Ethyl Gallate Displays Elicitor Activities in Tobacco Plants - Journal of

Sep 29, 2017 - Alkyl gallates showed elicitor activities on tobacco in both whole plants and cell suspensions. Methyl gallate (MG), ethyl gallate (EG)...
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Ethyl gallate displays elicitor activities in tobacco plants Pascale GOUPIL, Razik Benouaret, and Claire Richard J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.7b03051 • Publication Date (Web): 29 Sep 2017 Downloaded from http://pubs.acs.org on October 2, 2017

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Journal of Agricultural and Food Chemistry

Title: Ethyl gallate displays elicitor activities in tobacco plants

Authors: Pascale Goupil1,2 *, Razik Benouaret1,2, Claire Richard3,4

Affiliations: 1

Université Clermont Auvergne, UMR 547-UBP/INRA PIAF, Campus universitaire des Cézeaux, 8 avenue Blaise Pascal, 63178 Aubière cedex, France, 2

INRA, UMR 547 PIAF, Clermont-Ferrand, France

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Université Clermont Auvergne, CNRS, UMR 6296, Campus universitaire des Cézeaux, Institut de Chimie de Clermont-Ferrand (ICCF), 24 avenue Blaise Pascal, 63178 Aubière cedex, France

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Equipe Photochimie CNRS, UMR 6296, ICCF, 63178 Aubière, France

*Author for correspondence: Pascale Goupil Phone: (33) 04 73 40 79 40 Fax: (33) 04 73 40 79 42 E-mail: [email protected]

Running title: Alkyl gallates in plant defence

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Abstract

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Alkyl gallates showed elicitor activities on tobacco in both whole plants and cell suspensions.

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Methyl gallate (MG), ethyl gallate (EG) and propyl gallate (PG) infiltration into tobacco

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leaves induced hypersensitive reaction-like lesions and topical production of autofluorescent

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compounds revealed under UV light. When sprayed on tobacco plants at 5 mM, EG promoted

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upregulation of defence-related genes such as the antimicrobial PR1, -1,3-glucanase PR2,

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chitinase PR3 and osmotin PR5 target genes. Tobacco BY-2 cells challenged with EG

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underwent cell death in 48 h, significantly reduced in the presence of the protease inhibitor

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aprotinin. The three alkyl gallates all caused alkalinisation of the BY-2 extracellular medium,

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whereas gallic acid did not trigger any pH variation. Using EGTA or LaCl3, we showed that

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Ca2+ mobilisation occurred in BY-2 cells elicited with EG. Overall, our findings are the first

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evidence of alkyl gallate elicitor properties with early perception events on plasma membrane,

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potential hypersensitive reactions and PR-related downstream defence responses in tobacco.

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Key words: Alkyl gallates, BY-2, Elicitors, Ethyl gallate, Pathogenesis-related protein, Plant

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defence reactions, Tobacco

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Introduction

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Open-field crops are always vulnerable to pathogens, and so extensive farming requires

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constant control of pathogen populations. Synthetic pesticides are commonly used for direct

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pest control, but need repeated spreading for season-long protection. Pesticide action is

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mostly selective and requires combinations of active compounds in an integrated pest

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management approach. A promising alternative that emerged in the 1990s is based primarily

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on improving the endogenous defence capabilities of plants. When plants are attacked by

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pathogens, they defend themselves with an arsenal of defence mechanisms. These active plant

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defence responses comprise three successive events: (i) recognition of the pathogen, (ii) signal

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transduction, and (iii) execution of the defence programmes with activation of defence genes.1

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The recognition events involve pathogen- or plant-derived signalling entities termed elicitors.2

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Intracellular signal conversion and transduction include the very early elicitor-induced

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signalling processes such as protein phosphorylation, influx of Ca2+, efflux of H+, K+ and Cl−

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leading to extracellular alkalinisation, depolarisation of the plasma membrane, and active

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oxygen species production, culminating in the hypersensitive response, a localised cell

