Sharing and community curation of mass spectrometry data with Global Natural Products Social Molecular Networking

Wang, Mingxun; Carver, Jeremy; Phelan, Vanessa V.; Sanchez, Laura M.; Garg, Neha; Peng, Yao; Nguyen, Don D.; Watrous, Jeramie D.; Kapono, Clifford A.; Luzzatto-Knaan, Tal; Porto, Carla; Bouslimani, Amina; Melnik, Alexey V.; Meehan, Michael J.; Liu, Wei-Ting; Crüsemann, Max; Boudreau, Paul D.; Esquenazi, Eduardo; Sandoval-Calderón, Mario; Kersten, Roland D.; Pace, Laura A.; Quinn, Robert A.; Duncan, Katherine R.; Hsu, Cheng-Chih; Floros, Dimitrios J.; Gavilán, Ronnie G.; Kleigrewe, Karin; Northen, Trent; Dutton, Rachel J.; Parrot, Delphine; Carlson, Erin E.; Aigle, Bertrand; Michelsen, Charlotte Frydenlund; Jelsbak, Lars; Sohlenkamp, Christian; Pevzner, Pavel A.; Edlund, Anna; McLean, Jeffrey S.; Piel, Jörn; Murphy, Brian T.; Gerwick, Lena; Liaw, Chih‐Chuang; Yang, Yu‐Liang; Humpf, Hans‐Ulrich; Maansson, Maria; Keyzers, Robert A.; Sims, Amy C.; Johnson, Andrew R.; Sidebottom, Ashley M.; Sedio, Brian E.; Klitgaard, Andreas; Larson, Christopher; P., Cristopher A. Boya; Torres-Mendoza, Daniel; Gonzalez, David J.; Silva, Denise Brentan; Marques, Lucas Maciel Mauriz; Demarque, Daniel P.; Pociūtė, Eglė; O’Neill, Ellis C.; Briand, Enora; Helfrich, Eric J. N.; Granatosky, Eve A.; Glukhov, Evgenia; Ryffel, Florian; Houson, Hailey; Mohimani, Hosein; Kharbush, Jenan J.; Zeng, Yi; Vorholt, Julia A.; Kurita, Kenji L.; Charusanti, Pep; McPhail, Kerry L.; Nielsen, Kristian Fog; Vuong, Lisa; Elfeki, Maryam; Traxler, Matthew F.; Engene, Niclas; Koyama, Nobuhiro; Vining, Oliver B.; Baric, Ralph S.; Silva, Ricardo R.; Mascuch, Samantha J.; Tomasi, Sophie; Jenkins, Stefan; Macherla, Venkat R.; Hoffman, Thomas J.; Agarwal, Vinayak; Williams, Philip G.; Dai, Jingqui; Neupane, Ram; Gurr, Joshua R.; Rodríguez, Andrés; Lamsa, Anne; Zhang, Chen; Dorrestein, Kathleen; Duggan, Brendan M.; Almaliti, Jehad; Allard, Pierre‐Marie; Phapale, Prasad; Nothias, Louis‐Félix; Alexandrov, Theodore; Litaudon, Marc; Wolfender, Jean‐Luc; Kyle, Jennifer; Metz, Thomas O.; Peryea, Tyler; Nguyễn, Ðắc-Trung; VanLeer, Danielle; Shinn, Paul; Jadhav, Ajit; Müller, Rolf; Waters, Katrina M.; Shi, Wenyuan; Liu, Xueting; Zhang, Linxin; Knight, Rob; Jensen, Paul R.; Palsson, Bernhard Ø.; Pogliano, Kit; Linington, Roger G.; Gutiérrez, Marcelino; Lopes, Norberto P.; Gerwick, William H.; Moore, Bradley S.; Dorrestein, Pieter C.; Bandeira, Nuno

doi:10.1038/nbt.3597

Cited by 2,885 publications

(3,020 citation statements)

References 65 publications

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“…This analysis defines spectral proximity between all MS/MS spectra of a dataset and visualizes them in a spectral network (Watrous et al, 2012). For the molecular annotation we compared the MS/MS spectra to a spectral library including the GNPS community contributed spectral library as well as Massbank, ReSpect, HMDB, and NIST14 (Forsythe and Wishart, 2009;Horai et al, 2010;Sawada et al, 2012;Stein, 2014;Wang et al, 2016). The overall goal of such an analysis is to enable robust, untargeted comparison of multiple samples at the molecular level.…”

