Your search keyword '"Clauser, P."' showing total 26 results

1. TMT Labeling for the Masses: A Robust and Cost-efficient, In-solution Labeling Approach*[S]

Author

Zecha, Jana, Satpathy, Shankha, Kanashova, Tamara, Avanessian, Shayan C., Kane, M. Harry, Clauser, Karl R., Mertins, Philipp, Carr, Steven A., and Kuster, Bernhard

Abstract

Isobaric labeling using tandem mass tags (TMTs) is increasingly applied for deep-scale proteomic studies in a multitude of organisms and addressing diverse research questions. The cost of labeling reagents represents a substantial proportion of the total expenses for conducting such experiments. Here, Zecha et al.present an economically optimized TMT labeling approach that reduces the quantity of required labeling reagent by a factor of eight and reproducibly achieves complete labeling.

Published

2019

2. What Can Ribo-Seq, Immunopeptidomics, and Proteomics Tell Us About the Noncanonical Proteome?

Author

Prensner, John R., Abelin, Jennifer G., Kok, Leron W., Clauser, Karl R., Mudge, Jonathan M., Ruiz-Orera, Jorge, Bassani-Sternberg, Michal, Moritz, Robert L., Deutsch, Eric W., and van Heesch, Sebastiaan

Abstract

Ribosome profiling (Ribo-Seq) has proven transformative for our understanding of the human genome and proteome by illuminating thousands of noncanonical sites of ribosome translation outside the currently annotated coding sequences (CDSs). A conservative estimate suggests that at least 7000 noncanonical ORFs are translated, which, at first glance, has the potential to expand the number of human protein CDSs by 30%, from ∼19,500 annotated CDSs to over 26,000 annotated CDSs. Yet, additional scrutiny of these ORFs has raised numerous questions about what fraction of them truly produce a protein product and what fraction of those can be understood as proteins according to conventional understanding of the term. Adding further complication is the fact that published estimates of noncanonical ORFs vary widely by around 30-fold, from several thousand to several hundred thousand. The summation of this research has left the genomics and proteomics communities both excited by the prospect of new coding regions in the human genome but searching for guidance on how to proceed. Here, we discuss the current state of noncanonical ORF research, databases, and interpretation, focusing on how to assess whether a given ORF can be said to be “protein coding.”

Published

2023

3. Methods, Tools and Current Perspectives in Proteogenomics*

Author

Ruggles, Kelly V., Krug, Karsten, Wang, Xiaojing, Clauser, Karl R., Wang, Jing, Payne, Samuel H., Fenyö, David, Zhang, Bing, and Mani, D.R.

Abstract

With combined technological advancements in high-throughput next-generation sequencing and deep mass spectrometry-based proteomics, proteogenomics, i.e.the integrative analysis of proteomic and genomic data, has emerged as a new research field. Early efforts in the field were focused on improving protein identification using sample-specific genomic and transcriptomic sequencing data. More recently, integrative analysis of quantitative measurements from genomic and proteomic studies have identified novel insights into gene expression regulation, cell signaling, and disease. Many methods and tools have been developed or adapted to enable an array of integrative proteogenomic approaches and in this article, we systematically classify published methods and tools into four major categories, (1) Sequence-centric proteogenomics; (2) Analysis of proteogenomic relationships; (3) Integrative modeling of proteogenomic data; and (4) Data sharing and visualization. We provide a comprehensive review of methods and available tools in each category and highlight their typical applications.

Published

2017

4. Comparative Analysis of Mitochondrial N-Termini from Mouse, Human, and Yeast*

Author

Calvo, Sarah E., Julien, Olivier, Clauser, Karl R., Shen, Hongying, Kamer, Kimberli J., Wells, James A., and Mootha, Vamsi K.

Abstract

The majority of mitochondrial proteins are encoded in the nuclear genome, translated in the cytoplasm, and directed to the mitochondria by an N-terminal presequence that is cleaved upon import. Recently, N-proteome catalogs have been generated for mitochondria from yeast and from human U937 cells. Here, we applied the subtiligase method to determine N-termini for 327 proteins in mitochondria isolated from mouse liver and kidney. Comparative analysis between mitochondrial N-termini from mouse, human, and yeast proteins shows that whereas presequences are poorly conserved at the sequence level, other presequence properties are extremely conserved, including a length of ∼20–60 amino acids, a net charge between +3 to +6, and the presence of stabilizing amino acids at the N-terminus of mature proteins that follow the N-end rule from bacteria. As in yeast, ∼80% of mouse presequence cleavage sites match canonical motifs for three mitochondrial peptidases (MPP, Icp55, and Oct1), whereas the remainder do not match any known peptidase motifs. We show that mature mitochondrial proteins often exist with a spectrum of N-termini, consistent with a model of multiple cleavage events by MPP and Icp55. In addition to analysis of canonical targeting presequences, our N-terminal dataset allows the exploration of other cleavage events and provides support for polypeptide cleavage into two distinct enzymes (Hsd17b4), protein cleavages key for signaling (Oma1, Opa1, Htra2, Mavs, and Bcs2l13), and in several cases suggests novel protein isoforms (Scp2, Acadm, Adck3, Hsdl2, Dlst, and Ogdh). We present an integrated catalog of mammalian mitochondrial N-termini that can be used as a community resource to investigate individual proteins, to elucidate mechanisms of mammalian mitochondrial processing, and to allow researchers to engineer tags distally to the presequence cleavage.