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suicide.3 Ultimately, the pathogen challenge leads to the production of phytoalexins and

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pathogenesis-related proteins, cell wall and/or cuticle reinforcement which prevent pathogen

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development. Point inoculation of the pathogen, in addition to triggering the local acquired

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resistance response (LAR), can mobilise systemic acquired resistance (SAR), which alerts and

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predisposes the tissues to a more intensive response on subsequent infection.1,4 Salicylic acid

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(SA) plays a crucial role in the SAR induction processes. SA is involved in the signal

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transduction systems by activating enzyme expression catalysing biosynthetic reactions to

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produce defence compounds 5,6 and provide protection for plants against pathogens.

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As it is pathogenesis that initiates SAR, impact on disease is lower than if the SAR response

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had been activated before the arrival of the pathogen. The use of plant defence inducers 3

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(PDIs) to establish SAR intentionally and preventively in plants are thus currently a promising

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strategy in phytoprotection. PDIs are organic, inorganic, botanical or synthetic stimulus-

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triggering factors (elicitors) that mobilise plant defence reactions.7,8 By stimulating plant

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immunity, PDIs provide defence against subsequent infection.7,9 To date, only very few

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substances with high SAR activity have been described 9, and they mostly combine PDI and

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pesticide actions, not necessarily a disadvantage since both properties are inimical to

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pathogens. 10

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Agricultural applications of plant activators are far from valued.9 The synthetic agrochemicals

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now available are SA-like substances that mimic the action of this phytohormone. Of these,

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2,6-dichloro isonicotinic acid (INA) and acibenzolar-S-methyl (BTH) and their derivatives are

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the most thoroughly studied, currently marketed as BOOST®, Bion® and Actigard™. These

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resistance activators serve as efficient chemical inducers of SAR, with effectiveness against

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diverse plant diseases.11,12

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The identification of new chemicals able to induce disease resistance is beneficial not only for

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elucidating the pathways leading to SAR, but also for developing new plant protection agents.

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The effectiveness of various elicitors depends on plant taxonomy, and there are many

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examples where an elicitor is more effective on some plant species than on others.8 We have

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been engaged in seeking naturally-occurring or synthetic substances able to induce SAR

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reactions. As part of this research we evaluated the PDI activity of alkyl gallates (3,4,5-

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trihydroxybenzoates) on tobacco plants. Gallic acid derivatives had already been found to

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display antimicrobial properties. Octyl, nonyl and lauryl gallates exhibit fungicidal and

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bacterial activity.13,14 Silva et al.15 showed their potential for use in disease management,

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evaluating the inhibitory activity of a set of gallic acid alkyl esters on the plant pathogenic

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bacterium Xanthomonas citri. Here we demonstrate for the first time that alkyl gallates act at

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various points in the signalling pathway leading to defence reactions. We report evidence that 4

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treatment of tobacco with methyl, ethyl and n-propyl gallates induces hypersensitive-like

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reactions with activation of defence-related genes in the tobacco plant. These gallic acid

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derivatives trigger rapid extracellular alkalinisation of BY-2 plant cells with Ca2+

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mobilisation, suggesting that tobacco cells perceive the chemicals by modifying plasma

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membrane physical properties. Finally, the naturally-occurring and semisynthetic gallic acid

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derivatives revealed potent PDI actions, revealing a valuable source of compounds that could

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find use in green agriculture practices.

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Materials and methods

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Biological compounds and chemicals

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Methyl gallate (MG), ethyl gallate (EG), n-propyl gallate (PG), salicylic acid (SA), and gallic

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acid (GA) were purchased from Sigma-Aldrich (Saint-Quentin-Fallavier, France). All the

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compounds were dissolved in ultrapure water (MilliQ). PG needed warm (25 °C) ultrapure

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water to dissolve completely.

