In grapevine Vitis vinifera L. cv Pinot noir, the Pathogenesis-Related (PR) proteins CHI4D and TL3 are among the most abundant extractable PR proteins of ripe berries and accumulate during berry ripening from véraison until full maturation. Evidence was supplied in favor of the involvement of these two protein families in plant defense mechanisms and plant development. In order to better understand CHI4D and TL3 function in grapevine, we analyzed their temporal and spatial pattern of expression during maturation and after an abiotic stress (UV-C) by in situ hybridization (ISH) and immunohistolocalization. In ripening berries, CHI4D and TL3 genes were mainly expressed in the exocarp and around vascular bundles of the mesocarp. In UV-C exposed berries, CHI4D and TL3 gene expression was strongly induced before véraison. Corresponding proteins localized in the exocarp and, to a lesser extent, around vascular bundles of the mesocarp. The spatial and temporal accumulation of the two PR proteins during berry maturation and after an abiotic stress is discussed in relation to their putative roles in plant defense.
Citation: Colas S, Afoufa-Bastien D, Jacquens L, Clément C, Baillieul F, Mazeyrat-Gourbeyre F, et al. (2012) Expression and In Situ Localization of Two Major PR Proteins of Grapevine Berries during Development and after UV-C Exposition. PLoS ONE 7(8): e43681. https://doi.org/10.1371/journal.pone.0043681
Editor: Maria Gasset, Consejo Superior de Investigaciones Cientificas, Spain
Received: February 27, 2012; Accepted: July 24, 2012; Published: August 24, 2012
Copyright: © Colas et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by a fund from the Champagne Ardenne Area and the FEDER (Fonds Européen de Développement Régional). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Plants respond to environmental stimuli and pathogen attacks by inducing a variety of defense mechanisms. Among these, defense proteins, termed as pathogenesis-related (PR) proteins, are highly accumulated in all plant tissues and organs. PR proteins were first described in tobacco leaves, following infection with tobacco mosaic virus ,  and have subsequently been identified in numerous monocotyledonous and dicotyledonous plants, and hence can be considered as ubiquitously distributed in plant kingdom . In grapevine (Vitis vinifera L.) different families of PR proteins have been found to be induced in different organs after a stress or at specific developmental stages , , , , . In berries, expression of genes encoding several PR proteins dramatically increases at the onset of berry softening (véraison) , . These proteins are abundant in ripe berry and represent about 20% of the total proteins , . Among these, chitinase (PR-3) and thaumatin-like (PR-5) proteins are the two major PR protein families represented in berry juice , , , . Due to their resistance to proteolysis and stability at acidic pH, these proteins cause haze in wine and thus decrease its commercial value , . In berries, the most abundant proteins belonging to these two PR protein families are one chitinase of class IV CHI4D/CHV5 (NCBI reference sequence: XP_002275386.1) and two thaumatin-like proteins, VvTL1 (NCBI reference sequence: XP_002282910.1) and VvTL2/TL3 (NCBI reference sequence: XP_002282964.1) , , . However their concentration could vary depending on the cultivar and environmental conditions , , , . This accumulation throughout maturation concomitant with the accumulation of sugars that are source of carbon for fungi could constitute a preformed defense. Indeed some chitinase and thaumatin-like proteins are known to have antifungal properties , , . Chitinases known for degrading chitin, an insoluble homopolymer of β-(1–4)-linked N-acetylglucosamine units, may also perform signaling functions as releasing elicitors from invading fungal hyphae , . Thaumatin-like proteins enhance the permeability of fungal cell membrane by forming holes, which enables water influx and causes rupture of hyphal membrane , . In addition, some thaumatin-like proteins bind to β-1,3-glucans and display β-1,3-glucanase activity . Furthermore, some evidence exists for chitinase and thaumatin-like developmental regulation in specific tissues and at specific stages during plant development suggesting that both proteins could be involved in other functions than plant defense , , , . For example, PR-5 overexpression was shown to improve Arabidopsis seed germination . In order to better understand chitinase and thaumatin-like protein roles in grape berry maturation and/or defense, it is not only necessary to monitor their temporal pattern of expression throughout development but also to identify the tissues where their expression occurs, which has never been performed before. For that purpose, in situ hybridization and immunohistolocalization are to our knowledge, the best suitable approaches.