Published

2017

5. An Analysis of the Sensitivity of Proteogenomic Mapping of Somatic Mutations and Novel Splicing Events in Cancer*

Author

Ruggles, Kelly V., Tang, Zuojian, Wang, Xuya, Grover, Himanshu, Askenazi, Manor, Teubl, Jennifer, Cao, Song, McLellan, Michael D., Clauser, Karl R., Tabb, David L., Mertins, Philipp, Slebos, Robbert, Erdmann-Gilmore, Petra, Li, Shunqiang, Gunawardena, Harsha P., Xie, Ling, Liu, Tao, Zhou, Jian-Ying, Sun, Shisheng, Hoadley, Katherine A., Perou, Charles M., Chen, Xian, Davies, Sherri R., Maher, Christopher A., Kinsinger, Christopher R., Rodland, Karen D., Zhang, Hui, Zhang, Zhen, Ding, Li, Townsend, R. Reid, Rodriguez, Henry, Chan, Daniel, Smith, Richard D., Liebler, Daniel C., Carr, Steven A., Payne, Samuel, Ellis, Matthew J., and Fenyő, David

Abstract

Improvements in mass spectrometry (MS)-based peptide sequencing provide a new opportunity to determine whether polymorphisms, mutations, and splice variants identified in cancer cells are translated. Herein, we apply a proteogenomic data integration tool (QUILTS) to illustrate protein variant discovery using whole genome, whole transcriptome, and global proteome datasets generated from a pair of luminal and basal-like breast-cancer-patient-derived xenografts (PDX). The sensitivity of proteogenomic analysis for singe nucleotide variant (SNV) expression and novel splice junction (NSJ) detection was probed using multiple MS/MS sample process replicates defined here as an independent tandem MS experiment using identical sample material. Despite analysis of over 30 sample process replicates, only about 10% of SNVs (somatic and germline) detected by both DNA and RNA sequencing were observed as peptides. An even smaller proportion of peptides corresponding to NSJ observed by RNA sequencing were detected (<0.1%). Peptides mapping to DNA-detected SNVs without a detectable mRNA transcript were also observed, suggesting that transcriptome coverage was incomplete (∼80%). In contrast to germline variants, somatic variants were less likely to be detected at the peptide level in the basal-like tumor than in the luminal tumor, raising the possibility of differential translation or protein degradation effects. In conclusion, this large-scale proteogenomic integration allowed us to determine the degree to which mutations are translated and identify gaps in sequence coverage, thereby benchmarking current technology and progress toward whole cancer proteome and transcriptome analysis.

Published

2016

6. Sensitive, high-throughput HLA-I and HLA-II immunopeptidomics using parallel accumulation-serial fragmentation mass spectrometry

Author

Phulphagar, Kshiti Meera, Ctortecka, Claudia, Jacome, Alvaro Sebastian Vaca, Klaeger, Susan, Verzani, Eva K., Hernandez, Gabrielle M., Udeshi, Namrata D., Clauser, Karl R., Abelin, Jennifer G., and Carr, Steven A.

Abstract

Comprehensive, in-depth identification of the human leukocyte antigen HLA-I and HLA-II tumor immunopeptidome can inform the development of cancer immunotherapies. Mass spectrometry (MS) is powerful technology for direct identification of HLA peptides from patient derived tumor samples or cell lines. However, achieving sufficient coverage to detect rare, clinically relevant antigens requires highly sensitive MS-based acquisition methods and large amounts of sample. While immunopeptidome depth can be increased by off-line fractionation prior to MS, its use is impractical when analyzing limited amounts of primary tissue biopsies. To address this challenge, we developed and applied a high throughput, sensitive, single-shot MS-based immunopeptidomics workflow that leverages trapped ion mobility time-of-flight mass spectrometry on the Bruker timsTOF SCP. We demonstrate >2-fold improved coverage of HLA immunopeptidomes relative to prior methods with up to 15,000 distinct HLA-I and HLA-II peptides from 4e7 cells. Our optimized single-shot MS acquisition method on the timsTOF SCP maintains high coverage, eliminates the need for off-line fractionation and reduces input requirements to as few as 1e6 A375 cells for > 800 distinct HLA-I peptides. This depth is sufficient to identify HLA-I peptides derived from cancer-testis antigen, and non-canonical proteins. We also apply our optimized single-shot SCP acquisition methods to tumor derived samples, enabling sensitive, high throughput and reproducible immunopeptidome profiling with detection of clinically relevant peptides from less than 4e7 cells or 15 mg wet weight tissue.

Published

2023

7. Multiplexed, Quantitative Workflow for Sensitive Biomarker Discovery in Plasma Yields Novel Candidates for Early Myocardial Injury*

Author

Keshishian, Hasmik, Burgess, Michael W., Gillette, Michael A., Mertins, Philipp, Clauser, Karl R., Mani, D.R., Kuhn, Eric W., Farrell, Laurie A., Gerszten, Robert E., and Carr, Steven A.

