Repair of DNA strand gaps and nicks containing 3'-phosphate and 5'-hydroxyl termini by purified mammalian enzymes.

A putative role for mammalian polynucleotide kinases that possess both 5'-phosphotransferase and 3'-phosphatase activity is the restoration of DNA strand breaks with 5'-hydroxyl termini or 3'-phosphate termini, or both, to a form that supports the subsequent action of DNA repair polymerases and DNA ligases, i.e. 5'-phosphate and 3'-hydroxyl termini. To further assess this possibility, we compared the activity of the 3'-phosphatase of purified calf thymus polynucleotide kinase towards a variety of substrates. The rate of removal of 3'-phosphate groups from nicked or short (1 nt) gapped sites in double-stranded DNA was observed to be similar to that of 3'-phosphate groups from single-stranded substrates. Thus this activity of polynucleotide kinase does not appear to be influenced by steric accessibility of the phosphate group. We subsequently demonstrated that the concerted reactions of polynucleotide kinase and purified human DNA ligase I could efficiently repair DNA nicks possessing 3'-phosphate and 5'-hydroxyl termini, and similarly the combination of these two enzymes together with purified rat DNA polymerase beta could seal a strand break with a 1 nt gap. With a substrate containing a nick bounded by 3'- and 5'-OH termini, the rate of gap filling by polymerase beta was significantly enhanced in the presence of polynucleotide kinase and ATP, indicating the positive influence of 5'-phosphorylation. The reaction was further enhanced by addition of DNA ligase I to the reaction mixture. This is due, at least in part, to an enhancement by DNA ligase I of the rate of 5'-phosphorylation catalyzed by polynucleotide kinase.     

Stabilization of T4 polynucleotide kinase by macromolecular crowding.

T4 polynucleotide kinase rapidly loses activity during its reaction on duplex DNA termini. Addition of high concentrations of nonspecific polymers reverses or prevents this inactivation. In contrast, additions of related materials of lower molecular weight are relatively ineffective in stabilizing the kinase. Such a pattern suggests that the stabilizing effects of polymers on kinase activity are due to macromolecular crowding. An effect of crowding on the known tendency of the kinase to undergo oligomerization reactions is consistent with our observations.     

Some substrate properties of analogues of oligothymidylates with p-s-C5'' bonds.

The action of T4 polynucleotide kinase, T4 DNA polymerase, E. coli DNA polymerase I, snake venom phosphodiesterase (VPDE) and S1 nuclease on analogues of oligothymidilates with p-s-C5' bonds and the ability of these analogues to prime the replication of poly (dA) by T4 DNA polymerase were studied. These analogues were shown to be substrates for all these enzymes. Substitution of these analogues for corresponding oligothymidilates in the reaction mixtures resulted in drop in rates of enzymic reactions. This drop in reactions rates was not significant when these oligonucleotides were phosphorylated with T4 polynucleotide kinase or used as a primers, however in comparison with oligothymidilates these analogues were found to be considerably more resistant to nucleolytic hydrolysis. Some possible applications of these analogues are discussed.     

Enzyme action at 3' termini of ionizing radiation-induced DNA strand breaks

gamma-Irradiation of DNA in vitro produces two types of single strand breaks. Both types of strand breaks contain 5'-phosphate DNA termini. Some strand breaks contain 3'-phosphate termini, some contain 3'-phosphoglycolate termini (Henner, W.D., Rodriguez, L.O., Hecht, S. M., and Haseltine, W. A. (1983) J. Biol. Chem. 258, 711-713). We have studied the ability of prokaryotic enzymes of DNA metabolism to act at each of these types of gamma-ray-induced 3' termini in DNA. Neither strand breaks that terminate with 3'-phosphate nor 3'-phosphoglycolate are substrates for direct ligation by T4 DNA ligase. Neither type of gamma-ray-induced 3' terminus can be used as a primer for DNA synthesis by either Escherichia coli DNA polymerase or T4 DNA polymerase. The 3'-phosphatase activity of T4 polynucleotide kinase can convert gamma-ray-induced 3'-phosphate but not 3'-phosphoglycolate termini to 3'-hydroxyl termini that can then serve as primers for DNA polymerase. E. coli alkaline phosphatase is also unable to hydrolyze 3'-phosphoglycolate groups. The 3'-5' exonuclease actions of E. coli DNA polymerase I and T4 DNA polymerase do not degrade DNA strands that have either type of gamma-ray-induced 3' terminus. E. coli exonuclease III can hydrolyze DNA with gamma-ray-induced 3'-phosphate or 3'-phosphoglycolate termini or with DNase I-induced 3'-hydroxyl termini. The initial action of exonuclease III at 3' termini of ionizing radiation-induced DNA fragments is to remove the 3' terminal phosphate or phosphoglycolate to yield a fragment of the same nucleotide length that has a 3'-hydroxyl terminus. These results suggest that repair of ionizing radiation-induced strand breaks may proceed via the sequential action of exonuclease, DNA polymerase, and DNA ligase. The possible role of exonuclease III in repair of gamma-radiation-induced strand breaks is discussed.     

