a covalent Schiff's base intermediate with substrate DNA that is trapped by sodium borohydride, as proscribed by a beta-elimination mechanism. In contrast, a NaBH(4) trapped intermediate is not observed for pol V, even though the lyase specific activity of pol V is slightly higher than that of pol IV. Incubation of pol V (UmuD'(2)C) with a molar excess of UmuD drives an exchange of subunits to form UmuD'D+insoluble UmuC causing inactivation of polymerase and lyase activities. The concomitant loss of both activities is strong evidence that pol V contains a bona fide lyase activity.     

DNA polymerases are error-prone at RecA-mediated recombination intermediates

Genetic studies have suggested that Y-family translesion DNA polymerase IV (DinB) performs error-prone recombination-directed replication (RDR) under conditions of stress due to its ability to promote mutations during double-strand break (DSB) repair in growth-limited E. coli cells. In recent studies we have demonstrated that pol IV is preferentially recruited to D-loop recombination intermediates at stress-induced concentrations and is highly mutagenic during RDR in vitro. These findings verify longstanding genetic data that have implicated pol IV in promoting stress-induced mutagenesis at D-loops. In this Extra View, we demonstrate the surprising finding that A-family pol I, which normally exhibits high-fidelity DNA synthesis, is highly error-prone at D-loops like pol IV. These findings indicate that DNA polymerases are intrinsically error-prone at RecA-mediated D-loops and suggest that auxiliary factors are necessary for suppressing mutations during RDR in non-stressed proliferating cells.     

Engineered zinc finger nickases induce homology-directed repair with reduced mutagenic effects

Engineered zinc finger nucleases (ZFNs) induce DNA double-strand breaks at specific recognition sequences and can promote efficient introduction of desired insertions, deletions or substitutions at or near the cut site via homology-directed repair (HDR) with a double- and/or single-stranded donor DNA template. However, mutagenic events caused by error-prone non-homologous end-joining (NHEJ)-mediated repair are introduced with equal or higher frequency at the nuclease cleavage site. Furthermore, unintended mutations can also result from NHEJ-mediated repair of off-target nuclease cleavage sites. Here, we describe a simple and general method for converting engineered ZFNs into zinc finger nickases (ZFNickases) by inactivating the catalytic activity of one monomer in a ZFN dimer. ZFNickases show robust strand-specific nicking activity in vitro. In addition, we demonstrate that ZFNickases can stimulate HDR at their nicking site in human cells, albeit at a lower frequency than by the ZFNs from which they were derived. Finally, we find that ZFNickases appear to induce greatly reduced levels of mutagenic NHEJ at their target nicking site. ZFNickases thus provide a promising means for inducing HDR-mediated gene modifications while reducing unwanted mutagenesis caused by error-prone NHEJ.     

Low-fidelity Pyrococcus furiosus DNA polymerase mutants useful in error-prone PCR

Random mutagenesis constitutes an important approach for identifying critical regions of proteins, studying structure-function relations and developing novel proteins with desired properties. Perhaps, the most popular method is the error-prone PCR, in which mistakes are introduced into a gene, and hence a protein, during DNA polymerase-catalysed amplification cycles. Unfortunately, the relatively high fidelities of the thermostable DNA polymerases commonly used for PCR result in too few mistakes in the amplified DNA for efficient mutagenesis. In this paper, we describe mutants of the family B DNA polymerase from Pyrococcus furiosus (Pfu-Pol), with superb performance in error-prone PCR. The key amino acid changes occur in a short loop linking two long α-helices that comprise the ‘fingers’ sub-domain of the protein. This region is responsible for binding the incoming dNTPs and ensuring that only correct bases are inserted opposite the complementary base in the template strand. Mutations in the short loop, when combined with an additional mutation that abolishes the 3′–5′ proof-reading exonuclease activity, convert the extremely accurate wild-type polymerase into a variant with low fidelity. The mutant Pfu-Pols can be applied in error-prone PCR, under exactly the same conditions used for standard, high-fidelity PCR with the wild-type enzyme. Large quantities of amplified product, with a high frequency of nearly indiscriminate mutations, are produced. It is anticipated that the Pfu-Pol variants will be extremely useful for the randomization of gene, and hence protein, sequences.     

Two-step error-prone bypass of the (+)- and (-)-trans-anti-BPDE-N2-dG adducts by human DNA polymerases eta and kappa

Benzo[a]pyrene is a polycyclic aromatic hydrocarbon (PAH) associated with potent carcinogenic activity. Mutagenesis induced by benzo[a]pyrene DNA adducts is believed to involve error-prone translesion synthesis opposite the lesion. However, the DNA polymerase involved in this process has not been clearly defined in eukaryotes. Here, we provide biochemical evidence suggesting a role for DNA polymerase eta (Poleta) in mutagenesis induced by benzo[a]pyrene DNA adducts in cells. Purified human Poleta predominantly inserted an A opposite a template (+)- and (-)-trans-anti-BPDE-N2-dG, two important DNA adducts of benzo[a]pyrene. Both lesions also dramatically elevated G and T mis-insertion error rates of human Poleta. Error-prone nucleotide insertion by human Poleta was more efficient opposite the (+)-trans-anti-BPDE-N2-dG adduct than opposite the (-)-trans-anti-BPDE-N2-dG. However, translesion synthesis by human Poleta largely stopped opposite the lesion and at one nucleotide downstream of the lesion (+1 extension). The limited extension synthesis of human Poleta from opposite the lesion was strongly affected by the stereochemistry of the trans-anti-BPDE-N2-dG adducts, the nucleotide opposite the lesion, and the sequence context 5' to the lesion. By combining the nucleotide insertion activity of human Poleta and the extension synthesis activity of human Polkappa, effective error-prone lesion bypass was achieved in vitro in response to the (+)- and (-)-trans-anti-BPDE-N2-dG DNA adducts.