Mass Spectrometry-Based Thermal Shift Assay for Protein−Ligand Binding Analysis (original) (raw)
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The purification of recombinant proteins for biochemical assays and structural studies is timeconsuming and presents inherent difficulties that depend on the optimization of protein stability. The use of dyes to monitor thermal denaturation of proteins with sensitive fluorescence detection enables the rapid and inexpensive determination of protein stability using real-time PCR instruments. By screening a wide range of solution conditions and additives in 96-well format, the thermal shift assay easily identifies conditions that significantly enhance the stability of recombinant proteins. The same approach can be used as a low cost, initial screen to discover new protein:ligand interactions by capitalizing on increases in protein stability that typically occur upon ligand binding. This unit presents a methodological workflow for the small-scale, highthroughout thermal denaturation of recombinant proteins in the presence of SYPRO Orange dye.
Journal of the American Society For Mass Spectrometry, 2011
Described here is a stable isotope labeling protocol that can be used with a chemical modification- and mass spectrometry-based protein-ligand binding assay for detecting and quantifying both the direct and indirect binding events that result from protein-ligand binding interactions. The protocol utilizes an H{2/16}O2 and H{2/18}O2 labeling strategy to evaluate the chemical denaturant dependence of methionine oxidation in proteins both in the presence and absence of a target ligand. The differential denaturant dependence to the oxidation reactions performed in the presence and absence of ligand provides a measure of the protein stability changes that occur as a result of direct interactions of proteins with the target ligand and/or as a result of indirect interactions involving other protein-ligand interactions that are either induced or disrupted by the ligand. The described protocol utilizes the 18O/16O ratio in the oxidized protein samples to quantify the ligand-induced protein stability changes. The ratio is determined using the isotopic distributions observed for the methionine-containing peptides used for protein identification in the LC-MS-based proteomics readout. The strategy is applied to a multi-component protein mixture in this proof-of-principle experiment, which was designed to evaluate the technique's ability to detect and quantify the direct binding interaction between cyclosporin A and cyclophilin A and to detect the indirect binding interaction between cyclosporin A and calcineurin (i.e., the protein-protein interaction between cyclophilin A and calcineurin that is induced by cyclosporin A binding to cyclophilin A).
Journal of the American Society for Mass Spectrometry, 2003
An experimental approach is described for determining protein-small molecule non-covalent ligand binding sites and protein conformational changes induced by ligand binding. The methodology utilizes time resolved limited proteolysis and the high throughput analysis capability of MALDI TOF MS to determine the binding site in a tetanus toxin C-fragment (51 kDa)-doxorubicin (543 Da) non-covalent complex. Comparing relative ion abundances of peptides released from the time resolved limited proteolysis of tetanus toxin C-fragment (TetC) and the TetC-doxorubicin complex every 10 min from 10 to 120 min of digestion revealed that the binding of doxorubicin induced a significant change in surface topology of TetC. Four of the twenty-nine peptides observed by MALDI MS, including amino acids 351-360, 299-304, 305-311 and 312-316, had a lower abundance in the TetC-doxorubicin complex relative to TetC from 10 to 100 min of digestion. A decrease in ion abundance suggests doxorubicin obstructs the access of the protease to one or both termini of these peptides, identifying doxorubicin binding site(s). Conversely, five peptide ions, including amino acids 335-350, 364-375, 364-376, 281-298, and 316-328, all had a greater abundance in the digest of the complex, indicating an increase in accessibility to these sites. These five peptides flank regions of decreased ion abundance, suggesting that doxorubicin not only binds to the surface, but also induces a conformational change in TetC.
