Discovering Regulated Metabolite Families in Untargeted

Jul 24, 2016 - By integrated analysis of MS1 abundances and MS/MS spectra, the identification of regulated metabolite families is achieved. This appro...
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Discovering regulated metabolite families in untargeted metabolomics studies Hendrik Treutler, Hiroshi Tsugawa, Andrea Porzel, Karin Gorzolka, Alain Tissier, Steffen Neumann, and Gerd Ulrich Balcke Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b01569 • Publication Date (Web): 24 Jul 2016 Downloaded from http://pubs.acs.org on July 25, 2016

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Analytical Chemistry

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Discovering regulated metabolite families in

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untargeted metabolomics studies

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Hendrik Treutler2, Hiroshi Tsugawa4, Andrea Porzel3, Karin Gorzolka2, Alain Tissier¹, Steffen

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Neumann2, and Gerd Ulrich Balcke¹*

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¹Leibniz Institute of Plant Biochemistry, Dept. of Cell and Metabolic Biology, Weinberg 3, D-06120 Halle/Saale, Germany 2

Leibniz Institute of Plant Biochemistry, Dept. of Stress and Developmental Biology, Weinberg 3, D-06120

Halle/Saale, Germany 3

Leibniz Institute of Plant Biochemistry, Dept. of Bioorganic Chemistry, Weinberg 3, D-06120 Halle/Saale,

Germany 4

RIKEN Center for Sustainable Resource Science, Yokohama, Kanagawa, 230-0045, Japan

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ABSTRACT: The identification of metabolites by mass spectrometry constitutes a major bottleneck which considerably limits the throughput of metabolomics studies in biomedical or plant research. Here, we present a novel approach to analyze metabolomics data from untargeted, data-independent LC-MS/MS measurements. By integrated analysis of MS1 abundances and MS/MS spectra, the identification of regulated metabolite families is achieved. This approach offers a global view on metabolic regulation in comparative metabolomics. We implemented our approach in the web application ‘MetFamily’, which is freely available at http://msbi.ipb-halle.de/MetFamily/. MetFamily provides a dynamic link between the patterns based on MS1-signal intensity and the corresponding structural similarity at the MS/MS level. Structurally related metabolites are annotated as metabolite families based on a hierarchical cluster analysis of measured MS/MS spectra. Joint examination with principal component analysis of MS1 patterns, where this annotation is preserved in the loadings, facilitates the interpretation of comparative metabolomics data at the level of metabolite families. As a proof of concept, we identified two trichomespecific metabolite families from wild-type tomato Solanum habrochaites LA1777 in a fully unsupervised manner and validated our findings based on earlier publications and with NMR. 13 14

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INTRODUCTION

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Metabolomics experiments provide small molecule measurements from biological samples in

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a broad range of applications including cancer research, drug development, and plant

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science1-5. Mass spectrometry (MS) coupled to liquid chromatography (LC) is an essential

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analytical technology to acquire a snapshot of the metabolic state of a sample. Based on

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untargeted MS measurements, it is possible to measure thousands of detectable signals as

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MS1 features per chromatographic run and to acquire signal profiles of small molecules

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based on retention time (RT), accurate mass-to-charge ratio (m/z), and abundance6.

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Univariate or multivariate statistical analysis is then applied to signal profiles of different

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sample groups to detect MS1 features that are group-discriminating or of interest based on

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the experimental design.

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Hints for the structural characterization or even identification of MS1 features are obtained

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from tandem MS measurements (MS/MS), where the metabolites undergo fragmentation

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resulting in MS/MS spectra. MS/MS spectra can be collected by data-dependent acquisition

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(DDA) or in data-independent acquisition (DIA) mode, requiring a trade-off between dwell

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time and spectral purity7,8. Using DIA, it is possible to collect thousands of MS1 features from

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a single LC run as well as the associated MS/MS spectra9. However, in most studies, the

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identity of the vast majority of MS1 features is unknown. Structure elucidation of each

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individual MS1 feature from complex biological samples, e.g. by NMR and interpretation of

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MS/MS spectra, is currently out of reach. Thus, the biochemical relation between MS1

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features remains largely unexplained.

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Group-discriminating MS1 features are often structurally related, e.g. if particular metabolic

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pathways are differentially regulated as a consequence of disease10, stress11, genetic

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manipulation12 or in the case of organ-specific accumulation of structurally related

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metabolites13. Structurally related metabolites often exhibit latent similarity in their MS/MS

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spectra in which characteristic fragmentation patterns arise from common functional groups

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or structural features. For instance, upon negative mode ionization and collision-induced

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dissociation (CID), adenylated metabolites such as adenyl nucleotides, CoA esters, and

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NAD cofactors form a fragment ion of m/z 134.0472 Da (C5N5H4-), which corresponds to the

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mass of the purine core element. Under the same conditions, glucosides often form a

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fragment ion of m/z 161.0455 Da (C6H9O5-), characteristic of the hexose side-chain. Thus,

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based on existing information, precursor ions showing these characteristic fragments could

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be grouped together as metabolites sharing common structural features, or metabolite

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families. However, even pre-existing MS/MS information characteristic of certain metabolite

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families is sparse. Hence, novel approaches that turn MS1- and MS/MS-features into

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interpretable information within a reasonable amount of time are urgently needed. These

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approaches should be able to relate MS1 abundances to latent similarity at the MS/MS

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spectral level.

