Homologous recombination is elevated in some Werner-like syndromes but not during normal in vitro or in vivo senescence of mammalian cells

Human RECQL5: guarding the crossroads of DNA replication and transcription and providing backup capability

DNA helicases are ubiquitous enzymes that catalyze unwinding of duplex DNA and function in all metabolic processes in which access to single-stranded DNA is required, including DNA replication, repair, recombination and RNA transcription. RecQ helicases are a conserved family of DNA helicases that display highly specialized and vital roles in the maintenance of genome stability. Mutations in three of the five human RecQ helicases, BLM, WRN and RECQL4 are associated with the genetic disorders Bloom syndrome, Werner syndrome and Rothmund-Thomson syndrome that are characterized by chromosomal instability, premature aging and predisposition to cancer. The biological role of human RECQL5 is only partially understood and RECQL5 has not yet been associated with any human disease. Illegitimate recombination and replication stress are hallmarks of human cancers and common instigators for genomic instability and cell death. Recql5 knockout mice are cancer prone and show increased chromosomal instability. Recql5-deficient mouse embryonic fibroblasts are sensitive to camptothecin and display elevated levels of sister chromatid exchanges. Unlike other human RecQ helicases, RECQL5 is recruited to single-stranded DNA breaks and is also proposed to play an essential role in RNA transcription. Here, we review the established roles of RECQL5 at the cross roads of DNA replication, recombination and transcription, and propose that human RECQL5 provides important backup functions in the absence of other DNA helicases.

Homologous recombination: how RecA finds the perfect partner

How do two identical DNA sequences find each other during homologous recombination, amidst a 'sea' of unrelated DNA? New studies reveal how RecA promotes the search for homology by sampling DNA in three dimensions.

Mouse WRN Helicase Domain Is Not Required for Spontaneous Homologous Recombination-Mediated DNA Deletion

Werner syndrome is a rare disorder that manifests as premature aging and age-related diseases. WRN is the gene mutated in WS, and is one of five human RecQ helicase family members. WS cells exhibit genomic instability and altered proliferation, and in vitro studies suggest that WRN has a role in suppressing homologous recombination. However, more recent studies propose that other RecQ helicases (including WRN) promote early events of homologous recombination. To study the role of WRN helicase on spontaneous homologous recombination, we obtained a mouse with a deleted WRN helicase domain and combined it with the in vivo pink-eyed unstable homologous recombination system. In this paper, we demonstrate that WRN helicase is not necessary for suppressing homologous recombination in vivo contrary to previous reports using a similar mouse model.

Depletion of Werner helicase results in mitotic hyperrecombination and pleiotropic homologous and nonhomologous recombination phenotypes

Werner syndrome (WS) is a rare, segmental progeroid syndrome caused by defects in the WRN gene, which encodes a RecQ helicase. WRN has roles in many aspects of DNA metabolism including DNA repair and recombination. In this study, we exploited two different recombination assays previously used to describe a role for the structure-specific endonuclease ERCC1-XPF in mitotic and targeted homologous recombination. We constructed Chinese hamster ovary (CHO) cell lines isogenic with the cell lines used in these previous studies by depleting WRN using shRNA vectors. When intrachromosomal, mitotic recombination was assayed in WRN-depleted CHO cells, a hyperrecombination phenotype was observed, and a small number of aberrant recombinants were generated. Targeted homologous recombination was also examined in WRN-depleted CHO cells using a plasmid-chromosome targeting assay. In these experiments, loss of WRN resulted in a significant decrease in nonhomologous integration events and ablation of recombinants that required random integration of the corrected targeting vector. Aberrant recombinants were also recovered, but only from WRN-depleted cells. The pleiotropic recombination phenotypes conferred by WRN depletion, reflected in distinct homologous and nonhomologous recombination pathways, suggest a role for WRN in processing specific types of homologous recombination intermediates as well as an important function in nonhomologous recombination.

The role of cellular senescence in Werner syndrome: toward therapeutic intervention in human premature aging

Werner syndrome (WS) is a premature aging disorder used as a model of normal human aging. WS individuals have several characteristics of normal aging, such as cataracts, hair graying, and skin aging, but manifest these at an early age. Additionally, WS individuals have high levels of inflammatory diseases, such as atherosclerosis and type 2 diabetes. The in vivo aging in WS is associated with accelerated aging of fibroblasts in culture. The cause of the accelerated senescence is not understood, but may be due to the genomic instability that is a hallmark of WS. Genome instability results in activation of stress kinases, such as p38, and the p38-specific inhibitor SB203580, prevents the accelerated senescence seen in WS fibroblasts. However, oxidative damage plays a role, as low oxygen conditions and antioxidant treatment revert some of the accelerated senescence phenotype. The effects of oxidative stress appear to be suppressible by SB203580; however, it does not appear to be transduced by p38. As SB203580 is known to inhibit other kinases in addition to p38, this suggests that more than one kinase pathway is involved. The recent development of p38 inhibitors with different binding properties, specificities, and oral bioavailability, and of new potent and selective inhibitors of JNK and MK2, will make it possible to dissect the roles of various kinase pathways in the accelerated senescence of WS cells. If this accelerated senescence is reflective of WS aging in vivo, these kinase inhibitors may well form the basis of antiaging therapies for individuals with WS.

Probing the roles of active site residues in the 3'-5' exonuclease of the Werner syndrome protein

Werner syndrome is a premature aging disease caused by mutations in the WS gene and a deficiency in the function of Werner protein (WRN). The lack of WRN results in a cellular phenotype of genomic instability. WRN belongs to the RecQ DNA helicase family, but unlike other RecQ family members it possesses a functional exonuclease domain. We determined the crystal structure of mWRNexo (residues 31-238) bound to Zn(2+) and the sulfate ion. Compared with the structure of human WRNexo (hWRNexo), notable conformational changes were observed in several active site residues in an H5-H6 loop and in helices H6 and H7 of mWRNexo, presumably because of the presence of sulfate, which mimics the phosphate of substrate DNA. In particular, the side chains of Lys(185) and Tyr(206) were reoriented toward the Zn(2+) ion, whereas the side chain of Arg(190) pointed away from the active site center. Mutational analysis of these conserved residues abolished WRN exonuclease activity, suggesting that these residues play a critical role in the WRNexo activity. Based on substrate modeling and mutational analyses, we propose a mechanism by which WRNexo becomes activated upon substrate DNA binding. We also describe the low resolution trimeric structure of mouse WRNexoL (mWRNexoL, residues 31-330), as elucidated by small angle x-ray scattering (SAXS) analyses.