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Plant material and treatments

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The biological activity of alkyl gallates was measured on 3-month old tobacco plants

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(Nicotiana tabacum L.) bearing 20–22 leaves (preflowering stage). Tobacco plants were

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grown in a greenhouse under controlled conditions (22 ± 5 °C with a photoperiod of 16 h

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light). The chemical solutions to be tested (50 µl) were infiltrated into the leaf tissue using a

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plastic syringe (without a needle), on an area of 1–2 cm2. As a positive control, leaves were

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infiltrated with 2 mM SA. For the negative control, leaves were infiltrated with ultrapure

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water. The compounds were infiltrated into distinct areas on the same leaf for the examination 5

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of macroscopic symptoms under bright field or UV light (at 312 nm). For PR transcript

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quantification, three mature leaves were sprayed on both their upper (adaxial) and lower

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(abaxial) surfaces. Foliar spray treatments were administered with a fine atomiser until the

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solutions dripped (3 mL per leaf on average). The negative control was leaves sprayed with

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ultrapure water.

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Tobacco cell suspensions of Nicotiana tabacum L. cv. Bright Yellow-2 (BY-2) were grown in

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MS medium (Duchefa, Netherlands) supplemented with sucrose (30 g.L-1), thiamine (1 mg.L-

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1

), myo-inositol (102 mg.L-1) and 2,4-dichlorophenoxyacetic acid (0.2 mg.L-1) at pH 5.8. Cells

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were agitated in the dark (140 rpm, 25 °C) and subcultured weekly by dilution at a 1:15 ratio

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in fresh medium. For determination of extracellular pH changes, cells from culture in

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exponential-phase growth were collected by filtration, washed with 175 mM mannitol, 0.5

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mM CaCl2, 0.25 mM MgCl2, 1 mM KCl and 1 mM sucrose, and resuspended at 0.1 g fresh

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weight (FW)/mL in the same medium. The initial pH was about 4.8.

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Semi-quantitative RT-PCR

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The patterns of PR gene expression were analysed by real-time quantitative PCR (RT-qPCR)

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using SYBR-green and the iCycler iQv5 (Bio-Rad). Total RNA was extracted from tobacco

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leaf tissue (200 mg) in cetyltrimethylammonium bromide extraction buffer, as described by

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Chang et al.16. Total RNA was cleaned up with 0.5 U DNase I solution (Euromedex, France)

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containing 20 U RNase inhibitor (Euromedex, France). RNA integrity was verified on a 1%

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agarose gel by detecting ribosomal RNA. RNA concentrations were measured

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spectrophotometrically at 260 nm. First-strand cDNA was synthesised from up to 1 µg of total

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RNA with Euroscript Reverse Transcriptase (Eurogentec, France) according to the

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manufacturer’s instructions. PCR reactions were prepared using the qPCR kit Mastermix for 6

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SYBR green (Eurogentec) according to the manufacturer’s protocol. The cDNA concentration

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used produced a threshold cycle value (CT) of between 15 and 30 cycles. Amplification

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specificity was checked by melting-curve analysis. The relative quantity (QR) of PR gene

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transcripts using the EF-1α gene

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mathematical model.18 Values are given as log2QR. For every PR gene analysed, three

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independent biological replicates were run, and every run was carried out at least in triplicate.

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Primers and amplicon sizes are given in Benouaret and Goupil.19

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as internal standard was calculated with the delta-delta

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BY-2 Extracellular alkalinisation

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The pH variations of the culture medium were recorded by introducing a glass microelectrode

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(Hanna Instrument, HI1330B, France) into 6 ml of the equilibrated cell suspension culture.

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The pH was measured every 10 min starting immediately after treatment with elicitors or

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ultrapure water (negative control). The ∆pH was the pH measured every 10 min relative to the

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pH measured at t0 immediately after adding elicitors or ultrapure water. Each experiment was

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repeated at least three times to check reproducibility. Figures depict the results of typical

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experiments. Pharmacological treatments were conducted using the chelator EGTA (2 mM)

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and the Ca2+ channel blocker LaCl3 (2 mM).

