The phosphatase activity of mammalian polynucleotide kinase takes precedence over its kinase activity in repair of single strand breaks

The dual function mammalian DNA repair enzyme, polynucleotide kinase (PNK), facilitates strand break repair through catalysis of 5′-hydroxyl phosphorylation and 3′-phosphate dephosphorylation. We have examined the relative activities of the kinase and phosphatase functions of PNK using a novel assay, which allows the simultaneous characterization of both activities in processing nicks and gaps containing both 3′-phosphate and 5′-hydroxyl. Under multiple turnover conditions the phosphatase activity of the purified enzyme is significantly more active than its kinase activity. Consistent with this result, phosphorylation of the 5′-hydroxyl is rate limiting in cell extract mediated-repair of a nicked substrate. On characterizing the effects of individually mutating the two active sites of PNK we find that while site-directed mutagenesis of the kinase domain of PNK does not affect its phosphatase activity, disruption of the phosphatase domain also abrogates kinase function. This loss of kinase function requires the presence of a 3′-phosphate, but it need not be present in the same strand break as the 5′-hydroxyl. PNK preferentially binds 3′-phosphorylated substrates and DNA binding to the phosphatase domain blocks further DNA binding by the kinase domain.     

Ferrocene-functionalized SWCNT for electrochemical detection of T4 polynucleotide kinase activity

A novel electrochemical strategy for monitoring the activity and inhibition of T4 polynucleotide kinase (PNK) is developed by use of titanium ion (Ti(4+)) mediated signal transition coupled with signal amplification of single wall carbon nanotubes (SWCNTs). In this method, a DNA containing 5'-hydroxyl group is self-assembled onto the gold electrode and used as substrate for PNK. The biofunctionalized SWCNTs with anchor DNA and ferrocene are chosen as the signal indicator by virtue of the intrinsic 5'-phosphate end of anchor DNA and the high loading of ferrocene for electrochemical signal generation and amplification. The 5'-hydroxyl group of the substrate DNA on the electrode is phosphorylated by T4 PNK in the presence of ATP, and the resulting 5'-phosphoryl end product can be linked with the signal indicator by Ti(4+). The redox ferrocene group on the SWCNTs is grafted to the electrode and generates the electrochemical signal, the intensity of which is proportional to the activity of T4 PNK. This assay can measure activity of T4 PNK down to 0.01 UmL(-1). The developed method is a potentially useful tool in researching the interactions between proteins and nucleic acids and provides a diversified platform for a kinase activity assay.     

Highly specific fluorescence detection of T4 polynucleotide kinase activity via photo-induced electron transfer

Sensitive and reliable study of the activity of polynucleotide kinase (PNK) and its potential inhibitors is of great importance for biochemical interaction related to DNA phosphorylation as well as development of kinase-targeted drug discovery. To achieve facile and reliable detection of PNK activity, we report here a novel fluorescence method for PNK assay based on a combination of exonuclease cleavage reaction and photo-induced electron transfer (PIET) by using T4 PNK as a model target. The fluorescence of 3′-carboxyfluorescein-labeled DNA probe (FDNA) is effectively quenched by deoxyguanosines at the 5′ end of its complementary DNA (cDNA) due to an effective PIET between deoxyguanosines and fluorophore. Whereas FDNA/cDNA hybrid is phosphorylated by PNK and then immediately cleaved by lambda exonuclease (λ exo), fluorescence is greatly restored due to the break of PIET. This homogeneous PNK activity assay does not require a complex design by taking advantage of the quenching ability of deoxyguanosines, making the proposed strategy facile and cost-effective. The activity of PNK can be sensitively detected in the range of 0.005 to 10 U mL⁻¹ with a detection limit of 2.1 × 10⁻³ U mL⁻¹. Research on inhibition efficiency of different inhibitors demonstrated that it can be explored to evaluate inhibition capacity of inhibitors. The application for detection of PNK activity in complex matrix achieved satisfactory results. Therefore, this PIET strategy opens a promising avenue for studying T4 PNK activity as well as evaluating PNK inhibitors, which is of great importance for discovering kinase-targeted drugs.     

