Ashwini S Kamath-Loeb

Publications (9)46.2 Total impact

• Article: The Werner syndrome exonuclease facilitates DNA degradation and high fidelity DNA polymerization by human DNA polymerase δ.

  Ashwini S Kamath-Loeb, Jiang-Cheng Shen, Michael W Schmitt, Lawrence A Loeb
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  ABSTRACT: DNA Polymerase δ (Pol δ) and the Werner syndrome protein, WRN, are involved in maintaining cellular genomic stability. Pol δ synthesizes the lagging strand during replication of genomic DNA and also functions in the synthesis steps of DNA repair and recombination. WRN is a member of the RecQ helicase family, loss of which results in the premature aging and cancer-prone disorder, Werner syndrome. Both Pol δ and WRN encode 3' → 5' DNA exonuclease activities. Pol δ exonuclease removes 3'-terminal mismatched nucleotides incorporated during replication to ensure high fidelity DNA synthesis. WRN exonuclease degrades DNA containing alternate secondary structures to prevent formation and enable resolution of stalled replication forks. We now observe that similarly to WRN, Pol δ degrades alternate DNA structures including bubbles, four-way junctions, and D-loops. Moreover, WRN and Pol δ form a complex with enhanced ability to hydrolyze these structures. We also present evidence that WRN can proofread for Pol δ; WRN excises 3'-terminal mismatches to enable primer extension by Pol δ. Consistent with our in vitro observations, we show that WRN contributes to the maintenance of DNA synthesis fidelity in vivo. Cells expressing limiting amounts (∼10% of normal) of WRN have elevated mutation frequencies compared with wild-type cells. Together, our data highlight the importance of WRN exonuclease activity and its cooperativity with Pol δ in preserving genome stability, which is compromised by the loss of WRN in Werner syndrome.
  Journal of Biological Chemistry 02/2012; 287(15):12480-90. · 4.77 Impact Factor
• Article: XPG and WRN: an unexpected partnership.

  Ashwini S Kamath-Loeb, Lawrence A Loeb
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  ABSTRACT: Comment on: Trego KS, et al. Cell Cycle 2011; 10:1998-2007.
  Cell cycle (Georgetown, Tex.) 09/2011; 10(18):3051. · 5.36 Impact Factor
• Article: Werner syndrome gene variants in human sarcomas.

  Jessica J Hsu, Ashwini S Kamath-Loeb, Eitan Glick, Brett Wallden, Karen Swisshelm, Brian P Rubin, Lawrence A Loeb
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  ABSTRACT: Werner syndrome is an autosomal inherited disease that is characterized by premature aging. The gene mutated in Werner syndrome (WS), WRN, encodes both a 3' --> 5' DNA helicase and a 3' --> 5' DNA exonuclease. Among the WS phenotypes is an exceptionally high incidence of sarcomas. We asked whether spontaneous sarcomas, not known to be associated with WS, also harbor mutations or unreported single nucleotide polymorphisms (SNPs) in WRN. We analyzed RNA or DNA sequences within the helicase and exonuclease domains from 51 and 69 matched sarcoma and adjacent normal tissues, respectively. Among a total of 13 nucleotide variants detected, we identified three novel nonsynonymous substitutions: c.611C>T, c.809_810insT, and c.1882C>G. We further characterized one, c.611C>T, which results in substitution of an evolutionarily conserved proline at amino acid 204 in the exonuclease domain with leucine. We show that P204L WRN exhibits a reduction of WRN exonuclease activity; the specific activity is approximately 10-fold lower than that of wild-type WRN. In contrast, the helicase activity of P204L WRN is reduced less than twofold.
  Molecular Carcinogenesis 10/2009; 49(2):166-74. · 3.16 Impact Factor
• Article: The Werner syndrome protein binds replication fork and holliday junction DNAs as an oligomer.

  Sarah A Compton, Gökhan Tolun, Ashwini S Kamath-Loeb, Lawrence A Loeb, Jack D Griffith
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  ABSTRACT: Werner syndrome is an inherited disease displaying a premature aging phenotype. The gene mutated in Werner syndrome encodes both a 3' --> 5' DNA helicase and a 3' --> 5' DNA exonuclease. Both WRN helicase and exonuclease preferentially utilize DNA substrates containing alternate secondary structures. By virtue of its ability to resolve such DNA structures, WRN is postulated to prevent the stalling and collapse of replication forks that encounter damaged DNA. Using electron microscopy, we visualized the binding of full-length WRN to DNA templates containing replication forks and Holliday junctions, intermediates observed during DNA replication and recombination, respectively. We show that both wild-type WRN and a helicase-defective mutant bind with exceptionally high specificity (>1000-fold) to DNA secondary structures at the replication fork and at Holliday junctions. Little or no binding is observed elsewhere on the DNA molecules. Calculations of the molecular weight of full-length WRN revealed that, in solution, WRN exists predominantly as a dimer. However, WRN bound to DNA is larger; the mass is consistent with that of a tetramer.
  Journal of Biological Chemistry 08/2008; 283(36):24478-83. · 4.77 Impact Factor
• Source

  Available from: pnas.org

  Article: Werner syndrome protein interacts functionally with translesion DNA polymerases.

