Project description:Multifaceted interrogation of the proteome deepens the system-wide understanding of biological systems; however, mapping the redox changes in the proteome has so far been significantly less informative than expression and solubility/stability analyses. Here, we devise the first high-throughput redox proteomics approach integrated with expression analysis (REX) and combine it with Proteome Integral Solubility Alteration (PISA) assay. The whole PISA-REX experiment in three biological replicates is multiplexed in a single tandem mass tag set (TMTpro). For benchmarking this compact PISA-REX tool, we analyzed HCT116 cells treated with auranofin. Then we applied PISA-REX to study the targets of Pladienolide B in SW620 cells, proteome remodeling upon stimulation of human monocytes by interferon α, and to paired primary and metastatic colon cancer cells. Providing comprehensive multifaceted information on the proteome, the compact PISA-REX has the potential to become an industry-standard in proteomics and to open new windows into the biology of health and disease.

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:Most drugs used in the clinic and drug candidates target multiple proteins, and thus detailed characterization of their efficacy targets is required. While current methods rely on quantitative measurements at thermodynamic equilibrium, kinetic parameters such as the residence time of a drug on its target provide a better proxy for efficacy in vivo. Here, we present a new Residence Time Proteome Integral Solubility Alteration (ResT-PISA) assay which provides monitoring temporal protein solubility profiles after drug removal in either cell lysate or intact cells, quantifying the lifetime of the drug-target interaction. A compressed version of the assay measures the integral under the off-curve and enables the multiplexing of binding affinity proxy measurements with residence time assessment into a single proteomic analysis. We introduce a combined scoring system for three parametric dimensions to improve prioritization of targets. By providing complementary information to other characteristics of drug-target interaction, ResT-PISA approach can become a useful tool in drug development and precision medicine.

Project description:The molecular consequences of traumatic brain injuries or TBI are poorly understood. Here, we simulated TBI using an innovative laboratory apparatus employing a 5.1 kg dummy impact generating a ≤3,300 g-force acceleration and performed system-wide profiling of neuronal cells using Proteome Integral Solubility Alteration (PISA) assay. Dynamic impact led to both reduction in neuron viability and massive solubility changes in the proteome. The affected proteins mapped not only to the expected pathways like cell adhesion, collagen and laminin structures, as well as response to stress, but also to other dense protein networks, such as immune response, complement and coagulation cascades. An energy absorbing material largely rescues the loss of cell viability and dampens proteome solubility changes. The cellular effects are found to be mainly due to the shockwave rather than the g-force acceleration. This study paves the way to introducing a proteome-based shock-meter as well as identifying TBI protein biomarkers and potential drug targets for primary prevention and intervention.

Project description:The molecular consequences of traumatic brain injuries or TBI are poorly understood. Here, we simulated TBI using an innovative laboratory apparatus employing a 5.1 kg dummy impact generating a ≤3,300 g-force acceleration and performed system-wide profiling of neuronal cells using Proteome Integral Solubility Alteration (PISA) assay. Dynamic impact leads to both reduction in neuron viability and massive solubility changes in the proteome. The affected proteins map not only to pathways such as cell adhesion, collagen and laminin structures, as well as response to stress, but also to other dense protein networks, such as immune response, complement and coagulation cascades. An energy absorbing material largely rescues the loss of cell viability and dampens proteome solubility changes. The cellular effects are found to be mainly due to the shockwave rather than the g-force acceleration. This study paves the way to introducing a proteome-based shock-meter as well as identifying TBI protein biomarkers and potential drug targets for prevention and intervention.

Project description:The One Health initiative connects human and animal health with their shared environment. The development of novel methodology to unbiased identification of mechanisms of action of chemicals and chemicals mixtures would address one of today´s challenges of environmental and human toxicology. Zebrafish embryos offer a unique opportunity to explore the proteome integral solubility alteration (PISA) assay to study the proteins that increase or decrease their solubility as protein targets of the bioactive compounds in an organism at an developmental stage. We presented here 4 different applications of the PISA method in zebrafish embryo with different types of compounds of environmental and health concern: i) endocrine disrupting chemical, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) to outline the pathways compromised under exposure; ii) complex chemical mixtures composed by TCDD + alpha-endosulfan + bisphenol A (BPA) previously studied in vitro cells lines to evaluate single chemical versus mixture; iii) novel compounds from blue-green circular economy to map the organismal response, and a iv) novel drug directed to anti-cancer activity in lymphoma models to discharge side-effects at non-target organs. Our results demonstrated the unique opportunities of PISA assay in zebrafish for toxicology. We remark some differences to its application for drug target deconvolution. First, we evaluate both targets arising from an increase in solubility and in those decreasing, as both would be involved in modulation the cellular functions. Second, the method could be applicable to bioactive compound before chemical characterization or a chemical mixture of unknown stoichiometry. Third, the results from zebrafish embryo could provide a first glimpse of unspecific interactions with proteins in non-target tissues.The introduction of PISA assay in toxi- and ecotoxicoproteomics offers high-resolution and throughput in support with the 3R, and 3M principles.