Characterization and Quantification of Covalent Modification of Proteins Using Mass Spectrometry
2018
Identification and characterization of various post-translational modifications of protein is a key to understanding many unknown cellular processes. In the last few decades, mass spectrometry has evolved as an essential and effective analytical tool for qualitative and quantitative analysis of proteins. In this research, we have developed a novel MALDI-MS 2 based quantification method for Desmosine and Isodesmosine, which served as cross-linking amino acids of elastin, in order to measure the elastin degradation in the body. This is the first quantification method that not only illustrates the potential of MALDI-Ion Trap MS 2 , but also improvement over the current LC-MS method, in terms of analysis time and solvent consumption, while maintaining similar analytical characteristics. The method is utilized to evaluate the time-dependent degradation of Des upon UV radiation (254nm) and result found to be consistent with quantification by 1 H NMR. This work also involves the investigation of potential phosphorylation sites and evaluation of its role in various biochemical processes during HIV infection. Based on the results from different phosphorylation prediction algorithms, many in-vitro kinase assays were performed on HIV-derived peptides/proteins in presence of potential kinases. We have successfully identified few novel interactions between host-kinases/HIV phosphorylation substrates. These include the interactions of phosphorylation sites of Vif, Nef and Capsid v proteins with protein kinase C (PKC), protein kinase A (PKA), and p38 MAPK respectively. Moreover, this work includes the development of cell-active inhibitors for cysteine cathepsins, a class of enzymes involve in many important cellular processes and in various disorders. In this study, we have synthesized library of two different classes of molecules containing oxirane and vinylsulfonate moieties. Various cell-based experiments were conducted to successfully demonstrate intracellular inhibition of cysteine cathepsin by these developed inhibitory molecules. The result of our study shows 2-(2-ehtylphenylsulfonyl) oxirane is cellpermeable and irreversible inhibitor of cathepsin B. On the other hand, peptidyl vinylsulfonate inhibitor (KD-1) is highly potent and selective cathepsin L inhibitor. vi Acknowledgement First of all, I would like to thank Almighty for everything he has offered me and for navigating me on the road of the life.
Analytical Chemistry, 2009
A protease digestion strategy was incorporated into single-point SUPREX (stability of unpurified proteins from rates of H/D exchange), which is an H/D exchange-and mass spectrometry-based assay for the detection of protein-ligand binding. Single-point SUPREX is an abbreviated form of SUPREX in which protein-ligand binding interactions are detected by measuring the increase in a protein's thermodynamic stability upon ligand binding. The new protease digestion protocol provides a noteworthy increase in the efficiency of single-point SUPREX because peptide masses can be determined with greater precision than intact protein masses in the MALDI readout of single-point SUPREX. The protocol was evaluated in test screens on two model protein systems, including cyclophilin A (CypA) and the minor allele variant of human alanine:glyoxylate aminotransferase (AGTmi). The test screening results obtained on both proteins revealed that the peptide readout of the single-point SUPREX-protease digestion protocol was more efficient than the intact protein readout of the original single-point SUPREX protocol at discriminating hits and non-hits. In addition to this improvement in screening efficiency, the protease digestion strategy described here is expected to significantly increase the generality of the single-point SUPREX assay.
Biophysical Journal, 2013
Autoxidation of linoleic acid (LA) enhanced by Fe(II)/ascorbate generates unsaturated hydroperoxides which undergo further oxidative evolution resulting in a mixture of electrophiles, including epoxyketooctadecenoic acid and dienones with intact C-18 chains as well as oxidative cleavage products such as 4-hydroxy-2(E)-nonenal (HNE), 4-oxo-2(E)-nonenal (ONE), 2(E)-octenal, 9-hydroxy-12-oxo-10(E)dodecenoic acid, 9,12-dioxo-10(E)-dodecenoic acid, and 11-oxoundec-9(E)-enoic acid. Mass spectrometric (MALDI-TOF-MS and LC-ESI-MS/MS) studies have been performed following incubation of the model protein -lactoglobulin with LA, Fe(II), and ascorbate, which identified adducts of these electrophiles with three different protein nucleophiles. Deuterium labeled linoleic acid 17,17,18,18,18-d 5 -(9Z,12Z)octadeca-9,12-dienoic acid (d 5 -LA) was synthesized to facilitate the detection and characterization of the protein modifications by mass spectrometry. Reduction by NaBH 4 served to trap reversible adducts and to quantify the number of reducible functional groups in each adduct. This study, which mimics the distribution of reactive lipid peroxidation products generated by a continuous low level flux of reactive oxygen species present in ViVo under conditions of oxidative stress, confirms that many irreversibly formed adducts previously identified following exposure of model proteins to pure electrophilic modifiers such as HNE and ONE are also generated during in situ oxidation of LA. These adducts include HNE-His Michael adducts (MA), ONE-Lys 4-ketoamide, ONE-Lys pyrrolinone, and a Cys/His-ONE-Lys pyrrole cross-link. However, reversibly formed adducts, such as the HNE-Lys Schiff base, are not present at detectable levels. The isotopic labeling allowed less commonly identified mirror-image adducts derived from the carboxy terminus of LA to be identified. A novel 2-octenoic acid-His MA was discovered.
