Persistence of DNA synthesis arrest sites in the presence of T4 DNA polymerase and T4 gene 32, 44, 45 and 62 DNA polymerase accessory proteins.

DNA synthesis by phage T4 DNA polymerase is arrested at specific sequences in single-stranded DNA templates. To determine whether or not T4 DNA polymerase accessory proteins 32, 44, 45 and 62 eliminated recognition of these arrest sites, unique primer-templates were constructed in which DNA synthesis began at a DNA primer located at different distances from palindromic and nonpalindromic arrest sites. Nucleotide positions that caused polymerase to pause or leave the template were identified by sequence analysis of 5'-end labeled nascent DNA chains. Stable hairpin structures at palindromic sequences were confirmed by acetylation of single-stranded sequences with bromoacetaldehyde. Our results confirmed that these T4 DNA polymerase accessory proteins stimulated T4 DNA polymerase activity and processivity on natural as well as homopolymer primer-templates. However, they did not alter recognition of DNA synthesis arrest sites by T4 DNA polymerase. Extensive DNA synthesis resulted from an increased rate of translocation and/or processivity to the same extent over all DNA sequences.     

A DNA polymerase stop assay for G-quadruplex-interactive compounds.

We have developed and characterized an assay for G-quadruplex-interactive compounds that makes use of the fact that G-rich DNA templates present obstacles to DNA synthesis by DNA polymerases. Using Taq DNA polymerase and the G-quadruplex binding 2, 6-diamidoanthraquinone BSU-1051, we find that BSU-1051 leads to enhanced arrest of DNA synthesis in the presence of K+by stabilizing an intramolecular G-quadruplex structure formed by four repeats of either TTGGGG or TTAGGG in the template strand. The data provide additional evidence that BSU-1051 modulates telomerase activity by stabilization of telomeric G-quadruplex DNA and point to a polymerase arrest assay as a sensitive method for screening for G-quadruplex-interactive agents with potential clinical utility.     

Influence of DNA structure on DNA polymerase beta active site function: extension of mutagenic DNA intermediates

In the ternary substrate complex of DNA polymerase (pol) beta, the nascent base pair (templating and incoming nucleotides) is sandwiched between the duplex DNA terminus and polymerase. To probe molecular interactions in the dNTP-binding pocket, we analyzed the kinetic behavior of wild-type pol beta on modified DNA substrates that alter the structure of the DNA terminus and represent mutagenic intermediates. The DNA substrates were modified to 1) alter the sequence of the duplex terminus (matched and mismatched), 2) introduce abasic sites near the nascent base pair, and 3) insert extra bases in the primer or template strands to mimic frameshift intermediates. The results indicate that the nucleotide insertion efficiency (k(cat)/K(m), dGTP-dC) is highly dependent on the sequence identity of the matched (i.e. Watson-Crick base pair) DNA terminus (template/primer, G/C approximately A/T > T/A approximately C/G). Mismatches at the primer terminus strongly diminish correct nucleotide insertion efficiency but do not affect DNA binding affinity. Transition intermediates are generally extended more easily than transversions. Most mismatched primer termini decrease the rate of insertion and binding affinity of the incoming nucleotide. In contrast, the loss of catalytic efficiency with homopurine mismatches at the duplex DNA terminus is entirely due to the inability to insert the incoming nucleotide, since K(d)((dGTP)) is not affected. Abasic sites and extra nucleotides in and around the duplex terminus decrease catalytic efficiency and are more detrimental to the nascent base pair binding pocket when situated in the primer strand than the equivalent position in the template strand.     

DNA polymerase delta: a second eukaryotic DNA replicase

During the past few years significant progress has been made in our understanding of the structure and function of the proteins involved in eukaryotic DNA replication. Data from several laboratories suggest that, in contrast to prokaryotic DNA replication, two distinct DNA polymerases are required for eukaryotic DNA replication, i.e. DNA polymerase delta for the synthesis of the leading strand and DNA polymerase alpha for the lagging strand. Several accessory proteins analogous to prokaryotic replication factors have been identified and some of these are specific for pol delta whereas others affect both DNA replicases. The replicases and their accessory proteins appear to be highly conserved in eukaryotes, as homologous proteins have been found in species ranging from humans to yeast.     

