Much of the current effort in cancer biology is concentrated on studying either the cell growth and proliferation or the programmed cell death (apoptosis) pathways individually, and little is known about the coregulation of these two vital processes. Understanding processes and controls common to both cell proliferation and apoptosis would provide a new paradigm for identifying novel targets in the treatment of hematologic malignancies and other cancers. We propose that the processes of mitotic segregation and apoptosis are mechanistically linked and that proteins important for sister chromatid cohesion play a role in regulating normal apoptotic processes. Deregulation of this joint process can lead to formation and progression of hematologic cancers and development of therapy-resistant leukemia and lymphoma. Cohesin Rad21, a mitotic regulatory protein may play an important role in the interface between cell proliferation and apoptosis. Rad21 functions in chromosome segregation and DMA damage repair during cell proliferation but promotes cell death once apoptosis is induced. Our lab is one of two laboratories that have recently identified a novel role for Rad21 in apoptosis. To test the central hypothesis that mitotic segregation and apoptosis are linked processes, we will focus on specific roles of the cohesin protein Rad21 in apoptosis.
Our aims are (a) to identify the nuclear protease that cleaves Rad21 in the nucleus at the early stage of apoptosis induction and to elucidate its role in Rad21 -mediated apoptosis, (b) to identify proteins interacting with C-terminal Rad21 in the apoptotic pathway, and (c) to determine the pathways through which C-terminal Rad21 amplifies apoptotic signals and activates effector caspases in leukemia cell lines. The series of studies proposed will provide novel information about how mitotic proteins regulate apoptosis and their role in carcinogenesis. Understanding the details of cohesin cleavage and subsequent steps in the apoptotic cascade in leukemic cells is expected to lead to the identification of novel targets and strategies for the treatment of hematologic cancers. Furthermore, identification of the mechanism through which C- terminal Rad21 promotes programmed cell death will help explain why leukemic cells are able to evade and resist apoptosis and will aid the design of new strategies for treating chemotherapy-resistant leukemia. ? ?
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