Coordinate action of the helicase and 3' to 5' exonuclease of Werner syndrome protein

Werner syndrome is a human disorder characterized by premature aging, genomic instability, and abnormal telomere metabolism. The Werner syndrome protein (WRN) is the only known member of the RecQ DNA helicase family that contains a 3' --> 5'-exonuclease. However, it is not known whether both activities coordinate in a biological pathway. Here, we describe DNA structures, forked duplexes containing telomeric repeats, that are substrates for the simultaneous action of both WRN activities. We used these substrates to study the interactions between the WRN helicase and exonuclease on a single DNA molecule. WRN helicase unwinds at the forked end of the substrate, whereas the WRN exonuclease acts at the blunt end. Progression of the WRN exonuclease is inhibited by the action of WRN helicase converting duplex DNA to single strand DNA on forks of various duplex lengths. The WRN helicase and exonuclease act in concert to remove a DNA strand from a long forked duplex that is not completely unwound by the helicase. We analyzed the simultaneous action of WRN activities on the long forked duplex in the presence of the WRN protein partners, replication protein A (RPA), and the Ku70/80 heterodimer. RPA stimulated the WRN helicase, whereas Ku stimulated the WRN exonuclease. In the presence of both RPA and Ku, the WRN helicase activity dominated the exonuclease activity.     

Adenovirus terminal protein protects single stranded DNA from digestion by a cellular exonuclease.

Adenovirus 5 DNA-protein complex is isolated from virions as a duplex DNA molecule covalently attached by the 5' termini of each strand to virion protein of unknown function. The DNA-protein complex can be digested with E. coli exonuclease III to generate molecules analogous to DNA replication intermediates in that they contain long single stranded regions ending in 5' termini bound to terminal protein. The infectivity of pronase digested Adenovirus 5 DNA is greatly diminished by exonuclease III digestion. However, the infectivity of the DNA-protein complex is not significantly altered when up to at least 2400 nucleotides are removed from the 3' ends of each strand. This indicates that the terminal protein protects 5' terminated single stranded regions from digestion by a cellular exonuclease. DNA-protein complex prepared from a host range mutant with a mutation mapping in the left 4% of the genome was digested with exonuclease III, hybridized to a wild type restriction fragment comprising the left 8% of the genome, and transfected into HeLa cells. Virus with wild type phenotype was recovered at high frequency.     

DNase I footprinting and enhanced exonuclease function of the bipartite Werner syndrome protein (WRN) bound to partially melted duplex DNA.

Werner syndrome is a premature aging and cancer-prone hereditary disorder caused by deficiency of the WRN protein that harbors 3' -->5' exonuclease and RecQ-type 3' --> 5' helicase activities. To assess the possibility that WRN acts on partially melted DNA intermediates, we constructed a substrate containing a 21-nucleotide noncomplementary region asymmetrically positioned within a duplex DNA fragment. Purified WRN shows an extremely efficient exonuclease activity directed at both blunt ends of this substrate, whereas no activity is observed on a fully duplex substrate. High affinity binding of full-length WRN protects an area surrounding the melted region of the substrate from DNase I digestion. ATP binding stimulates but is not required for WRN binding to this region. Thus, binding of WRN to the melted region underlies the efficient exonuclease activity directed at the nearby ends. In contrast, a WRN deletion mutant containing only the functional exonuclease domain does not detectably bind or degrade this substrate. These experiments indicate a bipartite structure and function for WRN, and we propose a model by which its DNA binding, helicase, and exonuclease activities function coordinately in DNA metabolism. These studies also suggest that partially unwound or noncomplementary regions of DNA could be physiological targets for WRN.     

Identification and characterization of a Drosophila ortholog of WRN exonuclease that is required to maintain genome integrity

The premature human aging Werner syndrome (WS) is caused by mutation of the RecQ-family WRN helicase, which is unique in possessing also 3'-5' exonuclease activity. WS patients show significant genomic instability with elevated cancer incidence. WRN is implicated in restraining illegitimate recombination, especially during DNA replication. Here we identify a Drosophila ortholog of the WRN exonuclease encoded by the CG7670 locus. The predicted DmWRNexo protein shows conservation of structural motifs and key catalytic residues with human WRN exonuclease, but entirely lacks a helicase domain. Insertion of a piggyBac element into the 5' UTR of CG7670 severely reduces gene expression. DmWRNexo mutant flies homozygous for this insertional allele of CG7670 are thus severely hypomorphic; although adults show no gross morphological abnormalities, females are sterile. Like human WS cells, we show that the DmWRNexo mutant flies are hypersensitive to the topoisomerase I inhibitor camptothecin. Furthermore, these mutant flies show highly elevated rates of mitotic DNA recombination resulting from excessive reciprocal exchange. This study identifies a novel WRN ortholog in flies and demonstrates an important role for WRN exonuclease in maintaining genome stability.     

