Sage Journals: Discover world-class research

Abstract

Currently, mass spectrometry-based data-dependent acquisition protocols require several micrograms to milligram amounts of proteins to start with, and needs fractionation and enrichment or depletion protocols to identify low abundant proteins and their modifications. However, a data-independent acquisition (DIA) approach can help us to identify a large number of proteins irrespective of their abundance, from even a very low amount of protein. In the DIA protocol, mass spectrometry data are matched against a previously established tandem mass spectrometry (MS/MS) spectra for each peptide. Therefore, establishing a spectral library is a prerequisite for successful DIA protocol. However, the DIA protocol becomes extremely important to investigate biological systems, where there is a difficulty in gathering reasonable amounts of proteins. In this context, DIA can become a valuable tool to investigate proteome dynamics of slow growing pathogen such as Mycobacterium tuberculosis that causes tuberculosis. We report here a case study of the DIA approach that is ideal for M. tuberculosis, which cannot be scaled up easily as it requires specific BSL3 laboratory facilities to be grown. We generated a spectral library for M. tuberculosis proteome using six publicly available proteomic data sets. The in-house M. tuberculosis proteome spectral library contains MS/MS spectra for peptides corresponding to 88% of proteins when compared with the M. tuberculosis H37Rv proteome. We believe that the public availability of the M. tuberculosis spectral library is an important step forward to facilitate the research community to adopt DIA approaches, for example, to investigate M. tuberculosis proteome with greater depth and efficiency.

Get full access to this article

View all access options for this article.

References

Advani

, Verma

, Chatterjee

, et al. (2019). Whole genome sequencing of Mycobacterium tuberculosis clinical isolates from India reveals genetic heterogeneity and region-specific variations that might affect drug susceptibility. Front Microbiol, 10, 309.

Bruderer

, Bernhardt

, Gandhi

, et al. (2017). Optimization of experimental parameters in data-independent mass spectrometry significantly increases depth and reproducibility of results. Mol Cell Proteomics, 16, 2296–2309.

Calder

, Soares

, De Kock

, and Blackburn

. (2015). Mycobacterial proteomics: Analysis of expressed proteomes and post-translational modifications to identify candidate virulence factors. Expert Rev Proteomics, 12, 21–35.

Cohen

, Manson

, Desjardins

, Abeel

, and Earl

. (2019). Deciphering drug resistance in Mycobacterium tuberculosis using whole-genome sequencing: Progress, promise, and challenges. Genome Med, 11, 45.

Cortes

, Schubert

, Banaei-Esfahani

, et al. (2017). Delayed effects of transcriptional responses in Mycobacterium tuberculosis exposed to nitric oxide suggest other mechanisms involved in survival. Sci Rep, 7, 8208.

Cox

, and Mann

. (2008). MaxQuant enables high peptide identification rates, individualized ppb-range mass accuracies, and proteome-wide protein quantification. Nat Biotechnol, 26, 1367–1372.

Craft

, Chen

, and Nairn

. (2013). Recent advances in quantitative neuroproteomics. Methods, 61, 186–218.

Deutsch

, Perez-Riverol

, Chalkley

, et al. (2018). Expanding the use of spectral libraries in proteomics. J Proteome Res, 17, 4051–4060.

Frewen

, and Maccoss

. (2007). Using BiblioSpec for creating and searching tandem MS peptide libraries. Curr Protoc Bioinformatics Chapter 13, Unit 13.17.

10.

Gessulat

, Schmidt

, Zolg

, et al. (2019). Prosit: Proteome-wide prediction of peptide tandem mass spectra by deep learning. Nat Methods, 16, 509–518.

11.

Gillet

, Navarro

, Tate

, et al. (2012). Targeted data extraction of the MS/MS spectra generated by data-independent acquisition: A new concept for consistent and accurate proteome analysis. Mol Cell Proteomics, 11, O111.016717.

12.