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Cell death measurement

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The Evans Blue assay was performed according to Amano et al. (2003) using a plastic syringe

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device. The pigment enters cells with damaged plasmalemma. The assay was first calibrated

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with a set of viability standards using mixtures of living and dead tobacco BY-2 cells

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(Benouaret et al., 2014). Tobacco cells (500 µL) were withdrawn from the culture medium

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immediately (t0) and then 24 h after elicitation. Pharmacological treatment was conducted

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with the serine protease inhibitor aprotinin (0.2 µM) 30 min before cell death rate

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determination. Absorbance at 600 nm was measured to estimate cell death. Each experiment

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was repeated three times with three independent BY-2 cultures.

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Results

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Macroscopic changes of tobacco tissues challenged with alkyl gallates

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Foliar tobacco tissues were infiltrated with the three alkyl gallates (Fig. 1) at 5 mM, and the

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macroscopic changes were examined under bright and UV light. Fig. 2 shows the kinetics of

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appearance of macroscopic symptoms on the abaxial face of tobacco leaves exposed to bright

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light (Fig. 2A-D) and UV light (Fig. 2E-H). UV light examination (λ = 312 nm) revealed that

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the methyl gallate (MG)-, ethyl gallate (EG)- and n-propyl gallate (PG)-infiltrated zones and

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the surrounding tissues displayed autofluorescence indicative of the accumulation of phenolic

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compounds (Fig. 2F-H). At 2 and 4 dpi, tobacco mesophyll infiltrated with MG was

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unchanged under bright light, but the chemical induced autofluorescence in the surrounding

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tissues. A restricted chlorotic zone appeared at 8 dpi without production of fluorescent

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compounds. By contrast, the EG-infiltrated tissues turned chlorotic by 4 dpi and tissue injury

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was enlarged at 8 dpi. The surrounding zone was loaded with phenolic compounds. The PG-

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infiltrated tissues showed the most pronounced signs, with restricted brown areas at 2 dpi and

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a brown extended zone at 4 and 8 dpi. Examination of the leaf tissue by UV light revealed that

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the necrotic zone was surrounded by a scattered pattern of fluorescence. Overall, tobacco

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leaves were receptive to the three alkyl gallates tested. Since the alkyl gallates themselves did

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not emit fluorescence (Fig. 2E), these results evidence that the chemical compounds induced

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marked metabolic changes over the interveinal areas of the leaves. The naturally-occurring 8

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EG was retained for further work, since it proved highly active in inducing accumulation of

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autofluorescent compounds.

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A dose-response experiment was undertaken on EG-infiltrated tobacco tissues. Macroscopic

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symptoms were examined under bright and UV light for EG concentrations ranging from 5

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mM to 0.5 mM. Fig. 3 shows the infiltrated areas at 4 dpi. The 5 mM-infiltrated zone

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appeared slightly chlorotic and displayed a large fluorescent surrounding area. Expansion of

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autofluorescence was induced dose-dependently. EG infiltration at 2 mM resulted in faint

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autofluorescence, and at 1 mM had no effect. As expected, SA (2 mM) induced a necrotic

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area with local accumulation of fluorescent compounds.

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Responses of cultured cells to alkyl gallates

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We used medium alkalinisation as a readily measurable effect on suspension-cultured BY-2

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cells to test the potential elicitor activity of alkyl gallates. As shown in Fig. 4A, alkalinisation

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of the culture medium in response to AG was evidenced for the 1 mM and 5 mM

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concentrations. Suspended cells responded to AG by a rapid, sustained alkalinisation of the

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incubation medium. Extracellular alkalinisation was detected immediately after adding the

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AG. The three alkyl gallates induced a ∆pH reaching 0.8 to 1.1 units at 1 mM and 1.5 to 1.8

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units at 5 mM after 150 min. Fig. 4B shows that the extent of pH variation was dose-

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dependent in the concentration range used for EG. The threshold value was not reached in our

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experimental system; the lowest concentration (0.5 mM) could still cause a pH change of 0.8

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units. As expected, no pH shift was detected with the control cells treated with water.