XRCC1 stimulates polynucleotide kinase by enhancing its damage discrimination and displacement from DNA repair intermediates

Human polynucleotide kinase (hPNK) is required for processing and rejoining DNA strand break termini. The 5'-DNA kinase and 3'-phosphatase activities of hPNK can be stimulated by the "scaffold" protein XRCC1, but the mechanism remains to be fully elucidated. Using a variety of fluorescence techniques, we examined the interaction of hPNK with XRCC1 and substrates that model DNA single-strand breaks. hPNK binding to substrates with 5'-OH termini was only approximately 5-fold tighter than that to identical DNA molecules with 5'-phosphate termini, suggesting that hPNK remains bound to the product of its enzymatic activity. The presence of XRCC1 did not influence the binding of hPNK to substrates with 5'-OH termini, but sharply reduced the interaction of hPNK with DNA bearing a 5'-phosphate terminus. These data, together with kinetic data obtained at limiting enzyme concentration, indicate a dual function for the interaction of XRCC1 with hPNK. First, XRCC1 enhances the capacity of hPNK to discriminate between strand breaks with 5'-OH termini and those with 5'-phosphate termini; and second, XRCC1 stimulates hPNK activity by displacing hPNK from the phosphorylated DNA product.     

Kinase-catalyzed biotinylation of DNA

Prior work documented use of γ-phosphate modified ATP analogs to label DNA using T4 polynucleotide kinases (T4PNK), although applications have been limited. To fully characterize kinase-catalyzed labeling of nucleic acids, we explored use of ATP-biotin as a cosubstrate with T4PNK. T4PNK accepted ATP-biotin to 5′-label single stranded DNA. However, T4PNK-mediated labeling of double stranded substrates was low yielding. In addition, the phosphoramidate bond connecting the biotin group to the DNA was unstable. These results suggest that kinase-catalyzed biotinylation will be useful with single stranded DNA substrates and mild reaction conditions. By revealing the scope and limitations of kinase-catalyzed biotinylation, these studies provide a foundation for future development and application of kinase-catalyzed labeling to DNA-based biological studies.     

Polymer-stimulated ligation: enhanced ligation of oligo- and polynucleotides by T4 RNA ligase in polymer solutions.

The effects of macromolecular crowding were tested on several reactions catalyzed by T4 RNA ligase. The rate of cyclization of oligoriboadenylates was stimulated up to 10-fold by relatively high concentrations of several polymers (polyethylene glycol (PEG) 8000 or 20,000; bovine plasma albumin; Ficoll 70). In addition, higher concentrations of PEG 8000 or PEG 20,000 allowed the novel formation of large linear products from the oligoriboadenylates. Also stimulated by high concentrations of PEG 8000 were the rate at which T4 RNA ligase joined p(dT)10 to oligoriboadenylates and the rate at which the enzyme activated p(dT)n by transfer of an adenylyl moiety from ATP to the oligonucleotides. These results with T4 RNA ligase are compared to earlier studies on the effects of crowding on DNA ligases.     