  Ashwini S Kamath-Loeb, Li Lan, Satoshi Nakajima, Akira Yasui, Lawrence A Loeb
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  ABSTRACT: Werner syndrome (WS) is characterized by premature onset of age-associated disorders and predisposition to cancer. The WS protein, WRN, encodes 3' --> 5' DNA helicase and 3' --> 5' DNA exonuclease activities, and is implicated in the maintenance of genomic stability. Translesion (TLS) DNA polymerases (Pols) insert nucleotides opposite replication-blocking DNA lesions and presumably prevent replication fork stalling/collapse. Here, we present in vitro and in vivo data that demonstrate functional interaction between WRN and the TLS Pols, Poleta, Polkappa, and Poliota. In vitro, WRN stimulates the extension activity of TLS Pols on lesion-free and lesion-containing DNA templates, and alleviates pausing at stalling lesions. Stimulation is mediated through an increase in the apparent V(max) of the polymerization reaction. Notably, by accelerating the rate of nucleotide incorporation, WRN increases mutagenesis by Poleta. In vivo, WRN and Poleta colocalize at replication-dependent foci in response to UVC irradiation. The functional interaction between WRN and TLS Pols may promote replication fork progression, at the expense of increased mutagenesis, and obviate the need to resolve stalled/collapsed forks by processes involving chromosomal rearrangements.
  Proceedings of the National Academy of Sciences 06/2007; 104(25):10394-9. · 9.68 Impact Factor
• Article: The first US-Japan meeting on error-prone DNA synthesis, Maui, Hawaii, December 20-21, 2004.

  Ashwini S Kamath-Loeb, Lawrence A Loeb, Yuji Masuda, Fumio Hanaoka
  DNA Repair 07/2005; 4(6):740-7. · 4.14 Impact Factor
• Article: The enzymatic activities of the Werner syndrome protein are disabled by the amino acid polymorphism R834C.

  Ashwini S Kamath-Loeb, Piri Welcsh, Maureen Waite, Elinor T Adman, Lawrence A Loeb
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  ABSTRACT: The Werner syndrome protein, WRN, is a member of the RecQ family of DNA helicases. It possesses both 3'-->5' DNA helicase and 3'-->5' DNA exonuclease activities. Mutations in WRN are causally associated with a rare, recessive disorder, Werner syndrome (WS), distinguished by premature aging and genomic instability; all are reported to result in loss of protein expression. In addition to WS-linked mutations, single nucleotide polymorphisms, with frequencies that exceed those of WS-associated mutations, are also present in WRN. We have initiated studies to determine if six of these polymorphisms affect the enzymatic activities of WRN. We show that two common polymorphisms, F1074L and C1367R, and two infrequent polymorphisms, Q724L and S1079L, exhibit little change in activity relative to wild-type WRN; the polymorphism, T172P, shows a small but consistent reduction of activity. However, an infrequent polymorphism, R834C, located in the helicase domain dramatically reduces WRN helicase and helicase-coupled exonuclease activity. The structure of the E. coli helicase core suggests that R834 may be involved in interactions with ATP. As predicted, substitution of Arg with Cys interferes with ATP hydrolysis that is absolutely required for unwinding DNA. R834C thus represents the first missense amino acid polymorphism in WRN that nearly abolishes enzymatic activity while leaving expression largely unaffected.
  Journal of Biological Chemistry 01/2005; 279(53):55499-505. · 4.77 Impact Factor
• Article: Werner Syndrome Protein

  Ashwini S. Kamath-Loeb, Jiang-Cheng Shen, Lawrence A. Loeb, Michael Fry
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  ABSTRACT: 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.
  Journal of Biological Chemistry 12/1998; 273(51):34145-34150. · 4.77 Impact Factor
• Article: Werner Syndrome Protein

  Jiang-Cheng Shen, Matthew D. Gray, Junko Oshima, Ashwini S. Kamath-Loeb, Michael Fry, Lawrence A. Loeb
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  ABSTRACT: Werner Syndrome (WS) is a human progeroid disorder characterized by genomic instability. The gene defective in WS encodes a 3′ → 5′ DNA helicase (Gray, M. D., Shen, J.-C., Kamath-Loeb, A. S., Blank, A., Sopher, B. L., Martin, G. M., Oshima, J., and Loeb, L. A.(1997) Nat. Genet. 17, 100–103). Sequence alignment analysis identified an N-terminal motif in WRN that is homologous to several exonucleases. Using combined molecular genetic, biochemical, and immunochemical approaches, we demonstrate that WRN also exhibits an integral DNA exonuclease activity. First, whereas wild-type recombinant WRN possesses both helicase and exonuclease activities, mutant WRN lacking the nuclease domain does not display exonucleolytic activity. In contrast, WRN proteins with defective helicase activity are active in exonucleolytic digestion of DNA. Second, the exonuclease co-purifies with the 160-kDa WRN protein and its associated DNA helicase and ATPase activities through successive steps of ion exchange and affinity chromatography, suggesting that all three activities are physically associated. Lastly, anti-WRN antiserum specifically co-precipitates the WRN helicase and exonuclease activities indicating that both activities reside on the same antigenic WRN polypeptide. The association of an exonuclease with WRN distinguishes it from other RecQ homologs and raises the possibility that the distinct phenotypic characteristics of WS may be due in part to a defective exonuclease.
  Journal of Biological Chemistry 12/1998; 273(51):34139-34144. · 4.77 Impact Factor