Inhibition of Werner syndrome helicase activity by benzo[a]pyrene diol epoxide adducts can be overcome by replication protein A

RecQ helicases are believed to function in repairing replication forks stalled by DNA damage and may also play a role in the intra-S-phase checkpoint, which delays the replication of damaged DNA, thus permitting repair to occur. Since little is known regarding the effects of DNA damage on RecQ helicases, and because the replication and recombination defects in Werner syndrome cells may reflect abnormal processing of damaged DNA associated with the replication fork, we examined the effects of specific bulky, covalent adducts at N(6) of deoxyadenosine (dA) or N(2) of deoxyguanosine (dG) on Werner (WRN) syndrome helicase activity. The adducts are derived from the optically active 7,8-diol 9,10-epoxide (DE) metabolites of the carcinogen benzo[a]pyrene (BaP). The results demonstrate that WRN helicase activity is inhibited in a strand-specific manner by BaP DE-dG adducts only when on the translocating strand. These adducts either occupy the minor groove without significant perturbation of DNA structure (trans adducts) or cause base displacement at the adduct site (cis adducts). In contrast, helicase activity is only mildly affected by intercalating BaP DE-dA adducts that locally perturb DNA double helical structure. This differs from our previous observation that intercalating dA adducts derived from benzo[c]phenanthrene (BcPh) DEs inhibit WRN activity in a strand- and stereospecific manner. Partial unwinding of the DNA helix at BaP DE-dA adduct sites may make such adducted DNAs more susceptible to the action of helicase than DNA containing the corresponding BcPh DE-dA adducts, which cause little or no destabilization of duplex DNA. The single-stranded DNA binding protein RPA, an auxiliary factor for WRN helicase, enabled the DNA unwinding enzyme to overcome inhibition by either the trans-R or cis-R BaP DE-dG adduct, suggesting that WRN and RPA may function together to unwind duplex DNA harboring specific covalent adducts that otherwise block WRN helicase acting alone.

Current advances in unraveling the function of the Werner syndrome protein

Werner syndrome (WS) is an autosomal recessive premature aging disease manifested by the mimicry of age-related phenotypes such as atherosclerosis, arteriosclerosis, cataracts, osteoporosis, soft tissue calcification, premature thinning, graying, and loss of hair, as well as a high incidence of some types of cancers. The gene product defective in WS, WRN, is a member of the RecQ family of DNA helicases that are widely distributed in nature and believed to play central roles in genomic stability of organisms ranging from prokaryotes to mammals. Interestingly, WRN is a bifunctional protein that is exceptional among RecQ helicases in that it also harbors an exonuclease activity. Furthermore, it preferentially operates on aberrant DNA structures believed to exist in vivo as intermediates in specific DNA transactions such as replication (forked DNA), recombination (Holliday junction, triplex and tetraplex DNA), and repair (partial duplex with single stranded bubble). In addition, WRN has been shown to physically and functionally interact with a variety of DNA-processing proteins, including those that are involved in resolving alternative DNA structures, repair DNA damage, and provide checkpoints for genomic stability. Despite significant research activity and considerable progress in understanding the biochemical and molecular genetic function of WRN, the in vivo molecular pathway(s) of WRN remain elusive. The following review focuses on the recent advances in the biochemistry of WRN and considers the putative in vivo functions of WRN in light of its many protein partners.

Cancer and aging: the importance of telomeres in genome maintenance

Telomeres are the specialized DNA-protein structures that cap the ends of linear chromosomes, thereby protecting them from degradation and fusion by cellular DNA repair processes. In vertebrate cells, telomeres consist of several kilobase pairs of DNA having the sequence TTAGGG, a few hundred base pairs of single-stranded DNA at the 3' end of the telomeric DNA tract, and a host of proteins that organize the telomeric double and single-stranded DNA into a protective structure. Functional telomeres are essential for maintaining the integrity and stability of genomes. When combined with loss of cell cycle checkpoint controls, telomere dysfunction can lead to genomic instability, a common cause and hallmark of cancer. Consequently, normal mammalian cells respond to dysfunctional telomeres by undergoing apoptosis (programmed cell death) or cellular senescence (permanent cell cycle arrest), two cellular tumor suppressor mechanisms. These tumor suppressor mechanisms are potent suppressors of cancer, but recent evidence suggests that they can antagonistically also contribute to aging phenotypes. Here, we review what is known about the structure and function of telomeres in mammalian cells, particularly human cells, and how telomere dysfunction may arise and contribute to cancer and aging phenotypes.

A mouse model of Werner Syndrome: what can it tell us about aging and cancer?

The molecular mechanisms involved in mammalian aging and the consequent organ dysfunction/degeneration pathologies are not well understood. Studies of progeroid syndromes such as Werner Syndrome have advanced our understanding of how certain genetic pathways can influence the aging process on both cellular and molecular levels. In addition, improper maintenance of telomere length and the consequent cellular responses to dysfunctional telomeres have been proposed to promote replicative senescence that impact upon the onset of premature aging and cancer. Recent studies of the telomerase-Werner double null mouse link telomere dysfunction to accelerated aging and tumorigenesis in the setting of Werner deficiency. This mouse model thus provides a unique genetic platform to explore molecular mechanisms by which telomere dysfunction and loss of WRN gene function leads to the onset of premature aging and cancer.

The N-terminal domain of the large subunit of human replication protein A binds to Werner syndrome protein and stimulates helicase activity

Werner syndrome (WS) is a recessive inherited human disease characterized by the early onset of aging. The gene mutated in WS encodes a DNA helicase that unwinds the double helical structure of DNA in the 3'-->5' direction as well as a 3'-->5' exonuclease. Our previous studies indicated that the activity of Werner syndrome helicase (WRN) could be stimulated by human replication protein A (hRPA), a heterotrimeric single-stranded DNA binding protein. We now localize the interaction between WRN and hRPA by measuring the stimulation of helicase activity and the binding of WRN by hRPA and its derivatives. The large subunit of hRPA (hRPA70) stimulates WRN helicase to the same extent as the hRPA heterotrimer, whereas the dimer of the two smaller subunits (hRPA 32.14) does not stimulate. By examining hRPA70 mutants with progressive deletions from either the C- or N-terminus, we found that the domain responsible for stimulation lies in the N-terminal half of the protein. By using enzyme-linked immunosorbent assay (ELISA) to examine physical interaction between WRN and the same deletion mutants, we found that the WRN-binding motif is located within amino acids 100-300 and overlaps with the single-stranded DNA binding domain (amino acids 150-450). We suggest that hRPA, by engaging in both protein-protein and protein-DNA interactions, facilitates unwinding events catalyzed by WRN helicase during DNA synthetic processes. These data should help further elucidation of the molecular mechanisms of genetic instability and premature aging phenotypes manifested by WS.

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.