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Recently, several studies reported on the organization of hundreds of MS1 features by

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molecular networking depicting relationships between structurally related molecules based

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on their spectral similarity14-17. However, an explicit assignment of MS1 features to similarity

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clusters and the source of structural similarity between up- or downregulated MS1 features

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was not apparent. Previously, Wagner et al. used GC-MS data for hierarchical cluster

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analysis (HCA) to arrange known and structurally related metabolites18. Using HCA, it was

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possible to identify structural classes amongst 59 metabolites. Rasche et al. described FT-

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BLAST19 to compare spectra and computationally derived fragmentation trees, revealing

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clusters of structurally closely related compounds. However, neither Wagner et al. nor

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Rasche et al. considered the abundance of MS1 features in different samples.

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Inspired by the idea to comprehensively analyze molecular networks and to explicitly group

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MS1 features, we performed HCA across hundreds of MS/MS spectra obtained from

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glandular trichomes of wild-type tomato Solanum habrochaites LA1777. Glandular trichomes

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of vascular plants such as tomato are metabolic factories producing a plethora of secondary

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metabolites involved in plant defense and the communication with its environment13,20. We

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considered characteristic fragments prevalent in MS/MS similarity clusters to assign MS1

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features to certain trichome-specific metabolite families. In addition, we applied principal

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component analysis (PCA) to metabolite profiles for the discovery of group-discriminating

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MS1 features and combined the information on metabolite families obtained from HCA

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(MS/MS feature similarity) with the PCA loadings (sample-specific MS1 abundance). This

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combination of statistical analyses of MS1 feature abundances and MS/MS structural

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annotations can not only speed-up the individual analysis steps, but allows to address new

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questions, such as the discovery of group-discriminating metabolite families with biochemical

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relevance. Here, we exemplarily selected two metabolite families being produced by tomato

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glandular trichomes which play important roles in the plant defense against herbivores,

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namely the branched chain acyl sugars21-24 and the sesquiterpene glucosides which are

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potentially poisonous to plant herbivores25,26. We implemented the proposed methodology in

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the Open Source web application ‘MetFamily’ and made our approach freely available

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(accessible via http://msbi.ipb-halle.de/MetFamily/).

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MATERIALS AND METHODS

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Fragment matrix assembly. MetFamily processes a metabolite profile of a set of MS1

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features together with an MS/MS library comprising MS/MS spectra for these MS1 features.

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We obtain both data sets as output of MS-DIAL9, where the metabolite profile contains

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extracted m/z / retention time features from MS1 scans with the corresponding feature

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abundances (Data S-1) and the MS/MS library contains deconvoluted MS/MS spectra of the

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MS1 features with relative intensities of the fragment ions (Fig. 1, Data S-2). Instead of MS-

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DIAL, other tools can produce similar input data as described in Note S-3. Upon data import,

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MetFamily aligns all MS/MS spectra with a user-defined m/z error to create the fragment

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matrix as shown in Fig. 2, where the relative intensity of unique MS/MS fragments is

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associated with the corresponding MS1 feature (i.e. precursor ion) and its MS1 abundance in

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individual samples (Data S-3). For our showcase this preprocessing step takes one or two

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minutes. The fragment matrix is assembled as follows.

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First, we process the set of all fragments. Here, we remove fragments with an intensity

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below a user-defined noise threshold. We normalize fragment intensities within each MS/MS

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spectrum to a maximum of 1 (base peak). In addition, we add one neutral loss (NL) for each

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fragment by calculating the mass of the neutral loss as the difference of fragment m/z and

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precursor m/z in MS1 (intentionally a negative m/z value). The intensity of the NLs is chosen

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equal to the intensity of the corresponding fragment. In this manuscript, we treat fragments

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and NLs equally by denoting both as fragments.

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Second, we align the individual MS/MS spectra (Figures 1 and 2). Here, we match fragments

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from different MS/MS spectra with similar m/z and merge these to fragment groups of unique

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m/z. We call the mean of all fragment m/z’s of one fragment group the fragment group mean.

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For the alignment of the individual MS/MS spectra, we use an efficient algorithm

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implemented in the R package xcms31 (version 1.44.0). This algorithm avoids the usage of

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fixed m/z bins with a heuristic approach that groups fragments with similar m/z and

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decomposes contiguous fragment groups using hierarchical clustering. Here, a fragment m/z

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matches a fragment group, if

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|



|≤

/

+



/

/1 6,

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where

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parameter representing the absolute m/z error, and

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m/z error in ppm (parts per million). See Table S-3 for a summary of user-customizable

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parameters. After fragment group assembly, we remove fragment groups which correspond

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to isotopic ions. Specifically, we detect fragment groups with a m/z difference of 1.0033 Da

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(regarding the fragment group means +/- m/z error) which correspond to 13C isotopes. Third,

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we create the fragment matrix with one row for each unique MS1 precursor and columns of

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fragment groups (Fig. 2). We register the intensity of each fragment in the row and column of

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the corresponding MS1 feature and fragment group, respectively. For each MS1 feature, we

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generate an ID given by “m/z / retention time” in MS1.

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Finally, we add the set of MS1 abundances in all samples and other annotations to each row

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resulting in a combined data matrix. The combined data matrix represents the data basis for

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subsequent analyses and can be examined in a spreadsheet program for complementing

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analyses (Fig. 2 and Data S-3).