Methods in molecular biology (Clifton, N.J.), 2008
Mass spectrometry (MS) is widely used within structural and functional proteomics for a variety of tasks including protein quality assessment, identification, and characterization. MS is used routinely for the determination of the total mass of proteins, including N-glycosylated proteins, analysis of selenomethionine incorporation, crystal content verification, and analysis of N-glycosylation site occupancy. Protocols for sample preparation, data collection, and analysis are given.A recent development is the fluorescence-based thermal shift (ThermoFluor) assay. It uses an environmentally sensitive dye, Sypro Orange, to monitor the thermal stability of a protein and investigate factors (e.g., buffers, additives, and ligands) affecting this stability. This chapter describes the application of this method using a 96-condition in-house screen. The measurements are performed on a commercially available real-time PCR machine. Multiangle or static light scattering (SLS) is a very powerful ...
Analytica Chimica Acta, 2003
Recently, we developed a new method for measuring the thermodynamic stability of proteins. The method, termed Stability of Unpurified Proteins from Rates of H/D Exchange (SUPREX), utilizes matrix-assisted laser desorption/ionization (MALDI) mass spectrometry and exploits the H/D exchange properties of proteins to determine folding free energies (i.e. G • f values) for proteins. Here we report on the SUPREX analysis of seven new model proteins. The results of these analyses and the results of previously reported SUPREX analysis on seven additional proteins are used to assess the accuracy and precision of the SUPREX technique for measuring G • f values. We find that the accuracy of the SUPREX technique for measuring the G • f values of proteins is on the order of 20% and precision (relative standard deviation) of the technique is on the order 10%. These measures of accuracy and precision are comparable to those of conventional methods.
Journal of the American Society for Mass Spectrometry, 2008
An H/D exchange-and MALDI mass spectrometry-based screening assay was applied to search for novel ligands that bind to cyclophilin A, a potential therapeutic and diagnostic target in lung cancer. The assay is based on SUPREX (stability of unpurified proteins from rates of H/D exchange), which exploits the H/D exchange properties of amide protons to measure the increase in a protein's thermodynamic stability upon ligand binding in solution. The current study evaluates the throughput and efficiency with which 880 potential ligands from the Prestwick Chemical Library could be screened for binding to cyclophilin A. Screening was performed at a rate of 3 min/ligand using a conventional MALDI mass spectrometer. False positive and false negative rates, based on a set of control data, were as low as 0% and 9%, respectively. Based on the 880-member library screening, a false positive rate of 0% was observed when a 2-tier selection strategy was implemented. Although novel ligands for cyclophilin A were not discovered, cyclosporin A, a known ligand to CypA and a blind control in the library, was identified as a hit. We also describe a new strategy to eliminate some of the complications related to back exchange that can arise in screening applications of SUPREX.
Journal of The American Society for Mass Spectrometry, 2011
We report on the characterization by mass spectrometry (MS) of a rapid, reagentless and sitespecific cleavage at the N-terminus of the amino acid cysteine (C) in peptides and proteins induced by the thermal decomposition at 220-250°C for 10 s in solid samples. This thermally induced cleavage at C occurs under the same conditions and simultaneously to our previously reported thermally induced site-specific cleavage at the C-terminus of aspartic acid (D) (Zhang, S.; Basile, F. J. Proteome Res. 2007, 6, (5), 1700-1704). The C cleavage proceeds through cleavage of the nitrogen and α-carbon bond (N-terminus) of cysteine and produces modifications at the cleavage site with an amidation (−1 Da) of the N-terminal thermal decomposition product and a −32 Da mass change of the C-terminal thermal decomposition product, the latter yielding either an alanine or β-alanine residue at the N-terminus site. These modifications were confirmed by off-line thermal decomposition electrospray ionization (ESI)-MS, tandem MS (MS/MS) analyses and accurate mass measurements of standard peptides. Molecular oxygen was found to be required for the thermal decomposition and cleavage at C as it induced an initial cysteine thiol side chain oxidation to sulfinic acid. Similar to the thermally induced D cleavage, missed cleavages at C were also observed. The combined thermally induced digestion process at D and C, termed thermal decomposition/digestion (TDD), was observed on several model proteins tested under ambient conditions and the site-specificity of the method confirmed by MS/MS.