Progeroid syndromes mimic aging at an accelerated rate and are key to understanding both premature and normal aging. One class of progeroid syndromes results from defective DNA repair pathways. For example, Werner syndrome (WS)?a rare inherited disease characterized by premature aging and cancer?is caused by mutations in the DNA repair helicase WRN. WS patients closely recapitulate many normal aging phenotypes, making WS a model system for aging. However, the cellular and molecular mechanisms involved in WS pathologies remain poorly understood. Here, I propose to answer critical questions regarding the functions of WRN via an interdisciplinary approach that includes structural biology, single-molecule biochemistry, and cell biology. My career goal is to establish an independent research program dedicated to understanding the molecular and cellular mechanisms of genomic instability associated with aging and aging-related diseases. As a first step to achieving this goal, I have pursued postdoctoral training in single-molecule microscopy and biochemistry, complementing my background in structural biology and biophysical techniques. The mentoring phase of the K99/R00 award will provide me with additional training in cryo-electron microscopy, cell biology, telomere biology, and the biology of human aging through an expert group of mentors and advisors. Here I propose to: (1) Determine the molecular architecture of full-length WRN (2) Identify how the nuclease and helicase activities of WRN are regulated (3) Determine how WRN cooperates with telomeric proteins to unwind G-quadruplexes during telomere replication to prevent telomere loss, and (4) determine how WRN-deficiency leads to inflammation and premature cellular senescence. Completion of these aims will represent a major step forward in our understanding of WRN?s role in preventing genomic instability and will lay the groundwork for my long-term goals to determine the mechanisms of genome maintenance by other DNA repair enzymes and their importance in human aging and age-related pathologies. A K99/R00 award will allow me to establish an independent research program that will make me a strong candidate for a tenure-track position at a leading U.S. research institution. My work will provide important insights into how WRN and its interaction partners maintain our genomes and help us understand the biological consequences of WRN dysregulation. Furthermore, these studies will provide a more detailed understanding of how WRN-deficiency leads to accelerated aging phenotypes found in WS.
. Genome instability is one of the critical drivers of normal and premature aging. This proposal aims to dissect the role(s) of genome maintenance by the Werner syndrome helicase (WRN) and to determine how the loss of WRN results in the accelerated aging phenotypes found in Werner syndrome (WS) patients. Successful completion of the proposed aims will provide a deeper insight into the pathophysiology of WS and WRN?s roles in preventing genome instability and cellular senescence during normal aging .