Abstract

We have developed a novel plasma protein analysis platform with optimized sample preparation, chromatography, and MS analysis protocols. The workflow, which utilizes chemical isobaric mass tag labeling for relative quantification of plasma proteins, achieves far greater depth of proteome detection and quantification while simultaneously having increased sample throughput than prior methods. We applied the new workflow to a time series of plasma samples from patients undergoing a therapeutic, “planned” myocardial infarction for hypertrophic cardiomyopathy, a unique human model in which each person serves as their own biologic control. Over 5300 proteins were confidently identified in our experiments with an average of 4600 proteins identified per sample (with two or more distinct peptides identified per protein) using iTRAQ four-plex labeling. Nearly 3400 proteins were quantified in common across all 16 patient samples. Compared with a previously published label-free approach, the new method quantified almost fivefold more proteins/sample and provided a six- to nine-fold increase in sample analysis throughput. Moreover, this study provides the largest high-confidence plasma proteome dataset available to date. The reliability of relative quantification was also greatly improved relative to the label-free approach, with measured iTRAQ ratios and temporal trends correlating well with results from a 23-plex immunoMRM (iMRM) assay containing a subset of the candidate proteins applied to the same patient samples. The functional importance of improved detection and quantification was reflected in a markedly expanded list of significantly regulated proteins that provided many new candidate biomarker proteins. Preliminary evaluation of plasma sample labeling with TMT six-plex and ten-plex reagents suggests that even further increases in multiplexing of plasma analysis are practically achievable without significant losses in depth of detection relative to iTRAQ four-plex. These results obtained with our novel platform provide clear demonstration of the value of using isobaric mass tag reagents in plasma-based biomarker discovery experiments.

Published

2015

8. Ischemia in Tumors Induces Early and Sustained Phosphorylation Changes in Stress Kinase Pathways but Does Not Affect Global Protein Levels*

Author

Mertins, Philipp, Yang, Feng, Liu, Tao, Mani, D.R., Petyuk, Vladislav A., Gillette, Michael A., Clauser, Karl R., Qiao, Jana W., Gritsenko, Marina A., Moore, Ronald J., Levine, Douglas A., Townsend, Reid, Erdmann-Gilmore, Petra, Snider, Jacqueline E., Davies, Sherri R., Ruggles, Kelly V., Fenyo, David, Kitchens, R. Thomas, Li, Shunqiang, Olvera, Narciso, Dao, Fanny, Rodriguez, Henry, Chan, Daniel W., Liebler, Daniel, White, Forest, Rodland, Karin D., Mills, Gordon B., Smith, Richard D., Paulovich, Amanda G., Ellis, Matthew, and Carr, Steven A.

Abstract

Protein abundance and phosphorylation convey important information about pathway activity and molecular pathophysiology in diseases including cancer, providing biological insight, informing drug and diagnostic development, and guiding therapeutic intervention. Analyzed tissues are usually collected without tight regulation or documentation of ischemic time. To evaluate the impact of ischemia, we collected human ovarian tumor and breast cancer xenograft tissue without vascular interruption and performed quantitative proteomics and phosphoproteomics after defined ischemic intervals. Although the global expressed proteome and most of the >25,000 quantified phosphosites were unchanged after 60 min, rapid phosphorylation changes were observed in up to 24% of the phosphoproteome, representing activation of critical cancer pathways related to stress response, transcriptional regulation, and cell death. Both pan-tumor and tissue-specific changes were observed. The demonstrated impact of pre-analytical tissue ischemia on tumor biology mandates caution in interpreting stress-pathway activation in such samples and motivates reexamination of collection protocols for phosphoprotein analysis.

Published

2014

9. Proteome Informatics Research Group (iPRG)_2012: A Study on Detecting Modified Peptides in a Complex Mixture*

Author

Chalkley, Robert J., Bandeira, Nuno, Chambers, Matthew C., Clauser, Karl R., Cottrell, John S., Deutsch, Eric W., Kapp, Eugene A., Lam, Henry H.N., McDonald, W. Hayes, Neubert, Thomas A., and Sun, Rui-Xiang

Abstract

The proteome informatics research group of the Association of Biomolecular Resource Facilities conducted a study to assess the community's ability to detect and characterize peptides bearing a range of biologically occurring post-translational modifications when present in a complex peptide background. A data set derived from a mixture of synthetic peptides with biologically occurring modifications combined with a yeast whole cell lysate as background was distributed to a large group of researchers and their results were collectively analyzed. The results from the twenty-four participants, who represented a broad spectrum of experience levels with this type of data analysis, produced several important observations. First, there is significantly more variability in the ability to assess whether a results is significant than there is to determine the correct answer. Second, labile post-translational modifications, particularly tyrosine sulfation, present a challenge for most researchers. Finally, for modification site localization there are many tools being employed, but researchers are currently unsure of the reliability of the results these programs are producing.