DNA synthesis on discontinuous templates by human DNA polymerases: implications for non-homologous DNA recombination.

DNA polymerases catalyze the synthesis of DNA using a continuous uninterrupted template strand. However, it has been shown that a 3'-->5' exonuclease-deficient form of the Klenow fragment of Escherichia coli DNA polymerase I as well as DNA polymerase of Thermus aquaticus can synthesize DNA across two unlinked DNA templates. In this study, we used an oligonucleotide-based assay to show that discontinuous DNA synthesis was present in HeLa cell extracts. DNA synthesis inhibitor studies as well as fractionation of the extracts revealed that most of the discontinuous DNA synthesis was attributable to DNA polymerase alpha. Additionally, discontinuous DNA synthesis could be eliminated by incubation with an antibody that specifically neutralized DNA polymerase alpha activity. To test the relative efficiency of each nuclear DNA polymerase for discontinuous synthesis, equal amounts (as measured by DNA polymerase activity) of DNA polymerases alpha, beta, delta (+/- PCNA) and straightepsilon (+/- PCNA) were used in the discontinuous DNA synthesis assay. DNA polymerase alpha showed the most discontinuous DNA synthesis activity, although small but detectable levels were seen for DNA polymerases delta (+PCNA) and straightepsilon (- PCNA). Klenow fragment and DNA polymerase beta showed no discontinuous DNA synthesis, although at much higher amounts of each enzyme, discontinuous synthesis was seen for both. Discontinuous DNA synthesis by DNA polymerase alpha was seen with substrates containing 3 and 4 bp single-strand stretches of complementarity; however, little synthesis was seen with blunt substrates or with 1 bp stretches. The products formed from these experiments are structurally similar to that seen in vivo for non-homologous end joining in eukaryotic cells. These data suggest that DNA polymerase alpha may be able to rejoin double-strand breaks in vivo during replication.     

Intramolecular Telomeric G-Quadruplexes Dramatically Inhibit DNA Synthesis by Replicative and Translesion Polymerases,Revealing their Potential to Lead to Genetic Change

Recent research indicates that hundreds of thousands of G-rich sequences within the human genome have the potential to form secondary structures known as G-quadruplexes. Telomeric regions, consisting of long arrays of TTAGGG/AATCCC repeats, are among the most likely areas in which these structures might form. Since G-quadruplexes assemble from certain G-rich single-stranded sequences, they might arise when duplex DNA is unwound such as during replication. Coincidentally, these bulky structures when present in the DNA template might also hinder the action of DNA polymerases. In this study, single-stranded telomeric templates with the potential to form G-quadruplexes were examined for their effects on a variety of replicative and translesion DNA polymerases from humans and lower organisms. Our results demonstrate that single-stranded templates containing four telomeric GGG runs fold into intramolecular G-quadruplex structures. These intramolecular G quadruplexes are somewhat dynamic in nature and stabilized by increasing KCl concentrations and decreasing temperatures. Furthermore, the presence of these intramolecular G-quadruplexes in the template dramatically inhibits DNA synthesis by various DNA polymerases, including the human polymerase δ employed during lagging strand replication of G-rich telomeric strands and several human translesion DNA polymerases potentially recruited to sites of replication blockage. Notably, misincorporation of nucleotides is observed when certain translesion polymerases are employed on substrates containing intramolecular G-quadruplexes, as is extension of the resulting mismatched base pairs upon dynamic unfolding of this secondary structure. These findings reveal the potential for blockage of DNA replication and genetic changes related to sequences capable of forming intramolecular G-quadruplexes.     

