Biochemical Characterization of Translesion Synthesis by Sulfolobus acidocaldarius DNA Polymerases

To study the DNA synthesis mechanism of Sulfolobus acidocaldarius, a thermophilic species from Crenarchaeota, two DNA polymerases of B family(polB1 and polB3), and one DNA polymerase of Y family(polIV) were recombinantly expressed, purified and biochemically characterized. Both DNA polymerases polB1(Saci_1537) and polB3(Saci_0074) possessed DNA polymerase and 3' to 5' exonuclease activities; however, both the activities of B3 were very inefficient in vitro. The polIV(Saci_0554) was a polymerase, not an exonuclease. The activities of all the three DNA polymerases were dependent on divalent metal ions Mn²⁺ and Mg²⁺. They showed the highest activity at pH values ranging from 8.0 to 9.5. Their activities were inhibited by KCl with high concentration. The optimal reaction temperatures for the three DNA polymerases were between 60 and 70℃. Deaminated bases dU and dI on DNA template strongly hindered primer extension by the two DNA polymerases of B family, not by the DNA polymerase of Y family. DNA polymerase of Y Family bypassed the two AP site analogues dSpacer and propane on template more easily than DNA polymerases of B family. Our results suggest that the three DNA polymerases coordinate to fulfill various DNA synthesis in Sulfolobus acidocaldarius cell.     

Sequence-specifically platinum metal deposition on enzymatically synthesized DNA block copolymer

Platinum metal was sequence-specifically deposited on the DNA block copolymer synthesized by the Klenow fragment of E. coli DNA polymerase I (3'-5' exonuclease deficient).     

Evaluation of 15 polymerases and phosphorothioate primer modification for detection of UV-induced C:G to T:A mutations by allele-specific PCR

Allele-specific polymerase chain reaction is based on polymerase extension from primers that contain a 3' end base that is complementary to a specific mutation and inhibition of extension with wild-type DNA due to a 3' end mismatch. Taq polymerase is commonly used for this assay, but because of the high rate of nucleotide extension from primer 3' base mismatches documented for Taq polymerase, high sensitivity is difficult to achieve. To determine whether other polymerases might improve assay sensitivity, 15 polymerases were tested with mutation-specific primers for two ultraviolet-induced mutations in the human 5S ribosomal RNA genes. Of the 15 polymerases tested, six were capable of discriminating these mutations at levels equivalent to or better than Taq polymerase. All primers were phosphorothioate modified on the 3' end to block removal of the critical 3' mutation-specific base by polymerases containing 3' --> 5' exonuclease "proofreading" activity. The effectiveness of phosphorothioate modification was measured in mock polymerase chain reaction reactions and a time course. All six enzymes containing this exonuclease activity showed some ability to digest phosphorothioate-modified primers and could be divided into two groups, showing fast and slow digestion kinetics. Of the three enzymes that showed slow digestion kinetics, two also showed significantly slower digestion kinetics of unmodified primers.     

Matrix-assisted laser desorption/ionization detection of polymerase chain reaction products by utilizing the 5'-3' exonuclease activity of Thermus aquaticus DNA polymerase

The 5'-3' exonuclease activity of DNA polymerase was utilized in the polymerase chain reaction system to generate a specific signal concomitant with amplification. These signals were detected by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS). This method obviates the need to perform extensive DNA purification of reaction products that is often necessary for detecting larger DNA molecules by mass spectrometry. Oligonucleotides complementary to the internal region of the amplicon are degraded by the 5'-3' exonuclease activity and the degradation products are analyzed by MALDI mass spectrometry. We refer to this assay as the Exo-taq assay or probe degradation assay. This method should be amenable to automation.     