Werner Syndrome Protein--Unwinding Function to Explain Disease

Werner syndrome (WS) is one of three heritable human genetic instability/cancer predisposition syndromes that result from mutations in a member of the gene family encoding human RecQ helicases. Cellular defects are a prominent part of the WS phenotype. Here we review recent work to identify in vivo functions of the WS protein and discuss how loss of function leads to cellular defects. These new results provide clues to the origin of cell lineage-specific defects in WS patients and suggest a broader role for Werner protein function in determining disease risk in the general population.

Stimulation of flap endonuclease-1 by the Bloom's syndrome protein

Bloom's syndrome (BS) is a rare autosomal recessive genetic disorder associated with genomic instability and an elevated risk of cancer. Cellular features of BS include an accumulation of abnormal replication intermediates and increased sister chromatid exchange. Although it has been suggested that the underlying defect responsible for hyper-recombination in BS cells is a temporal delay in the maturation of DNA replication intermediates, the precise role of the BS gene product, BLM, in DNA metabolism remains elusive. We report here a novel interaction of the BLM protein with the human 5'-flap endonuclease/5'-3' exonuclease (FEN-1), a genome stability factor involved in Okazaki fragment processing and DNA repair. BLM protein stimulates both the endonucleolytic and exonucleolytic cleavage activity of FEN-1 and this functional interaction is independent of BLM catalytic activity. BLM and FEN-1 are associated with each other in human nuclei as shown by their reciprocal co-immunoprecipitation from HeLa nuclear extracts. The BLM-FEN-1 physical interaction is mediated through a region of the BLM C-terminal domain that shares homology with the FEN-1 interaction domain of the Werner syndrome protein, a RecQ helicase family member homologous to BLM. This study provides the first evidence for a direct interaction of BLM with a human nucleolytic enzyme. We suggest that functional interactions between RecQ helicases and Rad2 family nucleases serve to process DNA substrates that are intermediates in DNA replication and repair.

Inhibition of Werner syndrome helicase activity by benzo[c]phenanthrene diol epoxide dA adducts in DNA is both strand-and stereoisomer-dependent

Helicases are among the first enzymes to encounter DNA damage during DNA processing within the cell and thus are likely to be targets for the adverse effects of DNA lesions induced by environmental chemicals. Here we examined the effect of cis- and trans-opened 3,4-diol 1,2-epoxide (DE) DNA adducts of benzo[c]phenanthrene (BcPh) at N6 of adenine on helicase activity. These adducts are derived from the highly tumorigenic (-)-(1R,2S,3S,4R)-DE as well as its less carcinogenic (+)-(1S,2R,3R,4S)-DE enantiomer in both of which the benzylic 4-hydroxyl group and epoxide oxygen are trans. The hydrocarbon portions of these adducts intercalate into DNA on the 3' or the 5' side of the adducted deoxyadenosine for the 1S- and 1R-adducts, respectively. These adducts inhibited the human Werner (WRN) syndrome helicase activity in a strand-specific and stereospecific manner. In the strand along which WRN translocates, cis-opened adducts were significantly more effective inhibitors than trans-opened isomers, indicating that WRN unwinding is sensitive to adduct stereochemistry. WRN helicase activity was also inhibited but to a lesser extent by cis-opened BcPh DE adducts in the displaced strand independent of their direction of intercalation, whereas inhibition by the trans-opened stereoisomers in the displaced strand depended on their orientation, such that only adducts oriented toward the advancing helicase inhibited WRN activity. A BcPh DE adduct positioned in the helicase-translocating strand did not sequester WRN, nor affect the rate of ATP hydrolysis relative to an unadducted control. Although the Bloom (BLM) syndrome helicase was also inhibited by a cis-opened adduct in a strand-specific manner, this helicase was not as severely affected as WRN. Because BcPh DEs form substantial amounts of deoxyadenosine adducts at dA, their adverse effects on helicases could contribute to genetic damage and cell transformation induced by these DEs. Thus, the unwinding activity of RecQ helicases is sensitive to the strand, orientation, and stereochemistry of intercalated polycyclic aromatic hydrocarbon adducts.

Werner syndrome protein contains three structure-specific DNA binding domains

Werner syndrome (WS) is a premature aging syndrome caused by mutations in the WS gene (WRN) and a deficiency in the function of the Werner protein (WRN). WRN is a multifunctional nuclear protein that catalyzes three DNA-dependent reactions: a 3'-5'-exonuclease, an ATPase, and a 3'-5'-helicase. Deficiency in WRN results in a cellular phenotype of genomic instability. The biochemical characteristics of WRN and the cellular phenotype of WRN mutants suggest that WRN plays an important role in DNA metabolic pathways such as recombination, transcription, replication, and repair. The catalytic activities of WRN have been extensively studied and are fairly well understood. However, much less is known about the domain-specific interactions between WRN and its DNA substrates. This study identifies and characterizes three distinct WRN DNA binding domains using recombinant truncated fragments of WRN and five DNA substrates (long forked duplex, blunt-ended duplex, single-stranded DNA, 5'-overhang duplex, and Holliday junction). Substrate-specific DNA binding activity was detected in three domains, one N-terminal and two different C-terminal WRN fragments (RecQ conserved domain and helicase RNase D conserved domain-containing domains). The substrate specificity of each DNA binding domain may indicate that each protein domain has a distinct biological function. The importance of these results is discussed with respect to proposed roles for WRN in distinct DNA metabolic pathways.

The exonucleolytic and endonucleolytic cleavage activities of human exonuclease 1 are stimulated by an interaction with the carboxyl-terminal region of the Werner syndrome protein

Exonuclease 1 (EXO-1), a member of the RAD2 family of nucleases, has recently been proposed to function in the genetic pathways of DNA recombination, repair, and replication which are important for genome integrity. Although the role of EXO-1 is not well understood, its 5' to 3'-exonuclease and flap endonuclease activities may cleave intermediates that arise during DNA metabolism. In this study, we provide evidence that the Werner syndrome protein (WRN) physically interacts with human EXO-1 and dramatically stimulates both the exonucleolytic and endonucleolytic incision functions of EXO-1. The functional interaction between WRN and EXO-1 is mediated by a protein domain of WRN which interacts with flap endonuclease 1 (FEN-1). Thus, the genomic instability observed in WRN-/- cells may be at least partially attributed to the lack of interactions between the WRN protein and human nucleases including EXO-1.

