A functional interaction of Ku with Werner exonuclease facilitates digestion of damaged DNA.

Werner syndrome (WS) is a premature aging disorder where the affected individuals appear much older than their chronological age. The single gene that is defective in WS encodes a protein (WRN) that has ATPase, helicase and 3'-->5' exonuclease activities. Our laboratory has recently uncovered a physical and functional interaction between WRN and the Ku heterodimer complex that functions in double-strand break repair and V(D)J recombination. Importantly, Ku specifically stimulates the exonuclease activity of WRN. We now report that Ku enables the Werner exonuclease to digest through regions of DNA containing 8-oxoadenine and 8-oxoguanine modifications, lesions that have previously been shown to block the exonuclease activity of WRN alone. These results indicate that Ku significantly alters the exonuclease function of WRN and suggest that the two proteins function concomitantly in a DNA damage processing pathway. In support of this notion we also observed co-localization of WRN and Ku, particularly after DNA damaging treatments.

Accelerated methylation of ribosomal RNA genes during the cellular senescence of Werner syndrome fibroblasts.

Ribosomal DNA (rDNA) metabolism has been implicated in cellular and organismal aging. The role of rDNA in premature and normal human aging was investigated by measuring rDNA gene copy number, the level of rDNA methylation, and rRNA expression during the in vitro senescence of primary fibroblasts from normal (young and old) donors and from Werner syndrome (WS) patients. In comparison to their normal counterparts, WS fibroblasts grew slowly and reached senescence after fewer doublings. The rDNA copy number did not change significantly throughout the life span of both normal and WS fibroblasts. However, in senescent WS and normal old fibroblasts, we detected rDNA species with unusually slow electrophoretic mobility. Cellular aging in Saccharomyces cerevisiae is accompanied by the formation and accumulation of rDNA circles. Our analysis revealed that the rDNA species observed in this study were longer, linear rDNA molecules attributable to the inhibition of ECO:RI cleavage by methylation. Furthermore, isoschizomeric restriction analysis confirmed that in vitro senescence of fibroblasts is accompanied by significant increases in cytosine methylation within rDNA genes. This increased methylation is maximal during the abbreviated life span of WS fibroblasts. Despite increased methylation of rDNA in senescent cells, the steady-state levels of 28S rRNA remained constant over the life span of both normal and WS fibroblasts.

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 nucleo-tides. In addition, we directly compared the 3'-->5' WRNp exonuclease activity with that of exo-nuclease 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, exo-nuclease 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 nucleo-tides 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.

Ku complex interacts with and stimulates the Werner protein.

Werner syndrome (WS) is the hallmark premature aging disorder in which affected humans appear older than their chronological age. The protein WRNp, defective in WS, has helicase function, DNA-dependent ATPase, and exonuclease activity. Although WRNp functions in nucleic acid metabolism, there is little or no information about the pathways or protein interactions in which it participates. Here we identify Ku70 and Ku86 as proteins that interact with WRNp. Although Ku proteins had no effect on ATPase or helicase activity, they strongly stimulated specific exonuclease activity. These results suggest that WRNp and the Ku complex participate in a common DNA metabolic pathway.

Identification of phage antibodies toward the Werner protein by selection on Western blots.

A procedure was established for selecting phage antibodies (phage-abs) from phage-displayed antibody repertoires by panning against proteins, separated by sodium dodecyl phosphate-polyacrylamide gel electrophoresis (SDS-PAGE) and electroblotted onto nitrocellulose membranes (Western blots). This immobilization strategy is applicable for secondary rounds of panning in selections against semipurified proteins, and directs the selection toward antibodies suitable as immunochemical reagents in Western blots. In model experiments, enrichment factors as high as 1.9x10(5) were obtained in a single round of panning. Furthermore, we demonstrate the application of this approach by selection of phage-abs recognizing the human Werner protein, which is defective in a premature aging syndrome.

The Werner syndrome protein is involved in RNA polymerase II transcription.

