Project description:Bottom-up proteomics approach has become an important strategy in diverse areas of biological research, and the enzymatic digestion is essential for this technology. Endopeptidase Arg-C catalyzing the hydrolytic cleavage of peptide bonds C-terminal to arginine could be an important protease in bottom-up proteomics. However, it has been seldom applied due to its low specificity and high cost. Reversible chemical derivatization of amine allows a real Arg-C digestion using trypsin. In this paper, a reversible amine derivatization method, citraconylation and decitraconylation were optimized and evaluated for large-scale proteomics studies. Combination of the reversible derivatization and trypsin digestion (termed Arg-C* digestion to distinguish from the conventional Arg-C digestion) resulted in 64.2% more peptide identification (11,925 ± 199 vs 7,262 ± 59) and significantly higher cleavage specificity (95.6% vs 73.6%) than the conventional Arg-C digestion. Comparison of Arg-C* digestion with the widely used trypsin and Lys-C digestion revealed that Arg-C* performed equally or slightly better than Lys-C although not comparable to trypsin. Therefore, the well-established Arg-C* digestion method is a promising approach for proteomics studies and could be used as the prior alternative digestion method to trypsin digestion in order to achieve higher proteome coverage.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:CUD samples: TMT-proteomics using Orbitrap FusionTM LumosTM TribridTM Mass Spectrometer, TMT10plex (N=8 sample batch) or TMT16plex (2x N=16 sample batches) Isobaric Label Reagent (Thermo Fisher Scientific, Waltham, MA, USA), experiment type: bottom-up proteomics; data-dependent acquisition.

Project description:Ctrl samples: TMT-proteomics using Orbitrap FusionTM LumosTM TribridTM Mass Spectrometer, TMT10plex (N=8 sample batch) or TMT16plex (2x N=16 sample batches) Isobaric Label Reagent (Thermo Fisher Scientific, Waltham, MA, USA), experiment type: bottom-up proteomics; data-dependent acquisition.

Project description:Proteins present in cellular environments with high levels of reactive oxygen and nitrogen species and/or low levels of antioxidants are highly susceptible to oxidative post-translational modification (PTM). Irreversible oxidative PTMs can generate a complex distribution of modified protein molecules, recently termed as proteoforms. Using ubiquitin as a model system, we mapped oxidative modification sites using trypsin, Lys-C, and Glu-C peptides. Several M+16 Da proteoforms were detected as well as proteoforms that include other previously unidentified oxidative modifications. This work highlights the use of multiple protease digestions to give insights to the complexity of oxidative modifications possible in bottom-up analyses.

Project description:Here we introduce novel hyperthermoacidic archaeal proteases (HTA-Proteases) isolated from organisms that thrive in nearly boiling acidic volcanic springs and investigate their use for bottom-up proteomic experiments. We find that HTA-Proteases have novel cleavage specificities, show no autolysis, function in dilute formic acid, and store at ambient temperature for years. HTA-Proteases function optimally at 70-90°C and pH of 2-4 with rapid digestion kinetics. The extreme reaction conditions actively denature sample proteins, obviate the use of chaotropes, and allow for a one-step/five-minute sample preparation protocol without sample manipulation, dilution, or additional cleanup. We find that brief one-step HTA-Protease protocols significantly increase proteome and protein sequence coverage with datasets orthogonal to trypsin. Importantly, HTA-Protease digests markedly increase coverage and identifications for ribonucleoproteins, histones, and mitochondrial membrane proteins as compared to tryptic digests. In addition to increased coverage in these classes, HTA-Proteases and simplified one-step protocols are expected to reduce technical variability and advance the fields of clinical and high-throughput proteomics. This work reveals significant utility of heretofore unavailable HTA-Proteases for proteomic workflows. We discuss some of the potential for these remarkable enzymes to empower new proteomics methods, approaches, and biological insights.

Project description:The development of mirror-image biology systems and related applications is hindered by the lack of effective methods to sequence mirror-image (D-) proteins. Although natural-chirality (L-) proteins can be sequenced by bottom–up liquid chromatography–tandem mass spectrometry (LC–MS/MS), the sequencing of long D-peptides and D-proteins with the same strategy requires digestion by a site-specific D-protease before mass analysis. Here we apply solid-phase peptide synthesis and native chemical ligation to chemically synthesize a mirror-image version of trypsin, a widely used protease for site-specific protein digestion. Using mirror-image trypsin digestion and LC–MS/MS, we sequence a mirror-image large subunit ribosomal protein (L25) and a mirror-image Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4), and distinguish between different mutants of D-Dpo4. We also perform writing and reading of digital information in a long D-peptide of 50 amino acids. Thus, mirror-image trypsin digestion in conjunction with LC–MS/MS may facilitate practical applications of D-peptides and D-proteins as potential therapeutic and informational tools.