Involvement of human polynucleotide kinase in double-strand break repair by non-homologous end joining

The efficient repair of double-strand breaks (DSBs) in DNA is critical for the maintenance of genome stability. In mammalian cells, repair can occur by homologous recombination or by non-homologous end joining (NHEJ). DNA breaks caused by reactive oxygen or ionizing radiation often contain non- conventional end groups that must be processed to restore the ligatable 3'-OH and 5'-phosphate moieties which are necessary for efficient repair by NHEJ. Here, using cell-free extracts that efficiently catalyse NHEJ in vitro, we show that human polynucleotide kinase (PNK) promotes phosphate replacement at damaged termini, but only within the context of the NHEJ apparatus. Phosphorylation of terminal 5'-OH groups by PNK was blocked by depletion of the NHEJ factor XRCC4, or by an inactivating mutation in DNA-PK(cs), indicating that the DNA kinase activity in the extract is coupled with active NHEJ processes. Moreover, we find that end-joining activity can be restored to PNK-depleted extracts by addition of human PNK, but not bacteriophage T4 PNK. This work provides the first demonstration of a direct, specific role for human PNK in DSB repair.     

Quencher-free hairpin probes for real-time detection of T4 polynucleotide kinase activity

Traditional methods of assaying polynucleotide kinase (PNK) activity are discontinuous, time-consuming, and laborious. Here we report a new quencher-free approach to real-time monitoring of PNK activity using a 2-aminopurine probe. When the 2-aminopurine probe was 5′-phosphorylated by PNK, it could be efficiently degraded by lambda exonuclease to release free 2-aminopurine molecules and generate a fluorescence signal. This method not only provides a universal approach to real-time monitoring of PNK activity, but also shows great potential for screening suitable inhibitor drugs for PNK.     

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.     

Structure of a tRNA repair enzyme and molecular biology workhorse: T4 polynucleotide kinase

T4 phage polynucleotide kinase (PNK) was identified over 35 years ago and has become a staple reagent for molecular biologists. The enzyme displays 5'-hydroxyl kinase, 3'-phosphatase, and 2',3'-cyclic phosphodiesterase activities against a wide range of substrates. These activities modify the ends of nicked tRNA generated by a bacterial response to infection and facilitate repair by T4 RNA ligase. DNA repair enzymes that share conserved motifs with PNK have been identified in eukaryotes. PNK contains two functionally distinct structural domains and forms a homotetramer. The C-terminal phosphatase domain is homologous to the L-2-haloacid dehalogenase family and the N-terminal kinase domain is homologous to adenylate kinase. The active sites have been characterized through structural homology analyses and visualization of bound substrate.     

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.     

The structural basis for substrate recognition by mammalian polynucleotide kinase 3' phosphatase

Mammalian polynucleotide kinase 3' phosphatase (PNK) plays a key role in the repair of DNA damage, functioning as part of both the nonhomologous end-joining (NHEJ) and base excision repair (BER) pathways. Through its two catalytic activities, PNK ensures that DNA termini are compatible with extension and ligation by either removing 3'-phosphates from, or by phosphorylating 5'-hydroxyl groups on, the ribose sugar of the DNA backbone. We have now determined crystal structures of murine PNK with DNA molecules bound to both of its active sites. The structure of ssDNA engaged with the 3'-phosphatase domain suggests a mechanism of substrate interaction that assists DNA end seeking. The structure of dsDNA bound to the 5'-kinase domain reveals a mechanism of DNA bending that facilitates recognition of DNA ends in the context of single-strand and double-strand breaks and suggests a close functional cooperation in substrate recognition between the kinase and phosphatase active sites.     