Section: Experimental Conceptmentioning

confidence: 99%

“…After feature extraction from MS1, we calculated molecular formulas based on exact masses of individual and consensus features. In parallel, we performed clustering of identical MS/MS spectra and multiple spectra alignments using the Global Natural Product Social molecular networking (GNPS) (Wang et al, 2016). This analysis defines spectral proximity between all MS/MS spectra of a dataset and visualizes them in a spectral network (Watrous et al, 2012).…”

Section: Experimental Conceptmentioning

confidence: 99%

“…Besides dereplication of known compounds from the libraries, an additional multiple spectral alignment of all clustered spectra was performed. Thereby, all spectra are compared to each other using cosine similarity scoring (Stein and Scott, 1994) and spectrum-spectrum matches, with a cosine score higher or equal to 0.7 are connected as "nodes" in a network (Watrous et al, 2012;Wang et al, 2016). If nodes yielded a database hit during a spectrum library search, they can be labeled as specific compounds and nodes around the "hit" can be assumed to have similar chemical scaffolds.…”

Section: Tandem Mass Spectrometry and Spectral Networkingmentioning

confidence: 99%

“…With a medium resolution (R m/z 200 = 17.000), the iterative scan cycles result in several thousand spectra per sample. To reduce redundancy and computation time we clustered identical spectra to consensus spectra (Frank et al, 2008) and searched them against several spectral libraries, including GNPS (Wang et al, 2016), MassBank (Horai et al, 2010), ReSpect (Sawada et al, 2012) HMDB (Forsythe and Wishart, 2009), and NIST 2014 (Stein, 2014). Hereby a strict precursor mass tolerance of m/z 0.01 was used first, followed by a maximum allowed precursor delta mass of up to m/z 100, with the intention to annotate putative analogs.…”

Section: Tandem Mass Spectrometry and Spectral Networkingmentioning

confidence: 99%

See 3 more Smart Citations

High-Resolution Liquid Chromatography Tandem Mass Spectrometry Enables Large Scale Molecular Characterization of Dissolved Organic Matter

et al. 2017

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Dissolved organic matter (DOM) is arguably one of the most complex exometabolomes on earth, and is comprised of thousands of compounds, that together contribute more than 600 × 10 15 g carbon. This reservoir is primarily the product of interactions between the upper ocean's microbial food web, yet abiotic processes that occur over millennia have also modified many of its molecules. The compounds within this reservoir play important roles in determining the rate and extent of element exchange between inorganic reservoirs and the marine biosphere, while also mediating microbe-microbe interactions. As such, there has been a widespread effort to characterize DOM using high-resolution analytical methods including nuclear magnetic resonance spectroscopy (NMR) and mass spectrometry (MS). To date, molecular information in DOM has been primarily obtained through calculated molecular formulas from exact mass. This approach has the advantage of being non-targeted, accessing the inherent complexity of DOM. Molecular structures are however still elusive and the most commonly used instruments are costly. More recently, tandem mass spectrometry has been employed to more precisely identify DOM components through comparison to library mass spectra. Here we describe a data acquisition and analysis workflow that expands the repertoire of high-resolution analytical approaches available to access the complexity of DOM molecules that are amenable to electrospray ionization (ESI) MS. We couple liquid chromatographic separation with tandem MS (LC-MS/MS) and a data analysis pipeline, that integrates peak extraction from extracted ion chromatograms (XIC), molecular formula calculation and molecular networking. This provides more precise structural characterization. Although only around 1% of detectable DOM compounds can be annotated through publicly available spectral libraries, community-wide participation in populating and annotating DOM datasets could rapidly increase the annotation rate and should be broadly encouraged. Our analysis also identifies shortcomings of the current Petras et al. LC-MS/MS Analysis of DOMdata analysis workflow that need to be addressed by the community in the future. This work will lay the foundation for an integrative, non-targeted molecular analysis of DOM which, together with next generation sequencing, meta-proteomics and physical data, will pave the way to a more comprehensive understanding of the role of DOM in structuring marine ecosystems.