Asymmetry of DNA replication fork progression in Werner's syndrome

Human aging is associated with accumulation of cells that have undergone replicative senescence. The rare premature aging Werner's syndrome (WS) provides a phenocopy of normal human aging and WS patient cells recapitulate the aging phenotype in culture as they rapidly lose the ability to proliferate or replicate their DNA. WS is associated with loss of functional WRN protein. Although the biochemical properties of WRN protein, which possesses both helicase and exonuclease activities, suggest an involvement in DNA metabolism, its action in cells is not clear. Here, we provide experimental evidence for a role of the WRN protein in DNA replication in normally proliferating cells. Most importantly, we demonstrate that in the absence of functional WRN protein, replication forks from origins of bidirectional replication fail to progress normally, resulting in marked asymmetry of bidirectional forks. We propose that WRN acts in normal DNA replication to prevent collapse of replication forks or to resolve DNA junctions at stalled replication forks, and that loss of this capacity may be a contributory factor in premature aging.

Biochemical characterization of the DNA substrate specificity of Werner syndrome helicase

Werner syndrome is a hereditary premature aging disorder characterized by genome instability. The product of the gene defective in WS, WRN, is a helicase/exonuclease that presumably functions in DNA metabolism. To understand the DNA structures WRN acts upon in vivo, we examined its substrate preferences for unwinding. WRN unwound a 3'-single-stranded (ss)DNA-tailed duplex substrate with streptavidin bound to the end of the 3'-ssDNA tail, suggesting that WRN does not require a free DNA end to unwind the duplex; however, WRN was completely blocked by streptavidin bound to the 3'-ssDNA tail 6 nucleotides upstream of the single-stranded/double-stranded DNA junction. WRN efficiently unwound the forked duplex with streptavidin bound just upstream of the junction, suggesting that WRN recognizes elements of the fork structure to initiate unwinding. WRN unwound two important intermediates of replication/repair, a 5'-ssDNA flap substrate and a synthetic replication fork. WRN was able to translocate on the lagging strand of the synthetic replication fork to unwind duplex ahead of the fork. For the 5'-flap structure, WRN specifically displaced the 5'-flap oligonucleotide, suggesting a role of WRN in Okazaki fragment processing. The ability of WRN to target DNA replication/repair intermediates may be relevant to its role in genome stability maintenance.

WRN helicase accelerates the transcription of ribosomal RNA as a component of an RNA polymerase I-associated complex

Werner syndrome (WS) is a rare autosomal recessive genetic disorder causing premature aging. The gene (WRN) responsible for WS encodes a protein homologous to the RecQ-type helicase. WRN has a nucleolar localization signal and shows intranuclear trafficking between the nucleolus and the nucleoplasm. WRN is recruited into the nucleolus when rRNA transcription is reactivated in quiescent cells. Inhibition of mRNA transcription with alpha-amanitin has no effect on nucleolar localization of WRN whereas inhibition of rRNA transcription with actinomycin D releases WRN from nucleoli, suggesting that nucleolar WRN is closely related to rRNA transcription by RNA polymerase I (RPI). A possible function of WRN on rRNA transcription through interaction with RPI is supported by the results described here showing that WRN is co-immunoprecipitated with an RPI subunit, RPA40. Here we show that WS fibroblasts are characterized by a decreased level of rRNA transcription compared with wild-type cells, and that the decreased level of rRNA transcription in WS fibroblasts recovers when wild-type WRN is exogenously expressed. By contrast, exogenously expressed mutant-type WRN lacking an ability to migrate into the nucleolus fails to stimulate rRNA transcription. These results suggest that WRN promotes rRNA transcription as a component of an RPI-associated complex in the nucleolus.

Roles of the Werner syndrome protein in pathways required for maintenance of genome stability

Werners syndrome is a disease of premature aging where the patients appear much older than their chronological age. The gene codes for a protein that is a helicase and an exonuclease, and recently we have learned about some of its protein interactions. These interactions are being discussed as they shed light on the molecular pathways in which Werner protein participates. Insight into these pathways brings insight into the aging process.

A model for the phenotypic presentation of Werner's syndrome

Werner's syndrome (WS) is a valuable model of accelerated ageing and results from mutations in a recQ helicase (wrn). WS fibroblasts show a mutator phenotype, replication fork stalling, increased rates of mean telomeric loss and accelerated cellular senescence. Senescence has been proposed as a candidate mechanism for the ageing of mitotic tissue. However, some mitotic tissues (such as the immune system) seem unaffected in WS. Is this evidence against a role for cell senescence in ageing? Two experiments resolve this paradox (i) the demonstration that the abbreviated replicative lifespan of WS fibroblasts can be corrected by the ectopic expression of telomerase and (ii) the demonstration that T cells derived from WS patients have the mutator phenotype characteristic of the disease but show no reduction in replicative potential. Since T cells can upregulate telomerase naturally these findings are consistent with a model in which the only wrn-mediated deletions that have a significant effect on replicative lifespan are those at or near the telomere. These data are thus supportive of a role for senescence in the ageing of the immune system. Emerging data on divisional counting mechanisms have the potential to produce many other apparent WS "paradoxes". Accordingly, we propose a general model for the phenotypic presentation of WS, which includes a modification of the Olovnikov model of telomere erosion. Somewhat unexpectedly, this predicts that accelerated senescence should not be observed in all telomerase-negative WS cell types.

Analysis of microsatellite instability and hypermutation of immunoglobulin variable genes in Werner syndrome

Werner syndrome (WS) is a human premature aging syndrome, which is associated with high frequencies of neoplasia and genetic instability. We have examined the occurrence of microsatellite instability, which may result from defective mismatch repair, in lymphoblastoid cell lines derived from nine WS patients. Instability was measured at the D2S123 locus by gel analysis of PCR products. Three WS cell lines had 4-13% altered alleles, compared with 0% in the other six lines. The increased frequency of microsatellite instability could not readily be associated with overt cancer or any other known clinical condition in the three patients. To examine whether the WS defect affected the humoral immune system, we measured the hypermutation of immunoglobulin variable genes in peripheral blood cells from the WS patient who donated the cell line with the highest frequency of microsatellite instability. The frequency and pattern of mutation was similar to that from normal individuals, suggesting that the Werner protein is not involved in generating hypermutation.