Published

2014

10. Shotgun Protein Sequencing with Meta-contig Assembly*

Author

Guthals, Adrian, Clauser, Karl R., and Bandeira, Nuno

Abstract

Full-length de novosequencing from tandem mass (MS/MS) spectra of unknown proteins such as antibodies or proteins from organisms with unsequenced genomes remains a challenging open problem. Conventional algorithms designed to individually sequence each MS/MS spectrum are limited by incomplete peptide fragmentation or low signal to noise ratios and tend to result in short de novosequences at low sequencing accuracy. Our shotgun protein sequencing (SPS) approach was developed to ameliorate these limitations by first finding groups of unidentified spectra from the same peptides (contigs) and then deriving a consensus de novosequence for each assembled set of spectra (contig sequences). But whereas SPS enables much more accurate reconstruction of de novosequences longer than can be recovered from individual MS/MS spectra, it still requires error-tolerant matching to homologous proteins to group smaller contig sequences into full-length protein sequences, thus limiting its effectiveness on sequences from poorly annotated proteins. Using low and high resolution CID and high resolution HCD MS/MS spectra, we address this limitation with a Meta-SPS algorithm designed to overlap and further assemble SPS contigs into Meta-SPS de novocontig sequences extending as long as 100 amino acids at over 97% accuracy without requiring any knowledge of homologous protein sequences. We demonstrate Meta-SPS using distinct MS/MS data sets obtained with separate enzymatic digestions and discuss how the remaining de novosequencing limitations relate to MS/MS acquisition settings.

Published

2012

11. Modification Site Localization Scoring: Strategies and Performance

Author

Chalkley, Robert J. and Clauser, Karl R.

Abstract

Using enrichment strategies many research groups are routinely producing large data sets of post-translationally modified peptides for proteomic analysis using tandem mass spectrometry. Although search engines are relatively effective at identifying these peptides with a defined measure of reliability, their localization of site/s of modification is often arbitrary and unreliable. The field continues to be in need of a widely accepted metric for false localization rate that accurately describes the certainty of site localization in published data sets and allows for consistent measurement of differences in performance of emerging scoring algorithms. In this article are discussed the main strategies currently used by software for modification site localization and ways of assessing the performance of these different tools. Methods for representing ambiguity are reviewed and a discussion of how the approaches transfer to different data types and modifications is presented.

Published

2012

12. Methods for Quantification of in vivoChanges in Protein Ubiquitination following Proteasome and Deubiquitinase Inhibition*

Author

Udeshi, Namrata D., Mani, D.R., Eisenhaure, Thomas, Mertins, Philipp, Jaffe, Jacob D., Clauser, Karl R., Hacohen, Nir, and Carr, Steven A.

Abstract

Ubiquitination plays a key role in protein degradation and signal transduction. Ubiquitin is a small protein modifier that is adducted to lysine residues by the combined function of E1, E2, and E3 enzymes and is removed by deubiquitinating enzymes. Characterization of ubiquitination sites is important for understanding the role of this modification in cellular processes and disease. However, until recently, large-scale characterization of endogenous ubiquitination sites has been hampered by the lack of efficient enrichment techniques. The introduction of antibodies that specifically recognize peptides with lysine residues that harbor a di-glycine remnant (K-ε-GG) following tryptic digestion has dramatically improved the ability to enrich and identify ubiquitination sites from cellular lysates. We used this enrichment technique to study the effects of proteasome inhibition by MG-132 and deubiquitinase inhibition by PR-619 on ubiquitination sites in human Jurkat cells by quantitative high performance mass spectrometry. Minimal fractionation of digested lysates prior to immunoaffinity enrichment increased the yield of K-ε-GG peptides three- to fourfold resulting in detection of up to ∼3300 distinct K-GG peptides in SILAC triple encoded experiments starting from 5 mg of protein per label state. In total, we identify 5533 distinct K-ε-GG peptides of which 4907 were quantified in this study, demonstrating that the strategy presented is a practical approach to perturbational studies in cell systems. We found that proteasome inhibition by MG-132 and deubiquitinase inhibition by PR-619 induces significant changes to the ubiquitin landscape, but that not all ubiquitination sites regulated by MG-132 and PR-619 are likely substrates for the ubiquitin-proteasome system. Additionally, we find that the proteasome and deubiquitinase inhibitors studied induced only minor changes in protein expression levels regardless of the extent of regulation induced at the ubiquitin site level. We attribute this finding to the low stoichiometry of the majority ubiquitination sites identified in this study.

Published

2012

13. Interlaboratory Study Characterizing a Yeast Performance Standard for Benchmarking LC-MS Platform Performance

Author

Paulovich, Amanda G., Billheimer, Dean, Ham, Amy-Joan L., Vega-Montoto, Lorenzo, Rudnick, Paul A., Tabb, David L., Wang, Pei, Blackman, Ronald K., Bunk, David M., Cardasis, Helene L., Clauser, Karl R., Kinsinger, Christopher R., Schilling, Birgit, Tegeler, Tony J., Variyath, Asokan Mulayath, Wang, Mu, Whiteaker, Jeffrey R., Zimmerman, Lisa J., Fenyo, David, Carr, Steven A., Fisher, Susan J., Gibson, Bradford W., Mesri, Mehdi, Neubert, Thomas A., Regnier, Fred E., Rodriguez, Henry, Spiegelman, Cliff, Stein, Stephen E., Tempst, Paul, and Liebler, Daniel C.