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MS1 / MS/MS combined data analysis. A principal component analysis (PCA) for the set of

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is the fragment m/z,

MS1 features in

is the fragment group mean, /

samples is performed as follows. Given the

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is a

is representing the relative

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matrix of scaled MS1

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abundances, we calculate the scores and the loadings. Here, MetFamily supports the

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scaling functions log2 transformation, Pareto scaling, Centering, and Autoscaling27. The

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scores comprise one data point per sample and reflect differences between samples. The

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loadings comprise one data point per MS1 feature and emphasize MS1 features with

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differential abundance between samples.

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We perform a hierarchical cluster analysis (HCA) on MS/MS spectra of a set of MS1

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precursor features as follows. We calculate the distance matrix of pairwise dissimilarities

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between the MS/MS spectra of all MS1 features. Here, we provide different distance

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functions to score common and distinct fragments. Specifically, we recommend the distance

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function ‘Jaccard (intensity-weighted)’, which sums the intensities of common and disjoint

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fragments:

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!( !# ( $ ∩ !( !# ( $ ∪

( , )=1−

& ))

,

& ))

are the fragments in the MS/MS spectrum of MS1 feature ( and ) . To

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where

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suppress noise and emphasize the importance of intense fragments,

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intensities of the fragments as follows. Intensities smaller than 0.2 are mapped to 0.01,

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intensities greater or equal than 0.2 and smaller than 0.4 are mapped to 0.2, and intensities

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greater or equal than 0.4 are mapped to 1. Given the distance matrix, we calculate a

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hierarchical cluster dendrogram where each cluster of MS1 features represents a putative

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metabolite family.

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For each cluster of MS/MS spectra, we calculate the cluster-discriminating power for

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prevalent fragments as follows. For each fragment present in more than 50% of the MS/MS

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spectra in a cluster, we measure the ability of this fragment to discriminate spectra in the

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cluster from spectra outside the cluster as

and

,-+(

.,/ )

=

+0−+

*+ discretizes the

1

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where

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3-th cluster containing the fragment

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th cluster containing the fragment

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cluster. If +

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fragment is in the range from zero to one and a fragment with a cluster-discriminating power

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close to one indicates a very specific fragment.

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Clusters containing fragments with a cluster-discriminating power close to one indicate

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metabolite families. Currently, the annotation of metabolite families based on characteristic

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MS/MS fragments is performed by a mass spectrometry expert who manually evaluates the

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hierarchy of putative metabolite families and labels a set of clusters with functional and/or

.,/

is the 2-th fragment of the 3-th cluster, + 0 is the number of MS/MS spectra in the

1

.,/ ,

.,/ ,

+

and

> + 0 , then we define ,-+(

1

is the number of MS/MS spectra outside the 3is the total number of MS/MS spectra in the 3-th

.,/ )

= 0. The cluster-discriminating power of a

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structural annotations based on characteristic fragment patterns. Each MS1 feature can be

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labeled with one annotation, i.e. membership in a metabolite family.

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Plant growth and harvest. Solanum habrochaites LA1777 was grown on soil in a

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greenhouse (65% humidity, light intensity: 165 µmol s-1 mm2, 21-24 °C, 16 h light period) and

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watered with tap water every two days. The plant material was harvested 12 weeks after

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germination during the light phase in the early afternoon. For trichome harvest, tomato

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leaves were put on the hand palm (using gloves) and trichomes were quickly brushed off the

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leaves by a 2 cm broad paint brush which was dipped in liquid nitrogen. The frozen

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trichomes were collected in a mortar filled with liquid nitrogen. Trichomes from 15 plant

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leaves were pooled under cryogenic conditions and further purified by sieving through steel

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sieves of 150 µm mesh width (Retsch, Hahn, Germany). After removal of trichomes, the

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plant leaves were immediately quenched in liquid nitrogen. Pooled leaves were ground in a

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mortar under liquid nitrogen conditions. After evaporation of all liquid nitrogen during storage

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at -80 °C leaves and trichomes were lyophilized overnight and stored in a deep freezer until

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extraction.

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Metabolite extraction. Using wall-reinforced cryo-tubes of 1.6 mL volume (Precellys Steel

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Kit 2.8mm, Peqlab Biotechnologie GmbH, Erlangen, Germany) filled with 5 steel beads (3

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mm), 25 mg aliquots of dry leaf or trichome powder was suspended in 900 µL

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dichloromethane/ ethanol (-80 °C). Then, 200 µL of 50 mM aqueous ammonium formate/

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formic acid buffer (0 °C, pH 3) was added to each vial and two rounds of cell rupture/

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metabolite extraction were conducted by FastPrep bead beating (60 s, speed 5.5 m/s, 1st

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round -80 °C, 2nd round room temperature, FastPrep24 instrument with cryo adapter, MP

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Biomedicals LLC, Santa Ana, CA, USA). After phase separation by centrifugation at 20,000

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g (2 min, 0°C) the aqueous phase was removed and 600 µL of the organic phase was

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collected. Following, 500 uL tetrahydrofuran (THF) was added to exhaustively extract

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hydrophobic metabolites and the Fastprep and centrifugation were repeated accordingly.

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The THF supernatant was combined with the first organic phase extract and dried in a

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stream of nitrogen gas. The dried extract was re-suspended in 150 µL 75% methanol

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(aqueous) and filtered over 0.2 µm PVDF.

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Analytical conditions for liquid chromatography and mass spectrometry. 0.5 µL

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methanolic extract was injected into an Acquity-UPLC (Waters Inc.) and separated on a

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Nucleoshell RP18 (150 mm x 2 mm x 2.7 µm; Macherey & Nagel, Düren, Germany) at 40°C.

