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2. Expanding the Use of Spectral Libraries in Proteomics.

Author

Deutsch, Eric W., Perez-Riverol, Yasset, Chalkley, Robert J., Wilhelm, Mathias, Tate, Stephen, Sachsenberg, Timo, Walzer, Mathias, Käll, Lukas, Delanghe, Bernard, Böcker, Sebastian, Schymanski, Emma L., Wilmes, Paul, Dorfer, Viktoria, Kuster, Bernhard, Volders, Pieter-Jan, Jehmlich, Nico, Vissers, Johannes P. C., Wolan, Dennis W., Wang, Ana Y., and Mendoza, Luis

Published
2018
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4. Prosit: proteome-wide prediction of peptide tandem mass spectra by deep learning

Author

Gessulat, Siegfried, Schmidt, Tobias, Zolg, Daniel, Samaras, Patroklos, Schnatbaum, Karsten, Zerweck, Johannes, Knaute, Tobias, Rechenberger, Julia, Delanghe, Bernard, Huhmer, Andreas, Reimer, Ulf, Ehrlich, Hans-Christian, Aiche, Stephan, Kuster, Bernhard, and Wilhelm, Mathias

Abstract

In mass-spectrometry-based proteomics, the identification and quantification of peptides and proteins heavily rely on sequence database searching or spectral library matching. The lack of accurate predictive models for fragment ion intensities impairs the realization of the full potential of these approaches. Here, we extended the ProteomeTools synthetic peptide library to 550,000 tryptic peptides and 21 million high-quality tandem mass spectra. We trained a deep neural network, termed Prosit, resulting in chromatographic retention time and fragment ion intensity predictions that exceed the quality of the experimental data. Integrating Prosit into database search pipelines led to more identifications at >10× lower false discovery rates. We show the general applicability of Prosit by predicting spectra for proteases other than trypsin, generating spectral libraries for data-independent acquisition and improving the analysis of metaproteomes. Prosit is integrated into ProteomicsDB, allowing search result re-scoring and custom spectral library generation for any organism on the basis of peptide sequence alone. A deep learning–based tool, Prosit, predicts high-quality peptide tandem mass spectra, improving peptide-identification performance compared with that of traditional proteomics analysis methods.

Published
2019
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5. Expanding the Use of Spectral Libraries in Proteomics

Author

Deutsch, Eric W., Perez-Riverol, Yasset, Chalkley, Robert J., Wilhelm, Mathias, Tate, Stephen, Sachsenberg, Timo, Walzer, Mathias, Käll, Lukas, Delanghe, Bernard, Böcker, Sebastian, Schymanski, Emma L., Wilmes, Paul, Dorfer, Viktoria, Kuster, Bernhard, Volders, Pieter-Jan, Jehmlich, Nico, Vissers, Johannes P. C., Wolan, Dennis W., Wang, Ana Y., Mendoza, Luis, Shofstahl, Jim, Dowsey, Andrew W., Griss, Johannes, Salek, Reza M., Neumann, Steffen, Binz, Pierre-Alain, Lam, Henry, Vizcaíno, Juan Antonio, Bandeira, Nuno, and Röst, Hannes

Abstract

The 2017 Dagstuhl Seminar on Computational Proteomics provided an opportunity for a broad discussion on the current state and future directions of the generation and use of peptide tandem mass spectrometry spectral libraries. Their use in proteomics is growing slowly, but there are multiple challenges in the field that must be addressed to further increase the adoption of spectral libraries and related techniques. The primary bottlenecks are the paucity of high quality and comprehensive libraries and the general difficulty of adopting spectral library searching into existing workflows. There are several existing spectral library formats, but none captures a satisfactory level of metadata; therefore, a logical next improvement is to design a more advanced, Proteomics Standards Initiative-approved spectral library format that can encode all of the desired metadata. The group discussed a series of metadata requirements organized into three designations of completeness or quality, tentatively dubbed bronze, silver, and gold. The metadata can be organized at four different levels of granularity: at the collection (library) level, at the individual entry (peptide ion) level, at the peak (fragment ion) level, and at the peak annotation level. Strategies for encoding mass modifications in a consistent manner and the requirement for encoding high-quality and commonly seen but as-yet-unidentified spectra were discussed. The group also discussed related topics, including strategies for comparing two spectra, techniques for generating representative spectra for a library, approaches for selection of optimal signature ions for targeted workflows, and issues surrounding the merging of two or more libraries into one. We present here a review of this field and the challenges that the community must address in order to accelerate the adoption of spectral libraries in routine analysis of proteomics datasets.