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The calcium mobilisation in EG-induced pH changes was investigated by adding the chelator

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agent EGTA (2 mM) and the Ca2+-channel blocker LaCl3 (2 mM) to the culture medium

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concomitantly with the EG. Both chemicals radically suppressed the pH shift. Adding the

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chemicals during the alkalinisation phase, i.e. 30 min after elicitation, resulted in rapid

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abolition of the pH rise. EDTA and LaCl3 had an inverse effect on the extracellular pH

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medium in control cells, with slight medium acidification (Fig. 4C).

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The eliciting activity of gallic acid (GA) was measured by medium pH determination.

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Addition of GA at 0.5 mM and 5 mM to the BY-2 cell suspension did not trigger any pH

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variation in the extracellular medium, suggesting that the compound was not perceived by the

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tobacco cells, at least as noted above (Fig. 4D).

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The EG-triggered hypersensitive-like response was investigated in BY-2 cells using the Evans

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blue test (Fig. 5). Cell death rate was measured in tobacco cells exposed to EG at 0.5 mM,

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2 mM and 5 mM for 48 h (Fig. 5A). Cell death rate was 10% on average in control cells

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(without EG). The EG elicitation induced significantly higher cell death. The exposure of

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tobacco cells to 2 mM and 5 mM EG increased the magnitude of the cell death rate, which

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reached 25% and 45% respectively. The action of the plant cell death inhibitor aprotinin was

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examined on 5 mM EG-elicited cells. As shown in Fig. 5B, the protease inhibitor lowered cell

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death rate by 19%, whereas the inhibitor did not affect cell viability in control tobacco cells.

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Ethyl gallate-induced PR transcript accumulation

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The ability of EG to induce defence-related gene expression was investigated in tobacco

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plants. Transcript levels of four PR target genes were quantified by quantitative real-time

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PCR in EG-treated leaves 4 days after spraying. At 1 mM, EG failed to induce significant

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transcript accumulation of the four PR markers. At 5 mM, EG led to high PR transcript

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accumulation: 60-fold for the antimicrobial PR1, 50-fold for β-1,3-glucanase PR2, 35-fold for

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chitinase PR3, and 30-fold for osmotin PR5, on average (Fig. 6).

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Discusion

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The present work demonstrates the ability of three alkyl gallates to elicit plant defence

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reactions. Using tobacco as a plant model, we show the potential of methyl gallate (MG),

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ethyl gallate (EG) and n-propyl gallate (PG) to trigger local injuries, biochemical changes and

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PR transcript accumulation. Infiltration of tobacco leaves with the chemicals resulted in foliar

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symptoms and local accumulation of fluorescent compounds. The three compounds induced

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restricted chlorotic tissues visualised under bright light, with production of phenolics in the

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surrounding areas, suggesting cell death initiation of the mesophyll cells. The topical

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reactions induced by the three alkyl gallates were of different severity in terms of tissue injury

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and production of phytoalexin-like entities. The fact that the intensity of effects varied with

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the alkyl gallates (MG < EG < PG) suggests that the compounds were active to different

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degrees at the 5 mM concentration, or that their modes of action differed in the necrotic

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reaction associated with cell death. EG and PG seemed to be the most potent inducers of local

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cell death in our experiment. Localised cell death in plant tissue resulting from attack by

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pathogens can occur either in hypersensitive resistant response or in harmful reactions such as

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necrosis potentially caused by toxins.22 We demonstrate here that BY-2 cell death is sensitive

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to protease inhibitor, suggesting that infiltrated tobacco tissues may evolve towards

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hypersensitive status. However, phytotoxic reactions caused by alkyl gallate cannot be ruled

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out.

