Integrating MS1 and MS2 Scans in High-Resolution Parallel Reaction

Dec 2, 2016 - Quantification of targeted metabolites, especially trace metabolites and structural isomers, in complex biological materials is an ongoi...
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Integrating MS1 and MS2 scans in high-resolution parallel reaction monitoring assays for targeted metabolite quantification and dynamic 13C-labeling metabolism analysis Zhucui Li, Yujing Li, Wujiu Chen, Qichen Cao, Yufeng Guo, Ni Wan, Xiaolong Jiang, Yinjie J. Tang, Qinhong Wang, and Wenqing Shui Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b03947 • Publication Date (Web): 02 Dec 2016 Downloaded from http://pubs.acs.org on December 5, 2016

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Analytical Chemistry

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Integrating MS1 and MS2 scans in high-resolution parallel reaction monitoring

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assays for targeted metabolite quantification and dynamic

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metabolism analysis

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Zhucui Li1,2#, Yujin Li3#, Wujiu Chen1, Qichen Cao1, Yufeng Guo1, Ni Wan4, Xiaolong

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Jiang1, Yinjie J. Tang4, Qinhong Wang1, Wenqing Shui2*

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1

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300308

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2

iHuman Institute, ShanghaiTech University, Shanghai 201210, China

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3

College of Life Sciences, Nankai University, Tianjin 300071, China

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Department of Energy, Environmental and Chemical Engineering, Washington

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University in St. Louis, St. Louis, MO 63130, USA

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C-labeling

Tianjin Institute of Industrial Biotechnology, Chinese Academy of Sciences, Tianjin

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#These authors contribute equally to this work

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*To whom correspondence should be addressed to:

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Wenqing Shui, iHuman Institute, ShanghaiTech University, Shanghai 201210, China;

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Tel: 86-21-20685595; email: [email protected]

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Abstract

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Quantification of targeted metabolites, especially trace metabolites and structural

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isomers, in complex biological materials is an ongoing challenge for metabolomics.

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Initially developed for proteomic analysis, the parallel reaction monitoring (PRM)

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technique exploiting high-resolution MS2 fragment ion data has shown high promise

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for targeted metabolite quantification. Notably, MS1 ion intensity data acquired

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independently as part of each PRM scan cycle are often underutilized in the PRM

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assay. In this study, we developed an MS1/MS2-combined PRM workflow for

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quantification of central carbon metabolism intermediates, amino acids and shikimate

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pathway-related metabolites on an orthogonal QqTOF system. Concentration curve

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assessment revealed that exploiting both MS1 and MS2 scans in PRM analysis

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afforded higher sensitivity, wider dynamic range and better reproducibility than

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relying on either scan mode for quantification. Furthermore, Skyline was incorporated

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into our workflow to process the MS1/MS2 ion intensity data, and eliminate noisy

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signals and transitions with interferences. This integrated MS1/MS2 PRM approach

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was applied to targeted metabolite quantification in engineered E. coli strains for

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understanding of metabolic pathway modulation. In addition, this new approach,

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when first implemented in a dynamic

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advantage in capturing and correcting isotopomer labeling curves to facilitate

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nonstationary 13C-labeling metabolism analysis.

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C-labeling experiment, showed its unique

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Introduction

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Mass spectrometry (MS) coupled to different separation techniques such as liquid

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chromatography (LC), gas chromatography (GC) and capillary electrophoresis (CE)

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has become the leading platform for large-scale identification and quantitation of

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metabolites in various biological systems.1-3 Non-targeted MS-based metabolomic

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surveys mainly employ the high-resolution full scanning instruments to profile

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hundreds of endogenous and drug metabolites.4-6 In these studies, metabolite

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identification is typically ensured by MS/MS analysis of isolated precursors using a

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data-dependent acquisition (DDA) strategy.1 However, metabolite quantification

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relying on MS1 scan data could suffer from low reproducibility due to inadequate

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sensitivity of MS1 scans for metabolites that are less abundant, prone to matrix

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interference or have isomeric compounds.3 Very recently, a data-independent

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acquisition (DIA) workflow using SWATH-MS technique initially developed for

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proteomic quantification has been adapted to global metabolomics to allow for

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sensitive, reproducible and high-throughput metabolite quantification based on

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fragment ion intensities in MS2 scans7.