Highly sensitive fluorescence assay of T4 polynucleotide kinase activity and inhibition via enzyme-assisted signal amplification

DNA phosphorylation catalyzed by polynucleotide kinase (PNK) is an indispensable process in the repair, replication, and recombination of nucleic acids. Here, an enzyme-assisted amplification strategy was developed for the ultrasensitive monitoring activity and inhibition of T4 PNK. A hairpin oligonucleotide (hpDNA) was designed as a probe whose stem can be degraded from the 5′ to 3′ direction by lambda exonuclease (λ exo) when its 5′ end is phosphorylated by PNK. So, the 3′ stem and loop part of hpDNA was released as an initiator strand to open a molecular beacon (MB) that was designed as a fluorescence reporter, leading to a fluorescence restoration. Then, the initiator strand was released again by the nicking endonuclease (Nt.BbvCI) to hybridize with another MB, resulting in a cyclic reaction and accumulation of fluorescence signal. Based on enzyme-assisted amplification, PNK activity can be sensitively and rapidly detected with a detection limit of 1.0 × 10⁻⁴ U/ml, which is superior to those of most existing approaches. Furthermore, the application of the proposed strategy for screening PNK inhibitors also demonstrated satisfactory results. Therefore, it provided a promising platform for monitoring activity and inhibition of PNK as well as for studying the activity of other nucleases.     

Cadmium and copper inhibit both DNA repair activities of polynucleotide kinase

Human exposure to heavy metals is of increasing concern due to their well-documented toxicological and carcinogenic effects and rising environmental levels through industrial processes and pollution. It has been widely reported that such metals can be genotoxic by several modes of action including generation of reactive oxygen species and inhibition of DNA repair. However, although it has been observed that certain heavy metals can inhibit single strand break (SSB) rejoining, the effects of these metals on SSB end-processing enzymes has not previously been investigated. Accordingly, we have investigated the potential inhibition of polynucleotide kinase (PNK)-dependent single strand break repair by six metals: cadmium, cobalt, copper, nickel, lead and zinc. It was found that micromolar concentrations of cadmium and copper are able to inhibit the phosphatase and kinase activities of PNK in both human cell extracts and purified recombinant protein, while the other metals had no effect at the concentrations tested. The inhibition of PNK by environmentally and physiologically relevant concentrations of cadmium and copper suggests a novel means by which these toxic heavy metals may exert their carcinogenic and neurotoxic effects.     

Xrcc4 physically links DNA end processing by polynucleotide kinase to DNA ligation by DNA ligase IV

Nonhomologous end joining (NHEJ) is the major DNA double-strand break (DSB) repair pathway in mammalian cells. A critical step in this process is DNA ligation, involving the Xrcc4-DNA ligase IV complex. DNA end processing is often a prerequisite for ligation, but the coordination of these events is poorly understood. We show that polynucleotide kinase (PNK), with its ability to process ionizing radiation-induced 5'-OH and 3'-phosphate DNA termini, functions in NHEJ via an FHA-dependent interaction with CK2-phosphorylated Xrcc4. Analysis of the PNK FHA-Xrcc4 interaction revealed that the PNK FHA domain binds phosphopeptides with a unique selectivity among FHA domains. Disruption of the Xrcc4-PNK interaction in vivo is associated with increased radiosensitivity and slower repair kinetics of DSBs, in conjunction with a diminished efficiency of DNA end joining in vitro. Therefore, these results suggest a new role for Xrcc4 in the coordination of DNA end processing with DNA ligation.     

Real-time investigation of nucleic acids phosphorylation process using molecular beacons

Phosphorylation of nucleic acids is an indispensable process to repair strand interruption of nucleic acids. We have studied the process of phosphorylation using molecular beacon (MB) DNA probes in real-time and with high selectivity. The MB employed in this method is devised to sense the product of a ‘phosphorylation–ligation’ coupled enzyme reaction. Compared with the current assays, this novel method is convenient, fast, selective, highly sensitive and capable of real-time monitoring in a homogenous solution. The preference of T4 polynucleotide kinase (T4 PNK) has been investigated using this approach. The results revealed that a single-stranded oligonucleotide containing guanine at the 5′ termini is most preferred, while those utilizing cytosine in this location are least preferred. The preference of (T)₉ was reduced greatly when phosphoryl was modified at the 5′ end, implying that T4 PNK could discern the phosphorylated/unphosphorylated oligonucleotides. The increase of oligonucleotide DNA length leads to an enhancement in preference. A fast and accurate method for assaying the kinase activity of T4 PNK has been developed with a wide linear detection range from 0.002 to 4.0 U/ml in 3 min. The effects of certain factors, such as NTP, ADP, (NH₄)₂SO₄ and Na₂HPO₄, on phosphorylation have been investigated. This novel approach enables us to investigate the interactions between proteins and nucleic acids in a homogenous solution, such as those found in DNA repair or in drug development.     