Replication protein A physically interacts with the Bloom's syndrome protein and stimulates its helicase activity

Bloom's syndrome is a rare autosomal recessive disorder characterized by genomic instability and predisposition to cancer. BLM, the gene defective in Bloom's syndrome, encodes a 159-kDa protein possessing DNA-stimulated ATPase and ATP-dependent DNA helicase activities. We have examined mechanistic aspects of the catalytic functions of purified recombinant BLM protein. Through analyzing the effects of different lengths of DNA cofactor on ATPase activity, we provide evidence to suggest that BLM translocates along single-stranded DNA in a processive manner. The helicase reaction catalyzed by BLM protein was examined as a function of duplex DNA length. We show that BLM catalyzes unwinding of short DNA duplexes (</=71 base pairs (bp)) but is severely compromised on longer DNA duplexes (>/=259-bp). The presence of the human single-stranded DNA-binding protein (human replication protein A (hRPA)) stimulates the BLM unwinding reaction on the 259-bp partial duplex DNA substrate. Heterologous single-stranded DNA-binding proteins fail to stimulate similarly the helicase activity of BLM protein. This is the first demonstration of a functional interaction between BLM and another protein. Consistent with a functional interaction between hRPA and the BLM helicase, we demonstrate a direct physical interaction between the two proteins mediated by the 70-kDa subunit of RPA. The interactions between BLM and hRPA suggest that the two proteins function together in vivo to unwind DNA duplexes during replication, recombination, or repair.

Potent inhibition of werner and bloom helicases by DNA minor groove binding drugs

Maintenance of genomic integrity is vital to all organisms. A number of human genetic disorders, including Werner Syndrome, Bloom Syndrome and Rothmund-Thomson Syndrome, exhibit genomic instability with some phenotypic characteristics of premature aging and cancer predisposition. Presumably the aberrant cellular and clinical phenotypes in these disorders arise from defects in important DNA metabolic pathways such as replication, recombination or repair. These syndromes are all characterized by defects in a member of the RecQ family of DNA helicases. To obtain a better understanding of how these enzymes function in DNA metabolic pathways that directly influence chromosomal integrity, we have examined the effects of non-covalent DNA modifications on the catalytic activities of purified Werner (WRN) and Bloom (BLM) DNA helicases. A panel of DNA-binding ligands displaying unique properties for interacting with double helical DNA was tested for their effects on the unwinding activity of WRN and BLM helicases on a partial duplex DNA substrate. The levels of inhibition by a number of these compounds were distinct from previously reported values for viral, prokaryotic and eukaryotic helicases. The results demonstrate that BLM and WRN proteins exhibit similar sensitivity profiles to these DNA-binding ligands and are most potently inhibited by the structurally related minor groove binders distamycin A and netropsin (K(i) Collapse

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MESH Headings

• Adenosine Triphosphatases/antagonists & inhibitors
• Adenosine Triphosphatases/chemistry
• Bloom Syndrome/enzymology
• DNA Helicases/antagonists & inhibitors
• DNA Helicases/chemistry
• Distamycins/pharmacology
• Enzyme Inhibitors/chemistry
• Enzyme Inhibitors/pharmacology
• Exodeoxyribonucleases
• Humans
• Intercalating Agents/chemistry
• Intercalating Agents/pharmacology
• Kinetics
• Ligands
• Netropsin/pharmacology
• RecQ Helicases
• Recombinant Proteins/antagonists & inhibitors
• Topoisomerase I Inhibitors
• Werner Syndrome/enzymology
• Werner Syndrome Helicase

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Affiliation(s)

R M Brosh Laboratory of Molecular Genetics, Box 1, National Institute on Aging, GRC, NIH, 5600 Nathan Shock Drive, Baltimore, MD 21224, USA
J K Karow
E J White
N D Shaw
I D Hickson
V A Bohr

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Characterization of the human and mouse WRN 3'-->5' exonuclease

Werner's syndrome (WS) is an autosomal recessive disorder in humans characterized by the premature development of a partial array of age-associated pathologies. WRN, the gene defective in WS, encodes a 1432 amino acid protein (hWRN) with intrinsic 3'-->5' DNA helicase activity. We recently showed that hWRN is also a 3'-->5' exonuclease. Here, we further characterize the hWRN exonuclease. hWRN efficiently degraded the 3' recessed strands of double-stranded DNA or a DNA-RNA heteroduplex. It had little or no activity on blunt-ended DNA, DNA with a 3' protruding strand, or single-stranded DNA. The hWRN exonuclease efficiently removed a mismatched nucleotide at a 3' recessed terminus, and was capable of initiating DNA degradation from a 12-nt gap, or a nick. We further show that the mouse WRN (mWRN) is also a 3'-->5' exonuclease, with substrate specificity similar to that of hWRN. Finally, we show that hWRN forms a trimer and interacts with the proliferating cell nuclear antigen in vitro. These findings provide new data on the biochemical activities of WRN that may help elucidate its role(s) in DNA metabolism.

Partial suppression of the fission yeast rqh1(-) phenotype by expression of a bacterial Holliday junction resolvase

A key stage during homologous recombination is the processing of the Holliday junction, which determines the outcome of the recombination reaction. To dissect the pathways of Holliday junction processing in a eukaryote, we have targeted an Escherichia coli Holliday junction resolvase to the nuclei of fission yeast recombination-deficient mutants and analysed their phenotypes. The resolvase partially complements the UV and hydroxyurea hypersensitivity and associated aberrant mitoses of an rqh1(-) mutant. Rqh1 is a member of the RecQ subfamily of DNA helicases that control recombination particularly during S-phase. Significantly, overexpression of the resolvase in wild-type cells partly mimics the loss of viability, hyper-recombination and 'cut' phenotype of an rqh1(-) mutant. These results indicate that Holliday junctions form in wild-type cells that are normally removed in a non-recombinogenic way, possibly by Rqh1 catalysing their reverse branch migration. We propose that in the absence of Rqh1, replication fork arrest results in the accumulation of Holliday junctions, which can either impede sister chromatid segregation or lead to the formation of recombinants through Holliday junction resolution.

Functional interaction between the Werner Syndrome protein and DNA polymerase delta

Werner Syndrome (WS) is an inherited disease characterized by premature onset of aging, increased cancer incidence, and genomic instability. The WS gene encodes a 1,432-amino acid polypeptide (WRN) with a central domain homologous to the RecQ family of DNA helicases. Purified WRN unwinds DNA with 3'-->5' polarity, and also possesses 3'-->5' exonuclease activity. Elucidation of the physiologic function(s) of WRN may be aided by the identification of WRN-interacting proteins. We show here that WRN functionally interacts with DNA polymerase delta (pol delta), a eukaryotic polymerase required for DNA replication and DNA repair. WRN increases the rate of nucleotide incorporation by pol delta in the absence of proliferating cell nuclear antigen (PCNA) but does not stimulate the activity of eukaryotic DNA polymerases alpha or epsilon, or a variety of other DNA polymerases. Moreover, we show that functional interaction with WRN is mediated through the third subunit of pol delta: i.e., Pol32p of Saccharomyces cerevisae, corresponding to the recently identified p66 subunit of human pol delta. Absence of the third subunit abrogates stimulation by WRN, and stimulation is restored by reconstituting the three-subunit enzyme. Our findings suggest that WRN may facilitate pol delta-mediated DNA replication and/or DNA repair and that disruption of WRN-pol delta interaction in WS cells may contribute to the previously observed S-phase defects and/or the unusual sensitivity to a limited number of DNA damaging agents.

