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:Exploring the therapeutic effects of bioactive compounds has been traditionally approaching by phenotypic screenings followed by functional validation by in vitro assays. The thermal proteome profiling (TPP) has been successfully applied to study drug targets and off-target. We applied a modified protocol based on TPP to elucidate the mechanism of actions (MOA)s of novel bioactives compounds from marine biodiscovery. We have modified the method to gain the specificity for its application to compounds with limited chemical or structural characterization. Method implementation includes increasing the centrifugation force to precipitate the microsomal fraction previous to the thermal shift assay. The range of temperatures has been reduced to optimize the analysis without compromising resolution. Finally, the mass spectrometry analysis was based on label-free quantitative proteomics. Comparison of the targets among methodologies confirmed that the precipitation of the microsomal membranes before TPP is an essential step to discriminate between true targets from proteins precipitates after subcellular fractionation by centrifugation force. As a probe of concept, a novel marine bioactive compound has been analyzed on the hepatic cell line HepG2. We found that 2 targets proteins, aldehyde dehydrogenase and isocitrate dehydoregenase, can be related with beneficial properties towards obesity and obesity-related comorbidities. Identification of targets is key to decipher the MOAs of bioactive compound, predict the mode of action as well as possible harmful effects.

Project description:Existing thermal shift-based mass spectrometry approaches are able to identify target proteins without chemical modification of the ligand, but they are suffering from complicated workflows with limited throughput. Herein, we present a new thermal shift-based method, termed matrix thermal shift assay (mTSA), for fast deconvolution of ligand-binding targets and binding affinities at the proteome level. In mTSA, a sample matrix, treated horizontally with five different compound concentrations and vertically with five technical replicates of each condition, was denatured at a single temperature to induce protein precipitation, and then, data-independent acquisition was employed for quick protein quantification. Compared with previous thermal shift assays, the analysis throughput of mTSA was significantly improved, but the costs as well as efforts were reduced. More importantly, the matrix experiment design allowed simultaneous computation of the statistical significance and fitting of the dose–response profiles, which can be combined to enable a more accurate identification of target proteins, as well as reporting binding affinities between the ligand and individual targets. Using a pan-specific kinase inhibitor, staurosporine, we demonstrated a 36% improvement in screening sensitivity over the traditional thermal proteome profiling (TPP) and a comparable sensitivity with a latest two-dimensional TPP. Finally, mTSA was successfully applied to delineate the target landscape of perfluorooctanesulfonic acid (PFOS), a persistent organic pollutant that is hard to perform modification on, and revealed several potential targets that might account for the toxicities of PFOS.

Project description:Toxoplasma gondii is a single-celled eukaryotic parasite that chronically infects a quarter of the global population. In recent years, phenotypic screens have identified compounds that block parasite replication. Unraveling the complexity of pathogenesis and molecular mechanisms and pathways perturbed by such compounds requires target deconvolution. Thermal proteome profiling (TPP), also known as the cellular thermal shift assay (CETSA), recently emerged as a method to identify small molecule–target interactions in living cells and cell extracts in a variety of organisms, including unicellular eukaryotic pathogens. Ligand binding induces a thermal stability shift—stabilizing or destabilizing proteins that change conformationally in response to the ligand—that can be measured by mass spectrometry (MS). Cells are incubated with different concentrations of ligand and heated, causing thermal denaturation of proteins. The soluble protein is extracted and quantified with multiplexed, quantitative MS, giving rise to thousands of thermal denaturation profiles. Proteins engaging the ligand can be identified by their concentration-dependent thermal shift. The protocol provided here can be used to identify compound-target interactions and assess the impact of environmental or genetic perturbation on the thermal stability of the proteom in T. gondii and other eukaryotic pathogens. Here, we generate a reference dataset of the thermal profiles of extracellular T. gondii tachyzoites.

Project description:Thermal condition is an important envrionment factor to produce healthy pig. A mineral heat ware, RAVI is a regenerative far-infrared heating system. The purpose of this sutyd was to evaluate immunostimulating effects in pigs when RAVI was applied to maintain thermal condition compared with gasoline heater.

Project description:Coral bleaching and coral reef degradation become severe as the surface seawater temperature rises. Much research to date has focused on the bacterial community composition properties within the coral holobiont, but less attention has been paid to the interactions of bacteria and corals under thermal stress. We investigated the changes of coral symbiotic bacteria and metabolites under thermal stress, and analyzed the internal relationship between bacteria and metabolites as well as their relationship with coral health. We found obvious signs of coral bleaching after heating treatment, and the interaction within symbiotic bacterial community became closer. The coral symbiotic bacterial community and metabolites changed significantly under thermal stress, and bacteria such as Flavobacterium, Shewanella and Psychrobacter increased significantly. Bacteria associated with stress tolerance, biofilm formation and mobile elements decreased, and bacterial DMSP metabolism increased slightly after heating treatment. Differential metabolites in corals after heating treatment were associated with cell cycle regulation and antioxidant. This study revealed the correlation between differential metabolites and bacterial community composition changes in corals under thermal stress, and providing valuable insight on metabolomics research of corals.

Project description:Unbiased drug target engagement deconvolution and mechanism of action elucidation are major challenges in drug development. Modification-free target engagement methods, such as thermal proteome profiling, have gained increasing popularity over the last several years. However, these methods have limitations, and, in any case, new orthogonal approaches are needed. Here we present a novel isothermal method for comprehensive characterization of protein solubility alterations using the effect on protein solubility of cations and anions in the Hofmeister series. We combine this ion-based protein precipitation approach with Proteome Integrated Solubility Alteration (PISA) analysis and use this I-PISA assay to delineate the targets of several anti-cancer drugs both in cell lysate and in living cells. Lastly, we demonstrate that I-PISA can detect solubility changes in minute amounts of sample, opening chemical proteomics applications to small and rare biological material.

Project description:Unbiased drug target engagement deconvolution and mechanism of action elucidation are major challenges in drug development. Modification-free target engagement methods, such as thermal proteome profiling, have gained increasing popularity over the last several years. However, these methods have limitations, and, in any case, new orthogonal approaches are needed. Here we present a novel isothermal method for comprehensive characterization of protein solubility alterations using the effect on protein solubility of cations and anions in the Hofmeister series. We combine this ion-based protein precipitation approach with Proteome Integrated Solubility Alteration (PISA) analysis and use this I-PISA assay to delineate the targets of several anti-cancer drugs both in cell lysate and in living cells. Lastly, we demonstrate that I-PISA can detect solubility changes in minute amounts of sample, opening chemical proteomics applications to small and rare biological material.

Project description:The thermal shift assay is a robust method of discovering protein-ligand interactions by measuring the alterations in protein thermal stability under various conditions. Several thermal shift assays have been developed and their throughput has been advanced greatly by the rapid progress in tandem mass tag-based quantitative proteomics. A recent paper by Gaetani et al. (J Proteome Res 2019, 18 (11), 4027-4037) introduced proteome integral solubility alteration (PISA) assay, further increasing throughput and simplifying the data analysis. Yet, it remains unclear how fold changes (integral treated samples versus integral control samples) perform in this assay. We show that fold changes have compromised linearity with ΔTm (shift in melting points) by simulation, and the magnitudes of the fold changes are inherently small in PISA assay, which is a challenge for quantitation. Both simulation and experimental results show that the selection of heating temperatures can tackle the small fold change problem and improve the sensitivity and specificity of the PISA assay.

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