Werner syndrome (WS) is a human progeroid syndrome characterized by the early onset of a large number of clinical features associated with the normal aging process. The complex molecular and cellular phenotypes of WS involve characteristic features of genomic instability and accelerated replicative senescence. The gene involved (WRN) was recently cloned, and its gene product (WRNp) was biochemically characterized as a helicase. Helicases play important roles in a variety of DNA transactions, including DNA replication, transcription, repair, and recombination. We have assessed the role of the WRN gene in transcription by analyzing the efficiency of basal transcription in WS lymphoblastoid cell lines that carry homozygous WRN mutations. Transcription was measured in permeabilized cells by [3H]UTP incorporation and in vitro by using a plasmid template containing the RNA polymerase II (RNA pol II)-dependent adenovirus major late promoter. With both of these approaches, we find that the transcription efficiency in different WS cell lines is reduced to 40-60% of the transcription in cells from normal individuals. This defect can be complemented by the addition of normal cell extracts to the chromatin of WS cells. Addition of purified wild-type WRNp but not mutated WRNp to the in vitro transcription assay markedly stimulates RNA pol II-dependent transcription carried out by nuclear extracts. A nonhelicase domain (a direct repeat of 27 amino acids) also appears to have a role in transcription enhancement, as revealed by a yeast hybrid-protein reporter assay. This is further supported by the lack of stimulation of transcription when mutant WRNp lacking this domain was added to the in vitro assay. We have thus used several approaches to show a role for WRNp in RNA pol II transcription, possibly as a transcriptional activator. A deficit in either global or regional transcription in WS cells may be a primary molecular defect responsible for the WS clinical phenotype.

Enzymatic and DNA binding properties of purified WRN protein: high affinity binding to single-stranded DNA but not to DNA damage induced by 4NQO.

Mutations in the WRN gene result in Werner syndrome, an autosomal recessive disease in which many characteristics of aging are accelerated. A probable role in some aspect of DNA metabolism is suggested by the primary sequence of the WRN gene product. A recombinant His-tagged WRN protein (WRNp) was overproduced in insect cells using the baculovirus system and purified to near homogeneity by several chromatographic steps. This purification scheme removes both nuclease and topoisomerase contaminants that persist following a single Ni(2+)affinity chromatography step and allows for unambiguous interpretation of WRNp enzymatic activities on DNA substrates. Purified WRNp has DNA-dependent ATPase and helicase activities consistent with its homology to the RecQ subfamily of proteins. The protein also binds with higher affinity to single-stranded DNA than to double-stranded DNA. However, WRNp has no higher affinity for various types of DNA damage, including adducts formed during 4NQO treatment, than for undamaged DNA. Our results confirm that WRNp has a role in DNA metabolism, although this role does not appear to be the specific recognition of damage in DNA.

Functional and physical interaction between WRN helicase and human replication protein A.

The human premature aging disorder Werner syndrome (WS) is associated with a large number of symptoms displayed in normal aging. The WRN gene product, a DNA helicase, has been previously shown to unwind short DNA duplexes (

DNA repair and transcription in human premature aging disorders.

The human progeroid disorders Cockayne syndrome and Werner syndrome present with several clinical features that are associated with normal aging. These include distinct changes in the skin. The genes responsible for these conditions have recently been cloned and characterized. They both contain a characteristic helicase sequence, and helicase activity has been demonstrated using the purified Werner protein. Helicases are involved in a number of DNA metabolic transactions, including transcription, replication, and DNA repair. Cockayne cells are deficient in a special type of DNA repair, transcription coupled DNA repair, but they also appear to be defective in basal transcription. The diverse functions of the Cockayne protein are under intense study. Werner cells may have subtle defects in DNA repair, and possibly also in transcription. The biochemical clarification of the precise role of these gene products is likely to provide very significant clues into the mechanism of aging.

Persistent DNA damage inhibits S-phase and G2 progression, and results in apoptosis.