Physical and functional interaction between p53 and the Werner's syndrome protein

Werner's syndrome is a human autosomal recessive disorder leading to premature aging. The mutations responsible for this disorder have recently been localized to a gene (WRN) encoding a protein that possesses DNA helicase and exonuclease activities. Patients carrying WRN gene mutations exhibit an elevated rate of cancer, accompanied by increased genomic instability. The latter features are also characteristic of the loss of function of p53, a tumor suppressor that is very frequently inactivated in human cancer. Moreover, changes in the activity of p53 have been implicated in the onset of cellular replicative senescence. We report here that the WRN protein can form a specific physical interaction with p53. This interaction involves the carboxyl-terminal part of WRN and the extreme carboxyl terminus of p53, a region that plays an important role in regulating the functional state of p53. A small fraction of WRN can be found in complex with endogenous p53 in nontransfected cells. Overexpression of WRN leads to augmented p53-dependent transcriptional activity and induction of p21(Waf1) protein expression. These findings support the existence of a cross-talk between WRN and p53, which may be important for maintaining genomic integrity and for preventing the accumulation of aberrations that can give rise to premature senescence and cancer.

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 (</=53 base pairs) in a reaction stimulated by single-stranded DNA-binding proteins. We have studied the helicase activity of purified WRN protein on a variety of DNA duplex substrates to characterize the unwinding properties of the enzyme in greater detail. WRN helicase can catalyze unwinding of long duplex DNA substrates up to 849 base pairs in a reaction dependent on human replication protein A (hRPA). Escherichia coli SSB and bacteriophage T4 gene 32 protein (gp32) completely failed to stimulate WRN helicase to unwind long DNA duplexes indicating a specific functional interaction between WRN and hRPA. So far, there have been no reports of any physical interactions between WRN helicase and other proteins. In support of the functional interaction, we demonstrate a direct interaction between WRN and hRPA by coimmunoprecipitation of purified proteins. The physical and functional interaction between WRN and hRPA suggests that the two proteins may function together in vivo in a pathway of DNA metabolism such as replication, recombination, or repair.

Recombination and its roles in DNA repair, cellular immortalization and cancer

Genetic recombination is the creation of new gene combinations in a cell or gamete, which differ from those of progenitor cells or parental gametes. In eukaryotes, recombination may occur at mitosis or meiosis. Mitotic recombination plays an indispensable role in DNA repair, which presumably directed its early evolution; the multiplicity of recombination genes and pathways may be best understood in this context, although they have acquired important additional functions in generating diversity, both somatically (increasing the immune repertoire) and in germ line (facilitating evolution). Chromosomal homologous recombination and HsRad51 recombinase expression are increased in both immortal and preimmortal transformed cells, and may favor the occurrence of multiple oncogenic mutations. Tumorigenesis in vivo is frequently associated with karyotypic instability, locus-specific gene rearrangements, and loss of heterozygosity at tumor suppressor loci - all of which can be recombinationally mediated. Genetic defects which increase the rate of somatic mutation (several of which feature elevated recombination) are associated with early incidence and high risk for a variety of cancers. Moreover, carcinogenic agents appear to quite consistently stimulate homologous recombination. If cells with high recombination arise, either spontaneously or in response to "recombinogens," and predispose to the development of cancer, what selective advantage could favor these cells prior to the occurrence of growth-promoting mutations? We propose that the augmentation of telomere-telomere recombination may provide just such an advantage, to hyper-recombinant cells within a population of telomerase-negative cells nearing their replicative (Hayflick) limit, by extending telomeres in some progeny cells and thus allowing their continued proliferation.

Werner syndrome protein. II. Characterization of the integral 3' --> 5' DNA exonuclease

In addition to its DNA helicase activity, Werner syndrome protein (WRN) also possesses an exonuclease activity (Shen, J.-C., Gray, M. D., Kamath-Loeb, A. S., Fry, M., Oshima, J., and Loeb, L. A. (1998) J. Biol. Chem. 273, 34139-34144). Here we describe the properties of nearly homogeneous WRN exonuclease. WRN exonuclease hydrolyzes a recessed strand in a partial DNA duplex but does not significantly digest single-stranded DNA, blunt-ended duplex, or a protruding strand of a partial duplex. Although DNA is hydrolyzed in the absence of nucleoside triphosphates, nuclease activity is markedly stimulated by ATP, dATP, or CTP. WRN exonuclease digests DNA with a 3' --> 5' directionality to generate 5'-dNMP products, and DNA strands terminating with either a 3'-OH or 3'-PO4 group are hydrolyzed to similar extents. A recessed DNA strand with a single 3'-terminal mismatch is hydrolyzed more efficiently by WRN than one with a complementary nucleotide, but the enzyme fails to hydrolyze a DNA strand terminating with two mismatched bases. WRN exonuclease is distinguished from known mammalian DNA nucleases by its covalent association with a DNA helicase, preference for a recessed DNA strand, stimulation by ATP, ability to equally digest DNA with 3'-OH or 3'-PO4 termini, and its preferential digestion of DNA with a single 3'-terminal mismatch.

Mechanisms of cellular senescence

Aging is a near universal process, yet the molecular mechanisms that underlie cellular senescence have remained elusive. Recent progress in determining the roles of various genetic influences in controlling the rate of cellular aging has made this an exciting time in aging research. Genetic screens designed to isolate long-lived mutants in Saccharomyces cerevisiae and Caenorhabditis elegans have implicated factors involved in transcriptional silencing and the dauer pathway in the control of aging. The gene responsible for Werner's syndrome, a disease with symptoms of premature aging, was isolated and found to be a member of the RecQ subfamily of DNA helicases. The regulation of telomere length and its role in senescence and cellular immortalization has been found to be more complex than expected. In C. elegans, mutations have been isolated in maternal-effect genes that presumably control its biological clocks and can dramatically extend its lifespan. Indeed, aging research within the past year has implicated a variety of mechanisms ranging from the control of gene expression, stress resistance, and DNA metabolism to the overall 'rate of living'.

Positional cloning of the Werner's syndrome gene

Werner's syndrome (WS) is an inherited disease with clinical symptoms resembling premature aging. Early susceptibility to a number of major age-related diseases is a key feature of this disorder. The gene responsible for WS (known as WRN) was identified by positional cloning. The predicted protein is 1432 amino acids in length and shows significant similarity to DNA helicases. Four mutations in WS patients were identified. Two of the mutations are splice-junction mutations, with the predicted result being the exclusion of exons from the final messenger RNA. One of the these mutations, which results in a frameshift and a predicted truncated protein, was found in the homozygous state in 60 percent of Japanese WS patients examined. The other two mutations are nonsense mutations. The identification of a mutated putative helicase as the gene product of the WS gene suggests that defective DNA metabolism is involved in the complex process of aging in WS patients.