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The mobile phase A was 0.33 mM ammonium formate with 0.66 mM formic acid in water;

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mobile phase B was acetonitrile. The gradient was 0 min, 5% B; 2 min, 5 % B; 19 min, 95%

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B; 21 min, 95% B; 21.1 min, 5% B; 24 min, 5% B. The column flow rate was 0.4 mL/min, the

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autosampler temperature was 4 °C.

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ESI-(-)-Mass spectrometry was performed on an AB Sciex TripleTOF 5600 system (Q-TOF)

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equipped with a DuoSpray ion source. All analyses were performed at the high sensitivity

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mode for both TOF MS1 and product ion scan. The mass calibration was automatically

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performed every 20 injections using an APCI calibrant solution via a calibration delivery

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system (CDS). The instrument (TripleTOF 5600, Sciex, Toronto, Canada) was configured to

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simultaneously acquire high resolution MS/MS spectra for all MS1 features (sequential

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window acquisition of all theoretical fragment-ion spectra, SWATH)28 (Fig. S-1). The SWATH

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parameters were MS1 accumulation time, 150 ms; MS2 accumulation time, 20 ms; collision

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energy, -45 V; collision energy spread, 35 V; cycle time, 1160 ms; Q1 window, 25 Da; mass

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range, m/z 65–1250. The other parameters were curtain gas, 35; ion source gas 1, 60; ion

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source gas 2, 70; temperature, 600 °C; ion spray voltage floating, -4.5 kV; declustering

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potential, 35 V.

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Raw data processing. After measurement, raw data of triplicate trichome and trichome-free

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leaf material was converted from the vendor file format (in our case *.wiff) into the common

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file format of Reifycs Inc. (Analysis Base File format *.abf) using the freely available Reifycs

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ABF converter (http://www.reifycs.com/AbfConverter/index.html).This process took about one

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minute per sample. After conversion, the freely available MS-Dial software was used for

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feature detection, ion species annotation, compound spectra extraction, and peak alignment

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between samples9. Data processing by MS-Dial using the parameters in Table S-1 took

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about 30 min. Data processing by MetFamily using the parameters in Table S-2 took 1 min.

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Notably, neither the use of SWATH-triggered CID fragmentation nor the use of MS-Dial are

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prerequisite to run MetFamily. Any data independent or data dependent acquisition to collect

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MS/MS spectra and other peak picking and deconvolution software can alternatively be used

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29-32

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and a msp-type spectral library which are formatted as exemplified in Data S-1 and Fig. 1,

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and described in Note S-3. However, as unique feature, MS-Dial jointly deconvolutes MS1

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and MS/MS features and automatically predicts the precursor ion when DIA was applied. Via

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the Reifycs ABF converter, MS-DIAL accepts all of major MS vendor-formats as well as the

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common mzML data and is applicable to either DIA or DDA MS/MS fragmentation methods.

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Substance Purification. Since NMR requires purified analytes in the upper µm range, 1 kg

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of LA1777 leaf material was surface-extracted with methanol for 2 h. After evaporation, a

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methanolic concentrate of this extract was produced and injected into a LC system in 100 µL

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increments. For peak separation using semi-preparative HPLC and an analysis by mass

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spectrometry (1260 Infinity system, Agilent), a full scan between 200-800 m/z was performed

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after negative electrospray ionisation (ion source: API-ES, gas temperature: 350 °C, drying

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gas 10 mL/min, nebulizer pressure 35 psig, capillary voltage 4500 V). For HPLC, a XTerra

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prep MS C18 column (5 µm x 7.8 mm x 150 mm; Waters) was used and run at a flow rate of

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6 mL/min at 25 °C. Solvent A was 0.3 mM ammonium formate acidified with formic acid to

. In that case, their output has to be provided as a text file containing the peak intensities

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pH 6.2. Solvent B was acetonitrile. Gradient conditions were: 0-5 min 5% B; 5-87 min linear

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gradient to 95% B; 87-88 min 95% B; 88-90 min 5% B. For fractionation, m/z 605.5, 737.5,

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and 751.5 triggered the selective collection. A make-up pump that transferred an aliquot of

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the eluate to the mass analyser was set to 0.5 mL/min 50% A - 50% B. Subsequently, all

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collected fractions were dried by lyophilisation prior to NMR analysis.

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Analytical conditions for NMR. NMR spectra were recorded on an Agilent/Varian VNMRS

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600 NMR spectrometer operating at a proton NMR frequency of 599.83 MHz using a 5 mm

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inverse detection cryoprobe. 2D NMR spectra were recorded using standard pulse

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sequences (gDQCOSY, zTOCSY, gHSQCAD, gHMBCAD) implemented in Agilent (Varian)

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VNMRJ 4.2A (CHEMPACK 7.1) spectrometer software. A TOCSY mixing time of 80 msec

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was used. HSQC experiments were run with multiplicity editing and optimized for 1JCH = 146

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Hz. HMBC experiments were optimized for a long-range coupling constant of 8 Hz; a 2-step

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1

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internal TMS (0 ppm).