Influence of template primary and secondary structure on the rate and fidelity of DNA synthesis

High resolution gel electrophoresis was used to monitor the successive addition of dNMP residues onto the 3'-OH ends of discrete 5'-32P-primers, during DNA synthesis on natural templates. Resulting autoradiographic banding patterns revealed considerable variation in the relative rates of incorporation at different positions along the template. The pattern of "pause sites" along the template was unique for each of three different DNA polymerases (polymerase I (the "large fragment" form of Escherichia coli), T4 polymerase (encoded by bacteriophage T4), and AMV polymerase (DNA polymerase of avian myeloblastosis virus]. Most pause sites were not caused by attenuation of polymerization at regions of local secondary structure in the template. Assays of the accuracy of incorporation at different positions along the template (in which elongation was monitored in the presence of only 3 of the 4 2'-deoxynucleoside 5'-triphosphates) strongly suggested that the relative fidelity of DNA synthesis catalyzed by different polymerases depends on the position on the template at which the comparison is made. Primer-templates were constructed that permitted comparison of elongation during synthesis on a single-stranded template with that during polymerization through a double-stranded region (wherein elongation required concomitant displacement of a strand annealed adjacent to the 5'-32P-primer). Although strand displacement DNA synthesis catalyzed by polymerase I occurred approximately ten times more slowly than synthesis in the same region of a single-stranded viral template, most of the pause sites were the same in the presence or absence of "tandem" primer. Electrophoretic assays of the fidelity of DNA synthesis suggested that an increased tendency toward misincorporational "hotspots" occurred when elongation required concomitant strand displacement.     

The role of palindromic and non-palindromic sequences in arresting DNA synthesis in vitro and in vivo

The nature of specific DNA sequences that arrest synthesis by mammalian DNA polymerase alpha in vitro was analyzed using circular, single-stranded M13 or phi X174 virion DNA templates annealed to a unique, terminally labeled, DNA primer. This method rigorously defined both the starting nucleotide position and the direction of synthesis, as well as making the amount of radioactivity proportional to the number rather than the length of nascent DNA chains. The precise nucleotide locations of arrest sites were determined over templates with complementary sequences by cloning unique DNA restriction fragments into M13 DNA and isolating virions containing either the Watson or Crick strand. Results were correlated with the locations of palindromic (self-complementary) sequences, repeated sequences, and repeated sequences with mirror-image orientation. Two classes of DNA synthesis arrest sites were identified, distinct in structure but equivalent in activity. Class I sites consisted of palindromic sequences that formed a stable hairpin structure in solution and arrested DNA polymerase on both complementary templates. The polymerase stopped precisely at the base of the duplex DNA stem, regardless of the direction from which the enzyme approached. Class II sites consisted of non-palindromic sequences that could not be explained by either secondary structure or sequence symmetry elements, and whose complementary sequence was not an arrest site. Size limits, orientation and some sequence specificity for arrest sites were suggested by the data. Arrest sites were also observed in vivo by mapping the locations of 3'-end-labeled nascent simian virus 40 DNA strands throughout the genome. Arrest sites closest to the region where termination of replication occurs were most pronounced, and the locations of 80% of the most prominent sites appeared to be recognized by alpha-polymerase on the same template in vitro. However, class I sites were not identified in vivo, suggesting that palindromic sequences do not form hairpin structures at replication forks.     

Evolutionary conservation of residues in vertebrate DNA polymerase N conferring low fidelity and bypass activity

POLN is a nuclear A-family DNA polymerase encoded in vertebrate genomes. POLN has unusual fidelity and DNA lesion bypass properties, including strong strand displacement activity, low fidelity favoring incorporation of T for template G and accurate translesion synthesis past a 5S-thymine glycol (5S-Tg). We searched for conserved features of the polymerase domain that distinguish it from prokaryotic pol I-type DNA polymerases. A Lys residue (679 in human POLN) of particular interest was identified in the conserved ‘O-helix’ of motif 4 in the fingers sub-domain. The corresponding residue is one of the most important for controlling fidelity of prokaryotic pol I and is a nonpolar Ala or Thr in those enzymes. Kinetic measurements show that K679A or K679T POLN mutant DNA polymerases have full activity on nondamaged templates, but poorly incorporate T opposite template G and do not bypass 5S-Tg efficiently. We also found that a conserved Tyr residue in the same motif not only affects sensitivity to dideoxynucleotides, but also greatly influences enzyme activity, fidelity and bypass. Protein sequence alignment reveals that POLN has three specific insertions in the DNA polymerase domain. The results demonstrate that residues have been strictly retained during evolution that confer unique bypass and fidelity properties on POLN.     

Suicidal nucleotide sequences for DNA polymerization.