Project description:Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 0.5% of the global population. Despite its prevalence, there is no known cure, underscoring the persistent need for novel therapeutic strategies. In previous studies, we identified a specific subset of antibodies that target an epitope (F4) on type-II collagen (COL2), which seemed to offer protection against arthritis. Leveraging these findings, we have engineered a range of recombinant antibodies against this epitope. Notably, one such antibody, R69-4, has shown significant potential in suppressing arthritis. Here, we aim to identify potential cross-reactive targets of R69-4 to better understand its mechanism of action.

Project description:Unique traits of pluripotent stem cells are not fully known. Using thermal proteome profiling, we identified reduced stability of ribosomes in induced pluripotent cells (iPSCs) compared to that in somatic cells. Also, iPSCs exhibited lower protein synthesis rate and lower expression of a ribosome maturation factor, the Shwachman-Bodian-Diamond Syndrome protein (SBDS). Differentiation of iPSCs led to upregulation of SBDS and knock-down of SBDS slowed the differentiation while increasing expression of master pluripotency markers NANOG and OCT4. Mutations in the SBDS gene have been shown to impair ribosome assembly and to inhibit differentiation of hematopoietic stem cells causing the Shwachman-Diamond syndrome. Physiological SBDS-dependent destabilization of ribosomes appears to be a tool for translational control providing robustness to the state of pluripotency.

Project description:DZNep (3-deazaneplanocin A) is commonly used to reduce lysine methylation. DZNep inhibits S-adenosyl-L-homocysteine hydrolase (AHCY), preventing the conversion of S-adenosyl-L-homocysteine (SAH) into L-homocysteine and reducing the level of S-adenosylmethionine (SAM). As a result, the SAM to SAH ratio decreases, an indicator of the methylation potential within a cell. Many studies have characterized the impact of DZNep on histone lysine methylation or in specific cell or disease contexts. Recently, protein thermal stability has provided a new dimension for studying the mechanism of action of small molecule inhibitors. In addition to ligand binding, post-translational modifications and protein-protein interactions impact thermal stability. Here, we sought to characterize protein thermal stability changes induced by DZNep treatment in HEK293T cells using the Protein Integral Solubility Alteration (PISA) assay. DZNep treatment altered the thermal stability of 135 proteins, with over half previously reported to be methylated at lysine residues. In addition to thermal stability, we identify changes in transcript and protein abundance after DZNep treatment to distinguish between direct and indirect impacts on thermal stability. Nearly one-third of the proteins with altered thermal stability had no changes at the transcript or protein level. Of these thermally altered proteins, CDK6 had a stabilized methylated peptide, while its unmethylated counterpart was unaltered. Multiple methyltransferases were among the proteins with thermal stability alteration, including DNMT1, potentially due to changes in SAM/SAH levels. This study systematically evaluates DZNep’s impact on the transcriptome, the proteome, and the thermal stability of proteins.

Project description:Caspases are a family of proteins mostly known for their role in the activation of the apoptotic pathway leading to cell death. In the last decade, caspases have been found to fulfil other tasks regulating the cell phenotype independently to cell death. Microglia are the immune cells of the brain responsible for the maintenance of physiological brain functions but can also be involved in disease progression when overactivated. We have previously described non30 apoptotic roles of caspase-3 (CASP3) in the regulation of the inflammatory phenotype of microglial cells or pro-tumoral activation in the context of brain tumors. CASP3 can regulate protein functions by cleavage of their target and therefore could have multiple substrates. So far, identification of CASP3 substrates has been performed mostly in apoptotic conditions where CASP3 activity is highly upregulated and these approaches do not have the capacity to uncover CASP3 substrates at the physiological level. In our study, we aim at discovering highaffinity substrates of CASP3 involved in the normal regulation of the cell. We used an unconventional approach by chemically reducing the basal level activity of CASP3 (by DEVD38 fmk treatment) coupled to a Mass Spectrometry screen (PISA) to identify stabilized, and consequently, non-cleaved proteins in microglia cells. PISA identified several significantly stabilized proteins after DEVD-fmk treatment, including a few already known CASP3substrates which validated our approach. Among them, we focused on the Collectin12 (COLEC12 or CL-P1) transmembrane receptor and uncovered a potential role for CASP3 cleavage of COLEC12 in the regulation of the phagocytic capacity of microglial cells. Taken together, these findings suggest a new way to uncover non-apoptotic high-affinity substrates of CASP3 important for the modulation of microglia cell physiology.