Abstract
Werner syndrome (WS) is a premature aging disorder characterized by genomic instability. The WRN gene defective in WS encodes a protein with both helicase and exonuclease activities that interacts with proteins implicated in DNA metabolism. To understand its genetic functions, we examined the ability of human WRN to rescue phenotypes associated with sgs1, the sole RecQ helicase in Saccharomyces cerevisiae. WRN failed to rescue sgs1 sensitivity to the DNA damaging agent methylmethane sulfonate or replication inhibitor hydroxyurea, suggesting divergent functions of human and yeast RecQ helicases. However, physiological expression of WRN in sgs1 top3 restored top3 slow growth phenotype, whereas no effect on growth was observed with wild-type or sgs1 strains. Slow growth of WRN-transformed sgs1 top3 correlated with an elevated population of large-budded cells with undivided nuclei, indicating restoration of cell cycle delay in late S/G2 characteristic of top3. WRN helicase but not exonuclease activity was genetically required for restoration of top3 growth phenotype, demonstrating separation of function of WRN catalytic activities. A naturally occurring missense polymorphism in WRN that interferes with helicase activity abolished its ability to restore top3 slow growth phenotype. Proposed roles of WRN in genetic pathways important for the suppression of genomic instability are discussed.
Highlights
Understanding the genetic pathways of the Werner syndrome protein (WRN) helicase-exonuclease has posed a complex challenge to researchers
Since it has been proposed that Top3 may be an evolutionarily conserved partner of RecQ helicases, we examined if the expression of WRN could substitute for Sgs1 and confer slow growth in the sgs1 top3 background. sgs1 top3 double mutant cells transformed with YEp112SpGAL or YEp112SpGAL–WRN were streaked onto plates containing SC minus Trp media with 2% gal
Expression of WRN-R834C (Figure 4B) demonstrated comparable growth to that of sgs1 top3/vector (Figure 4D). These results demonstrate that the WRN-R834C polymorphism, similar to the K577M and K1016A mutations that interfere with WRN helicase activity, www.impactaging.com interfere with WRN function in the sgs1 top3 background
Summary
Understanding the genetic pathways of the WRN helicase-exonuclease has posed a complex challenge to researchers. Studies of WRN-deficient cell lines have provided evidence for a role of WRN in the response to replicational stress through a recombinational repair pathway [1, 2]; the precise molecular functions and protein interactions required for WRN to help cells proliferate, maintain genomic stability, and deal with endogenous or exogenously induced DNA damage are not well understood. To investigate the genetic functions of WRN in a defined setting, we have developed a yeast-based model system to study the functional requirements of WRN in pathways that are conserved between yeast and human. Sgs mutants exhibit sensitivity to DNA damaging agents or replication www.impactaging.com
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