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RESULTS and DISCUSSION

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As a proof of concept, we applied MS signal profiles to compare the metabolism of a special

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plant organ in tomato, the glandular trichomes, to tomato leaves. Plant glandular trichomes

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are secretory cells that protrude from the epidermis of many vascular plants. As “metabolic

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factories”, they produce important drugs such as the antimalaria artemisinin or compounds

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known to be involved in plant defense20,33. Here, we used Solanum habrochaites LA1777, a

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wild type tomato accession with a rich profile of secondary metabolites produced in the

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glandular trichomes34. We used six UPLC-(-)ESI-SWATH-MS/MS runs of triplicate trichome

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and trichome-free leaf extracts (cf. Materials and Methods). However, MetFamily is

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applicable to a larger number of samples and sample groups. We used MS-DIAL9 for data

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preprocessing and exported (i) a signal profile with MS1 features and (ii) a spectral library

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with deconvoluted MS/MS spectra extracted from the raw data (Data S-1 and Data S-2).

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Using the software MetFamily, we aligned the MS/MS spectra of the spectral library resulting

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in a novel fragment matrix structure and we fused this fragment matrix with the matching set

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of MS1 features from the six individual samples to a single matrix (cf. Materials and Methods,

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Figures 1 and 2, Data S-3, Table S-3).

JCH filter was used (130–165 Hz). Proton and carbon chemical shifts are referenced to

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Figure 1. MS/MS library format before upload into MetFamily.

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Figure 2. Combined data matrix after data pre-processing by MetFamily. The quantification

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part (red, left) contains the MS1 features (rows; precursor ions) and the MS1 abundances in

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individual samples. In the fragment part (green, right), the column headers are the mean of

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binned MS/MS features (m/z or neutral loss) from the MS/MS library. Upper zoom: m/z;

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retention time of feature (628.2452; 9.16) and its respective peak heights in two trichome

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samples. Lower zoom: relative MS/MS intensities of fragment ion m/z 323.09570 Da. Arrows

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to the left and to the right: MS1 abundances are analyzed using PCA and MS/MS spectra are

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analyzed using HCA.

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MetFamily provides options to perform principal component analyses (PCA). Here, we

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performed a PCA on 2585 MS1 features detected in glandular trichomes or leaves of LA1777

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using Pareto-scaled data. In our example, PC1 shows a clear separation between trichomes

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and leaves with R2=0.90, Q2=0.82 and a large number of MS1 features more abundant in

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glandular trichomes (Fig. 3A and B). A Scree plot on additional principal components is

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provided in Fig. S-2. Up to this point, all data has been acquired in a fully untargeted manner

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and traditionally this is where group-discriminating MS1 features would be subjected to

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tedious manual structure elucidation. In our approach, we amended the loadings plot of the

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PCA (Fig. 3B) with a set of structural annotations based on characteristic MS/MS fragments

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which we identified in different signal-clusters using HCA (Fig. 4). Using MetFamily, we

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performed a hierarchical cluster analysis (HCA) on MS/MS spectra of the fragment matrix

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(Data S-3). For PCA as well as for HCA, MetFamily allows the usage of thresholds for the

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MS1 abundance of individual MS1 features (average of all samples) and for the log2-fold

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change between the average MS1 abundance of two sample groups. Since we were

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interested in abundant trichome-specific metabolites, we retained 135 MS1 features in the

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HCA with MS1 abundances ≥20,000 counts and a log2-fold change ≥2 comparing trichomes

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versus leaf. After hierarchical cluster analysis, the resulting dendrogram indicated a clear

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segregation into two main clades with internal spectral similarity (Fig. 4).

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The first signal-cluster contained 73 MS1 features which correspond to short branched chain

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acyl sugars21 (AS, blue in Fig. 4). The structural similarities among members of this clade

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was supported by prevalent fragment ions 87.0451 Da (theoretical mass for C4H7O2- is

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87.0452) and 101.0603 Da (theoretical mass for C5H9O2- is 101.0608), which are indicative

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for short branched acyl groups. These acyl moieties were esterified to sucrose as reflected

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by the fragments 323.0957 Da (theoretical mass for C12H19O10- is 323.0984; sucrose-H2O-H-)

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and 305.0864 Da (theoretical mass for C12H17O9- is 305.0878; sucrose-2H2O-H]-). MS/MS

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fragmentation patterns and NMR analysis of two selected MS1 features of this clade ([m/z;

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RT]: [737.3578; 14.65] and [751.3749; 15.64]) confirmed the membership to the metabolite

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family of short branched chain acyl sugars (Figures S-3, S-4, S-7, S-8, S-11 - S-14, S-15 - S-

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19 and Tables S-5, S-6). Our NMR analysis revealed that the feature [737.3578; 14.65]

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comprised an isomeric mixture of isobutyl, isopentyl, and anteisobutyl acyl moieties, which

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were not resolvable using our chromatography. MS/MS fragmentation and NMR of various

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AS have been thoroughly studied earlier by Ghosh et al., where compounds selected here

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for analysis were annotated as acylsucrose S4:21[2] (theoretical m/z:737.36012 Da (formate

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adduct-H)) and acylsucrose S4:22[6] (theoretical m/z: 751.37577 Da (formate adduct-H)),

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respectively21.

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The second signal-cluster contained a group of four MS1 features which correspond to

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sesquiterpene glycosides (SQT-glucosides, red in Fig. 4). The structural similarities among

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members of this clade was supported by three prevalent fragment ions: m/z 401.2548 Da

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(theoretical mass for C21H37O7- is 401.2545), 563.3051 Da (theoretical mass for C27H47O12- is

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563.3073), and 605.3176 Da (theoretical mass for C29H49O13- is 605.3179) (Fig. S-5).