Purification of wheat germ RNA ligase. I. Characterization of a ligase-associated 5'-hydroxyl polynucleotide kinase activity

An RNA ligase that catalyzes the formation of a 2'-phosphomonoester-3',5'-phosphodiester bond in the presence of ATP and Mg2+ was purified approximately 6000-fold from raw wheat germ. A 5'-hydroxyl polynucleotide kinase activity copurified with RNA ligase through all chromatographic steps. Both activities cosedimented upon glycerol gradient centrifugation even in the presence of high salt and urea. RNA ligase and kinase activities sedimented as a single peak on glycerol gradients with a sedimentation coefficient of 6.2 S. The purified polynucleotide kinase activity required dithiothreitol and a divalent cation for activity and was inhibited by pyrophosphate and by ADP. The kinase phosphorylated a variety of 5'-hydroxyl-terminated polynucleotide chains including some that were substrates for the RNA ligase (e.g. 2',3'-cyclic phosphate-terminated poly(A)) and others that were not ligase substrates (e.g. DNA or RNA containing 3'-hydroxyl termini). RNA molecules containing either 5'-hydroxyl or 5'-phosphate and 2',3'-cyclic or 2'-phosphate termini were substrates for the purified RNA ligase activity. The rate of ligation of 5'-hydroxyl-terminated RNA chains was greater than that of 5'-phosphate-terminated molecules, suggesting that an interaction between the wheat germ kinase and ligase activities occurs during the course of ligation.     

End labeling procedures

There are two ways to label a DNA molecular; by the ends or all along the molecule. End labeling can be performed at the 3′- or 5′-end. Labeling at the 3′ end is performed by filling 3′-end recessed ends with a mixture or labeled and unlabeled dNTPs using Klenow or T4 DNA polymerases. Both reactions are template dependent. Terminal deoxynucleotide transferase incorporates dNTPs at the 3′ end of any kind of DNA molecule or RNA. Labels incorporated at the 3′-end of the DNA molecule prevent any further extension or ligation to any other molecule, but this can be overcome by labeling the 5′-end of the desired DNA molecule. 5′-end labeling is performed by enzymatic methods (T4 polynucleotide kinase exchange and forward reactions), by chemical modification of sensitized oligonucleotides with phosphoroamidite, or by combined methods. Probe cleanup is recommended when high background problems occur, but caution should be taken not to damage the attached probe with harsh chemicals or by light exposure.     

An optimized recipe for cloning of the polymerase chain reaction-amplified DNA inserts into plasmid vectors

This study compares a number of parameters that are important in the ligation of the polymerase chain reaction-amplified DNA inserts into plasmid vectors and their efficient transformation to bacterial cells. The parameters covered were: T4 polynucleotide kinase treatment followed by either the large fragment of E. coli DNA polymerase or T4 DNA polymerase reactions, the amount of T4 DNA ligase, temperature and duration of ligation, molar ratio of insert to vector as well as the total DNA concentration. The results show that the T4 polynucleotide kinase-treated group without further enzymatic manipulation, at an insert to vector ratio of 3:1 gave the highest recombination efficiency when 10 microg/ml DNA and 20 units T4 DNA ligase were applied for ligation for 12 h at 4 degrees C.     

The Enzymatic Phosphorylation of Nucleic Acids and Its Application to End-Group Analysis

Polynucleotide kinase catalyzes the transfer of a phosphate group from ATP to the 5'-hydroxyl termini of polynucleotides. Selective labeling of the 5'-hydroxyl termini of DNA with polynucleotide kinase has been used to study the number and the identity of the 5'-terminal residues of bacteriophage DNA's, and to examine the nature of the phosphodiester bond cleavages produced by endonucleases and by sonic irradiation. The intact strands of T7 DNA bear 5'-phosphoryl end-groups; only deoxyadenylate and deoxythymidylate are present as 5'-terminal residues. The intact strands of native λ-DNA bear 5'-hydroxyl end-groups. M13 DNA, a circular molecule, cannot be phosphorylated. End-group labeling of DNA provides a method for determination of molecular weight; calibration against other DNA preparations is not required. The molecular weight of a single strand of T7 DNA, determined by end-group labeling, is 13.1 x 10⁶; the molecular weight of a single strand of λ-DNA is 16.0 x 10⁶. These values are in agreement with molecular weight estimates by sedimentation analysis and electron microscopy. Sonic irradiation of DNA has been shown to favor the production of polynucleotides terminated by 5'-phosphomonoester groups. All four deoxyribonucleotides are present as 5'-terminal residues of sonicated DNA.     