THE ROLE OF DNA POLYMERASE I IN LIQUID HOLDING RECOVERY OF UV-IRRADIATED ESCHERICHIA COLI

Abstract. –Excision of cyclobutyl dipyrimidines from, and accumulation of strand interruptions in, DNA of different strains of E. coli K12 were determined during liquid holding recovery after UV irradiation. The extent of Pyr <> Pyr excision was the same (20–25%) for both a pol A mutant ( E. coli P3478) and its parental wild type strain ( E. coli W3110); however, single strand interruptions accumulate during liquid holding of polA cells, but not in the parental strain. In contrast, excision was greatly reduced in a mutant (KMBL 1789) which is defective in the 5'→3' exonucleolytic function of DNA polymerase I. These data suggest that excision and resynthesis during liquid holding are carried out primarily, if not entirely, by DNA polymerase I. We further conclude that excision alone is both a necessary and sufficient condition to elicit liquid holding recovery, and that this excision requires a functional polymerase I 5'→ 3' exonuclease.     

Exonuclease activity of proofreading DNA polymerases is at the origin of artifacts in molecular profiling studies

CE fingerprint methods are commonly used in microbial ecology. We have previously noticed that the position and number of peaks in CE-SSCP (single-strand conformation polymorphism) profiles depend on the DNA polymerase used in PCR [1]. Here, we studied the fragments produced by Taq polymerase as well as four commercially available proofreading polymerases, using the V3 region of the Escherichia coli rss gene as a marker. PCR products rendered multiple peaks in denaturing CE; Taq polymerase was observed to produce the longest fragments. Incubation of the fragments with T4 DNA polymerase indicated that the 3'-ends of the proofreading polymerase amplicons were recessed, while the Taq amplicon was partially +A tailed. Treatment of the PCR product with proofreading DNA polymerase rendered trimmed fragments. This was due to the 3'-5' exonuclease activity of these enzymes, which is essential for proofreading. The nuclease activity was reduced by increasing the concentration of dNTP. The Platinum Pfx DNA polymerase generated very few artifacts and could produce 85% of blunted PCR products. Nevertheless, despite the higher error rate, we recommend the use of Taq polymerase rather than proofreading in the framework for molecular fingerprint studies. They are more cost-effective and therefore ideally suited for high-throughput analysis; the +A tail artifact rate can be controlled by modifying the PCR primers and the reaction conditions.     

Characterization of a Family B DNA Polymerase from the Hyperthermophilic Crenarchaeon Ignicoccus hospitalis KIN4/I and Its Application to PCR

A family B DNA polymerase gene from the hyperthermophilic crenarchaeon Ignicoccus hospitalis KIN4/I was highly expressed under the control of T7lac promoter of pET-28ARG in Escherichia coli BL21-CodonPlus(DE3)-RIL cells. The produced I. hospitalis (Iho) DNA polymerase was purified by heat treatment followed by HisTrap? HP column and HiTrap? SP column chromatographies. The molecular mass of the purified Iho DNA polymerase was 88 kDa as estimated by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). The optimal pH for Iho DNA polymerase activity was 7.0 and the optimal temperature was 70 °C. Iho DNA polymerase was strongly activated by the presence of magnesium ion at an optimum concentration of 3 mM. The optimal concentration of KCl for Iho DNA polymerase activity was 60 mM. The half-life of the enzyme at 94 °C was about 2 h. The optimal conditions for polymerase chain reaction (PCR) were determined. Iho DNA polymerase possesses 3′?→?5′ exonuclease activity, and the fidelity of the Iho DNA polymerase was similar to that of Pfu and Vent DNA polymerases. However, Iho DNA polymerase provided more enhanced efficiency of PCR amplification than Pfu and Vent DNA polymerases. Iho DNA polymerase could successfully amplify a 2-kb λ DNA target with a 10-s extension time and could amplify a DNA fragment up to 8 kb λ DNA.     

MONOFUNCTIONAL ANGULAR FUROCOUMARINS: SEQUENCE SPECIFICITY IN DNA HOTOBINDING OF 6,4,4''-TRIMETHYLANGELICIN and OTHER ANGELICINS