Abstract

Optimal performance of LC-MS/MS platforms is critical to generating high quality proteomics data. Although individual laboratories have developed quality control samples, there is no widely available performance standard of biological complexity (and associated reference data sets) for benchmarking of platform performance for analysis of complex biological proteomes across different laboratories in the community. Individual preparations of the yeast Saccharomyces cerevisiae proteome have been used extensively by laboratories in the proteomics community to characterize LC-MS platform performance. The yeast proteome is uniquely attractive as a performance standard because it is the most extensively characterized complex biological proteome and the only one associated with several large scale studies estimating the abundance of all detectable proteins. In this study, we describe a standard operating protocol for large scale production of the yeast performance standard and offer aliquots to the community through the National Institute of Standards and Technology where the yeast proteome is under development as a certified reference material to meet the long term needs of the community. Using a series of metrics that characterize LC-MS performance, we provide a reference data set demonstrating typical performance of commonly used ion trap instrument platforms in expert laboratories; the results provide a basis for laboratories to benchmark their own performance, to improve upon current methods, and to evaluate new technologies. Additionally, we demonstrate how the yeast reference, spiked with human proteins, can be used to benchmark the power of proteomics platforms for detection of differentially expressed proteins at different levels of concentration in a complex matrix, thereby providing a metric to evaluate and minimize preanalytical and analytical variation in comparative proteomics experiments.

Published

2010

14. Performance Metrics for Liquid Chromatography-Tandem Mass Spectrometry Systems in Proteomics Analyses

Author

Rudnick, Paul A., Clauser, Karl R., Kilpatrick, Lisa E., Tchekhovskoi, Dmitrii V., Neta, Pedatsur, Blonder, Nikša, Billheimer, Dean D., Blackman, Ronald K., Bunk, David M., Cardasis, Helene L., Ham, Amy-Joan L., Jaffe, Jacob D., Kinsinger, Christopher R., Mesri, Mehdi, Neubert, Thomas A., Schilling, Birgit, Tabb, David L., Tegeler, Tony J., Vega-Montoto, Lorenzo, Variyath, Asokan Mulayath, Wang, Mu, Wang, Pei, Whiteaker, Jeffrey R., Zimmerman, Lisa J., Carr, Steven A., Fisher, Susan J., Gibson, Bradford W., Paulovich, Amanda G., Regnier, Fred E., Rodriguez, Henry, Spiegelman, Cliff, Tempst, Paul, Liebler, Daniel C., and Stein, Stephen E.

Abstract

A major unmet need in LC-MS/MS-based proteomics analyses is a set of tools for quantitative assessment of system performance and evaluation of technical variability. Here we describe 46 system performance metrics for monitoring chromatographic performance, electrospray source stability, MS1 and MS2 signals, dynamic sampling of ions for MS/MS, and peptide identification. Applied to data sets from replicate LC-MS/MS analyses, these metrics displayed consistent, reasonable responses to controlled perturbations. The metrics typically displayed variations less than 10% and thus can reveal even subtle differences in performance of system components. Analyses of data from interlaboratory studies conducted under a common standard operating procedure identified outlier data and provided clues to specific causes. Moreover, interlaboratory variation reflected by the metrics indicates which system components vary the most between laboratories. Application of these metrics enables rational, quantitative quality assessment for proteomics and other LC-MS/MS analytical applications.

Published

2010

15. Interlaboratory Study Characterizing a Yeast Performance Standard for Benchmarking LC-MS Platform Performance*

Author

Paulovich, Amanda G., Billheimer, Dean, Ham, Amy-Joan L., Vega-Montoto, Lorenzo, Rudnick, Paul A., Tabb, David L., Wang, Pei, Blackman, Ronald K., Bunk, David M., Cardasis, Helene L., Clauser, Karl R., Kinsinger, Christopher R., Schilling, Birgit, Tegeler, Tony J., Variyath, Asokan Mulayath, Wang, Mu, Whiteaker, Jeffrey R., Zimmerman, Lisa J., Fenyo, David, Carr, Steven A., Fisher, Susan J., Gibson, Bradford W., Mesri, Mehdi, Neubert, Thomas A., Regnier, Fred E., Rodriguez, Henry, Spiegelman, Cliff, Stein, Stephen E., Tempst, Paul, and Liebler, Daniel C.

Abstract

Optimal performance of LC-MS/MS platforms is critical to generating high quality proteomics data. Although individual laboratories have developed quality control samples, there is no widely available performance standard of biological complexity (and associated reference data sets) for benchmarking of platform performance for analysis of complex biological proteomes across different laboratories in the community. Individual preparations of the yeast Saccharomyces cerevisiaeproteome have been used extensively by laboratories in the proteomics community to characterize LC-MS platform performance. The yeast proteome is uniquely attractive as a performance standard because it is the most extensively characterized complex biological proteome and the only one associated with several large scale studies estimating the abundance of all detectable proteins. In this study, we describe a standard operating protocol for large scale production of the yeast performance standard and offer aliquots to the community through the National Institute of Standards and Technology where the yeast proteome is under development as a certified reference material to meet the long term needs of the community. Using a series of metrics that characterize LC-MS performance, we provide a reference data set demonstrating typical performance of commonly used ion trap instrument platforms in expert laboratories; the results provide a basis for laboratories to benchmark their own performance, to improve upon current methods, and to evaluate new technologies. Additionally, we demonstrate how the yeast reference, spiked with human proteins, can be used to benchmark the power of proteomics platforms for detection of differentially expressed proteins at different levels of concentration in a complex matrix, thereby providing a metric to evaluate and minimize preanalytical and analytical variation in comparative proteomics experiments.