We used genetically related Chinese hamster ovary cell lines proficient or deficient in DNA repair to determine the direct role of UV-induced DNA photoproducts in inhibition of DNA replication and in induction of G2 arrest and apoptosis. UV irradiation of S-phase-synchronized cells causes delays in completion of the S-phase sometimes followed by an extended G2 arrest and apoptosis. The effects of UV irradiation during the S-phase on subsequent cell cycle progression are magnified in repair-deficient cells, indicating that these effects are initiated by persistent DNA damage and not by direct UV activation of signal transduction pathways. Moreover, among the lesions introduced by UV irradiation, persistence of (6-4) photoproducts inhibits DNA synthesis much more than persistence of cyclobutane pyrimidine dimers (which appear to be efficiently bypassed by the DNA replication apparatus). Apoptosis begins approximately 24 h after UV irradiation of S-phase-synchronized cells, occurs to a greater extent in repair-deficient cells, and correlates well with the inability to escape from an extended late S-phase-G2 arrest. We also find that nucleotide excision repair activity (including its coupling to transcription) is similar in the S-phase to what we have previously measured in G1 and G2.

Telomerase activity is elevated in early S phase in hamster cells.

Telomerase is a ribonucleoprotein that elongates telomeric repeats de novo. We examined the possibility that telomerase activity is cell cycle regulated by examining telomerase activity in cell cycle synchronized Chinese hamster ovary (CHO) B11 cells. Overall telomerase activity was similar in growing and quiescent cells. Further, cells synchronized in G1, S, or G2/M showed similar levels of telomerase activity. However, a detailed analysis of cells within S phase showed that there was a higher level of telomerase activity in early S phase when compared with other points in the cell cycle. These results suggest a relationship between telomerase activity and cell cycle regulation.

The human CSB (ERCC6) gene corrects the transcription-coupled repair defect in the CHO cell mutant UV61.

The human CSB gene, mutated in Cockayne's syndrome group B (partially defective in both repair and transcription) was previously cloned by virtue of its ability to correct the moderate UV sensitivity of the CHO mutant UV61. To determine whether the defect in UV61 is the hamster equivalent of Cockayne's syndrome, the RNA polymerase II transcription and DNA repair characteristics of a repair-proficient CHO cell line (AA8), UV61 and a CSB transfectant of UV61 were compared. In each cell line, formation and removal of UV-induced cyclobutane pyrimidine dimers (CPDs) were measured in the individual strands of the actively transcribed DHFR gene and in a transcriptionally inactive region downstream of DHFR. AA8 cells efficiently remove CPDs from the transcribed strand, but not from either the non-transcribed strand or the inactive region. There was no detectable repair of CPDs in any region of the genome in UV61. Transfection of the human CSB gene into UV61 restores the normal repair pattern (CPD removal in only the transcribed strand), demonstrating that the DNA repair defect in UV61 is homologous to that in Cockayne's syndrome (complementation group B) cells. However, we observe no significant deficiency in RNA polymerase II-mediated transcription in UV61, suggesting that the CSB protein has independent roles in DNA repair and RNA transcription pathways.

A UV-responsive G2 checkpoint in rodent cells.

We have studied the effect of UV irradiation on the cell cycle progression of synchronized Chinese hamster ovary cells. Synchronization of cells in S or G2 phase was accomplished by the development of a novel protocol using mimosine, which blocks cell cycle progression at the G1/S boundary. After removal of mimosine, cells proceed synchronously through the S and G2 phases, allowing manipulation of cells at specific points in either phase. Synchronization of cells in G1 was achieved by release of cells after a period of serum starvation. Cells synchronized by these methods were UV irradiated at defined points in G1, S, and G2, and their subsequent progression through the cell cycle was monitored. UV irradiation of G1-synchronized cells caused a dose-dependent delay in entry into S phase. Irradiation of S-phase-synchronized cells inhibited progression through S phase and then resulted in accumulation of cells for a prolonged interval in G2. Apoptosis of a subpopulation of cells during this extended period was noted. UV irradiation of G2-synchronized cells caused a shorter G2 arrest. The arrest itself and its duration were dependent upon the timing (within G2 phase) of the irradiation and the UV dose, respectively. We have thus defined a previously undescribed (in mammalian cells) UV-responsive checkpoint in G2 phase. The implications of these findings with respect to DNA metabolism are discussed.