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Recently, Ekanayaka et al. identified a novel class of trichome-specific sesquiterpene

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glucosides from S. habrochaites using these fragment ions and elucidated the structures of

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purified representatives by NMR26. In our study, CID fragmentation and preparative isolation

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of MS1 feature [605.3160; 7.07, an abundant in-source fragment] with subsequent NMR

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confirmed

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glucopyranosyl)-campherenane-2-endo,12-diol, a member of the novel sesquiterpene

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glucoside metabolite family (Figures S-3 - S-6, S-9, S-10 and Tables S-3, S-4).

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After annotation of both metabolite families, the corresponding MS1 features are highlighted

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by their color-code in the PCA loadings (Fig. 3B). In our case, it was evident that the

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representatives of both metabolite families were enriched in glandular trichomes, indicating a

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trichome-specific upregulation of short branched chain acyl sugars and sesquiterpene

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glucosides. Please note that the hierarchical cluster dendrogram comprised more clades

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with internal spectral similarity, but we concentrated on the short branched chain acyl sugars

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and sesquiterpene glucosides whose structures were confirmed by NMR. A detailed

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workflow exemplified here is given in Fig. S-1, and the full showcase protocol is given in

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Note S-1. A general user guide for MetFamily is given in Note S-2.

the

structure

of

12-O-(6’’-O-malonyl-β-D-glucopyranosyl-(1→2)-β-D-

Figure 3. Principal component analysis of metabolite extracts of glandular trichomes and leaves of Solanum habrochaites LA1777. Comparison of 2585 MS1 features from TOF-MS measurements (n=6). a: scores, b: loadings with annotations. The PCA loadings with annotations indicate a predominant enrichment of acyl sugars in glandular trichomes. AS: acyl sugars, SQT-glucosides: sesquiterpene glucosides, Unknown: Not characterized

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here. 332 333

Figure 4. Hierarchical cluster analysis of 135 trichome-specific MS1 features using the corresponding MS/MS spectra obtained from organic extracts of S. habrochaites LA1777. For comparison of the groups trichomes versus leaf focusing on trichome-specific features, the set of 2585 MS1 features was filtered using an MS1 abundance threshold of 20,000 counts and a log2-fold change (LFC) of two. The heatmap below depicts the LFC and the absolute MS1 abundance in glandular trichomes (TRI) and trichome-free leaves (LVS), respectively. The 135 filtered MS1 features clearly segregated into two main signal-clusters which in turn further segregated into signal-clusters with different levels of similarity between MS/MS spectra. Specifically, we identified a cluster of 73 short branched chain acyl sugars (AS, in blue) and a cluster of four sesquiterpene glucosides (SQT-glucosides, in red) on the basis of a set of characteristic fragments which were prevalent in both clusters (see legend ‘Annotations’ on the right). Both signal-clusters show characteristic fragments with a cluster-discriminating power of 80% and more (size of the branch nodes, see legend ‘Cluster-discriminating power’ on the right). 58 trichome-specific MS1 features partially showed further clusters, but remained uncharacterized in this study (Unknown in black). 334

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Additional features of MetFamily. MetFamily also supports semi-targeted analyses. In this

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case, sets of MS1 features can be selected by certain fragment masses, neutral losses or

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combinations thereof within a user-defined mass error in ppm as filter criteria. Using this

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option, only selected MS1 features are considered in subsequent PCA or HCA calculations

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and the data analysis is consequently constrained to selected metabolite families. For

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example, to isolate only glycosylated MS1 features from all data the user can specify a

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fragment ion of m/z 161.0455 Da (C6H9O5-) from MS/MS spectra in negative mode and can

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then focus on the regulation of enzymatic glycosylations in a biological context (for details

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see the MetFamily user guide in Note S-2). When we applied this filter with a mass error of

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25 ppm, we obtained 568 MS1 features from our example data, presumably containing a

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hexose as a structural moiety. In addition, it is possible to search MS1 features with certain

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fragments or neutral losses post-analysis. The corresponding MS1 features can then be

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jointly visualized in the PCA loadings and the hierarchical cluster dendrogram.

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It is possible to export different kinds of results from MetFamily. Selected sets of precursor

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ions can be exported and, e.g., reloaded into the original MS data acquisition software.

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Further, it is possible to export both the hierarchical cluster dendrogram and the PCA plots

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as publication-ready high quality images. The set of parameters used for the initial data

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import can be exported and imported. Finally, it is possible to export the whole project

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(including all annotations and color codes) to enable the user to share the project or to

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continue the data analysis at a later time (Data S-4).

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CONCLUSIONS

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The web application ‘MetFamily’ presented here constitutes a novel approach to analyze

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metabolomics data from untargeted, data-independent LC-MS/MS measurements. Rather

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than relying on the time-consuming structure identification of individual metabolites,

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MetFamily assists in the interpretation of complex metabolomics data by identifying

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metabolite families through patterns in MS/MS. These are generated by similarity clustering

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of associated MS/MS spectra and can be annotated with names and colors. After pre-

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processing of LC-MS/MS raw data, MetFamily performs a joint data analysis of MS1

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abundances and MS/MS spectra in which the annotation of metabolite families facilitates the

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interpretation of comparative data sets. Structure elucidation at the metabolite level can be

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performed afterwards in a much more focused way. As a proof of concept, we identified two

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trichome-specific metabolite families from wild type Solanum habrochaites LA1777 in a fully

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unsupervised manner and validated our findings based on earlier publications and with

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NMR. The plethora of identified trichome-specific acyl sucroses correlates with upregulation

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of acyltransferases of the BAHD family in tomato glandular trichomes (Schilmiller 2012). In

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addition, the size of the clade “acyl sugar” is related to a low substrate specificity of BAHD

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371

acyltransferases, illustrating that MetFamily can uncover links between enzymatic

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promiscuity and organ-specific regulation of enzymes.