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Rapid changes in membrane permeability are involved in plant defence-associated early

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responses to various biotic elicitors.23 Increased influx of protons and calcium mobilisation

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are both early events in the elicitor signalling network. Perception of alkyl gallates visualised

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by the pH rise in the incubation medium was evidenced on BY-2 cells. Medium alkalinisation

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is one of the very early events occurring in elicitor-binding sites in plant cells 24, and results

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from elicitor-induced depolarisation of the plasma membrane with subsequent K+/H+

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exchanges and Ca2+ influx/Cl− efflux. In our experiments, the effect of Ca2+ influx inhibitors

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EGTA or LaCl3 caused the decreased pH shift of the extracellular medium, suggesting that

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Ca2+ mobilisation occurred in BY-2 cells elicited with alkyl gallates. As a consequence of ion

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fluxes, a predictive cytoplasmic acidification should take place rapidly in BY-2 cells.

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Cytoplasmic acidification is regarded as an essential step in signal transduction, leading to

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early defence gene expression and secondary metabolite biosynthesis.25

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Kinetics of extracellular pH changes vary among elicitors, with two main different behaviours

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towards cells. According to the nature of the elicitor, the perception can induce a long-

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sustained pH rise, or the pH variation can be transient, with a return to the resting value. It is

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noteworthy that the modification of H+ flux in BY-2 cells following treatment by alkyl

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gallates was similar to the defence response elicited by a polyphenolic-enriched grape

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extract.21 The induced H+ flux modification lasting 150 min presented similar characteristics

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in the respective time course of the effect. This result suggests that the underlying processes

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are basically the same. EG is a naturally-occurring gallic acid derivative found in several plant

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sources and identified in wines from different varieties of Vitis vinifera.26 It was not detected

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in a red winery by-product extract (data not shown), suggesting that this biomolecule is not

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active in grape marc extract.

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Alkyl gallates are antioxidants. One of the earliest cellular responses following elicitor

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recognition is oxidative burst with production of active oxygen species (AOS). Despite their 12

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damaging effect, AOS are well-described second messengers producing plant responses.

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Whether AOS will act as a destructor or as a signalling entity depends on the equilibrium

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between AOS production and scavenging. Low concentrations of AOS act as signalling

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entities mediating the plant responses: however, high concentrations cause acute damage to

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cell components.27 In elicitor-challenged cells, disruption in cellular redox homeostasis appear

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to switch on a signalling cascade leading to programmed cell death, encountered during

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hypersensitive response (HR).28 Using pharmacological approaches, our group came near to

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the hypersensitive status of BY-2 cells that led to cell death on EG treatment. In this BY-2

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system, the antioxidant gallates acting as free radical scavengers could subsequently help to

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reduce physiological AOS equilibrium and induce HR-related cell death. The potential ability

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of phenolics to induce HR-related cell death has been previously demonstrated with

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polyphenolic-enriched grape marc extracts.21 Even though EG was not detected in the grape

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marc extracts, it can be assumed that the antioxidant properties of polyphenolics could be

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involved in HR establishment. Investigation of AOS as potential agents with pharmacological

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approaches will help to characterise the pathways leading to the hypersensitive status of EG-

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induced cell death in tobacco.

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Alkyl gallates evidently activate the SAR pathway, since they induced expression of the same

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set of SAR genes, i.e. PR1, PR2, PR3 and PR5, that are induced by SA.29 Numerous synthetic

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and/or bio-based elicitors can induce plant immune responses. The most marked chemical

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ones, acibenzolar-S-methyl (ASM) and 2,6-dichloroisonicotinic acid (INA), both induce SAR

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without SA accumulation; probenazole (PBZ) induces SAR through SA biosynthesis.11,30 SA

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involvement in alkyl gallate-regulated plant defences and the potential of these compounds to

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protect cultivated crops are being investigated in laboratory studies.