Gene-specific and strand-specific DNA repair in the G1 and G2 phases of the cell cycle.

We have analyzed the fine structure of DNA repair in Chinese hamster ovary (CHO) cells within the G1 and G2 phases of the cell cycle. Repair of inactive regions of the genome has been suggested to increase in the G2 phase of the cell cycle compared with other phases. However, detailed studies of DNA repair in the G2 phase of the cell cycle have been hampered by technical limitations. We have used a novel synchronization protocol (D. K. Orren, L. N. Petersen, and V. A. Bohr, Mol. Cell. Biol. 15:3722-3730, 1995) which permitted detailed studies of the fine structure of DNA repair in G2. CHO cells were synchronized and UV irradiated in G1 or early G2. The rate and extent of removal of cyclobutane pyrimidine dimers from an inactive region of the genome and from both strands of the actively transcribed dihydrofolate reductase (DHFR) gene were examined within each phase. The repair of the transcribed strand of the DHFR gene was efficient in both G1 and G2, with no major differences between the two cell cycle phases. Neither the nontranscribed strand of the DHFR gene nor an inactive region of the genome was repaired in G1 or G2. CHO cells irradiated early in G2 were more resistant to UV irradiation than cells irradiated in late G1. Since we found no major difference in repair rates in G1 and G2, we suggest that G2 resistance can be attributed to the increased time (G2 and G1) available for repair before cells commit to DNA synthesis.

Post-incision steps of nucleotide excision repair in Escherichia coli. Disassembly of the UvrBC-DNA complex by helicase II and DNA polymerase I.

UvrA, UvrB, and UvrC initiate nucleotide excision repair by incising a damaged DNA strand on each side of the damaged nucleotide. This incision reaction is substoichiometric with regard to UvrB and UvrC, suggesting that both proteins remain bound following incision and do not "turn over." The addition of only helicase II to such reaction mixtures turns over UvrC; UvrB turnover requires the addition of helicase II, DNA polymerase I, and deoxynucleoside triphosphates. Column chromatography and psoralen photocross-linking experiments show that following incision, the damaged oligomer remains associated with the undamaged strand, UvrB, and UvrC in a post-incision complex. Helicase II releases the damaged oligomer and UvrC from this complex, making repair synthesis possible; DNase I footprinting experiments show that UvrB remains bound to the resulting gapped DNA until displaced by DNA polymerase I. The specific binding of UvrB to a psoralen adduct in DNA inhibits psoralen-mediated DNA-DNA cross-linking, yet promotes the formation of UrvB-psoralen-DNA cross-links. The discovery of psoralen-UvrB photocross-linking offers the potential of active-site labeling.

Formation and enzymatic properties of the UvrB.DNA complex.

The UvrA, UvrB, and UvrC proteins collectively catalyze the dual incision of a damaged DNA strand in an ATP-dependent reaction. We previously reported (Orren, D. K., and Sancar, A. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 5237-5241) that UvrA delivers UvrB to damaged sites in DNA; upon addition of UvrC to these UvrB.DNA complexes, the DNA is incised. In the present study, we have further characterized both the delivery of UvrB to DNA and the subsequent incision process, with emphasis on the role of ATP in these reactions. The UvrA-dependent delivery of UvrB onto damaged DNA is relatively slow (kon approximately 6 x 10(4) M-1 s-1) and requires ATP hydrolysis (Km = 120 microM). Although ATP enhances the stability of UvrB.DNA complexes (koff = 8.5 x 10(-5) s-1), the isolated UvrB.DNA complexes do not contain any covalently attached or stably bound nucleotide. However, ATP binding is required for the UvrC-dependent dual incision of DNA bound by UvrB. Interestingly, adenosine 5'-(3-O-thio)triphosphate can substitute for ATP at this step. The Km for ATP during incision is 2 microM, but ATP is not hydrolyzed at a detectable level during the incision reaction. The incisions made by UvrB-UvrC are on both sides of the adduct and result in the excision of the damaged nucleotide.