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MS2-based quantification of small molecules has been primarily implemented in

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pharmaceutical labs for specified drug metabolite analysis.8-10 Multiple reaction

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monitoring (MRM) performed on triple quadrupole instruments is recognized as the

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“gold standard” MS technique for targeted bioanalyte quantification due to its high

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sensitivity and robustness.8-10 The MRM technique has been recently adopted in

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metabolomic studies focusing on a defined subset of metabolites representative of key 3

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pathways.11-14 This type of targeted metabolomics is a valuable tool for assessing

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changes of metabolic pathways or networks resulting from genetic mutation, altered

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gene expression, protein dysfunction or environmental perturbation. For example,

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Wei and colleagues developed an LC/MS/MRM platform to monitor 205 endogenous

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metabolites and applied it to targeted metabolite analysis in plasma samples.11

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Nevertheless, MRM assays performed on low-resolution mass spectrometers

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sometimes are limited by ambiguous metabolite identifications as a result of

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interfering peaks from complex matrix that resemble the compound of interest under a

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specific Q1/Q3 transition.15

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Technological improvements in high-resolution MS have led to new acquisition

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methods which have challenged the dominance of MRM for targeted MS.16 One

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approach, parallel reaction monitoring (PRM), has emerged as a capable alternative to

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MRM. In a PRM assay, the precursor ion is isolated in Q1 and fragmented in Q2, and

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all generated fragment ions are monitored in MS2 scans on a high resolution, accurate

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mass spectrometer.17 Then fragment ion intensities from MS2 spectra are used for

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specific precursor quantification. The PRM approach has been successfully

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implemented in a panel of targeted proteomic studies and demonstrated superior

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specificity, accuracy and multiplexing capability compared to the MRM assay.18-21 In

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contrast, there has been rare report of PRM application to targeted metabolomic

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analysis except the very latest research from Zhou et al22 and Qiu et al23. Both groups

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developed PRM assays on a hydrid Q-Exactive instrument (Thermo) for measurement

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of targeted metabolites. Zhou et al reported monitoring 237 endogenous metabolites 4

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for which structural identification solely relied on MS/MS spectra available in public

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databases.22 Qiu et al constructed PRM assays using chemical standards for

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quantification of 25 intracellular primary metabolites.23 It is worth noting that

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PRM-based quantification is carried out using ion intensities of MS2 fragments, yet

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the role of MS1 scans have largely been ignored, despite the fact that the respective

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ion signals of certain precursors could be stronger than those of fragments. Systematic

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evaluation of MS1 vs MS2 quantification in PRM assays has not been reported for

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either metabolite or peptide analysis.

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Our study, for the first time, has developed an MS1/MS2-combined PRM 13

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workflow for targeted metabolite quantification as well as

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analysis on an orthogonal QqTOF instrument (TripleTOF 6600). Sixty-five targeted

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metabolites include central carbon metabolism (CCM) and shikimate pathway

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intermediates, and free amino acids. After comparing the sensitivity, reproducibility

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and linearity of metabolite quantification based on MS1 vs MS2 ion chromatograms

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derived from PRM cycles, we concluded that exploiting both MS1 and MS2 scans in

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PRM assays achieves the best quantitative performance. Furthermore, Skyline can be

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incorporated into our workflow to process the MS1/MS2 ion intensity data, and

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eliminate noisy signals and transitions with interferences.24 The integrated MS1/MS2

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PRM approach was applied to targeted metabolite quantification in engineered E. coli

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strains for understanding of metabolic pathway modulation. In addition, this approach

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was first implemented in a dynamic 13C-labeling experiment to reveal its capability of

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accurate measurement of authentic isotopomers for tracing cell metabolism.

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Experimental Section

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Chemicals, details in sample preparation, and data processing can be found in

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Supporting Information.

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Metabolite Extraction from E. coli Cells. A wild-type E. coli strain AB2834 (WT)

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and two engineered strains (TIB01 and TIB02) with improved production of

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3-dehydroshikimic acid were grown in LB media aerobically at 30 °C, 250 rpm to

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produce the seed culture. The seed cultures were then transferred into a 250 ml flask

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containing the NBS minimal complete media and grew under 37 °C, 250 rpm till

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OD600 reached 2.0. Bacteria cultures of 5~6 ml were quenched by mixing with the

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same volume of frozen saline buffer and harvested through centrifugation at 4 °C for

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3 min at 3500 g. The cell pellet was washed twice with PBS and extracted using a

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pre-chilled solvent mixture of methanol: acetonitrile: water (4:4:2, v/v) with 0.1% FA

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which contains d4-succinic acid as the internal standard. The metabolite extracts were

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snap frozen in liquid nitrogen, thawed, and then sonicated in water bath. The

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freeze-thaw-sonication cycle was repeated twice. Then the samples were incubated at

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-20 °C for 2 h. After centrifugation at 16000 g for 20 min at 4 °C, the supernatant was

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harvested and dried out by speed vacuum and stored in -80 °C. Before HILIC-MS

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analysis, the metabolite extracts were reconstituted into the acetonitrile/water (1:1; v/v)

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solvent. Each strain was prepared in biological duplicate and metabolite extraction

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was processed in duplicate for each biological replicate.