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Using the proposed approach, it is now possible to obtain a comprehensive overview of data

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sets containing thousands of mass features within a reasonable amount of time. Thus, by

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providing a dynamic link between structural similarity at the MS/MS level (HCA) and the

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corresponding MS1-signal intensity-based patterns (PCA) we bridge the gap between raw

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data and structural information. Moreover, using MetFamily, precursor ions can now be

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filtered via combinations of fragment ions and neutral losses, permitting the selection of

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metabolite families based on characteristic fragmentation patterns.

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While traditional compound identification is based on the comparison of MS/MS spectra (or

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electron impact MS spectra) with reference spectra from known compounds, future

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developments should exploit spectral patterns of MS/MS features being characteristic of

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certain metabolite families. Public knowledge on such characteristic fragment ions or neutral

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losses, e.g. based on metabolite families, can assist mass spectrometry specialists in the

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elucidation of unknown features and will open new perspectives in life science.

386 387

AVAILABILITY

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Project name: MetFamily

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Source code: https://github.com/Treutler/MetFamily

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Availability: http://msbi.ipb-halle.de/MetFamily/

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Operating system(s): Platform independent

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Programming language: R

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Other requirements: Installation of R 3.2.2 or higher; License: GPL 3

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Any restrictions to use by non-academics: None

395

ASSOCIATED CONTENT

396

Supporting Information

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General work flow as flow chart (Fig. S-1) Scree plot of the first five principle components of

398

Figure 4. Exported parameter file of MS-DIAL (Table S-1) and exported parameter file from

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MetFamily and parameter explanation (Tables S-2, S-3). Structure elucidation of three

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selected MS1 features (Figures S-3 - S-19, Tables S-4 - S-6). Protocol for the presented

401

showcase (Note S-1) and a user guide for MetFamily (Note S-2). Detailed specification of

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MetFamily input files (Note S-3). Metabolite profile of the showcase (Data S-1), MS/MS

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library of the showcase (Data S-2), matrix of the showcase (Data S-3), and annotated

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MetFamily project file (Data S-4).

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AUTHOR INFORMATION

406

Corresponding Author

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*E-mail: [email protected]

408

Notes

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The authors declare that they have no competing financial interests.

410

ACKNOWLEDGMENTS

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We would like to thank Anja Ehrlich for the preparative isolation of metabolites, Anja Henning

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and Nick Bergau for trichome harvest and data acquisition. We thank Prof. Masanori Arita

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and Dr. Karin Gorzolka for fruitful discussions and review of the manuscript.

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REFERENCES

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(1) Jorge, T. F.; Rodrigues, J. A.; Caldana, C.; Schmidt, R.; van Dongen, J. T.; ThomasOates, J.; Antonio, C. Mass spectrometry reviews 2015. (2) Tonoli, D.; Varesio, E.; Hopfgartner, G. Chimia (Aarau) 2012, 66, 218-222. (3) Wishart, D. S.; Mandal, R.; Stanislaus, A.; Ramirez-Gaona, M. Metabolites 2016, 6. (4) Suhre, K.; Shin, S. Y.; Petersen, A. K.; Mohney, R. P.; Meredith, D.; Wagele, B.; Altmaier, E.; CardioGram; Deloukas, P.; Erdmann, J.; Grundberg, E.; Hammond, C. J.; de Angelis, M. H.; Kastenmuller, G.; Kottgen, A.; Kronenberg, F.; Mangino, M.; Meisinger, C.; Meitinger, T.; Mewes, H. W.; Milburn, M. V.; Prehn, C.; Raffler, J.; Ried, J. S.; RomischMargl, W.; Samani, N. J.; Small, K. S.; Wichmann, H. E.; Zhai, G.; Illig, T.; Spector, T. D.; Adamski, J.; Soranzo, N.; Gieger, C. Nature 2011, 477, 54-60. (5) Fiehn, O. Plant Mol Biol 2002, 48, 155-171. (6) Fernie, A. R.; Trethewey, R. N.; Krotzky, A. J.; Willmitzer, L. Nature reviews. Molecular cell biology 2004, 5, 763-769. (7) Roemmelt, A. T.; Steuer, A. E.; Poetzsch, M.; Kraemer, T. Anal Chem 2014, 86, 1174211749. (8) Zhu, X.; Chen, Y.; Subramanian, R. Anal Chem 2014, 86, 1202-1209. (9) Tsugawa, H.; Cajka, T.; Kind, T.; Ma, Y.; Higgins, B.; Ikeda, K.; Kanazawa, M.; VanderGheynst, J.; Fiehn, O.; Arita, M. Nature methods 2015, 12, 523-526. (10) Ferslew, B. C.; Xie, G.; Johnston, C. K.; Su, M.; Stewart, P. W.; Jia, W.; Brouwer, K. L.; Sidney Barritt, A. t. Digestive diseases and sciences 2015, 60, 3318-3328. (11) Kaling, M.; Kanawati, B.; Ghirardo, A.; Albert, A.; Winkler, J. B.; Heller, W.; Barta, C.; Loreto, F.; Schmitt-Kopplin, P.; Schnitzler, J. P. Plant Cell Environ 2015, 38, 892-904. (12) Qu, G.; Quan, S.; Mondol, P.; Xu, J.; Zhang, D.; Shi, J. J Integr Plant Biol 2014, 56, 849-863. (13) Glas, J. J.; Schimmel, B. C. J.; Alba, J. M.; Escobar-Bravo, R.; Schuurink, R. C.; Kant, M. R. Int J Mol Sci 2012, 13, 17077-17103. (14) Watrous, J.; Roach, P.; Alexandrov, T.; Heath, B. S.; Yang, J. Y.; Kersten, R. D.; van der Voort, M.; Pogliano, K.; Gross, H.; Raaijmakers, J. M.; Moore, B. S.; Laskin, J.; Bandeira, N.; Dorrestein, P. C. Proc Natl Acad Sci U S A 2012, 109, E1743-1752. (15) Garg, N.; Kapono, C. A.; Lim, Y. W.; Koyama, N.; Vermeij, M. J. A.; Conrad, D.; Rohwer, F.; Dorrestein, P. C. Int J Mass Spectrom 2015, 377, 719-727. (16) Nguyen, D. D.; Wu, C. H.; Moree, W. J.; Lamsa, A.; Medema, M. H.; Zhao, X. L.; Gavilan, R. G.; Aparicio, M.; Atencio, L.; Jackson, C.; Ballesteros, J.; Sanchez, J.; Watrous,