Published

2010

16. Performance Metrics for Liquid Chromatography-Tandem Mass Spectrometry Systems in Proteomics Analyses*

Author

Rudnick, Paul A., Clauser, Karl R., Kilpatrick, Lisa E., Tchekhovskoi, Dmitrii V., Neta, Pedatsur, Blonder, Nikša, Billheimer, Dean D., Blackman, Ronald K., Bunk, David M., Cardasis, Helene L., Ham, Amy-Joan L., Jaffe, Jacob D., Kinsinger, Christopher R., Mesri, Mehdi, Neubert, Thomas A., Schilling, Birgit, Tabb, David L., Tegeler, Tony J., Vega-Montoto, Lorenzo, Variyath, Asokan Mulayath, Wang, Mu, Wang, Pei, Whiteaker, Jeffrey R., Zimmerman, Lisa J., Carr, Steven A., Fisher, Susan J., Gibson, Bradford W., Paulovich, Amanda G., Regnier, Fred E., Rodriguez, Henry, Spiegelman, Cliff, Tempst, Paul, Liebler, Daniel C., and Stein, Stephen E.

Abstract

A major unmet need in LC-MS/MS-based proteomics analyses is a set of tools for quantitative assessment of system performance and evaluation of technical variability. Here we describe 46 system performance metrics for monitoring chromatographic performance, electrospray source stability, MS1 and MS2 signals, dynamic sampling of ions for MS/MS, and peptide identification. Applied to data sets from replicate LC-MS/MS analyses, these metrics displayed consistent, reasonable responses to controlled perturbations. The metrics typically displayed variations less than 10% and thus can reveal even subtle differences in performance of system components. Analyses of data from interlaboratory studies conducted under a common standard operating procedure identified outlier data and provided clues to specific causes. Moreover, interlaboratory variation reflected by the metrics indicates which system components vary the most between laboratories. Application of these metrics enables rational, quantitative quality assessment for proteomics and other LC-MS/MS analytical applications.

Published

2010

17. Shotgun Protein Sequencing

Author

Bandeira, Nuno, Clauser, Karl R., and Pevzner, Pavel A.

Abstract

Despite significant advances in the identification of known proteins, the analysis of unknown proteins by MS/MS still remains a challenging open problem. Although Klaus Biemann recognized the potential of MS/MS for sequencing of unknown proteins in the 1980s, low throughput Edman degradation followed by cloning still remains the main method to sequence unknown proteins. The automated interpretation of MS/MS spectra has been limited by a focus on individual spectra and has not capitalized on the information contained in spectra of overlapping peptides. Indeed the powerful shotgun DNA sequencing strategies have not been extended to automated protein sequencing. We demonstrate, for the first time, the feasibility of automated shotgun protein sequencing of protein mixtures by utilizing MS/MS spectra of overlapping and possibly modified peptides generated via multiple proteases of different specificities. We validate this approach by generating highly accurate de novoreconstructions of multiple regions of various proteins in western diamondback rattlesnake venom. We further argue that shotgun protein sequencing has the potential to overcome the limitations of current protein sequencing approaches and thus catalyze the otherwise impractical applications of proteomics methodologies in studies of unknown proteins.

Published

2007

18. TAILS Identifies Candidate Substrates and Biomarkers of ADAMTS7, a Therapeutic Protease Target in Coronary Artery Disease

Author

MacDonald, Bryan T., Keshishian, Hasmik, Mundorff, Charles C., Arduini, Alessandro, Lai, Daniel, Bendinelli, Kayla, Popp, Nicholas R., Bhandary, Bidur, Clauser, Karl R., Specht, Harrison, Elowe, Nadine H., Laprise, Dylan, Xing, Yi, Kaushik, Virendar K., Carr, Steven A., and Ellinor, Patrick T.

Abstract

Loss-of-function mutations in the secreted enzyme ADAMTS7 (a disintegrin and metalloproteinase with thrombospondin motifs 7) are associated with protection for coronary artery disease. ADAMTS7 catalytic inhibition has been proposed as a therapeutic strategy for treating coronary artery disease; however, the lack of an endogenous substrate has hindered the development of activity-based biomarkers. To identify ADAMTS7 extracellular substrates and their cleavage sites relevant to vascular disease, we used TAILS (terminal amine isotopic labeling of substrates), a method for identifying protease-generated neo–N termini. We compared the secreted proteome of vascular smooth muscle and endothelial cells expressing either full-length mouse ADAMTS7 WT, catalytic mutant ADAMTS7 E373Q, or a control luciferase adenovirus. Significantly enriched N-terminal cleavage sites in ADAMTS7 WT samples were compared to the negative control conditions and filtered for stringency, resulting in catalogs of high confidence candidate ADAMTS7 cleavage sites from our three independent TAILS experiments. Within the overlap of these discovery sets, we identified 24 unique cleavage sites from 16 protein substrates, including cleavage sites in EFEMP1 (EGF-containing fibulin-like extracellular matrix protein 1/Fibulin-3). The ADAMTS7 TAILS preference for EFEMP1 cleavage at the amino acids 123.124 over the adjacent 124.125 site was validated using both endogenous EFEMP1 and purified EFEMP1 in a binary in vitrocleavage assay. Collectively, our TAILS discovery experiments have uncovered hundreds of potential substrates and cleavage sites to explore disease-related biological substrates and facilitate activity-based ADAMTS7 biomarker development.