A minimal exonuclease domain of WRN forms a hexamer on DNA and possesses both 3'- 5' exonuclease and 5'-protruding strand endonuclease activities

Werner syndrome is a rare autosomal recessive disease characterized by a premature aging phenotype, genomic instability, and a dramatically increased incidence of cancer and heart disease. Mutations in a single gene encoding a 1432-amino acid helicase/exonuclease (hWRN) have been shown to be responsible for the development of this disease. We have cloned, overexpressed, and purified a minimal, 171-amino acid fragment of hWRN that functions as an exonuclease. This fragment, encompassing residues 70-240 of hWRN (hWRN-N(70-240)), exhibits the same level of 3'-5' exonuclease activity as the previously described exonuclease fragment encompassing residues 1-333 of the full-length protein. The fragment also contains a 5'-protruding DNA strand endonuclease activity at a single-strand-double-strand DNA junction and within single-stranded DNA, as well as a 3'-5' exonuclease activity on single-stranded DNA. We find hWRN-N(70-240) is in a trimer-hexamer equilibrium in the absence of DNA when examined by gel filtration chromatography and atomic force microscopy. Upon addition of DNA substrate, hWRN-N(70-240) forms a hexamer and interacts with the recessed 3'-end of the DNA. Moreover, we find that the interaction of hWRN-N(70-240) with the replication protein PCNA also causes this minimal, 171-amino acid exonuclease region to form a hexamer. Thus, the active form of this minimal exonuclease fragment of human WRN appears to be a hexamer. The implications these results have on our understanding of hWRN's roles in DNA replication and repair are discussed.     

DNA polymerase X from Deinococcus radiodurans possesses a structure-modulated 3'-->5' exonuclease activity involved in radioresistance

Recently a family X DNA polymerase (PolXDr) was identified in the radioresistant bacterium Deinococcus radiodurans. Knockout cells show a delay in double-strand break repair (DSBR) and an increased sensitivity to gamma-irradiation. Here we show that PolXDr possesses 3'-->5' exonuclease activity that stops cutting close to a loop. PolXDr consists of a DNA polymerase X domain (PolXc) and a Polymerase and Histidinol Phosphatase (PHP) domain. Deletion of the PHP domain abolishes only the structure-modulated but not the canonical 3'-->5' exonuclease activity. Thus, the exonuclease resides in the PolXc domain, but the structure-specificity requires additionally the PHP domain. Mutation of two conserved glycines in the PolXc domain leads to a specific loss of the structure-modulated exonuclease activity but not the exonuclease activity in general. The PHP domain itself does not show any activity. PolXDr is the first family X DNA polymerase that harbours an exonuclease activity. The wild-type protein, the glycine mutant and the two domains were expressed separately in DeltapolXDr cells. The wild-type protein could restore the radiation resistance, whereas intriguingly the mutant proteins showed a significant negative effect on survival of gamma-irradiated cells. Taken together our in vivo results suggest that both PolXDr domains play important roles in DSBR in D. radiodurans.     

A domain of the Klenow fragment of Escherichia coli DNA polymerase I has polymerase but no exonuclease activity

The Klenow fragment of DNA polymerase I from Escherichia coli has two enzymatic activities: DNA polymerase and 3'-5' exonuclease. The crystal structure showed that the fragment is folded into two distinct domains. The smaller domain has a binding site for deoxynucleoside monophosphate and a divalent metal ion that is thought to identify the 3'-5' exonuclease active site. The larger C-terminal domain contains a deep cleft that is believed to bind duplex DNA. Several lines of evidence suggested that the large domain also contains the polymerase active site. To test this hypothesis, we have cloned the DNA coding for the large domain into an expression system and purified the protein product. We find that the C-terminal domain has polymerase activity (albeit at a lower specific activity than the native Klenow fragment) but no measurable 3'-5' exonuclease activity. These data are consistent with the hypothesis that each of the three enzymatic activities of DNA polymerase I from E. coli resides on a separate protein structural domain.     