Studying the activity of T7 DNA polymerase (Sequenase) on open circular DNAs, we observed virtually complete termination within potential triplex-forming sequences. Mutations destroying the triplex potential of the sequences prevented termination, while compensatory mutations restoring triplex potential restored it. We hypothesize that strand displacement during DNA polymerization of double-helical templates brings three DNA strands (duplex DNA downstream of the polymerase plus a displaced overhang) into close proximity, provoking triplex formation, which in turn prevents further DNA synthesis. Supporting this idea, we found that Sequenase is unable to propagate through short triple-helical stretches within single-stranded DNA templates. Thus, DNA polymerase, by inducing triplex formation at specific sequences in front of the replication fork, causes self-termination. Possible biological implications of such 'conformational suicide' are discussed. Our data also provide a novel way to target DNA polymerases at specific sequences using triplex-forming oligonucleotides.     

Participation of the fingers subdomain of Escherichia coli DNA polymerase I in the strand displacement synthesis of DNA

The replication of the genome requires the removal of RNA primers from the Okazaki fragments and their replacement by DNA. In prokaryotes, this process is completed by DNA polymerase I by means of strand displacement DNA synthesis and 5 '-nuclease activity. Here, we demonstrate that the strand displacement DNA synthesis is facilitated by the collective participation of Ser(769), Phe(771), and Arg(841) present in the fingers subdomain of DNA polymerase I. The steady and presteady state kinetic analysis of the properties of appropriate mutant enzymes suggest that: (a) Ser(769) and Phe(771) together are involved in the strand separation via the formation of a flap structure, and (b) Arg(841) interacts with the template strand to achieve the optimal strand separation and DNA synthesis. The amino acid residues Ser(769) and Phe(771) are constituents of the O1-helix, which together with O and O2 helices form a 3-helix bundle structure. We note that this 3-helix bundle motif also exists in prokaryotic RNA polymerase. Thus in both DNA and RNA polymerases, this motif may have been adopted to achieve the strand separation function.     

Fapyadenine is a moderately efficient chain terminator for prokaryotic DNA polymerases

Hypoxanthine?xanthine oxidase?Fe3+?ethylenediaminetetraacetate (EDTA) was used to modify ss M13 mp18 phage DNA. The dominant base modifications found by GC/IDMS-SIM were FapyGua, FapyAde, 8-hydroxyguanine, and thymine glycol. Analysis of in vitro DNA synthesis on oxidatively modified template by three DNA polymerases revealed that T7 DNA polymerase and Klenow fragment of polymerase I from Escherichia coli were blocked mainly by oxidized pyrimidines in the template whereas some purines that were easily bypassed by the prokaryotic polymerases constituted a block for DNA polymerase beta from calf thymus. DNA synthesis by T7 polymerase on poly(dA) template, where FapyAde content increased 16-fold on oxidation, yielded a final product with a discrete ladder of premature termination bands. When DNA synthesis was performed on template from which FapyAde, FapyGua, and 8OHGua were excised by the Fpg protein new chain terminations at adenine and guanine sites appeared or existing ones were enhanced. This suggests that FapyAde, when present in DNA, is a moderately toxic lesion. Its ability to arrest DNA synthesis depends on the sequence context and DNA polymerase. FapyGua might possess similar properties.     

Factor C from rabbit liver. A new poly(dC) and poly[d(G-C)] template-selective stimulatory protein of DNA polymerases