Published

2022

19. Mass spectrometry-based HLA-II peptidomics combined with multi-omics will aid the development of future immunotherapies

Author

Taylor, Hannah B., Klaeger, Susan, Clauser, Karl R., Sarkizova, Siranush, Weingarten-Gabbay, Shira, Graham, Daniel B., Carr, Steven A., and Abelin, Jennifer G.

Abstract

Immunotherapies have emerged to treat diseases by selectively modulating a patient’s immune response. Although the roles of T and B cells in adaptive immunity have been well studied, it remains difficult to select targets for immunotherapeutic strategies. Because human leukocyte antigen class II (HLA-II) peptides activate CD4+ T cells and regulate B cell activation, proliferation, and differentiation, these peptide antigens represent a class of potential immunotherapy targets and biomarkers. To better understand the molecular basis of how HLA-II antigen presentation is involved in disease progression and treatment, systematic HLA-II peptidomics combined with multi-omic analyses of diverse cell types in healthy and diseased states is required. For this reason, mass spectrometry based innovations that facilitate investigations into the interplay between disease pathologies and the presentation of HLA-II peptides to CD4+ T cells will aid in the development of patient focused immunotherapies.

Published

2021

20. Optimized Liquid and Gas Phase Fractionation Increases HLA-Peptidome Coverage for Primary Cell and Tissue Samples

Author

Klaeger, Susan, Apffel, Annie, Clauser, Karl R., Sarkizova, Siranush, Oliveira, Giacomo, Rachimi, Suzanna, Le, Phuong M., Tarren, Anna, Chea, Vipheaviny, Abelin, Jennifer G., Braun, David A., Ott, Patrick A., Keshishian, Hasmik, Hacohen, Nir, Keskin, Derin B., Wu, Catherine J., and Carr, Steven A.

Abstract

MS is the most effective method to directly identify peptides presented on human leukocyte antigen (HLA) molecules. However, current standard approaches often use 500 million or more cells as input to achieve high coverage of the immunopeptidome, and therefore, these methods are not compatible with the often limited amounts of tissue available from clinical tumor samples. Here, we evaluated microscaled basic reversed-phase fractionation to separate HLA peptide samples offline followed by ion mobility coupled to LC–MS/MS for analysis. The combination of these two separation methods enabled identification of 20% to 50% more peptides compared with samples analyzed without either prior fractionation or use of ion mobility alone. We demonstrate coverage of HLA immunopeptidomes with up to 8107 distinct peptides starting with as few as 100 million cells. The increased sensitivity obtained using our methods can provide data useful to improve HLA-binding prediction algorithms as well as to enable detection of clinically relevant epitopes such as neoantigens.

Published

2021

21. Streamlined Protocol for Deep Proteomic Profiling of FAC-sorted Cells and Its Application to Freshly Isolated Murine Immune Cells*

Author

Myers, Samuel A., Rhoads, Andrew, Cocco, Alexandra R., Peckner, Ryan, Haber, Adam L., Schweitzer, Lawrence D., Krug, Karsten, Mani, D.R., Clauser, Karl R., Rozenblatt-Rosen, Orit, Hacohen, Nir, Regev, Aviv, and Carr, Steven A.

Abstract

A streamlined and readily accessible sample preparation protocol has been developed to enable TMT-based proteomic profiling of relatively low numbers of cells directly from a flow cytometer. These methods were applied to 12 freshly isolated immune cell types from mice to a depth of over 7000 quantified proteins. These data recapitulate many aspects of known immunology, nominate new cell type specific protein markers, and provide evidence for post-transcriptional regulation of gene expression across the immune system.

Published

2019

22. iTRAQ Labeling is Superior to mTRAQ for Quantitative Global Proteomics and Phosphoproteomics*

Author

Mertins, Philipp, Udeshi, Namrata D., Clauser, Karl R., Mani, DR, Patel, Jinal, Ong, Shao-en, Jaffe, Jacob D., and Carr, Steven A.

