This project is part of a long-standing collaboration with the laboratory of Dr. Ettore Appella (LCB/NCI), in which the Wip1 protein was discovered. Initial characterization resulted in determining two classes of phosphorylated substrates, involving many proteins involved in cell growth regulation. The first has a diphosphorylated sequence motif (pT-X-pY), such as in p38 MAP Kinase, while the second has a mono-phosphorylated sequence motif (p(S/T)Q), such as in the p53, Chk1/2 and ATM proteins. By development of an atomic-scale computer model of the extended active site of Wip1 and a series of mutagenesis experiments, we were able to reveal the structural basis for the range of substrate specificity. This lead to the development of a cyclic peptide molecule that competitively inhibits Wip1, the first inhibitor of any kind for this family of enzymes. We then pursued development of a more drug-like, small molecule inhibitor in collaboration with Dr. Daniel Appella (LBC/NIDDK), who specializes in synthetic chemistry. The resultant small molecule is based on a pyrrole ring scaffold, with 5 different emanating sidechains to mimic the amino acids of the cyclic peptide. While successful, the final inhibition constant was still only in the low micromolar range. To further this effort, we returned to optimizing the cyclic peptide inhibitor. By multiple iterations of design and testing, we were able to drastically increase the binding affinity, resulting in an inhibition constant of 110 nM. The structural modeling involved in this process revealed both important new interactions in the extended active site, and the role of the proximal B-loop in binding substrate and regulating activity. Since the B-loop is unique to the Wip1 member of the PP2C family, its role was previously unknown. We are now applying these lessons to designing a new generation of pyrrole-based inhibitors. We are also pursuing generating sufficient Wip1 protein to determine the structure by X-ray crystallography, which will greatly aid in inhibitor optimization. Recently, we have verified the requirement of binding a 3rd magnesium ion for activity of Wip1 and the related PP2Ca homologue, and used deuterium exchange mass spectroscopy to study the functional conformational changes. We are currently determining the crystal and NMR structures of PP2Ca/cyclic peptide inhibitor complexes. Recently we used Deuterium Exchange Mass Spectroscopy to study the functional structural changes of Wip1 and the PP2Ca homologue. We have also determine the crystal structure of PP2Ca with a bound substrate.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Investigator-Initiated Intramural Research Projects (ZIA)
Project #
1ZIABC011379-08
Application #
9779878
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
8
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Basic Sciences
Department
Type
DUNS #
City
State
Country
Zip Code
Mazur, Sharlyn J; Gallagher, Elyssia S; Debnath, Subrata et al. (2017) Conformational Changes in Active and Inactive States of Human PP2C? Characterized by Hydrogen/Deuterium Exchange-Mass Spectrometry. Biochemistry 56:2676-2689
Tanoue, Kan; Miller Jenkins, Lisa M; Durell, Stewart R et al. (2013) Binding of a third metal ion by the human phosphatases PP2C? and Wip1 is required for phosphatase activity. Biochemistry 52:5830-43
Hayashi, Ryo; Tanoue, Kan; Durell, Stewart R et al. (2011) Optimization of a cyclic peptide inhibitor of Ser/Thr phosphatase PPM1D (Wip1). Biochemistry 50:4537-49