Potential for pharmacological intervention in Werner syndrome

Werner syndrome is a rare genetic disease of premature aging which manifests itself in the form of a variety of aging-like phenomena and diseases. It is an appropriate target for aging research because it is clear that the complications must be caused by one original gene defect. Another reason why this disease is of particular interest is observed at the cellular level. The abbreviated lifespan of cultured fibroblasts from patients with this disorder parallels the clinical features of this accelerated aging disease. Recent studies have met with some success in identifying certain genes involved in Werner syndrome and the roles they might play in normal cellular senescence. Such advances might result in a therapeutic breakthrough for this essentially incurable genetic disease. In addition, such a treatment might find some application in the control of the normal aging process.

Genetic control of intrachromosomal recombination

Intrachromosomal recombination between direct repeats can occur either as gene conversion events, which maintain exactly the number of repeat units, or as deletions, which reduce the number of repeat units. Gene conversions are classical recombination events that utilize the standard chromosome recombination machinery. Spontaneous deletions between direct repeats are generally recA-independent in E. coli and RAD52-independent in S. cerevisiae. This independence from the major recombination genes does not mean that deletions form through a nonrecombinational process. Deletions have been suggested to result from sister chromatid exchange at the replication fork in a recA-independent process. The same type of exchange is proposed to be RAD52-independent in Saccharomyces cerevisiae. RAD52-dependent events encompass all events that involve the initial steps of a recombination reaction, which include strand invasion to form a heteroduplex intermediate.

Overexpression of plasminogen activator inhibitor type-1 in senescent fibroblasts from normal subjects and those with Werner syndrome

We previously reported that plasminogen activator inhibitor type-1 (PAI-1) mRNA was present at higher steady-state levels in prematurely senescent fibroblasts derived from a subject with Werner syndrome (WS) compared to early passage (EP) fibroblasts from an age-matched normal subject (Murano et al., 1991, Mol. Cell. Biol. 11:3905-3914). To explore the generally of this phenomenon with respect to chronological age of donor (in vivo aging) and the late-passage (LP) or senescent phase of the fibroblast replicative lifespan, we assayed PAI-1 mRNA in cells and PAI-1 antigen in medium conditioned by 20 normal fibroblast strains at EP and LP and six WS strains during their curtailed replicative lifespans. The lowest accumulations of PAI-1 were found in medium conditioned by fetal and newborn cells with a shallow but progressive rise seen in postnatal cells from normal donors of increasing chronological age. With few exceptions, normal LP fibroblasts showed increased PAI-1 accumulations in medium compared to their EP counterparts. Conditioned medium from four of the six WS strains showed PAI-1 accumulations that were significantly higher than the media of any normal controls at EP and LP. PAI-1 mRNa levels were generally commensurate with the cumulative amount of PAI-1 in the medium but the frequent exceptions indicate that translational and post-translational mechanisms also regulate PAI-1 output. The augmentation in PAI-1 output of fibroblasts as a direct function of chronological age and during in vitro senescence suggests that PAI-1 may play an important role in the reduced capacity for wound healing and the increasing tendency to thrombogenesis and atherogenesis seen during biological aging and in particular in persons with Werner syndrome.

Hypermutable ligation of plasmid DNA ends in cells from patients with Werner syndrome

Werner Syndrome is a rare autosomal recessive disorder characterized by an increased cancer risk and by symptoms suggestive of premature aging. Cells from these patients demonstrate a typical pattern of chromosomal instability and a spontaneous hypermutability with a high rate of unusually large deletions. We have studied the in vivo DNA ligation in three lymphoblast cell lines from Werner syndrome patients and three from normal donors. In our host cell ligation assay we transfected linearized plasmid pZ189 and measured the amount of plasmid DNA ends rejoined by these host cells as the ability of the recovered plasmid to transform bacteria. A mutagenesis marker gene close to the ligation site allowed screening for mutations. Subsequent mutation analysis provided information about the accuracy of the ligation process. The cells from Werner syndrome patients were as effective as normal cells in ligating DNA ends. However, mutation analysis revealed that the three Werner syndrome cell lines introduced 2.4-4.6 times more mutations (p < 0.001) than the normal cell lines during ligation of the DNA ends: the mutation rates were 69.4, 97.2, and 58.7%, as compared to 23.6, 21.7, and 24.4% in the normal cell lines. These increased mutation frequencies in plasmids ligated during passage through Werner syndrome cells were mainly due to a significant (p < 0.001) increase in deletions. This error-prone DNA ligation might be responsible for the spontaneous hypermutability and the genomic instability in Werner syndrome cells and related to the apparently accelerated aging and high cancer risk in affected patients.

Spontaneous and induced homologous recombination between lacZ chromosomal direct repeats in CV-1 cells

A lacZ substrate for intrachromosomal homologous recombination was generated at a specific site within the genome of CV-1 cells by FLP recombinase-mediated gene targeting. A histochemical stain was used to detect cells that contained recombined lacZ genes. The spontaneous rate of homologous recombination was approximately 1 x 10(-5) events per cell generation. Recombination was induced 30-fold in cells following exposure to mitomycin C (MMC) and by serum starvation. These results demonstrate the utility of the FLP recombinase in modifying the genome of mammalian cells in a predetermined manner and show that homologous recombination between direct repeats is increased in cells as a result of the withdrawal of serum growth factors.

Werner syndrome and biological ageing: a molecular genetic hypothesis

Werner syndrome (WS) is an inherited disorder that produces somatic stunting, premature ageing and early onset of degenerative and neoplastic diseases. Cultured fibroblasts derived from subjects with WS are found to undergo premature replicative senescence and thus provide a cellular model system to study the disorder. Recently, several overexpressed gene sequences isolated from a WS fibroblast cDNA library have been shown to possess the capacity to inhibit DNA synthesis and disrupt many normal biochemical processes. Because a similar constellation of genes is overexpressed in WS and senescent normal fibroblasts, these data suggest the existence of a common molecular genetic pathway for replicative senescence in both types of cell. We propose that the primary defect in WS is a mutation in a gene for a trans-acting repressor protein that reduces its binding affinity for shared regulatory regions of several genes, including those that encode inhibitors of DNA synthesis (IDS). The mutant WS repressor triggers a sequence of premature expression of IDS and other genes, with resulting inhibition of DNA synthesis and early cellular senescence, events which occur much later in normal cells.

