SBIR-STTR Award

Protein kinases serve as critical mediators of signal transduction in human cells and impact virtually all aspects of cellular physiology, from the coordination of the cell cycle and cell division to apoptosis. The deregulation of kinase mediated signaling is now known to be involved in a variety of human diseases that include, diabetes, inflammation, cardiovascular diseases, tumor cell proliferation and metastasis making them a target for drug development. Structurally, kinases share a very similar architecture at the active-site (ATP-binding domain), making selectivity an issue in drug discovery and development. Thus, the development of rapid and economic methods for profiling drug candidates against a large panel of kinases in whole cells will not only aid in anticipating potential long term toxicit, but also help in understanding kinase targeted polypharmacology and aid in identifying new targets for old compounds. In this Phase I application, we will develop a split-luciferase based luminescent assay for kinase profiling in a cellular setting. These cell-based assays will meet a critical need for directly monitoring the effect of compounds on a target kinase not only to ascertain cell-permeability and cellular toxicity, but also to establish efficacy in the cellular mlieu in the presence of adaptor and regulatory proteins. We will test the generality of the approach for kinases across various groups and evaluate the feasibility of our assay for high throughput screening using a panel of 80 known kinase inhibitors. Our goal is to make cellular kinase profiling assays both easily available and affordable, so that compound profiling in a cellular or native context can be done earlier and thereby lead to early identification of failures, resulting n many more opportunities for success.

Thesaurus Terms:
Active Sites;Adaptor Signaling Protein;Apoptosis;Architecture;Base;Binding (Molecular Function);Biochemical;Biological;Biological Assay;Cardiovascular Diseases;Catalytic Domain;Cell Cycle;Cell Division;Cell Membrane;Cell Physiology;Cell Proliferation;Cells;Chemicals;Clinic;Communities;Complex;Cost;Cross Reactivity;Dasatinib;Data;Design;Development;Dhfr Gene;Diabetes Mellitus;Dihydrofolate Reductase;Dimerization;Disease;Drug Candidate;Drug Design;Drug Development;Drug Discovery;Early Identification;Economics;Effective Therapy;Escherichia Coli;Evaluation;Failure (Biologic Function);Fingerprint;Genetic Regulatory Protein;Genome;Goals;High Throughput Screening;Human;Human Disease;Human Genome;Hybrids;In Vitro;Inflammation;Inhibitor/Antagonist;Kinase Inhibitor;Lead;Length;Libraries;Luciferases;Luminescence;Luminescent Measurements;Measures;Mediating;Mediator Of Activation Protein;Meetings;Methodology;Methods;Monitor;Neoplasm Metastasis;Neoplastic Cell;Normal Cell;Pathway Interactions;Permeability;Pharmaceutical Preparations;Phase;Phosphorylation;Phosphotransferases;Physiology;Play;Property;Protein Kinase;Protein Tyrosine Kinase;Protein-Serine-Threonine Kinases;Public Health Relevance;Reporting;Role;Scaffolding Protein;Screening;Serine;Services;Signal Transduction;Stem;Success;Testing;Therapeutic Target;Threonine;Toxic Effect;Trafficking;Trees;Trimethoprim;Tyrosine;Work;

The human genome encodes 518 protein kinases that catalyze the phosphorylation of client proteins. Signal transduction mediated by protein impacts virtually all aspects of cellular physiology, from the coordination of the cell cycle and cll division to apoptosis. Not surprisingly, the deregulation of kinases is implicated in many diseases including diabetes, inflammation, cardiovascular diseases, tumor cell proliferation and metastasis, making them a target for drug development. Small molecule drug discovery targeting protein kinases has seen enormous success in the past decade with over 25 drugs approved for oncology and most recently rheumatoid arthritis with many more in the pipeline for diverse indications. However, the similarity of the ATP binding active site in kinases targeted by small molecules continues to make selectivity a significant concern in drug discovery and development, since a promiscuous drug is expected to give rise to undesired adverse-effects, especially for long term therapy. In this Phase II application, we will develop a split-luciferase based luminescent assay for kinome-wide screening and profiling of inhibitors in a cellular setting. Currently, there are several kinome scale in vitro biochemical assays that are used for screening and identification of kinase inhibitors, but these assays do not provide any information on the ability of a molecule to cross cell membranes or engage its desired target in a cell. In addition, most biochemical assays use the catalytic kinase domain, thereby limiting the identification of potentially more selective allosteric inhibitors that bind sites distal to the AT-binding site. We hypothesize that the development of kinome wide cell-based assays, which are in its infancy, will meet a critical need. The cell-based kinome assays proposed herein will allow for directly monitoring the effect of compounds on a target kinase to not only to ascertain cell-permeability and cellular toxicity, but also to establish efficacy in the cellular milieu in the presence of other ATP binding proteins. Our goal is to render cellular kinase profiling assays both easily available and affordable, so that compound profiling in a cellular or native context can be done earlier and thereby lead to early identification of failures, resulting in many more opportunities for success and new and safer clinical candidates.

Public Health Relevance Statement:


Public Health Relevance:
The activities of the 518 human protein kinases are tightly regulated inside cells and their dysregulation has been implicated in many diseases, validating them as therapeutic targets. The challenge in designing drugs against kinases stems from their cross-reactivity, which arises due to similar architecture of many kinases at the conserved ATP-binding pocket. Screening compounds against a large number of kinases in their native cellular context can help develop a selectivity fingerprint, which can be used to make critical decisions for advancing a compound into the clinic and provide efficacious drugs. Our application will seek to develop low-cost, sensitive, luminescence based kinase assays that measure direct binding of the target kinase by compounds inside cells and can be used for advancing the discovery of new and effective therapies for human diseases.

Project Terms:
Academia; Active Sites; Address; Adverse effects; Apoptosis; Architecture; assay development; base; Binding (Molecular Function); Binding Proteins; Binding Sites; Biochemical; Biological Assay; Cardiovascular Diseases; Cell Cycle; Cell membrane; Cell Membrane Permeability; Cell physiology; Cell Proliferation; Cells; Cleaved cell; Client; Clinic; Clinical; Cloning; Communities; Complex; cost; cross reactivity; Cysteine; Data; design; Development; Diabetes Mellitus; Disease; Distal; Drug Design; drug development; drug discovery; Drug Efflux; Drug Transport; Early identification; effective therapy; Evaluation; Failure (biologic function); Family; Fingerprint; Glean; Goals; high throughput screening; Human; human disease; Human Genome; Hybrids; In Vitro; Individual; Industry; infancy; Inflammation; inhibitor/antagonist; kinase inhibitor; Lead; Length; Letters; Libraries; Luciferases; luminescence; Luminescent Measurements; Measures; Mediating; meetings; Monitor; mutant; Neoplasm Metastasis; neoplastic cell; novel therapeutics; oncology; Permeability; Pharmaceutical Preparations; Phase; phase 1 study; Phosphorylation; Phosphotransferases; Play; Protein Kinase; Proteins; public health relevance; Reporting; Rheumatoid Arthritis; Role; Scaffolding Protein; screening; Serine; Services; Signal Transduction; small molecule; stem; success; therapeutic target; Threonine; Toxic effect; Tyrosine; Validation