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J. D.; Phelan, V. V.; van de Wiel, C.; Kersten, R. D.; Mehnaz, S.; De Mot, R.; Shank, E. A.; Charusanti, P.; Nagarajan, H.; Duggan, B. M.; Moore, B. S.; Bandeira, N.; Palsson, B. O.; Pogliano, K.; Gutierrez, M.; Dorrestein, P. C. P Natl Acad Sci USA 2013, 110, E2611-E2620. (17) Li, D.; Baldwin, I. T.; Gaquerel, E. Proc Natl Acad Sci U S A 2015, 112, E4147-4155. (18) Wagner, C.; Sefkow, M.; Kopka, J. Phytochemistry 2003, 62, 887-900. (19) Rasche, F.; Scheubert, K.; Hufsky, F.; Zichner, T.; Kai, M.; Svatos, A.; Bocker, S. Anal Chem 2012, 84, 3417-3426. (20) Tissier, A. Plant J 2012, 70, 51-68. (21) Ghosh, B.; Westbrook, T. C.; Jones, A. D. Metabolomics 2014, 10, 496-507. (22) Kim, J.; Kang, K.; Gonzales-Vigil, E.; Shi, F.; Jones, A. D.; Barry, C. S.; Last, R. L. Plant Physiol 2012, 160, 1854-1870. (23) Schilmiller, A.; Shi, F.; Kim, J.; Charbonneau, A. L.; Holmes, D.; Jones, A. D.; Last, R. L. Plant J 2010, 62, 391-403. (24) Schilmiller, A. L.; Charbonneau, A. L.; Last, R. L. P Natl Acad Sci USA 2012, 109, 16377-16382. (25) Ekanayaka, E. A.; Celiz, M. D.; Jones, A. D. Plant Physiol 2015. (26) Ekanayaka, E. A. P.; Li, C.; Jones, A. D. Phytochemistry 2014, 98, 223-231. (27) van den Berg, R. A.; Hoefsloot, H. C.; Westerhuis, J. A.; Smilde, A. K.; van der Werf, M. J. BMC genomics 2006, 7, 142. (28) Gillet, L. C.; Navarro, P.; Tate, S.; Rost, H.; Selevsek, N.; Reiter, L.; Bonner, R.; Aebersold, R. Mol Cell Proteomics 2012, 11, O111 016717. (29) Lommen, A. Anal Chem 2009, 81, 3079-3086. (30) Lommen, A.; Kools, H. J. Metabolomcis 2012, 8, 719-726. (31) Smith, C. A.; Want, E. J.; O'Maille, G.; Abagyan, R.; Siuzdak, G. Anal Chem 2006, 78, 779-787. (32) Kuhl, C.; Tautenhahn, R.; Bottcher, C.; Larson, T. R.; Neumann, S. Anal Chem 2012, 84, 283-289. (33) Paddon, C. J.; Westfall, P. J.; Pitera, D. J.; Benjamin, K.; Fisher, K.; McPhee, D.; Leavell, M. D.; Tai, A.; Main, A.; Eng, D.; Polichuk, D. R.; Teoh, K. H.; Reed, D. W.; Treynor, T.; Lenihan, J.; Fleck, M.; Bajad, S.; Dang, G.; Dengrove, D.; Diola, D.; Dorin, G.; Ellens, K. W.; Fickes, S.; Galazzo, J.; Gaucher, S. P.; Geistlinger, T.; Henry, R.; Hepp, M.; Horning, T.; Iqbal, T.; Jiang, H.; Kizer, L.; Lieu, B.; Melis, D.; Moss, N.; Regentin, R.; Secrest, S.; Tsuruta, H.; Vazquez, R.; Westblade, L. F.; Xu, L.; Yu, M.; Zhang, Y.; Zhao, L.; Lievense, J.; Covello, P. S.; Keasling, J. D.; Reiling, K. K.; Renninger, N. S.; Newman, J. D. Nature 2013, 496, 528-532. (34) McDowell, E. T.; Kapteyn, J.; Schmidt, A.; Li, C.; Kang, J. H.; Descour, A.; Shi, F.; Larson, M.; Schilmiller, A.; An, L. L.; Jones, A. D.; Pichersky, E.; Soderlund, C. A.; Gang, D. R. Plant Physiol 2011, 155, 524-539.

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