Restriction of bacteriophage lambda by Escherichia coli K

Derivatives of phage lambda, for which the numbers and positions of the recognition sites for endonuclease R. Eco_k are known, were used as substrates for the Escherichia coli K restriction system in vivo and in vitro. A single unmodified recognition site was sufficient for a DNA molecule to be bound and broken by the K restriction enzyme. Although discrete fragments of DNA were not produced, the breaks were made preferentially in the proximity of the recognition site. Breakage of a DNA molecule with only one recognition site required a 10 to 40-fold higher concentration of restriction enzyme than breakage of a DNA molecule with two or more recognition sites, but these substrates were all equally effective in a binding assay for the enzyme.The polynucleotide kinase reaction provided no evidence for new 5′-terminal sequences generated by restriction in vitro; the 5′ termini were either refractory to the polynucleotide kinase reaction or had no sequence specificity.     

32P-postlabeling of N-7, N2 and O6 2'-deoxyguanosine 3'-monophosphate adducts of styrene oxide

Adducts were prepared by reacting styrene oxide with 2-deoxyguanosine 3'-monophosphate (dGMP). Four isomeric N-7-, two diastereomeric N2- and three isomeric O6-adduct were isolated and characterized. The adducts were used as substrates in the 32P-postlabeling reaction. No phosphorylation products were seen with the N-7-alkylation products. One diastereomeric N2-adduct was labeled with 20% efficiency and the second with a markedly lower efficiency. Two of the three O6-adducts were labeled with 5% and the third with 10% labeling efficiency. The results suggest that large N-7-dGMP adducts are very poor substrates of T4 polynucleotide kinase. The diastereomeric products are labeled at different efficiencies indicating stereoselectivity in the kinase reaction.     

Bacteriophage phi29 terminal protein: its association with the 5' termini of the phi29 genome.

The location of the protein bound to bacteriophage phi29 DNA has been studied with restriction endonucleases, exonucleases, and polynucleotide kinase. The protein is invariably associated with the two terminal DNA fragments generated by restriction endonucleases. The phi29 DNA prepared with or without proteinase K treatment is resistant to the action of the 5'-terminal-specific exonucleases, lambda-exonuclease and T7 exonuclease. The phi29 DNA is also inaccessible to phosphorylation by polynucleotide kinase even after treatment with alkaline phosphatase. On the other hand, phi29 DNA is sensitive to exonuclease III, and the 3' termini of the DNA can be labeled by incubating with alpha-[32P]ATP and terminal deoxynucleotidyl transferase. The protein remains associated with the phi29 DNA after treatment with various chaotropic agents, including 8 M urea, 6 M guanidine-hydrochloride, 4 M sodium perchlorate, 2 M sodium thiocyanate, and 2 M LiCl. These results are consistent with the notion that the protein is linked covalently to the 5' termini of the phi29 DNA.     

Purification and substrate specificity of polydeoxyribonucleotide kinases isolated from calf thymus and rat liver

Damage to DNA can result in strand breaks with 5′-hydroxyl and 3′-phosphate termini. Before DNA polymerases and ligases can rejoin the broken strands, such termini have to be restored to 5′-phosphate and 3′-hydroxyl groups. Polydeoxynucleotide kinase is an enzyme that may fulfil this function. We have purified the kinases from calf thymus and rat liver to near homogeneity. Based on SDS-polyacrylamide gel electrophoresis and activity gels, the enzymes from both sources are ∼60-kDa polypeptides. Both enzymes have an acidic pH optimum (5.5–6.0) for kinase activity, and similar pl values (8.5–8.6), and a specificity for DNA. The calf thymus kinase possesses a 3′-phosphatase activity, as has previously been shown for the rat liver enzyme. The minimum size of oligonucleotide that can be labelled is 7–8 nucleotides in length, but the optimal size appears to be >18 nucleotides. Comparison of phosphorylation of oligo(dA)₂₄ and oligo(dT)₂₄ with oligonucleotides containing a varied nucleotide sequence indicated that the homopolymers are poorer substrates. Unlike the bacteriophage T4 polynucleotide kinase, the mammalian kinases exhibit no preference for 5′-overhanging termini when acting at DNA termini produced by restriction enzymes. With double-stranded oligonucleotide complexes designed to model single-strand gaps and nicks, the mammalian kinases preferentially phosphorylate the 5′-terminus associated with the gap or nick, in keeping with the idea that the kinases are involved in the repair of DNA single-strand breaks. J. Cell. Biochem. 64:258–272. © 1997 Wiley-Liss, Inc.     