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.     

Selective blockage of the 3'-->5' exonuclease activity of WRN protein by certain oxidative modifications and bulky lesions in DNA

Individuals with mutations in the WRN gene suffer from Werner syndrome, a disease with early onset of many characteristics of normal aging. The WRN protein (WRNp) functions in DNA metabolism, as the purified polypeptide has both 3′→5′ helicase and 3′→5′ exonuclease activities. In this study, we have further characterized WRNp exonuclease activity by examining its ability to degrade double-stranded DNA substrates containing abnormal and damaged nucleo­tides. In addition, we directly compared the 3′→5′ WRNp exonuclease activity with that of exo­nuclease III and the Klenow fragment of DNA polymerase I. Our results indicate that the presence of certain abnormal bases (such as uracil and hypoxanthine) does not inhibit the exonuclease activity of WRNp, exo­nuclease III or Klenow, whereas other DNA modifications, including apurinic sites, 8-oxoguanine, 8-oxoadenine and cholesterol adducts, inhibit or block WRNp. The ability of damaged nucleo­tides to inhibit exonucleolytic digestion differs significantly between WRNp, exonuclease III and Klenow, indicating that each exonuclease has a distinct mechanism of action. In addition, normal and modified DNA substrates are degraded similarly by full-length WRNp and an N-terminal fragment of WRNp, indicating that the specificity for this activity lies mostly within this region. The biochemical and physiological significance of these results is discussed.     

The 5'' to 3'' exonuclease activity of DNA polymerase I is essential for Streptococcus pneumoniae

Three different mutations were introduced in the polA gene of Streptococcus pneumoniae by chromosomal transformation. One mutant gene encodes a truncated protein that possesses 5' to 3' exonuclease but has lost polymerase activity. This mutation does not affect cell viability. Other mutated forms of polA that encode proteins with only polymerase activity or with no enzymatic activity could not substitute for the wild-type polA gene in the chromosome unless the 5' to 3' exonuclease domain was encoded elsewhere in the chromosome. Thus, it appears that the 5' to 3' exonuclease activity of the DNA polymerase I is essential for cell viability in S. pneumoniae. Absence of the polymerase domain of DNA polymerase I slightly diminished the ability of S. pneumoniae to repair DNA lesions after ultraviolet irradiation. However, the polymerase domain of the pneumococcal DNA polymerase I gave almost complete complementation of the polA5 mutation in Escherichia coli with respect to resistance to ultraviolet irradiation.     

Biochemical and kinetic characterization of the DNA helicase and exonuclease activities of werner syndrome protein

The WRN gene, defective in the premature aging and genome instability disorder Werner syndrome, encodes a protein with DNA helicase and exonuclease activities. In this report, cofactor requirements for WRN catalytic activities were examined. WRN helicase performed optimally at an equimolar concentration (1 mm) of Mg(2+) and ATP with a K(m) of 140 microm for the ATP-Mg(2+) complex. The initial rate of WRN helicase activity displayed a hyperbolic dependence on ATP-Mg(2+) concentration. Mn(2+) and Ni(2+) substituted for Mg(2+) as a cofactor for WRN helicase, whereas Fe(2+) or Cu(2+) (10 microm) profoundly inhibited WRN unwinding in the presence of Mg(2+).Zn(2+) (100 microm) was preferred over Mg(2+) as a metal cofactor for WRN exonuclease activity and acts as a molecular switch, converting WRN from a helicase to an exonuclease. Zn(2+) strongly stimulated the exonuclease activity of a WRN exonuclease domain fragment, suggesting a Zn(2+) binding site in the WRN exonuclease domain. A fluorometric assay was used to study WRN helicase kinetics. The initial rate of unwinding increased with WRN concentration, indicating that excess enzyme over DNA substrate improved the ability of WRN to unwind the DNA substrate. Under presteady state conditions, the burst amplitude revealed a 1:1 ratio between WRN and DNA substrate, suggesting an active monomeric form of the helicase. These are the first reported kinetic parameters of a human RecQ unwinding reaction based on real time measurements, and they provide mechanistic insights into WRN-catalyzed DNA unwinding.     