Published
2018
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7. Building ProteomeTools based on a complete synthetic human proteome

Author

Zolg, Daniel P, Wilhelm, Mathias, Schnatbaum, Karsten, Zerweck, Johannes, Knaute, Tobias, Delanghe, Bernard, Bailey, Derek J, Gessulat, Siegfried, Ehrlich, Hans-Christian, Weininger, Maximilian, Yu, Peng, Schlegl, Judith, Kramer, Karl, Schmidt, Tobias, Kusebauch, Ulrike, Deutsch, Eric W, Aebersold, Ruedi, Moritz, Robert L, Wenschuh, Holger, Moehring, Thomas, Aiche, Stephan, Huhmer, Andreas, Reimer, Ulf, and Kuster, Bernhard

Abstract

We describe ProteomeTools, a project building molecular and digital tools from the human proteome to facilitate biomedical research. Here we report the generation and multimodal liquid chromatography–tandem mass spectrometry analysis of >330,000 synthetic tryptic peptides representing essentially all canonical human gene products, and we exemplify the utility of these data in several applications. The resource (available at http://www.proteometools.org) will be extended to >1 million peptides, and all data will be shared with the community via ProteomicsDB and ProteomeXchange.

Published
2017
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8. Prosit-TMT: Deep Learning Boosts Identification of TMT-Labeled Peptides

Author

Gabriel, Wassim, The, Matthew, Zolg, Daniel P., Bayer, Florian P., Shouman, Omar, Lautenbacher, Ludwig, Schnatbaum, Karsten, Zerweck, Johannes, Knaute, Tobias, Delanghe, Bernard, Huhmer, Andreas, Wenschuh, Holger, Reimer, Ulf, Médard, Guillaume, Kuster, Bernhard, and Wilhelm, Mathias

Abstract

The prediction of fragment ion intensities and retention time of peptides has gained significant attention over the past few years. However, the progress shown in the accurate prediction of such properties focused primarily on unlabeled peptides. Tandem mass tags (TMT) are chemical peptide labels that are coupled to free amine groups usually after protein digestion to enable the multiplexed analysis of multiple samples in bottom-up mass spectrometry. It is a standard workflow in proteomics ranging from single-cell to high-throughput proteomics. Particularly for TMT, increasing the number of confidently identified spectra is highly desirable as it provides identification and quantification information with every spectrum. Here, we report on the generation of an extensive resource of synthetic TMT-labeled peptides as part of the ProteomeTools project and present the extension of the deep learning model Prosit to accurately predict the retention time and fragment ion intensities of TMT-labeled peptides with high accuracy. Prosit-TMT supports CID and HCD fragmentation and ion trap and Orbitrap mass analyzers in a single model. Reanalysis of published TMT data sets show that this single model extracts substantial additional information. Applying Prosit-TMT, we discovered that the expression of many proteins in human breast milk follows a distinct daily cycle which may prime the newborn for nutritional or environmental cues.

Published
2022
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9. A Novel Spectral Annotation Strategy Streamlines Reporting of mono-ADP-ribosylated Peptides Derived from Mouse Liver and Spleen in Response to IFN-γ

Author

Kuraoka, Shiori, Higashi, Hideyuki, Yanagihara, Yoshihiro, Sonawane, Abhijeet R., Mukai, Shin, Mlynarchik, Andrew K., Whelan, Mary C., Hottiger, Michael O., Nasir, Waqas, Delanghe, Bernard, Aikawa, Masanori, and Singh, Sasha A.