XRCC1 stimulates human polynucleotide kinase activity at damaged DNA termini and accelerates DNA single-strand break repair

XRCC1 protein is required for DNA single-strand break repair and genetic stability but its biochemical role is unknown. Here, we report that XRCC1 interacts with human polynucleotide kinase in addition to its established interactions with DNA polymerase-beta and DNA ligase III. Moreover, these four proteins are coassociated in multiprotein complexes in human cell extract and together they repair single-strand breaks typical of those induced by reactive oxygen species and ionizing radiation. Strikingly, XRCC1 stimulates the DNA kinase and DNA phosphatase activities of polynucleotide kinase at damaged DNA termini and thereby accelerates the overall repair reaction. These data identify a novel pathway for mammalian single-strand break repair and demonstrate a concerted role for XRCC1 and PNK in the initial step of processing damaged DNA ends.     

AP endonuclease-independent DNA base excision repair in human cells

The paradigm for repair of oxidized base lesions in genomes via the base excision repair (BER) pathway is based on studies in Escherichia coli, in which AP endonuclease (APE) removes all 3' blocking groups (including 3' phosphate) generated by DNA glycosylase/AP lyases after base excision. The recently discovered mammalian DNA glycosylase/AP lyases, NEIL1 and NEIL2, unlike the previously characterized OGG1 and NTH1, generate DNA strand breaks with 3' phosphate termini. Here we show that in mammalian cells, removal of the 3' phosphate is dependent on polynucleotide kinase (PNK), and not APE. NEIL1 stably interacts with other BER proteins, DNA polymerase beta (pol beta) and DNA ligase IIIalpha. The complex of NEIL1, pol beta, and DNA ligase IIIalpha together with PNK suggests coordination of NEIL1-initiated repair. That NEIL1/PNK could also repair the products of other DNA glycosylases suggests a broad role for this APE-independent BER pathway in mammals.     

Purification of a polynucleotide kinase from calf thymus, comparison of its 3'-phosphatase domain with T4 polynucleotide kinase, and investigation of its effect on DNA replication in vitro

Mammalian polynucleotide kinases (PNKs) carry out 5'-phosphorylation of nucleic acids. Although the cellular function(s) of these enzymes remain to be delineated, important suggestions have included a role in DNA repair and, more recently, in DNA replication. Like T4 PNK, some preparations of mammalian PNKs have been reported to have an associated 3'-phosphatase activity. Previously, we have identified in calf thymus glands an apparently novel PNK with a neutral to alkaline pH optimum that lacked 3'-phosphatase activity. In this report, we describe purification of another bovine PNK, SNQI-PNK, with a slightly acidic pH optimum that copurifies with a 3'-phosphatase activity. The enzyme appears to be a monomer of 60 kDa. Mammalian DNA replication reactions were supplemented with T4 PNK or SNQI-PNK, and no significant effect on DNA replication in vitro was observed. Database searches support the earlier mapping of the 3'-phosphatase activity of T4 PNK to the C-terminus and suggest that the 3'-phosphatase domain of T4 PNK is related to the protein superfamily of L-2-haloacid dehalogenases. Exopeptidase digestion experiments were carried out to compare the SNQI-PNK enzyme with T4 PNK and led to the inference that the domain organization of the bovine polypeptide may differ from that of the T4 enzyme.     