Abstract

Labeling of primary amines on peptides with reagents containing stable isotopes is a commonly used technique in quantitative mass spectrometry. Isobaric labeling techniques such as iTRAQ™ or TMT™ allow for relative quantification of peptides based on ratios of reporter ions in the low m/z region of spectra produced by precursor ion fragmentation. In contrast, nonisobaric labeling with mTRAQ™ yields precursors with different masses that can be directly quantified in MS1 spectra. In this study, we compare iTRAQ- and mTRAQ-based quantification of peptides and phosphopeptides derived from EGF-stimulated HeLa cells. Both labels have identical chemical structures, therefore precursor ion- and fragment ion-based quantification can be directly compared. Our results indicate that iTRAQ labeling has an additive effect on precursor intensities, whereas mTRAQ labeling leads to more redundant MS2 scanning events caused by triggering on the same peptide with different mTRAQ labels. We found that iTRAQ labeling quantified nearly threefold more phosphopeptides (12,129 versus4,448) and nearly twofold more proteins (2,699 versus1,597) than mTRAQ labeling. Although most key proteins in the EGFR signaling network were quantified with both techniques, iTRAQ labeling allowed quantification of twice as many kinases. Accuracy of reporter ion quantification by iTRAQ is adversely affected by peptides that are cofragmented in the same precursor isolation window, dampening observed ratios toward unity. However, because of tighter overall iTRAQ ratio distributions, the percentage of statistically significantly regulated phosphopeptides and proteins detected by iTRAQ and mTRAQ was similar. We observed a linear correlation of logarithmic iTRAQ to mTRAQ ratios over two orders of magnitude, indicating a possibility to correct iTRAQ ratios by an average compression factor. Spike-in experiments using peptides of defined ratios in a background of nonregulated peptides show that iTRAQ quantification is less accurate but not as variable as mTRAQ quantification.

Published

2012

23. The Matrisome: In Silico Definition and In Vivo Characterization by Proteomics of Normal and Tumor Extracellular Matrices

Author

Naba, Alexandra, Clauser, Karl R., Hoersch, Sebastian, Liu, Hui, Carr, Steven A., and Hynes, Richard O.

Abstract

The extracellular matrix (ECM) is a complex meshwork of cross-linked proteins providing both biophysical and biochemical cues that are important regulators of cell proliferation, survival, differentiation, and migration. We present here a proteomic strategy developed to characterize the in vivo ECM composition of normal tissues and tumors using enrichment of protein extracts for ECM components and subsequent analysis by mass spectrometry. In parallel, we have developed a bioinformatic approach to predict the in silico "matrisome" defined as the ensemble of ECM proteins and associated factors. We report the characterization of the extracellular matrices of murine lung and colon, each comprising more than 100 ECM proteins and each presenting a characteristic signature. Moreover, using human tumor xenografts in mice, we show that both tumor cells and stromal cells contribute to the production of the tumor matrix and that tumors of differing metastatic potential differ in both the tumor- and the stroma-derived ECM components. The strategy we describe and illustrate here can be broadly applied and, to facilitate application of these methods by others, we provide resources including laboratory protocols, inventories of ECM domains and proteins, and instructions for bioinformatically deriving the human and mouse matrisome.

Published

2012

24. The Matrisome: In SilicoDefinition and In VivoCharacterization by Proteomics of Normal and Tumor Extracellular Matrices*

Author

Naba, Alexandra, Clauser, Karl R., Hoersch, Sebastian, Liu, Hui, Carr, Steven A., and Hynes, Richard O.

Abstract

The extracellular matrix (ECM) is a complex meshwork of cross-linked proteins providing both biophysical and biochemical cues that are important regulators of cell proliferation, survival, differentiation, and migration. We present here a proteomic strategy developed to characterize the in vivoECM composition of normal tissues and tumors using enrichment of protein extracts for ECM components and subsequent analysis by mass spectrometry. In parallel, we have developed a bioinformatic approach to predict the in silico“matrisome” defined as the ensemble of ECM proteins and associated factors. We report the characterization of the extracellular matrices of murine lung and colon, each comprising more than 100 ECM proteins and each presenting a characteristic signature. Moreover, using human tumor xenografts in mice, we show that both tumor cells and stromal cells contribute to the production of the tumor matrix and that tumors of differing metastatic potential differ in both the tumor- and the stroma-derived ECM components. The strategy we describe and illustrate here can be broadly applied and, to facilitate application of these methods by others, we provide resources including laboratory protocols, inventories of ECM domains and proteins, and instructions for bioinformatically deriving the human and mouse matrisome.

Published

2012

25. A Face in the Crowd: Recognizing Peptides Through Database Search*

Author

Eng, Jimmy K., Searle, Brian C., Clauser, Karl R., and Tabb, David L.

Abstract

Peptide identification via tandem mass spectrometry sequence database searching is a key method in the array of tools available to the proteomics researcher. The ability to rapidly and sensitively acquire tandem mass spectrometry data and perform peptide and protein identifications has become a commonly used proteomics analysis technique because of advances in both instrumentation and software. Although many different tandem mass spectrometry database search tools are currently available from both academic and commercial sources, these algorithms share similar core elements while maintaining distinctive features. This review revisits the mechanism of sequence database searching and discusses how various parameter settings impact the underlying search.

Published

2011

26. A Face in the Crowd: Recognizing Peptides Through Database Search

Author

Eng, Jimmy K., Searle, Brian C., Clauser, Karl R., and Tabb, David L.

Abstract

Peptide identification via tandem mass spectrometry sequence database searching is a key method in the array of tools available to the proteomics researcher. The ability to rapidly and sensitively acquire tandem mass spectrometry data and perform peptide and protein identifications has become a commonly used proteomics analysis technique because of advances in both instrumentation and software. Although many different tandem mass spectrometry database search tools are currently available from both academic and commercial sources, these algorithms share similar core elements while maintaining distinctive features. This review revisits the mechanism of sequence database searching and discusses how various parameter settings impact the underlying search.

Published

2011