Project description:This project describe a novel lysine reactivity profiling method for proteome-wide identification of drug targets and binding sites

Project description:While thermal proteome profiling (TPP) shines in the field of drug target screening by analyzing the soluble fraction of the proteome samples treated with high temperature, the counterpart, insoluble precipitate has been overlooked for a long time. The analysis of precipitate is hampered by the inefficient sample processing procedure. Herein, we propose a novel method, termed Microparticle Assisted Precipitation Screening (MAPS), for drug target identification. The MAPS method exploits the principle that drug bound proteins will be more resistant to thermal unfolding similar as in classic TPP method, but the process of protein precipitation is assisted by microparticles. Upon heating, proteins will unfold and aggregate on the surface of microparticles, which benefits the following proteomic analysis of the precipitate. The introduction of microparticle simplifies the whole sample preparation workflow. The proteins that precipitate on the surface of microparticles will be subjected to wash, alkylation, and digestion. The whole sample preparation is processed conveniently on the surface of microparticles without any transferring. With the assistance of microparticles, sample loss is minimized. As a result, MAPS method is compatible with minute amount of initial proteins. MAPS was applied to screen the targets of several well-studied drugs and the known target proteins were successfully with high confidence and specificity. To investigate the specificity of MAPS method, it was applied it to screen the targets of the pan-kinase inhibitor, staurosporine, and 32 protein kinases (specificity of 80%) were identified by using only 20 µg initial proteins of each sample. MAPS is an unbiased robust method for identifying drug targets at the level of proteome, filling the vacancy of stability-based target screening using precipitate.

Project description:The target deconvolution of MMV897615 was evaluated using thermal proteome profiling (TPP), a chemical proteomics approach based on the stabilisation of protein targets upon ligand binding. In these TPP experiments we used a whole-cell strategy, exposing cells rather than lysates to the drug

Project description:Early identification of a compound’s mode of action can greatly benefit the discovery process. Thermal proteomics profiling (TPP) is a powerful, unbiased tool that can be used to identify potential ligands of protein targets. TPP takes advantage of the fact that a ligand binding to its target protein can significantly stabilise that protein, increasing its melting temperature (Tm). We previously optimised this technique for use in drug target deconvolution in the kinetoplastid parasite, Leishmania donovani1 and here report the optimisation and validation of TPP in the malaria-causing parasite P. falciparum.

Project description:Thermal proteome profiling (TPP) has significantly advanced the field of drug discovery by facilitating proteome-wide identification of drug targets and off-targets. However, TPP has not been widely applied for high-throughput drug screenings, since the method is labor intensive and requires a lot of measurement time on a mass spectrometer. Here, we present Single-tube TPP with Uniform Progression (STPP-UP), which significantly reduces both the amount of required input material and measurement time, while retaining the ability to identify drug targets for compounds of interest.

Project description:Thermal proteome profiling (TPP) has significantly advanced the field of drug discovery by facilitating proteome-wide identification of drug targets and off-targets. However, TPP has not been widely applied for high-throughput drug screenings, since the method is labor intensive and requires a lot of measurement time on a mass spectrometer. Here, we present Single-tube TPP with Uniform Progression (STPP-UP), which significantly reduces both the amount of required input material and measurement time, while retaining the ability to identify drug targets for compounds of interest.

Project description:The process of protein precipitation can be used to decipher the interaction of ligand and protein. For example, the classic Thermal Proteome Profiling (TPP) method uses heating as the driving force for protein precipitation, to discover the drug target protein. Under heating or other denature forces, the target protein that binds with the drug compound will be more resistant to precipitation than the free protein. Similar to thermal stress, mechanical stress can also induce protein precipitation. Upon mechanical stress, protein will gradually precipitate along with protein conformational changes, which can be exploited for the study of the ligand-protein interaction. Herein, we proposed a Mechanical Stress Induced Protein Precipitation (MSIPP) method for drug target deconvolution. Its streamlined workflow allows in situ sample preparation on the surface of microparticles, from protein precipitation to digestion. The mechanical stress was generated by vortexing the slurry of protein solution and microparticle materials. The mechanical stress induced protein precipitate was captured by the microparticles, which guarantees the MSIPP method to be scalable and user-friendly. The MSIPP method was successfully applied to four drug compounds, Methotrexate, Raltitrexed, SHP099, Geldanamycin and a pan-inhibitor of protein kinases, Staurosporine. Besides, DHFR was demonstrated to be a target of Raltitrexed, which has not been revealed by any other modification-free drug target discovery method yet. Thus, MSIPP is a complementary method to other drug target screening methods.

Project description:We introduce tissue Thermal Proteome Profiling (tissue-TPP) which enables the discovery of drug targets and off-targets as well as measurements of target occupancy in tissue samples derived from dosed animals. Here we report the first proteome-wide thermal stability map of tissues and organ-specific target profiles of the non-covalent histone deacetylase inhibitor, panobinostat. In addition, we devised blood-CETSA/TPP to monitor target and off-target engagement directly in whole blood.

Project description:We introduce tissue Thermal Proteome Profiling (tissue-TPP) which enables the discovery of drug targets and off-targets as well as measurements of target occupancy in tissue samples derived from dosed animals. Here we report the first proteome-wide thermal stability map of tissues and organ-specific target profiles of the non-covalent histone deacetylase inhibitor, panobinostat. In addition, we devised blood-CETSA/TPP to monitor target and off-target engagement directly in whole blood.

Project description:We introduce tissue Thermal Proteome Profiling (tissue-TPP) which enables the discovery of drug targets and off-targets as well as measurements of target occupancy in tissue samples derived from dosed animals. Here we report the first proteome-wide thermal stability map of tissues and organ-specific target profiles of the non-covalent histone deacetylase inhibitor, panobinostat. In addition, we devised blood-CETSA/TPP to monitor target and off-target engagement directly in whole blood.