Properties of and substrate determinants for the exonuclease activity of human apurinic endonuclease Ape1

Ape1 is the major human abasic endonuclease, initiating repair of this common DNA lesion by incising the phosphodiester backbone 5' to the damage site. This enzyme also functions in specific contexts to excise 3'-blocking termini, e.g. phosphate and phosphoglycolate residues, from DNA. Recently, the comparatively "minor" 3' to 5' exonuclease activity of Ape1 was found to contribute to the excision of certain 3'-mismatched nucleotides. In this study, I characterize more thoroughly the 3'-nuclease properties of Ape1 and define the effects of specific DNA determinants on this function. Data within shows that Ape1 is a non- or poorly processive exonuclease, which degrades one nucleotide gap, 3'-recessed, and nicked DNAs, but exhibits no detectable activity on blunt end or single-stranded DNA. A 5'-phosphate, compared to a 5'-hydroxyl group, reduced Ape1 degradation activity roughly tenfold, suggesting that the biological impact of certain DNA single strand breaks may be influenced by the terminal chemistry. In the context of a base excision repair-like DNA intermediate, a 5'-abasic residue exerted an about tenfold attenuation on the 3' to 5' exonuclease efficiency of Ape1. A 3'-phosphate group had little impact on Ape1 exonuclease activity, and oligonucleotides harboring these blocking termini were activated by Ape1 for DNA polymerase beta extension. Ape1 was also found to remove 3'-tyrosyl residues from 3'-recessed and nicked DNAs, suggesting a potential role in processing covalent topoisomerase I-DNA intermediates formed during chromosome relaxation. While exhibiting preferential excision of thymine in a T:G mismatch context, Ape1 was unable to degrade a triple 3'-thymine mispair. However, Ape1 was able to excise double nucleotide mispairs, apparently through a novel 3'-flap-type endonuclease activity, again activating these substrates for polymerase beta extension.     

Polymerization activity of an alpha-like DNA polymerase requires a conserved 3''-5'' exonuclease active site.

Most DNA polymerases are multifunctional proteins that possess both polymerizing and exonucleolytic activities. For Escherichia coli DNA polymerase I and its relatives, polymerase and exonuclease activities reside on distinct, separable domains of the same polypeptide. The catalytic subunits of the alpha-like DNA polymerase family share regions of sequence homology with the 3'-5' exonuclease active site of DNA polymerase I; in certain alpha-like DNA polymerases, these regions of homology have been shown to be important for exonuclease activity. This finding has led to the hypothesis that alpha-like DNA polymerases also contain a distinct 3'-5' exonuclease domain. We have introduced conservative substitutions into a 3'-5' exonuclease active site homology in the gene encoding herpes simplex virus DNA polymerase, an alpha-like polymerase. Two mutants were severely impaired for viral DNA replication and polymerase activity. The mutants were not detectably affected in the ability of the polymerase to interact with its accessory protein, UL42, or to colocalize in infected cell nuclei with the major viral DNA-binding protein, ICP8, suggesting that the mutation did not exert global effects on protein folding. The results raise the possibility that there is a fundamental difference between alpha-like DNA polymerases and E. coli DNA polymerase I, with less distinction between 3'-5' exonuclease and polymerase functions in alpha-like DNA polymerases.     

Characterization of a 3''----5'' exonuclease activity in the phage phi 29-encoded DNA polymerase.

Purified protein p2 of phage phi 29, characterized as a specific DNA polymerase involved in the initiation and elongation of phi 29 DNA replication, contains a 3'----5' exonuclease active on single-stranded DNA, but not on double-stranded DNA. No 5'----3' exonuclease activity was found. The 3'----5' exonuclease activity was shown to be associated with the DNA polymerase since 1) the two activities were heat-inactivated with identical kinetics and 2) both activities, present in purified protein p2, cosedimented in a glycerol gradient.     

p53 Modulates the exonuclease activity of Werner syndrome protein.

Werner syndrome (WS) is characterized by the early onset of symptoms of premature aging, cancer, and genomic instability. The molecular basis of the defects is not understood but presumably relates to the DNA helicase and exonuclease activities of the protein encoded by the WRN gene that is mutated in the disease. The attenuation of p53-mediated apoptosis in WS cells and reported physical interaction between WRN and the tumor suppressor p53 suggest that p53 and WRN functionally interact in a pathway necessary for the normal cellular response. In this study, we have demonstrated that p53 inhibits the exonuclease activity of the purified full-length recombinant WRN protein. p53 did not have an effect on a truncated amino-terminal WRN fragment that retains exonuclease activity but lacks the physical interaction domain for p53 located in the carboxyl terminus. Two naturally occurring p53 mutants found in human cancer displayed a reduced ability to inhibit WRN exonuclease activity. In cells arrested in S phase with hydroxyurea, WRN exits the nucleolus and colocalizes with p53 in the nucleoplasm. The regulation of WRN function by p53 is likely to play an important role in the maintenance of genomic integrity and prevention of cancer and other clinical symptoms associated with WS.     