Specific recognition of a multiply phosphorylated motif in the DNA repair scaffold XRCC1 by the FHA domain of human PNK

Short-patch repair of DNA single-strand breaks and gaps (SSB) is coordinated by XRCC1, a scaffold protein that recruits the DNA polymerase and DNA ligase required for filling and sealing the damaged strand. XRCC1 can also recruit end-processing enzymes, such as PNK (polynucleotide kinase 3′-phosphatase), Aprataxin and APLF (aprataxin/PNK-like factor), which ensure the availability of a free 3′-hydroxyl on one side of the gap, and a 5′-phosphate group on the other, for the polymerase and ligase reactions respectively. PNK binds to a phosphorylated segment of XRCC1 (between its two C-terminal BRCT domains) via its Forkhead-associated (FHA) domain. We show here, contrary to previous studies, that the FHA domain of PNK binds specifically, and with high affinity to a multiply phosphorylated motif in XRCC1 containing a pSer-pThr dipeptide, and forms a 2:1 PNK:XRCC1 complex. The high-resolution crystal structure of a PNK–FHA–XRCC1 phosphopeptide complex reveals the basis for this unusual bis-phosphopeptide recognition, which is probably a common feature of the known XRCC1-associating end-processing enzymes.     

Sterical recognition by T4 polynucleotide kinase of non-nucleosidic moieties 5'-attached to oligonucleotides.

The ability of T4 polynucleotide kinase (PNK) to phosphorylate non-nucleosidic moieties 5'-attached to oligodeoxynucleotides (ODNs) has been investigated. Non-nucleosidic phosphoramidite units were prepared from ethane-1,2-diol and propane-1,3-diol backbones. Some of them corresponded to pure enantiomers. They were used to obtain the corresponding 5'-end modified oligothymidylates X(pdT)10. The free primary hydroxyl of the non-nucleosidic moieties (X) of these oligomers was phosphorylated by PNK. We report the stereoselective phosphorylation of the L form of the 5'-end attached non-nucleosidic chiral fragments; the non-chiral moieties were completely phosphorylated. Dimers of glycerol analogue and thymidine 3'-phosphate were not recognized by PNK and the shortest modified ODN able to be phosphorylated was a trinucleotide X(pdT)3. A modified X(pdT)10, bearing a cyclic abasic site (X) at its 5'-end, was prepared by chemical synthesis from 1,2-dideoxyribose phosphoramidite and was phosphorylated with a 90% yield.     

Cloning of coliphage-T4 gene pseT and high-level synthesis of polynucleotide kinase in Escherichia coli

The gene, pseT, of coliphage T4 which encodes polynucleotide kinase (PNK) was cloned directly into an expression plasmid using the polymerase chain reaction. When placed under the control of the trp promoter, the pse T gene can be maintained stably in Escherichia coli and yields high levels of the enzyme upon induction. The system described facilitates purification and provides very high yields of PNK.     

Physical properties of human polynucleotide kinase: hydrodynamic and spectroscopic studies.

Human polynucleotide kinase (hPNK) is a putative DNA repair enzyme in the base excision repair pathway required for processing and rejoining strand-break termini. This study represents the first systematic examination of the physical properties of this enzyme. The protein was produced in Escherichia coli as a His-tagged protein, and the purified recombinant protein exhibited both the kinase and the phosphatase activities. The predicted relative molecular mass (M(r)) of the 521 amino acid polypeptide encoded by the sequenced cDNA for PNK and the additional 21 amino acids of the His tag is 59,538. The M(r) determined by low-speed sedimentation equilibrium under nondenaturing conditions was 59,600 +/- 1000, indicating that the protein exists as a monomer, in contrast to T4 phage PNK, which exists as a homotetramer. The size and shape of hPNK in solution were determined by analytical ultracentrifugation studies. The protein was found to have an intrinsic sedimentation coefficient, s(0)(20,w), of 3.54 S and a Stokes radius, R(s), of 37.5 A. These hydrodynamic data, together with the M(r) of 59 600, suggest that hPNK is a moderately asymmetric protein with an axial ratio of 5.51. Analysis of the secondary structure of hPNK on the basis of circular dichroism spectra, which revealed the presence of two negative dichroic bands located at 218 and 209 nm, with ellipticity values of -7200 +/- 300 and -7800 +/- 300 deg x cm(2) x d(mol(-1), respectively, indicated the presence of approximately 50% beta-structure and 25% alpha-helix. Binding of ATP to the protein induced an increase in beta-structure and perturbed tryptophan, tyrosine, and phenylalanine signals observed by aromatic CD and UV difference spectroscopy.