Late stage assay provider results from the probe development effort to identify inhibitors of LYPLA1: fluorescence-based biochemical gel-based Activity-Based Protein Profiling (ABPP) IC50 for anti-target ABHD11 Set 2
Name: Late stage assay provider results from the probe development effort to identify inhibitors of LYPLA1: fluorescence-based biochemical gel-based Activity-Based Protein Profiling (ABPP) IC50 for anti-target ABHD11 Set 2. ..more
BioActive Compounds: 3
Source (MLPCN Center Name): The Scripps Research Institute Molecular Screening Center (SRIMSC)
Center Affiliation: The Scripps Research Institute (TSRI)
Assay Provider: Benjamin Cravatt, TSRI
Network: Molecular Libraries Probe Production Centers Network (MLPCN)
Grant Proposal Number: 1 R01 CA132630
Grant Proposal PI: Benjamin Cravatt, TSRI
External Assay ID: ABHD11_INH_GEL_3XIC50_SET2
Name: Late stage assay provider results from the probe development effort to identify inhibitors of LYPLA1: fluorescence-based biochemical gel-based Activity-Based Protein Profiling (ABPP) IC50 for anti-target ABHD11 Set 2.
Protein palmitoylation is an essential post-translational modification necessary for trafficking and localization of regulatory proteins that play key roles in cell growth and signaling. Numerous proteins have been identified as targets of palmitoylation, including cytoskeletal proteins, kinases, receptors, and other proteins involved in various aspects of cellular signaling and homeostasis (1). Using a global chemo-proteomic method for the metabolic incorporation and identification of palmitoylated proteins, we were able to identify hundreds of palmitoylated proteins, revealing palmitoylation as a widespread post-translational modification (PTM) (2). Palmitoylation involves an acyl-thioester linkage to specific cysteines (3,4). Given the labile properties of thioesters, palmitoylation is potentially reversible and may be regulated in a manner analogous to other PTMs (e.g., phosphorylation). As such, identification of proteins responsible for the dynamic modulation of palmitoylation is paramount to understanding its patho/physiological roles. For example, multiple oncogenes, including HRAS and SRC, require palmitoylation for malignant transformation (5), suggesting protein palmitoyl thioesterases may have tumor suppressor activity required to repress aberrant growth signaling. More than a decade ago, the cytosolic serine hydrolase acyl-protein thioesterase 1 (APT1) was identified as an in vitro HRAS palmitoyl thioesterase (6). Initially classified as lysophospholipase 1 (LYPLA1) (7), the enzyme has since been demonstrated to have several hundred-fold higher activity as a protein thioesterase. While the in vitro data (6,8) provided an intriguing clue to its possible role in vivo, prior to our studies, little was known about the in vivo thioesterase activity of LYPLA1. Upon retroviral shRNA knockdown of LYPLA1, we found that HRAS was robustly hyper-palmitoylated, providing the first evidence that the endogenous enzyme is a functional protein palmitoyl thioesterase capable of regulating HRAS palmitoylation in mammalian cells. However, shRNA resulted in only an 80% reduction in LYPLA1 expression (unpublished). LYPLA2 (a.k.a. APT2) is 65% identical to LYPLA1, and also exhibits lysophospholipase activity in vitro, but its potential role as a thioesterase is unknown (9). shRNA knockdown studies of LYPLA2 revealed only partial knockdown of the enzyme, making substrate identification inconclusive (unpublished). A principle goal of post-genomic research is the determination of the molecular and cellular role of uncharacterized enzymes like LYPLA1 and LYPLA2. As such, a dual inhibitor selective for both LYPLA1 and LYPLA2 would greatly aid investigations into the biological function of these related enzymes. Several inhibitors of LYPLA1 have been described (10,11), but none of these agents have proven capable of inhibiting LYPLA1 activity in cells, and no selective inhibitors of LYPLA2 have been reported to date. To comprehensively identify LYPLA1 and LYPLA2 substrates and functionally test the role of these enzymes in dynamic de-palmitoylation and tumorigenesis, development of a high affinity inhibitor, capable of achieving temporal and more complete control over activity, is critical. Alpha/beta hydrolase domain-containing protein 11 (ABHD11) is a poorly characterized serine hydrolase; all that is known about its biology is that it is a mitochondrial enzyme (12) with broad tissue distribution, has little sequence homology to other proteins, and its gene is located in a region of chromosome 7 that is hemizygously deleted in Williams-Beuren syndrome, a rare genetic disease with symptoms that include vascular stenosis, mental retardation, and excessive sociability (13).
1. Smotrys, J.E. and Linder, M.E. PALMITOYLATION OF INTRACELLULAR SIGNALING PROTEINS: Regulation and Function. Annual Review of Biochemistry, 2004. 73: 559-587.
2. Martin, B.R. and Cravatt, B.F. Large-scale profiling of protein palmitoylation in mammalian cells. Nat Methods, 2009. 6: 135-138.
