Current drug discovery collaborations are mainly centered on the high---throughput screening of large libraries of commercially available compounds. This fixed modality provides little opportunity for synergy between chemists and biologists. We seek to benefit from the increasing amount of structural information on protein---protein interactions (PPIs), exemplified by the Protein Data Bank (PDB), to embark in a PDB---wide systems biology approach that combines biophysical insights, multiple component reaction (MCR) chemistry, and advanced computer science to develop a radically new open---access technology that facilitates true collaboration between biologists who are experts on specific protein---protein interactions (PPIs) and chemists who have the expertise to design, discover and develop small molecular weight compounds. Our approach builds on the role of anchor side chains: side chains that are deeply buried in the acceptor protein of the PPI and identify well---defined """"""""druggable"""""""" pockets. We use chemical mimicry of an anchor as an entry point into the rational design of MCR---accessible small molecular weight compounds. Contrary to traditional multistep sequential synthesis, MCR chemistry assembles advanced starting materials into a new product in a one---pot procedure resulting in a tremendous savings in cost and time. As a proof---of---concept, we have developed and validated a web---based technology that brings real---time rational drug design to the laptop of any scientist. Through a user---friendly interface, researchers can use their insights and expertise to design pharmacophores and screen millions of biased MCR---accessible compounds from over 20 distinct reactions in a matter of seconds. Using our approach we have obtained around a 50% hit rate when targeting the p53---MDM2 PPI.
Our specific aims are to: (a) expand the chemical space and targets covered by our libraries of novel, MCR---accessible virtual compounds;(b) improve the ranking, optimization and other analytical capabilities of our virtual screening technology;and (c) actively engage worldwide research groups with in vitro and/or in vivo assays with the goal of developing small molecular weight (ant)agonists. Based on the results of the virtual screening technology, we (or others) will be able to rapidly synthesize the predicted compounds. Our ultimate goal is to offer biomedical researchers direct access to virtual screening technologies and a limited number of potentially active novel compounds for them to use in their in---house small---scale screening capabilities. Active hits can then be optimized as chemical probes to study the functions of genes, cells, and biochemical pathways. This transformative resource is bound to lead to new ways to explore the functions of genes and signaling pathways in health and disease.
Current chemical biology collaborations are mainly based on high-throughput screening of large libraries of commercially existing compounds on targets of biological interest. However, this fix modality fails to provide much synergy between these two mature disciplines, i.e., chemistry and biology and often requires prior funding. We propose to develop a radically new open access technology to facilitate the true collaboration amongst biologists, say, experts on specific protein-protein interactions (PPIs) and chemists who are interested in the rational development of protein interaction small molecular weight (ant)-agonists. Specifically, we seek to benefit from the growing structural information on protein-protein interactions (PPIs), exemplified in the Protein Data Bank (PDB), to develop a PDB wide - sic system biology - approach that combine biophysical insights, multiple component reaction (MCR) chemistry to develop and screen million-size virtual libraries of chemically accessible novel compounds and potentiate small-scale lab assays with the ultimate goal to develop drugs for unmet medical needs, e.g. cancer, Alzheimer's and orphan diseases.
| Abdelraheem, Eman M M; Khaksar, Samad; Kurpiewska, Katarzyna et al. (2018) Two-Step Macrocycle Synthesis by Classical Ugi Reaction. J Org Chem 83:1441-1447 |
| Wingert, Bentley M; Camacho, Carlos J (2018) Improving small molecule virtual screening strategies for the next generation of therapeutics. Curr Opin Chem Biol 44:87-92 |
| Kurhade, Santosh; Diekstra, Elmar; Sutanto, Fandi et al. (2018) Multicomponent Reaction Based Synthesis of 1-Tetrazolylimidazo[1,5- a]pyridines. Org Lett 20:3871-3874 |
| Wang, Wenjia; Groves, Matthew R; Dömling, Alexander (2018) Artificial Macrocycles as IL-17A/IL-17RA Antagonists. Medchemcomm 9:22-26 |
| Pulugulla, Sree H; Workman, Riley; Rutter, Nathan W et al. (2018) A combined computational and experimental approach reveals the structure of a C/EBP?-Spi1 interaction required for IL1B gene transcription. J Biol Chem 293:19942-19956 |
| Konstantinidou, Markella; Zarganes-Tzitzikas, Tryfon; Magiera-Mularz, Katarzyna et al. (2018) Immune Checkpoint PD-1/PD-L1: Is There Life Beyond Antibodies? Angew Chem Int Ed Engl 57:4840-4848 |
| Patil, Pravin; Mishra, Bhupendra; Sheombarsing, Gitanjali et al. (2018) Library-to-Library Synthesis of Highly Substituted ?-Aminomethyl Tetrazoles via Ugi Reaction. ACS Comb Sci 20:70-74 |
| Kok, Tjie; Wapenaar, Hannah; Wang, Kan et al. (2018) Discovery of chromenes as inhibitors of macrophage migration inhibitory factor. Bioorg Med Chem 26:999-1005 |
| Wingert, Bentley M; Oerlemans, Rick; Camacho, Carlos J (2018) Optimal affinity ranking for automated virtual screening validated in prospective D3R grand challenges. J Comput Aided Mol Des 32:287-297 |
| Shaabani, Shabnam; Huizinga, Harmen P S; Butera, Roberto et al. (2018) A patent review on PD-1/PD-L1 antagonists: small molecules, peptides, and macrocycles (2015-2018). Expert Opin Ther Pat 28:665-678 |
Showing the most recent 10 out of 97 publications