The Apollo 5' exonuclease functions together with TRF2 to protect telomeres from DNA repair

A major issue in telomere research is to understand how the integrity of chromosome ends is preserved . The human telomeric protein TRF2 coordinates several pathways that prevent checkpoint activation and chromosome fusions. In this work, we identified hSNM1B, here named Apollo, as a novel TRF2-interacting factor. Interestingly, the N-terminal domain of Apollo is closely related to that of Artemis, a factor involved in V(D)J recombination and DNA repair. Both proteins belong to the beta-CASP metallo-beta-lactamase family of DNA caretaker proteins. Apollo appears preferentially localized at telomeres in a TRF2-dependent manner. Reduced levels of Apollo exacerbate the sensitivity of cells to TRF2 inhibition, resulting in severe growth defects and an increased number of telomere-induced DNA-damage foci and telomere fusions. Purified Apollo protein exhibits a 5'-to-3' DNA exonuclease activity. We conclude that Apollo is a novel component of the human telomeric complex and works together with TRF2 to protect chromosome termini from being recognized and processed as DNA damage. These findings unveil a previously undescribed telomere-protection mechanism involving a DNA 5'-to-3' exonuclease.     

Identification and characterization of a 3' to 5' exonuclease associated with spinach chloroplast DNA polymerase.

Spinach chloroplast DNA polymerase was shown to copurify with a 3' to 5' exonuclease activity during DEAE-cellulose, hydroxylapatite, and heparin-agarose column chromatography. In addition, both activities comigrated during nondenaturing polyacrylamide gel electrophoresis and cosedimented through a glycerol gradient with an apparent molecular weight of 105,000. However, two forms of exonuclease activity were detected following velocity sedimentation analysis. Form I constituted approximately 35% of the exonuclease activity and was associated with the DNA polymerase, whereas the remaining activity (form II) was free of DNA polymerase and exhibited a molecular weight of approximately 26,500. Resedimentation of form I exonuclease generated both DNA polymerase associated and DNA polymerase unassociated forms of the exonuclease, suggesting that polymerase/exonuclease dissociation occurred. The exonuclease activity (form I) was somewhat resistant to inhibition by N-ethylmaleimide, whereas the DNA polymerase activity was extremely sensitive. Using in situ detection following SDS-polyacrylamide activity gel electrophoresis, both form I and II exonucleases were shown to reside in a similar, if not identical, polypeptide of approximately 20,000 molecular weight. Both form I and II exonucleases were equally inhibited by NaCl and required 7.5 mM MgCl2 for optimal activity. The 3' to 5' exonuclease excised deoxyribonucleoside 5'-monophosphates from both 3'-terminally matched and 3'-terminally mismatched primer termini. In general, the exonuclease preferred to hydrolyze mismatched 3'-terminal nucleotides as determined from the Vmax/Km ratios for all 16 possible combinations of matched and mismatched terminal base pairs. These results suggest that the 3' to 5' exonuclease may be involved in proofreading errors made by chloroplast DNA polymerase.     

A specific 3'' exonuclease activity of UvrABC.

Specific cutting of undamaged DNA by UvrABC nuclease is observed. It occurs seven nucleotides (nt) from the 3' terminus of oligonucleotides annealed to single-stranded M13 DNA circles. Although the location of the UvrABC cut on undamaged DNA is similar to that of the cut on the 5' side of a damaged DNA site during the dual incision reaction, the cut of undamaged DNA is not an intermediate in the dual incision step. On DNA duplexes with a single AAF adduct, the anticipated cut at the eighth phosphodiester bond 5' of the lesion is present, but extra cuts at 7-nt increments are observed at the 15th and 22nd phosphodiester bonds. We suggest that these additional cuts are made by the UvrABC activity observed on undamaged DNA; such activity is referred to as ABC 3' exonuclease and may play a significant role by providing a suitable gap for RecA-mediated recombinational exchanges during repair of interstrand crosslinks and closely opposed lesions. This ABC 3' exonuclease activity depends on higher concentrations of Uvr proteins as compared with dual incision and may be relevant to reactions that occur when UvrA and UvrB are increased during SOS induction.