The sequence specificity in the photoreaction (365 nm) of 6,4,4'-trimethylangelicin (TMA) with DNA fragments of the lac I gene of Escherichia coli was studied by using DNA sequencing methodology. In order to map the sites of TMA photoaddition, we took advantage of the (3'-5') exonuclease activity associated with T4 DNA polymerase, which is blocked by bulky adducts, such as furocoumarin photoadducts. A quantitative analysis of the sites of photoaddition is reported. TMA was demonstrated to photoreact with thymine and, to a lower extent, to cytosine. AT-rich sequences and TTT sites in a GC context are the most reactive sites towards TMA whereas TA, AT, CA, AC sites are weaker sites with similar reactivity. Cytosines in alternated CG sequences are also targets of TMA photobinding. We observed a less pronounced sequence specificity of TMA than that of other psoralen derivatives already studied (Sage and Moustacchi, 1987; Boyer et al., 1988). A comparison with other furocoumarins 4,4'-dimethylangelicin (4,4'-DMA), 4'-methylangelicin (4'-MA), angelicin, 4,5',8-trimethylpsoralen (TMP) and 8-methoxypsoralen (8-MOP) is also reported. The role of flanking sequence and consequently of the local conformation at the various sites of photoaddition is discussed. A preferential orientation of the TMA molecule during the intercalation in the dark is suggested. Hot alkali treatment of TMA-modified DNA did not reveal any DNA strand breakage due to photooxidized bases.     

Efficient generation of 2'-deoxyuridin-5-yl at 5'-(G/C)AA(X)U(X)U-3' (X = Br, I) sequences in duplex DNA under UV irradiation

The photoreactivity of 5-halouracil-containing DNA was investigated using 450 base pair DNA fragments under 302 nm irradiation. Heat-dependent cleavage selectively occurs at 5'-(G/C)AAXUXU-3' and 5'-(G/C)AXUXU-3' (X = Br, I) sequences in double-stranded DNA. HPLC product analysis indicated that 2'-deoxyribonolactone residues are effectively generated at these sequences. These observations will be useful in studying the molecular basis of the sequence-dependent DNA-damaging process in UV-irradiated 5-halouracil-containing DNA.     

KF polymerase-based fluorescence aptasensor for the label-free adenosine detection

We have developed a simple, inexpensive, and label-free method for the selective detection of adenosine. Klenow fragment polymerase (KF polymerase) is a commonly-used 5' to 3' DNA polymerase, it also has 3' to 5' exonuclease activity that can digest single-stranded DNA. An adenosine binding DNA aptamer was employed, the aptamer was split into two pieces of single-stranded DNA (aptamer-A1 + aptamer-A2). Without the addition of adenosine, aptamer-A1 and aptamer-A2 existed as single-stranded DNA which could be efficiently degraded by the exonuclease activity of KF polymerase. Much reduced background fluorescence was obtained when SYBR Green dye was added. However, in the presence of adenosine, aptamer-A1 and aptamer-A2 bound to adenosine, and hybridization of the complementary sequences resulted in the formation of a duplex DNA structure, which could initiate DNA polymerization. The addition of SYBR Green dye resulted in a very high fluorescence enhancement, which could be used for the quantification of adenosine.     

recA-dependent DNA repair in UV-irradiated Escherichia coli

UV-radiation-induced lesions in DNA result in the formation of excision gaps, daughter-strand gaps (DSG) and double-strand breaks (DSB), which are repaired by several different mechanisms. Postreplication repair. The recA gene is a master gene that controls all of the pathways of postreplication repair. The repair of DSG proceeds by one pathway that is also recF dependent, and one pathway that is constitutive and independent of the recF and recBC genes. A small fraction of the recF recB-independent repair of DSG is dependent upon the umuC gene, and may define an error-prone pathway of postreplication repair. Unrepaired DSG can be converted to DSB, which are normally repaired by the RecBCD pathway. However, in the recBC sbcB background, these DSB are repaired by a recF-dependent process. The RecF pathways of postreplication repair appear to utilize DNA containing a single-stranded region (either a gap or a DSB with a single-stranded end), while the RecBCD pathway appears to utilize the blunt ends of duplex DNA to promote the recombinational repair of DSB. The polA gene (especially the 5'----3' exonuclease activity of DNA polymerase I) functions in pathways of postreplication repair (both for the repair of DSG and DSB) that are largely independent of the recF gene. Nucleotide excision repair. The repair of excision gaps is independent of the recA gene in cells with unreplicated chromosomes, but is recA dependent in cells with partially replicated chromosomes at the time of UV irradiation. This recA-dependent repair of excision gaps appears to be analogous to the recF- and recB-dependent pathways of postreplication repair, i.e. the RecF pathway repairs DNA gaps, and the RecBCD pathway repairs the DSB that arise at unrepaired gaps.     