We have undertaken a search for mammalian DNA-binding proteins that enhance the activity of DNA polymerases in a template sequence-specific fashion. In this paper, we report the extensive purification and characterization of a new DNA-binding protein from rabbit liver that selectively stimulates DNA polymerases to copy synthetic poly[d(G-C)] and the poly(dC) strand of poly(dC).poly(dG) as well as single-stranded natural DNA that contains stretches of oligo(dC). The enhancing protein, a polypeptide of 65 kDa designated factor C, stimulates the copying of the two synthetic templates by Escherichia coli DNA polymerase I, Micrococcus luteus polymerase, and eukaryotic DNA polymerases alpha and beta, but not by avian myeloblastosis virus polymerase. Factor C, however, does not affect utilization by these polymerases of the poly(dG) strand of poly(dC).poly(dG), of poly(dC) primed by oligo(dG), or of poly(dA).poly(dT) and poly[d(A-T)]. With polymerase I, Michaelis constants (Km) of poly[d(G-C)] and of the poly(dC) strand of poly(dC).poly(dG) are decreased by factor C 37- and 4.7-fold, respectively, whereas maximum velocity (Vmax) remains unchanged. By contrast, neither the Km value of the poly(dG) strand of poly(dC).poly(dG) nor the Vmax value with this template is altered by factor C. Rates of copying of activated DNA, denatured DNA, or singly primed M13 DNA are not affected significantly by factor C. However, primer extension analysis of the copying of recombinant M13N4 DNA that contains runs of oligo(dC) within an inserted thymidine kinase gene shows that factor C increases processivity by specifically augmenting the efficiency at which polymerase I traverses the oligo(dC) stretches. Direct binding of factor C to denatured DNA is indicated by retention of the protein-DNA complex on columns of DEAE-cellulose. Binding of factor C to poly[d(G-C)] is demonstrated by the specific adsorption of the enhancing protein to columns of poly[d(G-C)]-Sepharose. We propose that by binding to poly[d(G-C)] and to poly(dC).poly(dG), factor C enables tighter binding of some DNA polymerases to these templates and facilitates enzymatic activity.     

Requirements for synthesis of ribonucleic acid primers during lagging strand synthesis by the DNA polymerase and gene 4 protein of bacteriophage T7.

DNA polymerase and gene 4 protein of bacteriophage T7 catalyze DNA synthesis on duplex DNA templates. Synthesis is initiated at nicks in the DNA template, and this leading strand synthesis results in displacement of one of the parental strands. In the presence of ribonucleoside 5'-triphosphates the gene 4 protein catalyzes the synthesis of oligoribonucleotide primers on the displaced single strand, and their extension by T7 dna polymerase accounts for lagging strand synthesis. Since all the oligoribonucleotide primers bear adenosine 5'-triphosphate residues at their 5' termini, [gamma 32P]ATP is incorporated specifically into the product molecule, thus providing a rapid and sensitive assay for the synthesis of the RNA primers. Both primer synthesis and DNA synthesis are stimulated 3- to 5-fold by the presence of either Escherichia coli or T7 helix-destabilizing protein (DNA binding protein). ATP and CTP together fully satisfy the requirement for rNTPs and provide maximum synthesis of primers and DNA. Provided that T7 DNA polymerase is present, RNA-primed DNA synthesis occurs on either duplex or single-stranded DNA templates and to equal extents on either strand of T7 DNA. No primer-directed DNA synthesis occurs on poly(dT) or poly(dG) templates, indicating that synthesis of primers is template-directed.     

DNA polymerase III holoenzyme of Escherichia coli. III. Distinctive processive polymerases reconstituted from purified subunits

The 10 distinctive polypeptides of DNA polymerase III holoenzyme, purified as individual subunits or complexes, could be reconstituted to generate a polymerase with the high catalytic rate of the isolated intact holoenzyme. Functions and interactions of the subunits can be inferred from partial assemblies of the pol III core (alpha, epsilon, and theta subunits) with auxiliary subunits. The core possesses the polymerase and proofreading activities; the auxiliary subunits provide the core with processivity, the capacity to replicate long stretches of DNA without dissociating from the template. In a sequence of reconstruction steps, the beta subunit binds the primed template in an ATP-dependent manner through the catalytic action of a complex made up of the gamma, delta, delta', chi, and psi polypeptides. With the beta subunit in place, a processive polymerase is produced upon addition of the core. When the tau subunit is lacking, binding of polymerase to the primed template is less efficient and stable. The tau-less reconstituted polymerase is more prone to dissociation upon encountering secondary structures in the template in its path, such as a hairpin region in the single strand or a duplex region formed by a strand annealed to the template. With the tau subunit present, the interaction of the core.beta complex (the basic unit of a processive polymerase) with the primed template is strengthened. The tau-containing reconstituted polymerase can replicate DNA continuously through secondary structures in the template. The two distinctive kinds of processivity demonstrated by the tau-less and tau-containing reconstituted polymerases fit nicely into a scheme in which, organized as an asymmetric dimeric holoenzyme, the tau half is responsible for continuous synthesis of one strand, and the less stable half for discontinuous synthesis of the other.