Impaired S-phase transit of Werner syndrome cells expressed in lymphoblastoid cell lines

The clinical phenotype of Werner's syndrome (WS) includes short stature, premature cataracts, skin atrophy, osteoporosis, graying and loss of hair, neoplasia, diabetes mellitus, and arteriosclerosis. Cultured cells from patients with this autosomal recessive disorder exhibit chromosomal instability and a markedly reduced replicative lifespan and growth rate. To elucidate the cell cycle alterations associated with the growth deficit, we continuously labeled lymphoid cell lines from five WS patients and from four healthy adult controls with 5-bromodeoxyuridine. Bivariate Hoechst 33258/ethidium bromide flow cytometry revealed a 2.4-h prolongation in the minimal duration of the S phase of WS cells (P less than 0.005). Moreover, the fraction of proliferating cells irreversibly arrested in the S phase (5.4% vs 1.4% in controls) was significantly elevated in WS (P less than 0.001). Other cell cycle compartments were not significantly affected in WS cell lines. As a partial test of the hypothesis that the WS phenotype is due to a defect in DNA topoisomerase I (topo I) or DNA topoisomerase II (topo II) we exposed lymphoid cells from a healthy control to the topo I inhibitor camptothecin or to the topo II inhibitor 4'-(9-acridinylamino)methanesulfon-m-anisidine. The cell kinetic alterations elicited by these compounds differed from that exhibited by untreated WS patients. Thus, a primary defect in topo I or II is unlikely in WS. Our cell cycle results, however, provide important evidence that the biochemical genetic lesion is in fact expressed in lymphoblastoid cell lines, the most readily available cells from such subjects.

Insulin-like growth factor binding protein 3 accumulates to high levels in culture medium of senescent and quiescent human fibroblasts

Insulin-like growth factor binding protein 3 (IGFBP-3) mRNA levels were consistently higher in both senescent normal human diploid fibroblasts (HDFs) at late passage (old cells) and prematurely senescent HDFs from a subject with Werner syndrome (WS) during serum depletion and repletion of growth medium and during proliferation from sparse to high-density inhibited cultures, compared to normal early-passage (young) HDFs. However, IGFBP-3 protein accumulated to higher levels in conditioned medium of old cells than in medium of WS and young cells, in that order, under the same conditions. Insulin-like growth factor I (IGF-I) was not detected in naive medium or in any of the media conditioned by these three cell types, whereas IGF-II was detectable in serum-repleted medium and remained relatively constant. Thus, molar ratios of IGFBP-3/IGF-II were consistently higher in old and WS cells and increased substantially as all three cell types became quiescent, due to either serum depletion or high cell density. These data are consistent with either an adaptive or a causal role for IGFBP-3 protein in the senescent and quiescent growth arrest of HDFs.

Diverse gene sequences are overexpressed in werner syndrome fibroblasts undergoing premature replicative senescence

Genes that play a role in the senescent arrest of cellular replication are likely to be overexpressed in human diploid fibroblasts (HDF) derived from subjects with Werner syndrome (WS) because these cells have a severely curtailed replicative life span. To identify some of these genes, a cDNA library was constructed from WS HDF after they had been serum depleted and repleted (5 days in medium containing 1% serum followed by 24 h in medium containing 20% serum). Differential screening of 7,500 colonies revealed 102 clones that hybridized preferentially with [32P]cDNA derived from RNA of WS cells compared with [32P]cDNA derived from normal HDF. Cross-hybridization and partial DNA sequence determination identified 18 independent gene sequences, 9 of them known and 9 unknown. The known genes included alpha 1(I) procollagen, alpha 2(I) procollagen, fibronectin, ferritin heavy chain, insulinlike growth factor-binding protein-3 (IGFBP-3), osteonectin, human tissue plasminogen activator inhibitor type I, thrombospondin, and alpha B-crystallin. The nine unknown clones included two novel gene sequences and seven additional sequences that contained both novel segments and the Alu class of repetitive short interspersed nuclear elements; five of these seven Alu+ clones also contained the long interpersed nuclear element I (KpnI) family of repetitive elements. Northern (RNA) analysis, using the 18 sequences as probes, showed higher levels of these mRNAs in WS HDF than in normal HDF. Five selected mRNAs studied in greater detail [alpha 1(I) procollagen, fibronectin, insulinlike growth factor-binding protein-3, WS3-10, and WS9-14] showed higher mRNA levels in both WS and late-passage normal HDF than in early-passage normal HDF at various intervals following serum depletion/repletion and after subculture and growth from sparse to high-density confluent arrest. These results indicate that senescence of both WS and normal HDF is accompanied by overexpression of similar sets of diverse genes which may play a role in the senescent arrest of cellular replication and in the genesis of WS, normal biological aging, and attendant diseases.

Diverse gene sequences are overexpressed in werner syndrome fibroblasts undergoing premature replicative senescence

Genes that play a role in the senescent arrest of cellular replication are likely to be overexpressed in human diploid fibroblasts (HDF) derived from subjects with Werner syndrome (WS) because these cells have a severely curtailed replicative life span. To identify some of these genes, a cDNA library was constructed from WS HDF after they had been serum depleted and repleted (5 days in medium containing 1% serum followed by 24 h in medium containing 20% serum). Differential screening of 7,500 colonies revealed 102 clones that hybridized preferentially with [32P]cDNA derived from RNA of WS cells compared with [32P]cDNA derived from normal HDF. Cross-hybridization and partial DNA sequence determination identified 18 independent gene sequences, 9 of them known and 9 unknown. The known genes included alpha 1(I) procollagen, alpha 2(I) procollagen, fibronectin, ferritin heavy chain, insulinlike growth factor-binding protein-3 (IGFBP-3), osteonectin, human tissue plasminogen activator inhibitor type I, thrombospondin, and alpha B-crystallin. The nine unknown clones included two novel gene sequences and seven additional sequences that contained both novel segments and the Alu class of repetitive short interspersed nuclear elements; five of these seven Alu+ clones also contained the long interpersed nuclear element I (KpnI) family of repetitive elements. Northern (RNA) analysis, using the 18 sequences as probes, showed higher levels of these mRNAs in WS HDF than in normal HDF. Five selected mRNAs studied in greater detail [alpha 1(I) procollagen, fibronectin, insulinlike growth factor-binding protein-3, WS3-10, and WS9-14] showed higher mRNA levels in both WS and late-passage normal HDF than in early-passage normal HDF at various intervals following serum depletion/repletion and after subculture and growth from sparse to high-density confluent arrest. These results indicate that senescence of both WS and normal HDF is accompanied by overexpression of similar sets of diverse genes which may play a role in the senescent arrest of cellular replication and in the genesis of WS, normal biological aging, and attendant diseases.