Photosensitization of DNA of defined sequence by furochromones, khellin and visnagin

The sequence specificity in the in vitro DNA photobinding of khellin and visnagin, two naturally occurring furochromones proposed for chemotherapy of vitiligo, was investigated by using DNA sequencing methodology. The 3'-5' exonuclease associated with the T4 DNA polymerase served as a tool for determining photoadducts distribution on DNA fragments of the lac I gene of Escherichia coli. The photoadduct distribution of psoralen is also studied for comparison. Upon UVA irradiation, visnagin mainly forms monoadducts with thymine and to a lower extent with cytosine. Alternating (A-T)n sequences are hot spots for visnagin photoaddition. This is a property shared with furocoumarins. TTT sites are also quite reactive to visnagin, as they are to methylated angelicins. In contrast, with psoralen derivatives, there is no preferential photobinding in 5'-TpA sites, and 5'-ApT sites react as well. Furthermore, many sites such as T in the GC context, and C in any context, react, although weakly. The visnagin photoadduct distribution resembles very much the photoadduct distribution of methylated angelicins as described by Miolo et al. The photoreaction of these two series of compounds is less sequence dependent than the photobinding of psoralen derivatives as described by Sage and Moustacchi and by Boyer et al. The sequence specificity in khellin-DNA photobinding is the same as for visnagin, even though it forms much fewer photoadducts. The absence of photo-oxidation of DNA after treatment with visnagin or khellin plus UVA suggests that furochromones do not present any photodynamic effect on DNA.     

2',5,7-Trihydroxy-4',5'-(2,2-dimethylchromeno)-8-(3-hydroxy-3-methylbutyl) flavanone purified from Cudrania tricuspidata induces apoptotic cell death of human leukemia U937 cells

Cellular DNA topoisomerase I is an important target in cancer chemotherapy. A chloroform extract of the root barks of Cudrania tricuspidata showed an inhibitory effect on mammalian DNA topoisomerase I. The topoisomerase I inhibitory compound was purified and identified as 2',5,7-trihydroxy-4',5'-(2,2-dimethylchromeno)-8-(3-hydroxy-3-methylbutyl) flavanone. The compound, temporarily designated as PKH-3, was shown to inhibit the activity of topoisomerase I with IC50 about 1.0 mM. Concentration of 10 microM PKH-3 caused 50% growth inhibition of human cancer cell U937. PKH-3-induced cell death was characterized with the cleavage of poly(ADP-ribose) polymerase (PARP) and pro-caspase 3. Furthermore, PKH-3 induced the fragmentation of DNA into multiples of 180 b.p. (an apoptotic DNA ladder), indicating that the inhibitor triggered apoptosis. This induction of apoptosis by PKH-3 was also confirmed using flow cytometry analysis. Taken together, these results suggest that PKH-3 may function by inhibiting oncogenic disease, at least in part, through the inhibition of topoisomerase I activity.     

Processive replication of single DNA molecules in a nanopore catalyzed by phi29 DNA polymerase

Coupling nucleic acid processing enzymes to nanoscale pores allows controlled movement of individual DNA or RNA strands that is reported as an ionic current/time series. Hundreds of individual enzyme complexes can be examined in single-file order at high bandwidth and spatial resolution. The bacteriophage phi29 DNA polymerase (phi29 DNAP) is an attractive candidate for this technology, due to its remarkable processivity and high affinity for DNA substrates. Here we show that phi29 DNAP-DNA complexes are stable when captured in an electric field across the α-hemolysin nanopore. DNA substrates were activated for replication at the nanopore orifice by exploiting the 3'-5' exonuclease activity of wild-type phi29 DNAP to excise a 3'-H terminal residue, yielding a primer strand 3'-OH. In the presence of deoxynucleoside triphosphates, DNA synthesis was initiated, allowing real-time detection of numerous sequential nucleotide additions that was limited only by DNA template length. Translocation of phi29 DNAP along DNA substrates was observed in real time at ?ngstrom-scale precision as the template strand was drawn through the nanopore lumen during replication.     

