This project focuses on ZMPSTE24, an intriguing integral membrane zinc metalloprotease important for human health and longevity. ZMPSTE24 plays a critical role in the proteolytic processing of the farnesylated CAAX protein prelamin A, precursor of the nuclear scaffold component lamin A. Mutations in the genes encoding either prelamin A or ZMPSTE24 that block cleavage cause the severe premature aging disorder Hutchinson- Gilford Progeria syndrome (HGPS) and a set of related progeroid diseases in which an aberrant permanently farnesylated form of lamin A is the ?molecular culprit? that promotes aging-related symptoms. Importantly, diminished prelamin A processing by ZMPSTE24 may also be a critical factor in normal physiological aging. My laboratory pioneered the study of ZMPSTE24 in the early years of this project. We discovered this protease in yeast, where it is called Ste24, and showed that it has two distinct proteolytic activities in the biogenesis of the mating pheromone a-factor (cleavage of the CAAX motif and a second upstream cleavage). Importantly, we demonstrated that mammalian ZMPSTE24 performs these same cleavages in prelamin A maturation. Through this sustained body of work, together with a powerful new humanized yeast system for prelamin A cleavage recently developed in my laboratory, and our recent work showing a quality control role for ZMPSTE24 in removing misfolded proteins from ?clogged? translocons, we have at our fingertips a full arsenal of tools, including a variety of biochemical and in vivo assays, cell lines, and disease alleles that will facilitate the proposed studies. The recently published structure of human ZMPSTE24 and the nearly superimposable yeast Ste24 revealed surprising features, defining ZMPSTE24/Ste24p as truly novel class of intramembrane proteases. The seven transmembrane spans of ZMPSTE24/Ste24p form a voluminous water- filled intramembrane chamber with the zinc metalloprotease catalytic site facing the chamber interior, so that substrate access is restricted and must occur through one of several side portals. One major challenge in the field is to establish how this novel intramembrane protease works. We propose to mechanistically dissect human ZMPSTE24 and its substrate prelamin A to define precisely how proteolysis of prelamin A occurs inside of an intramembrane chamber. We will identify features of ZMPSTE24 and prelamin A important for substrate recognition, entry, binding, catalysis, and product release, and will determine the step at which ZMPSTE24 and lamin A disease alleles malfunction. We will also deploy powerful designer screens possible in yeast to identify new Ste24 substrates that may shed light on its mechanism. We will begin an exciting new series of studies aimed at exploring a second major challenge, namely whether and how diminished ZMPSTE24 activity and prelamin A accumulation may drive physiological aging. Together, these studies will reveal fundamental principles relevant to intramembrane protease biology, premature aging, and normal physiological aging. 1
As our population ages, understanding the molecular mechanisms involved in aging becomes ever more critical for the prevention and treatment of aging-related disorders. The subject of this research project, a protease called ZMPSTE24, is critical for healthy aging; mutations that alter ZMPSTE24 or its substrate prelamin A, result in the premature aging disease progeria. By combining the many biochemical and cell biological tools we have developed over the years since we discovered this enzyme with exciting new structural advances, we are poised to gain a precise view of how ZMPSTE24 works, which in turn could help children with progeria and importantly will provide insights into the normal aging process. 1