The present report focuses on the temporal and spatial expression of CHI4D and TL3 in the whole berry tissues at different developmental stages and after UV-C irradiation. This treatment allowed to study the incidence of a stress on morphologically preserved tissues contrary to fungus-infected berries where a tissue degradation follows fungal infection. Global expression of CHI4D and TL3 was followed by qRT-PCR and western blot analyses and was associated to in situ hybridization and immunohistolocalization approaches. The biological function of CHI4D and TL3 is discussed in relation to their tissular localization and variation in expression levels during berry maturation and after UV-C stress.
Materials and Methods
Berries of Vitis vinifera L. cv Pinot noir were collected in vineyard at the experimental station of the Comité Champagne, Plumecoq (France) in 2008, 2009 and 2010. Four stages of development were identified according to the BBCH scale : groat-sized berries (BBCH75), bunch closure (BBCH77), onset of véraison (BBCH81) and mature berries (BBCH89). All necessary permits were obtained for the described field studies.
Detached berries were placed on wet Whatman in Petri dishes and irradiated using a UV-C lamp (254 nm, Vilber Lourmat, Model VL-6.C, output 710 µW cm−2, 12 cm distant) for 7 min under agitation. Controls consisted of non-irradiated but agitated berries (named control) and non-irradiated and non-agitated berries (named untreated berries). Petri dishes were then sealed with parafilm and placed in a 22°C growth chamber (16/8 h photoperiod) for 48 and 96 h.
RNA Extraction and Real-time Quantitative PCR
RNA extraction and real-time quantitative PCR were performed as previously described in Petit et al. (2009)  with minor modifications. A 150 ng aliquot of total RNA was reverse-transcribed using Verso reverse transcriptase (AR-4113/A, Thermo scientific). Denaturation was carried out at 95°C for 10 s and detection system used was Chromo 4 (Bio-Rad). The results were expressed as mRNA copy number/1000 EF1-α mRNA. Expression profiles were statistically analyzed by Mann-Whitney U test (P<0.05). Specificity of primers (Table 1) was checked with Primer-BLAST analysis (NCBI) and by sequencing the different amplicons.
In situ Hybridization
Specific primers (Table 2) were designed to generate template DNA (including 3′UTR of target gene) with T7 promoter tailed (5′-GCGAAAT-TAATACGACTCACTATAGGGAGA-3′) for synthesis of RNA probes according to Colas et al. (2010) . Templates DNA were amplified from sequences subcloned into pGEM®-T easy vector (Promega) and submitted to BLAST search (NCBI) to confirm their specificity. Sense and antisense probes were labeled with UTP-digoxigenin during the transcription step. Preparation of berry samples, hybridization and signal detection were performed as described in Colas et al. (2010) .
A) Transcript accumulation of CHI4D and TL3 genes in Pinot noir grapevine berries during development. Analyses were performed by quantitative RT-PCR. Levels of transcripts were calculated using the standard curve method from duplicate data, with grapevine EF1-α gene as internal control and were expressed as mRNA copy number/1000 EF1-α mRNAs. Values represent the mean ± SD of duplicates of the harvest 2009. Letters indicate significant differences between BBCH stages as calculated by Mann-Whitney U test (P<0,05). The same trend was observed for 2008 and 2010. B) Western blot analysis of CHI4D and TL3 in Pinot noir berries during maturation. Results represent the harvest of 2009 the same trend was observed for 2008 and 2010.
Protein Extraction and Western Blotting
Berries were ground in liquid nitrogen to a fine powder. Extraction of proteins was realized according to Castro et al. (2005)  but proteins were precipitated for 1 night at −20°C. Total protein content was estimated for each sample according to Fey et al. (1997)  using BSA as standard. Two point five µg of proteins were diluted in Laemmli buffer  (2% SDS (w/v), 62.5 mM Tris-HCl pH 6.8, 10% glycerol (v/v), 1 M β-mercaptoethanol, 0.001% bromophenol blue (w/v)) and denatured at 95°C for 5 min. Proteins were separated by 15% SDS-PAGE electrophoresis at 20°C using the Mini-PROTEAN® Tetra Cell (Bio-Rad) at 200 V for 1 h and transferred on a polyvinylidene fluoride (PVDF) membrane for 7 min using I Blot gel transfer System (Invitrogen). The PVDF membrane was incubated for 1 h with TBST (20 mM Tris-HCl, 500 mM NaCl at pH 7.5, 0.05% Tween-20 (v/v)) containing 3% (w/v) of powdered milk to saturate the remaining protein binding sites. Membrane was incubated for 1 h with antibodies diluted in TBST with milk (1∶10000 for CHI4D and 1∶250 for TL3) and then with goat anti-rabbit IgG-horseradish peroxidase conjugate (1∶3000) (Bio-Rad). Immunoreacting bands were detected with ChemiDoc™ XRS by treatment with SuperSignal® west pico chemiluminescent substrate (Pierce) according to the manufacturer’s protocol. Polyclonal antibodies used in this study were raised against chitinase (CHI4D) and thaumatin-like (TL3) purified from Pinot noir grape berries by Manteau et al. (2003) .