The (A)BC excinuclease of Escherichia coli has only the UvrB and UvrC subunits in the incision complex.

The uvrA, uvrB, and uvrC genes control excision repair in Escherichia coli. Cells with mutations in any of these three genes cannot repair DNA by nucleotide excision. When the purified gene products--the UvrA, UvrB, and UvrC proteins--are mixed together, an excision nuclease is formed that incises on both sides of the damaged nucleotide in an ATP-dependent reaction; it has been presumed that the excision nuclease was an ABC complex containing all three Uvr proteins. To determine the stoichiometry of the subunits in the enzyme, we conducted hydrodynamic studies with mixtures of the subunits with or without DNA substrate. We found that without DNA the UvrA subunit is a dimer and that when UvrB protein is also present, a (UvrA)2(UvrB)1 complex forms. Without DNA no detectable interaction of either the UvrA or UvrB subunits or the (UvrA)2(UvrB)1 complex with the UvrC subunit occurs. Unexpectedly, with UV-irradiated DNA, the UvrA/UvrB ratio in isolated DNA-protein complexes is variable, and the ratio becomes infinitesimally low as the UvrA concentration in the reaction mixture decreases. Under conditions of saturating UvrB protein approximately one UvrB molecule binds to DNA per damaged site in a reaction that requires catalytic amounts of UvrA subunit. Addition of UvrC protein to purified UvrB-DNA complexes results in rapid incision of the DNA, presumably catalyzed by an excision nuclease containing only UvrB and UvrC subunits.

Quantitative analysis of ethyltin compounds in mammalian tissue using HPLC/FAAS.

Measurement of total tin and ethyln tin forms in mammalian tissue is described, using ion-exchange high performance liquid chromatography (HPLC) in tandem with flameless atomic absorption spectrometry (FAAS) for tin-specific detection. All tin forms in whole blood and tissue homogenates were liberated from biological (in vivo) binding by treatment with 6M hydrochloric acid for a period of 4 hr. Ethyln tin species, as the chlorides, were partitioned into chloroform:ethyl acetate (1:1) and analyzed via HPLC using a strong cation exchange column, with fraction collection by a programmable collector and fraction tin measurement by FAAS. Triethyl- and diethyltin were separated and quantitated using 0.167M ammonium citrate in 70:30 methanol:water, while monoethyltin required the use of 0.50M citrate salt in 70:30 water:methanol as mobile phase to effect elution. The difference between total and speciated tin content provides an estimate of remaining tin species, including the inorganic element.

Quantitative analysis of total and trimethyl lead in mammalian tissues using ion exchange HPLC and atomic absorption spectrometric detection.

Measurement of total and trimethyl lead in mammalian tissue is described, using ion exchange/high performance liquid chromatography in tandem with flameless atomic absorption spectrometry for lead-specific detection. All lead forms in whole blood and homogenates of soft tissue--brain, kidney, and liver--were liberated from tissue binding by treatment with dilute (3N) HCl for a period of 18 hr. Trimethyl lead was partitioned into chloroform/ethyl acetate after media neutralization to pH of approximately 4 and saturation with sodium chloride. The extract was chromatographically analyzed on a Partisil SCX-10 cation exchange column, using 0.167M ammonium citrate in methanol:water (70:30) as mobile phase. Fractions of eluate were collected using a programmable fraction collector, and the fractions collected from 3.5 to 5.0 min were analyzed by atomic absorption spectrometry. Total lead in tissue was measured by acid wet digestion and flameless atomic absorption spectrometry. The difference in the values from both analyses provided a measure of any trimethyl lead metabolites.