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HILIC-QqTOF Analysis. Metabolite standards or total cell extracts were

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analyzed on a Nexera HPLC system (SHIMADZU, Japan) connected to TripleTOFTM 6

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Analytical Chemistry

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6600 mass spectrometer (AB SCIEX, USA). LC separation was carried out on a

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ZIC-HILIC column (100 mm × 2.1 mm, 3.5 µm, Merck, Germany). The mobile phase

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A was 10 mM ammonium acetate in water, and mobile phase B was acetonitrile. The

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linear gradient used was as follows: 0-3 min, 90% B; 3-18 min, 90%-60% B; 18-25

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min, 60%-55% B; 25-27 min, 55%-50% B; 27-30 min, 50% B; and the column was

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re-equilibrated for 10 min. The flow rate was 0.2 ml/min and the sample injection

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volume was 5 µl. Each metabolite standard was also injected into the mass

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spectrometer through direct infusion to acquire reference MS/MS spectra. Mass

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spectra were acquired in negative ion ESI mode within a mass range from 100 to 1000

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m/z. The ion source parameters are ion spray voltage, -4500 V; curtain gas, 35 psi;

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nebulizer gas, 55 psi; heater gas, 55 psi; source temperature, 550 °C. Rolling CE and

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fixed CE were assessed using standards to acquire optimal CEs for individual

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metabolite targets.

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MS data acquisition for PRM analysis was programmed in the product ion mode,

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and consisted of one MS1 scan (150 ms) with the mass range from 50 to 900 m/z,

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followed by targeted MS2 scans (50 ms) under the optimal CE condition across the

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mass range from 30 to X (X = precursor mass + 10 Da) m/z. The maximal cycle time

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was 3.25 sec for a total of 65 targets. In the dynamic

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cell extracts sampled at different time points were also analyzed by HILIC-Q/TOF in

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the PRM mode. For certain metabolites having suspected interferences, targeted MS2

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scans were performed on specific isotopomers of interest.

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C-labeling experiment, total

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Results and Discussion

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Establishing PRM assays of 61 metabolites on TripleTOF 6600 mass

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spectrometer

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To develop PRM assays for quantification of 61 intracellular metabolites including 44

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central carbon metabolism (CCM) intermediates and 17 amino acids (full name and

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abbreviation in Table S1), we first analyzed a mixture of the synthetic metabolite

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standards on the TripleTOF 6600 mass spectrometer in PRM mode. Each metabolite

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exceeding the MS1 intensity threshold was subjected to MS/MS fragmentation under

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default sweeping collision energy (-35±15 eV). However, we noticed that the

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MS/MS spectra generated under default CE on certain metabolites were of low quality

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as a result of either insufficient or excessive fragmentation of the precursor ions

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(Figure S1A). This is different from peptide PRM assays in which the majority of

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peptides of diverse sequences are fragmented effectively under theoretically predicted

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CE based on the precursor m/z and charge state.17, 21 To improve MS/MS spectral

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quality, we manually optimized CE for each metabolite standard in a way similar to

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MRM assays on small molecules. For both NADPH and acetyl CoA, an increased CE

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relative to the default setting gave rise to a greater number of fragment ions as well as

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diminished precursor peaks (Figure S1B). For another metabolite TPP, two distinct

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fragment ions at m/z 176.938 and 301.970 of 10-fold higher intensity than the default

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condition were generated from the precursor subject to a lower CE (Figure S1B). The

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optimal CE values ranged from -15 to -60 eV for specific metabolites (Table S2).

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We then examined the optimized MS/MS spectra to select one to six fragments 8

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of relatively high abundance and large m/z for target quantification. Skyline software

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was used here to automatically extract MS2 ion chromatograms after we defined

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specific transitions for each metabolite precursor. As MS1 full scan was also

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performed in each cycle of the PRM assay, quantitative data were extracted for a

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given precursor ion using the same “Transition List” module in Skyline. Therefore we

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were able to extract both MS1 and MS2 transitions in a simultaneous data-processing

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workflow with Skyline.