In situ localization of CHI4D A) and TL3 B) mRNAs in Pinot noir berry tissues at BBCH75 (1, 2, 3, 4) and BBCH89 (5, 6, 7, 8) stages. Blue signal indicates the location of antisense (1, 2, 3, 5, 6, 7) and control sense (4, 8) probes. Sense probe controls indicate background staining. 1 and 5: central vascular bundles (CVB) in the mesocarp (MS), 2 and 6: peripheral vascular bundles (PVB) in the mesocarp, 3, 4, 7 and 8: exocarp (EX).
Immunofluorescence analysis was carried out according to Colas et al. (2010)  on samples prepared in the same conditions as used for in situ hybridization concerning BBCH stage, treatment (UV-C or not) and tissue preparation. Sections were incubated with the primary anti-CHI4D (1/200) or anti-TL3 antibodies (1/200) . Immunolabelling was detected after 1 h incubation at room temperature with the secondary antibodies Fluoprobes© 488 (Interchim) at a dilution of 1/250. Control sections were incubated only with the secondary antibody. Images were recorded using an LSM 710 confocal laser microscope system (ZEISS, Jena, Germany) equipped with an Axio-observer Z1 inverted microscope and a Plan-apochromat 20x/0.8 DIC. The 488 nm excitation line from Argon ion laser (0.8% power) was used to excite fluorescence of Fluoprobes© 488 and to record interference contrast images. The emitted fluorescence of Fluoprobes© 488 was transmitted in spectral detector including 32 photomultiplicators through dichroic beam splitter MBS 488. First, emitted spectra of Fluoprobes© 488 and specimen autofluorescence were recorded in this experimental configuration. Then, “spectral unmixing” mode of the confocal microscope is running to separate images respectively due to Fluoprobes© 488 and autofluorescence by spectral deconvolution of recorded signal. For each sample, Z stacks (n = 20 to 50) were acquired with Z step of 1 µm.
Immunolocalization of CHI4D A) and TL3 B) proteins in Pinot noir berry tissues at BBCH75 (1, 2, 3) and BBCH89 (4, 5, 6) stages. Controls without primary antibody indicate tissue background autofluorescence in berry tissues at BBCH75 (7) and BBCH89 (8) stages. 1 and 4: central vascular bundles (CVB) in the mesocarp (MS), 2 and 5: peripheral vascular bundles (PVB) in the mesocarp, 3, 6, 7 and 8: exocarp (EX). Epicuticular tissue (EP).
Global CHI4D and TL3 Expression in Grape Berry during Development
Expression of CHI4D and TL3 genes was investigated in the whole berry by qRT-PCR at four developmental stages (Fig. 1A). Before véraison, at BBCH75 and BBCH77 stages, both genes were weakly expressed even though TL3 was more expressed than CHI4D. During ripening stages (BBCH81 and BBCH89), expression greatly increased for both genes in comparison to the previous stages. This induction was approximately 4000- and 1100-fold respectively at full ripe, for CHI4D and TL3 compared with the BBCH75 stage.
Transcript accumulation of CHI4D (1, 2) and TL3 (3, 4) genes in Pinot noir grapevine berries 48 h after UV-C stress. Analyses were performed by quantitative RT-PCR. Levels of transcripts were calculated using the standard curve method from duplicate data, with grapevine EF1-α gene as internal control and were expressed as mRNA copy number/1000 EF1-α mRNA. Values represent the mean ± SD of duplicates of the harvest of 2009. Letters indicate significant differences between treatments at each BBCH stage as calculated by Mann-Whitney U test (P<0,05). The same trend was observed for 2008 and 2010. Abbreviations: untreated berries (NT), control detached berries (C), treated berries (T). B) Western blot analysis of CHI4D (1, 2) and TL3 (3, 4) in Pinot noir berries 48 h after an UV-C stress. Results represent the harvest of 2009. The same trend was observed for 2008 and 2010. Abbreviations: untreated berries (NT), control detached berries (C), treated berries (T).
