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The Bh3 Domain of Puma: Structure Determination and Small Molecular Inhibitor Design. Nicki Zevola Bahar Lab Lab Meeting March 25, 2009. Intro. What are BCl-2 proteins?. 1. A class of pro-survival and pro-apoptotic proteins Easily distinguishable
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The Bh3 Domain of Puma:Structure Determination and Small Molecular Inhibitor Design Nicki Zevola Bahar Lab Lab Meeting March 25, 2009
Intro. What are BCl-2 proteins? 1 • A class of pro-survival and pro-apoptotic proteins • Easily distinguishable • Pro-survival: BclXL, Bcl-w, MCl-1, A1, Bax, Bak • 2-4 BH domains • Pro-apoptotic: Bim, Bad, Bmf, Bid, Bik, Hrk, Noxa, Puma • Only 1 BH domain, Bh3 • Key interactions occur when pro-apoptotic proteins (e.g., Puma) inhibit pro-survival proteins (e.g., BclXL) 3 2 Crystal structure of BCl-xl (mouse) 1 Crystal structure of Puma (mouse)
Goal of Project: Develop small molecule mitochondrial-targeted drugs to inhibit the binding of the Puma Bh3 domain to Bcl-2 family proteins. Normally, Puma Bh3 domain:Bcl-2 protein binding antagonizes anti-apoptotic Bcl-2 proteins, inhibiting Apaf-1, and resulting in caspase release and apoptosis. Studies with Puma-deficient mice have shown that Puma not only activates, but is required for, apoptosis induced by oncogenes and DNA-damaging agents.1,2 Project Overview 1Qui et. al. PUMA Regulates Intestinal Progenitor Cell Radiosensitivity and Gastrointestinal Syndrome. Cell Stem Cell. 2008. 2(6):576-583. 2 Yu J., Zhang L., Hwang PM, Kinzler K.W., Vogelstein B. Puma induces the rapid apoptosis of colorectal cancer cells. Mol. Cell.2001. 7:3:673-82.
How We Will Find Small Molecular Inhibitors for Puma (Project Design) Analyze structure of Bh3 domain of Puma Determine key conserved interactions between Puma Bh3 domain and Bcl-2 proteins Develop pharmacophore models using conserved interactions Screen Zinc 8.0 database for lead-like compounds that match pharmacophore model Develop Puma models to prioritize hits In vitro testing
Day et. al.: How Puma Bh3 Domain Bh3-Mcl1 and Noxa Bh3-Mcl1 Structures were Obtained • 1. Two samples made • 1. 13C, 15N-labeled peptide + unlabeled Mcl-1 • 2. Unlabeled peptide + labeled Mcl-1 • 2. NMR techniques used for resonance assignments • 3. Structures evaluated for proper geometry • No distance violation > 0.2 Å • No angle violation > 5o (2rod) (2roc) • Why only the Bh3 Domain of Puma, Noxa with Mcl-1? • Puma and Noxa have extremely unstable structures, and hence only the Bh3 binding domain structure has been accurately determined. In the Bahar lab, we have used the i-Tasser server (Zhang) to help ascertain the entire Puma structure (see next slide).
i-Tasser • Sequence of hPUMA submitted to online server developed by Dr. Yang Zhang, Ph.D. (University of Kansas) • Finalist at CASP (Critical Assessment of Structural Predictions) Competition • Server uses LOMETS (a form of threading) in structural prediction • 5 models generated for hPuma • Problem: Best C-score: -3.46 • Will be addressed later
Step 2. Determine key conserved interactions between Puma Bh3 domain and BCl-2 proteins
Day et. al.: Comparison of MCl-1 complexes with other BCl-2 proteins • 1. Superimposition of Mcl-1:Puma with: • BClXL:Bim, • A1:Puma, • and BclXL • RMSD of backbone BClXL:Bim and Mcl-1: Puma: 1.5 Å • Most notable structural difference: BclXLhas a long loop between α1 and α2 not found in Mcl-1 or A1
Day et. al.: Comparison of Mcl-1 complexes with other Bcl-2 proteins (con’t) • 2. Structural Alignment • Sequence comparison (excluding BclXL loop residues): • BclXL,Mcl-1: 25.6% identity, 40.0% similarity • A1, Mcl-1: 25.4% identity, 46.% similarity
Day et. al.: The Consensus Bh3 Domain Binding Motif • The 13 residue consensus sequence that defines the Bh3 domain in PUMA is: φ1ΣXXφ2XXφ3ΣDZφ4L • where φ1-φ4 are hydrophobic residues • Σ are small residues • Z is usually an acidic residue • L is a hydrophilic residue capable of forming an intermolecular cap • D is the conserved aspartate Bh3 domains of Noxa (in yellow, left) and Puma (in pink,right).
in situ Mutagenesis Reveals Other Key Residues (Yu et. al., 2009) • Already known from Day et. al.: conserved interactions with Bcl2 proteins • Jian Yu et. al. (Univ. of Pittsburgh): 2 specific point mutations alter binding specificity upstream of the Bh3 binding domain! • These are therefore included in our pharmacophore model (next step) Images courtesy Gabriela Mustata, Ph.D.
Step 3. Develop pharmacophore models using conserved interactions
Pharmacophore Model Development • Our superimposition of our hPuma-A1 (from i-Tasser) with hPUMA-Mcl1 (from 2roc) structures resulted in an RMSD of 0.55Å! • Four key interactions of Bcl2 proteins and hPuma (see next slide): • Phe251.CB (Bcl2) – Leu141.CD1 (hPuma) • Ph395.CD1 (Bcl2) – Leu141.CD1 (hPuma) • Asp237.OD2 (Bcl2) – Asp142.NH1 (hPuma) • Arg244.NE (Bcl2) – Asp146.OD1 (hPuma)
Pharmacophore Model Development Slide courtesy Dr. Gabriela Mustata, Ph.D.
Step 4. Screen Zinc 8.0 database for compounds that match pharmacophore model
Pharmacophore Search Results Thus Far • Zinc 7.0 Lead-like Database • Found 1 hit • Zinc 8.0 Lead-like Database • So far…Screened 24/37 of database (about 1.3 x 106 compounds) • Found 20 hits thus far (some shown below)
Current Problem: i-Tasser model • 5 models of hPuma generated by i-Tasser are not entirely satisfactory, as shown by Fast Contact server (Camacho et. al.) • Current solution: Use MD Simulations for energy minimization of i-Tasser models, recalculate energies on Fast Contact server
Questions? Ideas? Comments? A special thank you: Dr. Ivet Bahar; Dr. Gabriela Mustata; Dr. Jian Yu; Dr. Joel Greenberger; Ahmet Bakan (for teaching MD Simulations); everyone else for listening,