3. Magee, A.I., Koyama, A.H., Malfer, C., Wen, D. and Schlesinger, M. J. Release of fatty acids from virus glycoproteins by hydroxylamine. Biochimica et Biophysica Acta (BBA) - General Subjects, 1984. 798: 156-166.
4. Rose, J.K., Adams, G.A. and Gallione, C.J. The presence of cysteine in the cytoplasmic domain of the vesicular stomatitis virus glycoprotein is required for palmitate addition. Proc Natl Acad Sci USA, 1984. 81: 2050-2054.
5. Willumsen, B.M., Cox, A.D., Solski, P.A., Der, C.J. and Buss, J.E. Novel determinants of H-Ras plasma membrane localization and transformation. Oncogene, 1996. 13: 1901-1909.
6. Duncan, J.A. and Gilman, A.G. A Cytoplasmic Acyl-Protein Thioesterase That Removes Palmitate from G Protein alpha Subunits and p21RAS. J Biol Chem, 1998. 273: 15830-15837.
7. Sugimoto, H., Hayashi, H. & Yamashita, S. Purification, cDNA cloning, and regulation of lysophospholipase from rat liver. J Biol Chem, 1996. 271: 7705-7711.
8. Hirano, T. et al. Thioesterase activity and subcellular localization of acylprotein thioesterase 1/lysophospholipase 1. Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids, 2009. 1791: 797-805.
9. Toyoda, T., Sugimoto, H. and Yamashita, S. Sequence, expression in Escherichia coli, and characterization of lysophospholipase II. Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids, 1999. 1437: 182-193.
10. Biel, M., Deck, P., Giannis, A. and Waldmann, H. Synthesis and Evaluation of Acyl Protein Thioesterase 1 (APT1) Inhibitors. Chemistry - A European Journal, 2006. 12: 4121-4143.
11. Deck, P. et al. Development and Biological Evaluation of Acyl Protein Thioesterase 1 (APT1) Inhibitors. Angewandte Chemie International Edition, 2005. 44: 4975-4980.
12. Forner, F., et al., Quantitative proteomic comparison of rat mitochondria from muscle, heart, and liver. Mol. Cell. Proteomics, 2006. 5(4): p. 608-19.
13. Schubert, C., The genomic basis of the Williams-Beuren syndrome. Cell. Mol. Life Sci., 2009. 66(7): p. 1178-97.
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The purpose of this assay is to determine the IC50 values of powder samples of test compounds for ABHD11 inhibition in a complex proteome. In this assay, a fluorophosphonate-conjugated rhodamine (FP-Rh) activity-based probe is used to label ABHD11 in the presence of test compounds. The reaction products are separated by SDS-PAGE and visualized in-gel using a flatbed fluorescence scanner. The percentage activity remaining is determined by measuring the integrated optical density of the bands. As designed, test compounds that act as ABHD11 inhibitors will prevent enzyme-probe interactions, thereby decreasing the proportion of bound fluorescent probe, giving lower fluorescence intensity in the band in the gel.
Soluble proteome (1 mg/ml in DPBS) of BW5147-derived murine T cells was incubated with DMSO or compound for 30 minutes at 37 C before the addition of FP-Rh at a final concentration of 2 uM in 50 uL total reaction volume. The reaction was incubated for 30 minutes at 25 C, quenched with 2x SDS-PAGE loading buffer, separated by SDS-PAGE and visualized by in-gel fluorescent scanning. The percentage activity remaining was determined by measuring the integrated optical density of the bands. IC50 values for inhibition of ABHD11 were determined from dose-response curves from three replicates at each inhibitor concentration (7-point 1:3 dilution series from 0.3 uM to 0.0003 uM).
The % inhibition was then calculated as follows:
%_Inhibition = ( 1 - ( IOD_Test_Compound - MedianIOD_Low_Control ) / ( MedianIOD_High_Control - MedianIOD_Low_Control ) ) * 100
Test_Compound is defined as ABHD11 in proteome treated with test compound.
High_Control is defined as ABHD11 in proteome treated with DMSO only (no compound).
Low_Control is defined as background in a blank region of the gel.
For each test compound, percent inhibition was plotted against the log of the compound concentration. A four parameter equation describing a sigmoidal dose-response curve was then fitted using GraphPad Prism (GraphPad Software Inc). The software-generated IC50 values are reported.
PubChem Activity Outcome and Score:
Compounds with an IC50 less than 0.1 uM were considered active. Compounds with an IC50 greater than or equal to 0.1 uM were considered inactive.
Any compound with a percent activity value < 50% at all test concentrations was assigned an activity score of zero. Any compound with a percent activity value >= 50% at any test concentration was assigned an activity score greater than zero.
Activity score was then ranked by the potency of the compounds with fitted curves, with the most potent compounds assigned the highest activity scores.
The PubChem Activity Score range for active compounds is 100-1. There are no inactive compounds.
List of Reagents:
Soluble proteome of BW5147-derived murine T cells
FP-Rh (provided by the Assay Provider)
DPBS (Cellgro 20-031-CV)
Categorized Comment - additional comments and annotations
* Activity Concentration. ** Test Concentration.
Data Table (Concise)