Recognition of DNA substrates by T4 bacteriophage polynucleotide kinase

T4 phage polynucleotide kinase (PNK) displays 5′-hydroxyl kinase, 3′-phosphatase and 2′,3′-cyclic phosphodiesterase activities. The enzyme phosphorylates the 5′ hydroxyl termini of a wide variety of nucleic acid substrates, a behavior studied here through the determination of a series of crystal structures with single-stranded (ss)DNA oligonucleotide substrates of various lengths and sequences. In these structures, the 5′ ribose hydroxyl is buried in the kinase active site in proper alignment for phosphoryl transfer. Depending on the ssDNA length, the first two or three nucleotide bases are well ordered. Numerous contacts are made both to the phosphoribosyl backbone and to the ordered bases. The position, side chain contacts and internucleotide stacking interactions of the ordered bases are strikingly different for a 5′-GT DNA end than for a 5′-TG end. The base preferences displayed at those positions by PNK are attributable to differences in the enzyme binding interactions and in the DNA conformation for each unique substrate molecule.     

Genome-linked protein associated with the 5' termini of bacteriophage phi29 DNA.

A DNA-protein complex was isolated from Bacillus subtilis bacteriophage phi29 by sucrose gradient sedimentation or gel filtration in the presence of agents known to break noncovalent bonds. A 28,000-dalton protein was released from this complex by subsequent hydrolysis of the DNA. The DNA-protein complex was examined for its susceptibility to enzymes which act upon the 5' and 3' termini of DNA molecules. It was susceptible to exonucleolytic degradation from the 3' termini by exonuclease III but not from the 5' termini by lambda exonuclease. Attempts to label radioactively the 5' termini by phosphorylation with T4 polynucleotide kinase were unsuccessful despite prior treatment with alkaline phosphatase or phosphatase treatment of denatured DNA. Removal of the majority of the bound protein by proteolytic digestion did not increase susceptibility. These results suggest that the linked protein is covalently attached to the 5' termini of phi29 DNA.     

An end-healing enzyme from Clostridium thermocellum with 5' kinase, 2',3' phosphatase, and adenylyltransferase activities

We identify and characterize an end-healing enzyme, CthPnkp, from Clostridium thermocellum that catalyzes the phosphorylation of 5'-OH termini of DNA or RNA polynucleotides and the dephosphorylation of 2',3' cyclic phosphate, 2'-phosphate, and 3'-phosphate ribonucleotides. CthPnkp also catalyzes an autoadenylylation reaction via a polynucleotide ligase-type mechanism. These characteristics are consistent with a role in end-healing during RNA or DNA repair. CthPnkp is a homodimer of an 870-amino-acid polypeptide composed of three catalytic domains: an N-terminal module that resembles the polynucleotide kinase domain of bacteriophage T4 Pnkp, a central metal-dependent phosphoesterase module, and a C-terminal module that resembles the nucleotidyl transferase domain of polynucleotide ligases. The distinctive feature of CthPnkp vis-à-vis known RNA repair enzymes is that its 3' end modification component belongs to the calcineurin-type phosphatase superfamily. It contains putative counterparts of the amino acids that form the dinuclear metal-binding site and the phosphate-binding site of bacteriophage lambda phosphatase. As with lambda phosphatase, the 2',3' cAMP phosphatase activity of CthPnkp is specifically dependent on nickel or manganese. We identify homologs of CthPnkp in other bacterial proteomes.     

The molecular architecture of the mammalian DNA repair enzyme, polynucleotide kinase

Mammalian polynucleotide kinase (PNK) is a key component of both the base excision repair (BER) and nonhomologous end-joining (NHEJ) DNA repair pathways. PNK acts as a 5'-kinase/3'-phosphatase to create 5'-phosphate/3'-hydroxyl termini, which are a necessary prerequisite for ligation during repair. PNK is recruited to repair complexes through interactions between its N-terminal FHA domain and phosphorylated components of either pathway. Here, we describe the crystal structure of intact mammalian PNK and a structure of the PNK FHA bound to a cognate phosphopeptide. The kinase domain has a broad substrate binding pocket, which preferentially recognizes double-stranded substrates with recessed 5' termini. In contrast, the phosphatase domain efficiently dephosphorylates single-stranded 3'-phospho termini as well as double-stranded substrates. The FHA domain is linked to the kinase/phosphatase catalytic domain by a flexible tether, and it exhibits a mode of target selection based on electrostatic complementarity between the binding surface and the phosphothreonine peptide.