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In conclusion, the present work offers evidence for plant immunity inducer properties of alkyl

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gallates. Plants can synthesise a wide range of phenolics as an integral part of their non-host 13

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resistance strategy. These secondary metabolites are natural defensive antibiotics, ensuring

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efficient chemical barriers to pathogens. Their elicitation properties are demonstrated here for

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the first time in alkyl gallates, which emerge as PDI agents suited to phytoprotection. Being

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naturally-occurring and ubiquitous, EG is the most promising of these agents. It is potentially

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non-toxic for the human being, and offers consumer benefits, with antioxidant, anti-

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inflammatory and anticarcinogenic activities. Given that EG can play a dual role in plant

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protection, as it also possesses direct antimicrobial activities, this biocontrol agent constitutes

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a potent product well-suited to environmentally-oriented schemes for high crop protection.

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Acknowledgements

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This work was supported by grants from FUI: Fonds Unique Interministériel.

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The authors thank Céline Sac for help with the tobacco cell cultures and laboratory assistance,

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and Dominique Marcon for technical assistance in photographic editing.

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development and application. Mol. Plant Microbe Interact. 2017, 30, 355-360.

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11. Bektas, Y.; Eulgem, T. Synthetic plant defense elicitors. Front. Plant Sci. 2015, 5, 804.

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doi: 10.3389/fpls.2014.00804.

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12. Dufour, M-C.; Magnin, N.; Dumas, B.; Vergnes, S.; Corio-Costet, M-F. High-throughput

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gene-expression quantification of grapevine defense responses in the field using microfluidic

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dynamic arrays. BMC Genomics 2016, 17, 957. doi :10.1186/s12864-016-3304-z.

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13. Kubo, I.; Xiao, P.; Fujita, K. Anti-MRSA activity of alkyl gallates. Bioorganic &

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14. Leal, P.C.; Mascarello, A.; Derita, M.; Zuljan, F.; Nunes, R.J.; Zacchino, S.; Yunes, R.A.

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Relation between lipophilicity of alkyl gallates and antifungal activity against yeasts and

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filamentous fungi. Bioorg. Med. Chem. Lett. 2009, 19, 1793-1796.

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15. Silva, I.C.; Regasini, L.O.; Petrônio, M.S.; Silva, D.H.S.; Bolzani, V.S.; Belasque, J.;

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Sacramento, L.V.S.; Ferreira, H. Antibacterial activity of alkyl gallates against Xanthomonas

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citri subsp. Citri. J. Bacteriol. 2013, 195, 85-94.

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16. Chang, S.; Puryear, J.; Cairney, J. A simple and efficient method for isolating RNA from

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pine trees. Plant Mol. Biol. Report. 1993, 11, 113-116.

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17. Peng, J-L., Bao, Z-L., Ren, H-Y., Wang, J-S., Dong, H-S. Expression of harpinXoo in

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transgenic tobacco induces pathogen defense in the absence of hypersensitive cell death.

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18. Pfaffl, M.W. A new mathematical model for relative quantification in real-time RT-PCR. 16

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against Phytophthora parasitica are impaired in NahG tobacco plants. J. Agric. Food Chem.

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2015, 63, 6653-6659.

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the accurate, time-resolved determination of cellular viability. Anal. Biochem. 2003, 314, 1-7.

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defence reactions and hypersensitive response in cultured tobacco cells. Plant Physiol.

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Biochem. 2014, 77, 84-89.

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mechanisms and role in plant defence against pathogens. J. Fruit Ornam. Plant Res. 2005, 13,

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Wendehenne, D.; Pugin, A. Early signaling events induced by elicitors of plant defenses. Mol.

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Plant Microbe Interact. 2006, 19, 711-724.

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plant secondary metabolites. Biotechnol. Adv. 2005, 23, 283-333.

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reactions and secondary metabolism. Int Rev Cytol. 2001, 206, 1-44.

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damage, and antioxidative defense mechanism in plants under stressful conditions. J. Bot.

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comparison between localized and systemic acquired resistance induced in tobacco by a

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Phytophthora megasperma glycoprotein elicitin. Plant Mol. Biol. 2003, 51, 109-118.