Single-molecule Förster resonance energy transfer reveals an innate fidelity checkpoint in DNA polymerase I

Enzymatic reactions typically involve complex dynamics during substrate binding, conformational rearrangement, chemistry, and product release. The noncovalent steps provide kinetic checkpoints that contribute to the overall specificity of enzymatic reactions. DNA polymerases perform DNA replication with outstanding fidelity by actively rejecting noncognate nucleotide substrates early in the reaction pathway. Substrates are delivered to the active site by a flexible fingers subdomain of the enzyme, as it converts from an open to a closed conformation. The conformational dynamics of the fingers subdomain might also play a role in nucleotide selection, although the precise role is currently unknown. Using single-molecule F?rster resonance energy transfer, we observed individual Escherichia coli DNA polymerase I (Klenow fragment) molecules performing substrate selection. We discovered that the fingers subdomain actually samples through three distinct conformations--open, closed, and a previously unrecognized intermediate conformation. We measured the overall dissociation rate of the polymerase-DNA complex and the distribution among the various conformational states in the absence and presence of nucleotide substrates, which were either correct or incorrect. Correct substrates promote rapid progression of the polymerase to the catalytically competent closed conformation, whereas incorrect nucleotides block the enzyme in the intermediate conformation and induce rapid dissociation from DNA. Remarkably, incorrect nucleotide substrates also promote partitioning of DNA to the spatially separated 3'-5' exonuclease domain, providing an additional mechanism to prevent misincorporation at the polymerase active site. These results reveal the existence of an early innate fidelity checkpoint, rejecting incorrect nucleotide substrates before the enzyme encloses the nascent base pair.     

PHOTOADDITION OF 8-METHOXYPSORALEN TO E. coli DNA POLYMERASE I. ROLE OF PSORALEN PHOTO-ADDUCTS IN THE PHOTOSENSITIZED ALTERATIONS OF POL I ENZYMATIC ACTIVITIES

Abstract— We have previously demonstrated that 8-methoxypsoralen (8-MOP)‡ plus UVA is able to inactivate the three enzymatic activities of E. coli DNA polymerase I and that oxygen is required for these reactions (M. Granger et al. , (1982) Photochem. Photobiol. , 36 , 175–180). We now show that UV-A irradiation produces a covalent incorporation of the psoralen derivative into the enzyme either in the presence or in the absence of oxygen. The excited psoralen binds directly to the protein in an oxygen-independent reaction; no complex was detected in the absence of irradiation. Fluorescence measurements reveal that at least two photoadducts are formed.
The 8-MOP-photomodified enzyme is still fully active but further irradiation leads to an inhibition of the 5'→ 3' polymerase activity whereas the 5'→ 3' exonuclease activity is not affected. A major part of the inhibition reaction is shown to be oxygen-dependent but singlet oxygen quenchers have no effect on the kinetics. This oxygen-dependent reaction is attributed to a photosensitization, due to covalently bound 8-MOP, of neighbouring amino acids through an intermediate reactive oxygen species which is not singlet oxygen. The oxygen-independent reaction is attributed to a direct photosensitization through, for example, a radical mechanism.     

Opposed steric constraints in human DNA polymerase beta and E. coli DNA polymerase I