Abstract

Mass spectrometry-enabled ADP-ribosylation workflows are developing rapidly, providing researchers a variety of ADP-ribosylome enrichment strategies and mass spectrometric acquisition options. Despite the growth spurt in upstream technologies, systematic ADP-ribosyl (ADPr) peptide mass spectral annotation methods are lacking. HCD-dependent ADP-ribosylome studies are common but the resulting MS2 spectra are complex, owing to a mixture of b/y-ions and the m/p-ion peaks representing one or more dissociation events of the ADPr moiety (m-ion) and peptide (p-ion). In particular, p-ions that dissociate further into one or more fragment ions can dominate HCD spectra but are not recognized by standard spectral annotation workflows. As a result, annotation strategies that are solely reliant upon the b/y-ions result in lower spectral scores that in turn reduce the number of reportable ADPr peptides. To improve the confidence of spectral assignments we implemented an ADPr peptide annotation and scoring strategy. All MS2 spectra are scored for the ADPr m-ions, but once spectra are assigned as an ADPr peptide they are further annotated and scored for the p-ions. We implemented this novel workflow to ADPr peptides enriched from the liver and spleen isolated from mice post 4-hour exposure to systemic IFN-γ. HCD collision energy experiments were first performed on the Orbitrap Fusion Lumos and the Q Exactive, with notable ADPr peptide dissociation properties verified with CID (Lumos). The m-ion and p-ion series score distributions revealed that ADPr peptide dissociation properties vary markedly between instruments and within instrument collision energy settings, with consequences on ADPr peptide reporting and amino acid localization. Consequentially, we increased the number of reportable ADPr peptides by 25% (liver) and 17% (spleen) by validation and the inclusion of lower confidence ADPr peptide spectra. This systematic annotation strategy will streamline future reporting of ADPr peptides that have been sequenced using any HCD/CID-based method.

Published
2021
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10. In-depth Quantitative Cardiac Proteomics Combining Electron Transfer Dissociation and the Metalloendopeptidase Lys-N with the SILAC Mouse

Author

Scholten, Arjen, Mohammed, Shabaz, Low, Teck Y., Zanivan, Sara, van Veen, Toon A. B., Delanghe, Bernard, and Heck, Albert J. R.

Abstract

In quantitative proteomics stable isotope labeling has progressed from cultured cells toward the total incorporation of labeled atoms or amino acids into whole multicellular organisms. For instance, the recently introduced 13C6-lysine labeled SILAC mouse allows accurate comparison of protein expression directly in tissue. In this model, only lysine, but not arginine, residues are isotope labeled, as the latter may cause complications to the quantification by in vivo conversion of arginine to proline. The sole labeling of lysines discourages the use of trypsin, as not all peptides will be quantifiable. Therefore, in the initial work Lys-C was used for digestion. Here, we demonstrate that the lysine-directed protease metalloendopeptidase Lys-N is an excellent alternative. As lysine directed peptides generally yield longer and higher charged peptides, alongside the more traditional collision induced dissociation we also implemented electron transfer dissociation in a quantitative stable isotope labeling with amino acid in cell culture workflow for the first time. The utility of these two complementary approaches is highlighted by investigating the differences in protein expression between the left and right ventricle of a mouse heart. Using Lys-N and electron transfer dissociation yielded coverage to a depth of 3749 proteins, which is similar as earlier investigations into the murine heart proteome. In addition, this strategy yields quantitative information on ∼2000 proteins with a median coverage of four peptides per protein in a single strong cation exchange-liquid chromatography-MS experiment, revealing that the left and right ventricle proteomes are very similar qualitatively as well as quantitatively.

Published
2011

11. In-depth Quantitative Cardiac Proteomics Combining Electron Transfer Dissociation and the Metalloendopeptidase Lys-N with the SILAC Mouse*

Author

Scholten, Arjen, Mohammed, Shabaz, Low, Teck Y., Zanivan, Sara, van Veen, Toon A.B., Delanghe, Bernard, and Heck, Albert J.R.

Abstract

In quantitative proteomics stable isotope labeling has progressed from cultured cells toward the total incorporation of labeled atoms or amino acids into whole multicellular organisms. For instance, the recently introduced 13C6-lysine labeled SILAC mouse allows accurate comparison of protein expression directly in tissue. In this model, only lysine, but not arginine, residues are isotope labeled, as the latter may cause complications to the quantification by in vivoconversion of arginine to proline. The sole labeling of lysines discourages the use of trypsin, as not all peptides will be quantifiable. Therefore, in the initial work Lys-C was used for digestion. Here, we demonstrate that the lysine-directed protease metalloendopeptidase Lys-N is an excellent alternative. As lysine directed peptides generally yield longer and higher charged peptides, alongside the more traditional collision induced dissociation we also implemented electron transfer dissociation in a quantitative stable isotope labeling with amino acid in cell culture workflow for the first time. The utility of these two complementary approaches is highlighted by investigating the differences in protein expression between the left and right ventricle of a mouse heart. Using Lys-N and electron transfer dissociation yielded coverage to a depth of 3749 proteins, which is similar as earlier investigations into the murine heart proteome. In addition, this strategy yields quantitative information on ∼2000 proteins with a median coverage of four peptides per protein in a single strong cation exchange-liquid chromatography-MS experiment, revealing that the left and right ventricle proteomes are very similar qualitatively as well as quantitatively.

Published
2011
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