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sustainable plant protection against pathogens. Biotechnol. Adv. 2015, 33, 994-1004.

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Figure captions

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Fig. 1. Structures of the active ingredients studied

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Fig. 2. Macroscopic symptoms induced in tobacco leaves by methyl gallate (MG), ethyl

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gallate (EG) and n-propyl gallate (PG) infiltration observed under bright field (A-D) and UV

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light (E-H) at 0 dpi (A,E), 2 dpi (B,F), 4 dpi (C,G) and 8 dpi (D,H). Alkyl gallates were

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infiltrated at 5 mM. Bars 2 cm

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Fig. 3. Macroscopic symptoms induced in tobacco leaves by EG infiltration observed under

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bright field (A) and UV light (B) at 4 dpi. Tobacco leaves were infiltrated with different EG

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concentrations: 5 mM (1), 4 mM (2), 3 mM (3), 2 mM (4), 1 mM (5) and 0.5 mM (6),

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ultrapure water (control), 2 mM SA. Bars 1 cm

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Fig. 4. Extracellular alkalinisation in tobacco BY-2 suspension cells over time elicited with

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methyl gallate (MG), ethyl gallate (EG), and n-propyl gallate (PG). A. Alkyl gallates used at 5

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and 1 mM, B. EG in the presence of Ca2+ inhibitors. EGTA and LaCl3 at 2 mM were added to

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the BY-2 medium at the onset of elicitation or at 30 min (arrow), C. EG added at 0.5 to 5 mM,

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D. Gallic acid (GA) and EG used at 5 and 0.5 mM. The control is water. The data are from

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representative experiments out of a total of five.

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Fig. 5. Cell death rate assessed by Evans Blue staining of tobacco BY-2 cell suspension

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treated with ethyl gallate (EG) at 0.5, 2 and 5 mM for 48 h. The protease inhibitor aprotinin

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was added 30 min before cell death measurement in BY-2 cells treated with water (control) or

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5 mM EG. Values are expressed relative to control (water treatment) values. The experiments

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were performed in triplicate with three different BY-2 cultures. Bars represent means ±SEM.

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Letters indicate significant differences between treated and control samples according to one-

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way ANOVA followed by LSD test (p ≤ 0.05). Bars represent the mean values ± SE, p ≤ 0.05.

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Fig. 6. PR transcript accumulation in tobacco leaves 4 days after 2 mM SA (positive control)

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or 1 and 5 mM ethyl gallate (EG) spraying. Transcripts were quantified by real-time RT-PCR

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in the sprayed leaves. Values are expressed relative to control (water treatment) values. Three

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leaves per plant were treated for each experiment. Each independent experiment was

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performed in triplicate. Bars represent means ± SEM. Letters indicate significant differences

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between treated and control samples according to one-way ANOVA followed by LSD test

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(p ≤ 0.05).

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Fig 1

Methyl  gallate  

Ethyl  gallate  

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Propyl  gallate  

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Fig 2

MG

MG

MG

MG

EG

EG

EG

EG

PG

PG

PG

PG

A  

B  

D  

C  

MG

MG

MG

MG

EG

EG

EG

EG

PG

PG

PG

PG

E  

F  

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H    

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Fig 3

CONTROL

1

1

2

2

3

CONTROL

3

4 SA 2mM

A

SA 2mM

4

5

5

6

6

B

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Fig 4

A

B

C

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c

Fig 5 b a a

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a

a

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Fig 6

a   b  

Rela9ve  transcript  quan99es  

70   60   50  

PR1  

40  

b  

30  

0  

PR2   PR3  

20   10  

b  

c   c   c   c   Control  

c  

c  

PR5  

c   c  

EG  1mM  

EG  5mM  

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TOC  

MG EG PG

PLANT DEFENSES REACTIONS in tobacco leaves and BY-2 -macroscopic symptoms -PR transcripts accumulation -cell death -perception events on membranes

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