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Section: Experimental Conceptmentioning

confidence: 99%

Section: Experimental Conceptmentioning

confidence: 99%

Section: Tandem Mass Spectrometry and Spectral Networkingmentioning

confidence: 99%

Section: Tandem Mass Spectrometry and Spectral Networkingmentioning

confidence: 99%

See 2 more Smart Citations

High-Resolution Liquid Chromatography Tandem Mass Spectrometry Enables Large Scale Molecular Characterization of Dissolved Organic Matter

et al. 2017

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“…This genus has already yielded over 190 new NPs in the past two decades, accounting for more than 40% of all reported marine cyanobacterial NPs (8). The discovery of these NPs was mostly driven by classical isolation approaches, although this has been accelerated by the recent development of mass spectrometry (MS)-based molecular networking (groups metabolites according to their MS fragmentation fingerprints, simplifying the search for new NPs or their analogs) (9). Genomic analyses of these filamentous cyanobacteria have revealed that even well-studied strains possess additional genetic capacity to produce novel and chemically unique NPs (10), and suggest that bottom-up approaches (11) would be productive; a recent example is given by the discovery and description of the columbamides from Moorea bouillonii (12).…”

mentioning

confidence: 99%

Comparative genomics uncovers the prolific and distinctive metabolic potential of the cyanobacterial genus Moorea

Leão

Castelão

Korobeynikov

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Cyanobacteria are major sources of oxygen, nitrogen, and carbon in nature. In addition to the importance of their primary metabolism, some cyanobacteria are prolific producers of unique and bioactive secondary metabolites. Chemical investigations of the cyanobacterial genus Moorea have resulted in the isolation of over 190 compounds in the last two decades. However, preliminary genomic analysis has suggested that genome-guided approaches can enable the discovery of novel compounds from even well-studied Moorea strains, highlighting the importance of obtaining complete genomes. We report a complete genome of a filamentous tropical marine cyanobacterium, Moorea producens PAL, which reveals that about one-fifth of its genome is devoted to production of secondary metabolites, an impressive four times the cyanobacterial average. Moreover, possession of the complete PAL genome has allowed improvement to the assembly of three other Moorea draft genomes. Comparative genomics revealed that they are remarkably similar to one another, despite their differences in geography, morphology, and secondary metabolite profiles. Gene cluster networking highlights that this genus is distinctive among cyanobacteria, not only in the number of secondary metabolite pathways but also in the content of many pathways, which are potentially distinct from all other bacterial gene clusters to date. These findings portend that future genome-guided secondary metabolite discovery and isolation efforts should be highly productive.

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Deciphering metabolic crosstalk in context: lessons from inflammatory diseases

Verheijen,

Tran,

Chang

et al. 2024

Molecular Oncology

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Metabolism plays a crucial role in regulating the function of immune cells in both health and disease, with altered metabolism contributing to the pathogenesis of cancer and many inflammatory diseases. The local microenvironment has a profound impact on the metabolism of immune cells. Therefore, immunological and metabolic heterogeneity as well as the spatial organization of cells in tissues should be taken into account when studying immunometabolism. Here, we highlight challenges of investigating metabolic communication. Additionally, we review the capabilities and limitations of current technologies for studying metabolism in inflamed microenvironments, including single‐cell omics techniques, flow cytometry‐based methods (Met‐Flow, single‐cell energetic metabolism by profiling translation inhibition (SCENITH)), cytometry by time of flight (CyTOF), cellular indexing of transcriptomes and epitopes by sequencing (CITE‐Seq), and mass spectrometry imaging. Considering the importance of metabolism in regulating immune cells in diseased states, we also discuss the applications of metabolomics in clinical research, as well as some hurdles to overcome to implement these techniques in standard clinical practice. Finally, we provide a flowchart to assist scientists in designing effective strategies to unravel immunometabolism in disease‐relevant contexts.

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Sharing and community curation of mass spectrometry data with Global Natural Products Social Molecular Networking

Cited by 2,885 publications

References 65 publications

High-Resolution Liquid Chromatography Tandem Mass Spectrometry Enables Large Scale Molecular Characterization of Dissolved Organic Matter

High-Resolution Liquid Chromatography Tandem Mass Spectrometry Enables Large Scale Molecular Characterization of Dissolved Organic Matter

Comparative genomics uncovers the prolific and distinctive metabolic potential of the cyanobacterial genus Moorea

Deciphering metabolic crosstalk in context: lessons from inflammatory diseases

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