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The reproducibility of MS2-based quantification of 45 tested metabolites was

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significantly impacted by CE conditions. With optimized CE, fragment peak areas for

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38 metabolites showed CVs < 20% in triplicate measurements whereas the number of

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metabolites with fragment peak area CVs < 20% dropped to 22 under the original CE

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condition (Figure S1C). It is noteworthy that the variation of CVs has little to do with

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the data sampling points over extracted ion chromatograms. In fact, a minimum of 18

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data points were acquired for all targeted metabolites considering the wide HILIC

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peak width (1-2 min) and the maximal cycling time including all MS2 acquisitions

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(~3.25 sec). Therefore, we would recommend optimization of CE settings for

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individual metabolites to ensure sensitivity and reproducibility of targeted PRM

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analysis, at least on a QqTOF instrument, even though rolling CE or constant CE is

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typically adopted in data-dependent acquisition for non-targeted metabolomics

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studies.25, 26

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Comparison of MS1 and MS2 quantification in PRM using concentration curves 9

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To compare the quantitative performance of MS1 and MS2 chromatogram extraction

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from PRM acquisitions, we carried out a series of dilution experiments in both simple

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and complex matrix. A mixture of 15 metabolite standards were diluted in simplex

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matrix (50% MeOH) spanning a concentration range from 5 pg to 100 ng on column.

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The MS1 peak area of the precursor ion and sum of MS2 peak areas of selected

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fragment ions provided independent quantitative measure of the targeted metabolite at

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MS1 and MS2 levels. The sensitivity and linear response range of metabolite

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quantification in simple matrix was summarized in Table S3, where 9 out of 15

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metabolites showed a lower LOQ when quantified by MS2 than by MS1. For instance,

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the LOQ of FAD quantification by extracting six MS2 transitions was 5 pg yet the

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LOQ was 10-fold higher (50 pg) for MS1 chromatogram extraction (Figure 1A). At

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low concentrations, the MS1 precursor ion chromatogram of FAD was more prone to

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ion suppression and interferences, leading to increased variability and reduced

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sensitivity. In contrast, the MS2 fragment ions of FAD appeared to be more robust and

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selective, thus offering a lower LOQ and a wider dynamic range (Figure 1A). Among

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the tested metabolites in simple matrix, five showed similar LOQ levels and linear

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response range between MS1 and MS2 quantification in PRM assays (Table S3). For

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example, the precursor and fragment ion chromatograms of L-malic acid (Mal)

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displayed comparable robustness in the low concentration range (Figure 1B). Notably,

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for 5-ALA, MS1 precursor quantification enabled much better sensitivity than MS2

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fragment quantification. The LOQ of 5-ALA quantification with MS2 scans was

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20-fold higher than that with MS1 scans, which was attributed to very weak signals of 10

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all detected fragment ions of this amino acid (Figure 1C).

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PRM quantification of all 61 targeted metabolites was also evaluated in complex

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matrix by preparing up to 210 fold dilution of an E. coli total extract in extraction

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solvent. Forty-one metabolites of our interest showed better sensitivity, consistency

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and wider dynamic range in MS2 vs MS1 quantification (full data in Table S4). In a

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representative case of D-ribose-5-phosphate (R5P), its MS1 precursor ion response

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plateaued at the low end of the concentration curve whereas the MS2 ion

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chromatograms encountered little interference and retained strong signals in the high

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dilution-fold region (Figure 2A). However, for other metabolites such as Val, very

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poor fragment ion chromatograms were observed with increase of the dilution fold,

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thus rendering MS2 quantification ineffective (Figure 2B). It is of our notion that

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metabolites of larger molecular weight including most sugar phosphates, organic acids

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and energy/redox cofactors that tend to generate a greater number of fragments of

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strong intensity are more amenable to MS2 quantification. In contrast, smaller

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metabolites especially amino acids producing fewer and weaker fragments are better

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to be quantified in MS1 scans. Depending on the quantitative reproducibility,

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sensitivity and linear response range of the total cell extract sample, we classified 50

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metabolites to be MS2 quantifiable and 11 to be MS1 quantifiable targets (Table S4).