By western blotting analyses, CHI4D and TL3 proteins were not detected before véraison (BBCH75 and BBCH77) probably due to a weak concentration whereas they strongly accumulated during ripening (BBCH81 and BBCH89) (Fig. 1B). The size of CHI4D was about 29 kDa and for TL3, two bands were detected at about 22 and 24 kDa.
In situ localization of CHI4D A) and TL3 B) mRNAs in Pinot noir berry tissues at BBCH75 stages 48 h after UV-C irradiation. Blue signal indicates the location of antisense probes. 1: central vascular bundles (CVB) in the mesocarp (MS), 2: peripheral vascular bundles (PVB) in the mesocarp, 3: exocarp (EX).
Localization of CHI4D and TL3 Expression Sites in Berry Tissues during Development
The localization of the expression sites of CHI4D and TL3 in berry tissues was carried out by in situ hybridization at the BBCH75 and BBCH89 stages because the global grape berry analysis showed maximal difference in expression levels at these stages for both genes. Control berry sections hybridized with CHI4D (Fig. 2 A: 4, 8) or TL3 (Fig. 2 B: 4, 8) sense probes showed only little background staining on berry pigments. No signal was detected without probes (data not shown). At the BBCH75 stage, neither CHI4D nor TL3 transcripts could be detected in the exocarp (Fig. 2 A: 3 and B: 3), the mesocarp (Fig. 2 A: 1, 2, 3 and B: 1, 2, 3) or in the pips (data not shown). At BBCH89 stage, CHI4D mRNAs were detected in the whole exocarp (Fig. 2 A: 7), in the mesocarp, mainly around the central vascular bundles (Fig. 2 A: 5) and in some cells associated with the peripheral vascular bundles (Fig. 2 A: 6). The same location was observed for TL3 mRNAs, in the exocarp (Fig. 2 B: 7) and in the mesocarp, mainly around the central (Fig. 2 B: 5) and the peripheral vascular bundles (Fig. 2 B: 6). Concerning the pips, no in situ hybridization data could be obtained because of the difficulty to fix them in sections of ripe berries.
Immunolocalization of CHI4D A) and TL3 B) proteins in Pinot noir berry tissues at BBCH75 stages 48 h after an UV-C irradiation. Green fluorescence indicates the localization of proteins. 1: central vascular bundles (CVB) in the mesocarp (MS), 2: peripheral vascular bundles (PVB) in the mesocarp, 3: exocarp (EX). Epicuticular tissue (EP).
The localization of CHI4D and TL3 proteins was performed at the BBCH75 and BBCH89 stages using immunofluorescence. Controls without primary antibodies revealed faint backgrounds (Fig. 3∶7, 8) mainly associated with the epicuticular tissue. At the BBCH75 stage, CHI4D and TL3 were not detected in the exocarp (Fig. 3 A: 3 and B: 3) but were weakly detected in the mesocarp mainly around the central and the peripheral vascular bundles (Fig. 3 A: 1, 2 and B: 1, 2). In the pips, no signal was detected for CHI4D whereas a weak signal was observed for TL3 (data not shown). At the BBCH89 stage, CHI4D and TL3 strongly accumulated in the exocarp (Fig. 3 A: 6 and B: 6) and in the mesocarp, mainly associated with the central (Fig. 3 A: 4 and B: 4) and the peripheral (Fig. 3 A: 5 and B: 5) vascular bundles.