DNA polymerase selectivity is crucial for the survival of any living species, yet varies significantly among different DNA polymerases. Errors within DNA polymerase-catalyzed DNA synthesis result from the insertion of noncanonical nucleotides and extension of misaligned DNA substrates. The substrate binding characteristics among DNA polymerases are believed to vary in properties such as shape and tightness of the binding pocket, which might account for the observed differences in fidelity. Here, we employed 4'-alkylated nucleotides and primer strands bearing 4'-alkylated nucleotides at the 3'-terminal position as steric probes to investigate differential active site properties of human DNA polymerase beta (Pol beta) and the 3'-->5'-exonuclease-deficient Klenow fragment of E. coli DNA polymerase I (KF(exo-)). Transient kinetic measurements indicate that both enzymes vary significantly in active site tightness at both positions. While small 4'-methyl and -ethyl modifications of the nucleoside triphosphate perturb Pol beta catalysis, extension of modified primer strands is only marginally affected. Just the opposite was observed for KF(exo-). Here, incorporation of the modified nucleotides is only slightly reduced, whereas size augmentation of the 3'-terminal nucleotide in the primer reduces the catalytic efficiency by more than 7000- and 260,000-fold, respectively. NMR studies support the notion that the observed effects derive from enzyme substrate interactions rather than inherent properties of the modified substrates. These findings are consistent with the observed differential capability of the investigated DNA polymerases in fidelity such as processing misaligned DNA substrates. The results presented provide direct evidence for the involvement of varied steric effects among different DNA polymerases on their fidelity.     

Unnatural substrate repertoire of A, B, and X family DNA polymerases

As part of an effort to develop unnatural base pairs that are stable and replicable in DNA, we examined the ability of five different polymerases to replicate DNA containing four different unnatural nucleotides bearing predominantly hydrophobic nucleobase analogs. The unnatural pairs were developed based on intensive studies using the Klenow fragment of DNA polymerase I from E. coli (Kf) and found to be recognized to varying degrees. The five additional polymerases characterized here include family A polymerases from bacteriophage T7 and Thermus aquaticus, family B polymerases from Thermococcus litoralis and Thermococcus 9(o)N-7, and the family X polymerase, human polymerase beta. While we find that some aspects of unnatural base pair recognition are conserved among the polymerases, for example, the pair formed between two d3FB nucleotides is typically well recognized, the detailed recognition of most of the unnatural base pairs is generally polymerase dependent. In contrast, we find that the pair formed between d5SICS and dMMO2 is generally well recognized by all of the polymerases examined, suggesting that the determinants of efficient and general recognition are contained within the geometric and electronic structure of these unnatural nucleobases themselves. The data suggest that while the d3FB:d3FB pair is sufficiently well recognized by several of the polymerases for in vitro applications, the d5SICS:dMMO2 heteropair is likely uniquely promising for in vivo use. T7-mediated replication is especially noteworthy due to strong mispair discrimination.     

Incorporation of 4'-C-aminomethyl-2'-O-methylthymidine into DNA by thermophilic DNA polymerases

The dual modified nucleotide 4'-C-aminomethyl-2'-O-methylthymidine 5'-triphosphate was synthesized and enzymatically incorporated into DNA by the thermophilic DNA polymerases Pfu and Therminator III. The dual ribose modification imparted increased exonuclease resistance to DNA compared to the well-known 2'-O-methyl modification.     

In vitro evolution of an RNA-cleaving DNA enzyme into an RNA ligase switches the selectivity from 3'-5' to 2'-5'

Deoxyribozymes that ligate RNA expand the scope of nucleic acid catalysis and allow preparation of site-specifically modified RNAs. Previously, deoxyribozymes that join a 5'-hydroxyl and a 2',3'-cyclic phosphate were identified by in vitro selection from random DNA pools. Here, the alternative strategy of in vitro evolution was used to transform the 8-17 deoxyribozyme that cleaves RNA into a family of DNA enzymes that ligate RNA. The parent 8-17 DNA enzyme cleaves native 3'-5' phosphodiester linkages but not 2'-5' bonds. Surprisingly, the new deoxyribozymes evolved from 8-17 create only 2'-5' linkages. Thus, reversing the direction of the DNA-mediated process from ligation to cleavage also switches the selectivity in forming the new phosphodiester bond. The same change in selectivity was observed upon evolution of the 10-23 RNA-cleaving deoxyribozyme into an RNA ligase. The DNA enzymes previously isolated from random pools also create 2'-5' linkages. Therefore, deoxyribozyme-mediated formation of a non-native 2'-5' phosphodiester linkage from a 5'-hydroxyl and a 2',3'-cyclic phosphate is strongly favored in many different contexts.