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When each metabolite was measured in its optimal mode (MS1 vs MS2), 89% of

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all targeted metabolites diluted in complex matrix had a linear regression coefficient

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(R2) of the concentration curves above 0.995, and 95% of metabolites had r2 above

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0.990 across 2-3 orders of magnitude (Figure 2C, Table S4). Moreover, the median 11

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CV of metabolite quantification in triplicate measurements was below 20% over the

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entire concentration range down to 210-fold dilution of the original cell extract (Figure

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2D). These results indicated that excellent linearity, reproducibility and sensitivity of

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the PRM assay can be achieved by combining MS1 and MS2 scans.

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Quantification of isomeric metabolites by PRM MS2 scans

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MS2 scans are particularly useful for differentiation of co-eluting structural isomers

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of identical or very similar molecular weight.27 Within our target list, two pairs of

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isomeric metabolites (citrate/isocitrate and leucine/isoleucine) that completely or in

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most part co-elute in HILIC separation, were indistinguishable based on their MS1

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precursor chromatograms. However, these isomers could be differentiated with the

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isomer-specific fragment ions. For instance, two ions at m/z 72.995 and 117.019 are

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unique fragments derived from isocitrate whereas the abundant ion at m/z 87.009

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specifically originates from citrate (Figure 3A). In this way the unique transitions

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allowed for differentiation and quantification of this isomeric pairs in complex matrix

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even though their MS1 chromatograms were overlapped (Figure 3B). Likewise, Leu

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and Ile both having their unique fragment ions were quantified with distinct MS

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chromatograms of specific isomers (Figure 3C, 3D)

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With PRM MS2 scans, strong linear response of these metabolite isomers were

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obtained in both simple and complex matrix (R2 > 0.98 for all four metabolites, see

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detailed data in Table S3 and S4). Notably, it is difficult to differentiate these two

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pairs of isomeric metabolites in traditional MRM assays11 because MRM typically 12

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selects the most abundant fragment ion which is common to both isomers in this case.

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Therefore, PRM enables quantification of specific isomers by selecting less abundant

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and unique transitions that are of adequate sensitivity and free of interferences from

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the complex background owing to the high-resolution MS2 scans. The previous study

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by Zhou J et al also demonstrated the advantage of PRM in increased specificity of

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metabolite identification and flexibility of post-acquisition assay refinement.22

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Integrated MS1 and MS2 for metabolomic study of engineered E. coli strains

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To further explore the benefits of integrated MS1 and MS2 scans in PRM assays, we

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performed targeted metabolite analysis in three different E. coli strains of WT, TIB01

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and TIB02. Strains TIB01 and TIB02 were genetically engineered from the wild-type

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(WT) in the shikimate pathway for improved production of 3-dehydroshikimic acid

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(DHS).28 DHS is a key hydroaromatic intermediate in the biocatalytic conversion of

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glucose into aromatic bio-products and a variety of industrial chemicals.29 In addition

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to the CCM intermediates and amino acids, we established PRM methods for

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measurement of DHS and three related intermediates (DAHP, DHQ and SK, full name

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in Table S1) in its biosynthetic pathway. Then we conducted PRM analysis of all 65

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targeted metabolites in the cell extracts from strains WT, TIB01 and TIB02 in four

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replicates. As MS1 and MS2 ion intensity data were acquired simultaneously in each

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PRM scan cycle, we extracted the quantification data for each metabolite from

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separate MS1 and MS2 scans in Skyline. Evaluation of peak area CV distribution for

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all targeted metabolites revealed that combining MS1 and MS2 quantification 13

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achieved the best precision (Figure 4A). The median CVs of the combined MS1/MS2

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PRM assays for all targets were 20.3%, 18.1% and 13.9% for WT, TIB01 and TIB02

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strains respectively. This result reflects remarkable analytical reproducibility of our

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approach if considering relatively large variation in cell culture and sample

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preparation. Thus it is advantageous to exploit MS1 scan data in PRM assays which is

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often underutilized so as to further enhance robustness and sensitivity for targeted

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metabolome analysis.

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The pretreated data matrix from targeted metabolites quantified in three strains

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was used to develop an unsupervised PCA model (R2=0.914, Q2=0.944). The result

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exhibited a well-segregated, closely clustered pattern among different groups in the

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PCA score plot, indicating a specific molecular signature of each strain that was

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distinguishable between each other (Figure 4B). Replicates of the same strain were all

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clustered together, again suggesting good reproducibility of our targeted metabolite

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quantification. Significantly modulated metabolites in the CCM and shikimic acid

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pathways as well as free amino acids in two engineered stains vs WT were then

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identified according to dual criteria of VIP score in a supervised OPLS-DA model > 1

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and p-value in the ANOVA test