Type of Document Dissertation Author Zhao, Song Author's Email Address email@example.com URN etd-01122008-105708 Title Part 1 Design, Synthesis and Bioactivity of a Phosphorylated Prodrug for the Inhibition of Pin1 Part 2 Conformational Specificity of Cdc25c Substrate for Cdc2 Kinase using LC-MS/MS Degree PhD Department Chemistry Advisory Committee
Advisor Name Title Etzkorn, Felicia A. Committee Chair Carlier, Paul R. Committee Member Castagnoli, Neal Jr. Committee Member Kingston, David G. I. Committee Member Taylor, Larry T. Committee Member Keywords
- cell cycle
Date of Defense 2007-12-17 Availability unrestricted AbstractThe phosphorylation-dependent PPIase (peptidyl prolyl isomerase), Pin1 (Protein interacting with NIMA#1), has been found to regulate cell cycle through a simple conformational change, the cis-trans isomerization of phospho-Ser/Thr-Pro amide bonds. A variety of key cell cycle regulatory phosphoproteins, including Cdc25 phosphatase,Cdc27, p53 oncogene, c-Myc oncogene, Wee1 kinase, Myt1 kinase, and NIMA kinas, have been confirmed as substrates of Pin1. Pin1 was also observed to be overexpressed in a variety of cancer cell lines, and the inhibitors of Pin1 showed antiproliferative activities towards these cancer cells. These results implied that Pin1 might serve as a potential anti-cancer drug target. Besides, Pin1 has an important neuroprotective function and represents a potential new therapeutic agent for Alzheimer’s disease.
In order to understand the interaction between Pin1 and Cdc25c and the role of Pin1 in the mechanism for the regulation of mitosis, two amide isosteres, Ser-Ψ[(Z)CH=C]-Pro-OH and Ser-Ψ[(E)CH=C]-Pro-OH were incorporated into two peptidomimetics derived from human Cdc25c. Phosphorylation of these two peptidomimetics by the incubation with Cdc2 was studied using LC-MS/MS technique. It was found that Cdc2 kinase was conformationally specific to its Cdc25c substrate. Only the trans conformer of Cdc25c at its Ser168-Pro position can be recognized and phosphorylated by Cdc2 kinase, thereby creating the binding site for Pin1.
In an effort to improve the cell permeability of the charged inhibitors of Pin1, bisPOM (pivaloyloxymethyl) prodrug moiety was introduced to mask the phosphate group of Fmoc-pSer-Ψ[(Z)CH=C]-Pro-(2)-N-(3)-ethylaminoindole, which is one inhibitor of Pin1. Fmoc-pSer-Ψ[(Z)CH=C]-Pro-(2)-N-(3)-ethylaminoindole and its bisPOM prodrug were synthesized efficiently starting with Boc-Ser-Ψ[(Z)CH=C]-Pro-OH in 24% and 12% yields respectively. The charged inhibitor showed a moderate inhibition towards Pin1 (IC50 = 28.3 μM). Its antiproliferative activity towards A2780 ovarian cancer cells (IC50 = 46.2 μM) was significantly improved by its bisPOM prodrug (IC50 = 26.9 μM), which is comparable to the IC50 of the charged inhibitor towards Pin1 enzymatic activity. These results not only established the bisPOM strategy as an efficient prodrug choice for Pin1 inhibitors, but also added additional evidence for Pin1 as a potential anticancer drug target.
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