Jhingan

, Kumari

, Jamwal

, et al. (2016). Comparative proteomic analyses of avirulent, virulent, and clinical strains of Mycobacterium tuberculosis identify strain-specific patterns. J Biol Chem, 291, 14257–14273.

13.

Kind

, Tsugawa

, Cajka

, et al. (2018). Identification of small molecules using accurate mass MS/MS search. Mass Spectrom Rev, 37, 513–532.

14.

Lam

. (2011). Building and searching tandem mass spectral libraries for peptide identification. Mol Cell Proteomics, 10, R111.008565.

15.

Maclean

, Tomazela

, Shulman

, et al. (2010). Skyline: An open source document editor for creating and analyzing targeted proteomics experiments. Bioinformatics, 26, 966–968.

16.

Nieto

, Mehaffy

, Islam

, et al. (2018). Biochemical characterization of isoniazid-resistant Mycobacterium tuberculosis: Can the analysis of clonal strains reveal novel targetable pathways?. Mol Cell Proteomics, 17, 1685–1701.

17.

Pinto

, Verma

, Advani

, et al. (2018). Integrated multi-omic analysis of Mycobacterium tuberculosis H37Ra redefines virulence attributes. Front Microbiol, 9, 1314.

18.

Schubert

, Gillet

, Collins

, et al. (2015a). Building high-quality assay libraries for targeted analysis of SWATH MS data. Nat Protoc, 10, 426–441.

19.

Schubert

, Ludwig

, Kogadeeva

, et al. (2015b). Absolute proteome composition and dynamics during dormancy and resuscitation of Mycobacterium tuberculosis. Cell Host Microbe, 18, 96–108.

20.

Sharma

, Eng

, Feldman

, et al. (2010). Precursor charge state prediction for electron transfer dissociation tandem mass spectra. J Proteome Res, 9, 5438–5444.

21.

Stahl

, Swiderek

, Davis

, and Lee

. (1996). Data-controlled automation of liquid chromatography/tandem mass spectrometry analysis of peptide mixtures. J Am Soc Mass Spectrom, 7, 532–540.

22.

Swaney

, Wenger

, and Coon

. (2010). Value of using multiple proteases for large-scale mass spectrometry-based proteomics. J Proteome Res, 9, 1323–1329.

23.

Tiwary

, Levy

, Gutenbrunner

, et al. (2019). High-quality MS/MS spectrum prediction for data-dependent and data-independent acquisition data analysis. Nat Methods, 16, 519–525.

24.

Venable

, Dong

, Wohlschlegel

, Dillin

, and Yates

. (2004). Automated approach for quantitative analysis of complex peptide mixtures from tandem mass spectra. Nat Methods, 1, 39–45.

25.

Verma

, Pinto

, Patil

, et al. (2017). Quantitative proteomic and phosphoproteomic analysis of H37Ra and H37Rv strains of Mycobacterium tuberculosis. J Proteome Res, 16, 1632–1645.

26.

Yimer

, Birhanu

, Kalayou

, et al. (2017). Comparative proteomic analysis of Mycobacterium tuberculosis lineage 7 and lineage 4 strains reveals differentially abundant proteins linked to slow growth and virulence. Front Microbiol, 8, 795.

27.

Zhang

, Zhang

, Xu

, Lou

, and Qiu

. (2017). TLR-4/miRNA-32-5p/FSTL1 signaling regulates mycobacterial survival and inflammatory responses in Mycobacterium tuberculosis-infected macrophages. Exp Cell Res, 352, 313–321.

28.

Zhu

, Zhu

, Xuan

, et al. (2020). DPHL: A DIA pan-human protein mass spectrometry library for robust biomarker discovery. Genomics Proteomics Bioinformatics, 18, 104–119.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

11.48 MB

Data-Independent Acquisition Approach to Proteome: A Case Study and a Spectral Library for Mass Spectrometry-Based Investigation of Mycobacterium tuberculosis

Abstract

Get full access to this article

References

Supplementary Material