Global CHI4D and TL3 Expression in Grape Berry under UV-C Stress Condition
CHI4D and TL3 gene expression was carried out by qRT-PCR analysis 48 h after an UV-C treatment at the four BBCH stages previously described (Fig. 4 A). Depending on the developmental stage, expression of CHI4D was induced to different levels in control detached berries as compared with untreated ones (from 1.3- to 44-fold) probably due to wounds caused by the berry detachment (Fig. 4 A: 1 and 2). In UV-C-treated berries, induction was higher compared to control and untreated berries (Fig. 4 A: 1) at BBCH75 (5.4- and 89-fold, respectively) and BBCH77 stages (2.4- and 107-fold respectively). However, at the BBCH81 and BBCH89 stages (Fig. 4 A: 2), very low induction in CHI4D gene expression level was observed in control detached (2.1- and 1.3-fold respectively) and UV-C treated berries (1.7- and 1.6-fold respectively) compared to untreated ones. Surprisingly, at BBCH81 stage induction was slightly stronger in control detached berries (1.2-fold) compared to UV-C treated ones probably due to heterogeneity of samples. Indeed, BBCH81 stage corresponds to the beginning of véraison with berries more or less colored. At this stage, berries of a same cluster might undergo asynchronous changes in numerous biological processes including alteration of defense responses to abiotic/biotic stimuli. As observed for CHI4D, expression of TL3 in control berries was also induced compared to untreated ones depending on the developmental stage (from 1.8- to 24.5-fold) (Fig. 4 A: 3 and 4). In UV-C treated berries induction was higher compared to control and untreated berries (Fig. 4 A: 3) at BBCH75 (5- and 91-fold, respectively) and BBCH77 stages (3.4- and 82-fold, respectively). As observed for CHI4D, at the BBCH81 and BBCH89 stages (Fig. 4 A: 4), very low induction in TL3 gene expression level was observed in control (2.6- and 1.8-fold respectively) and UV-C treated berries (1.3- and 1.8-fold respectively) compared to untreated ones and induction was slightly stronger in control (1.3-fold) compared to UV-C at BBCH81 stage.
CHI4D and TL3 protein contents were followed after UV-C treatment using western blot analyses along the four maturation stages studied before. In control berries, both proteins were detected from the BBCH77 stage (Fig. 4 B). At BBCH75 and BBCH77 stages, CHI4D (Fig. 4 B: 1) and TL3 (Fig. 4 B: 3) accumulated in treated berries but not in untreated ones. As previously described, two bands were visible for TL3 against a single one for CHI4D. Accumulation for both proteins was more intense at the BBCH77 than at the BBCH75 stage. CHI4D and TL3 accumulation was rather similar between BBCH81 and BBCH89 stages and between untreated, control and treated berries (Fig. 4 B: 2 and 4).
Localization of CHI4D and TL3 Expression Sites in Berry Tissues under UV-C Stress Condition
The localization of CHI4D and TL3 mRNAs/proteins in berry tissues after UV-C exposure was investigated at the BBCH75 stage using in situ hybridization and immunofluorescence. Controls performed with CHI4D and TL3 RNA sense probes showed only little background staining on berry pigments as shown in Fig. 2. Transcripts of CHI4D in UV-C treated berries were detected in the exocarp (Fig. 5 A: 3) and in association to the central (Fig. 5 A: 1) and peripheral vascular bundles (Fig. 5 A: 2) in the mesocarp. As for CHI4D, TL3 mRNAs were detected in the exocarp (Fig. 5 B: 3) and around central and peripheral vascular bundles (Fig. 5 B: 1 and 2). However, unlike CHI4D, TL3 mRNAs were detected in the whole mesocarp after an UV-C stress (Fig. 5 B: 3). No mRNA was detected in the pips neither for CHI4D nor for TL3 (data not shown).
Immunofluorescence showed that CHI4D was widely spread in the exocarp (Fig. 6 A: 3) and in the mesocarp including sites around the peripheral vascular bundles (Fig. 6 A: 2) but weakly detected around the central vascular bundles (Fig. 6 A: 1) as in control (data not shown) and untreated berries (Fig. 3 A: 1). These observations concerning the mesocarp are however surprising compared to in situ hybridization experiments that showed a strong presence of CHI4D mRNAs mainly around the central (Fig. 5 A: 1) and peripheral (Fig. 5 A: 2) vascular bundles. TL3 proteins were detected in the exocarp (Fig. 6 B: 3) and in the mesocarp but they appeared less diffuse in this tissue than CHI4D (Fig. 6 B: 2) and accumulated more intensely around the peripheral vascular bundles. As observed with CHI4D, TL3 was barely detected around the central vascular bundles (Fig. 6 B: 1) as in control (data not shown) and untreated berries (Fig. 3 B: 1), while mRNAs had been obviously observed at these sites (Fig. 5 B: 1). At the BBCH89 stage no difference in tissular localization between untreated, control and UV-C-treated berries was observed for both proteins and their corresponding mRNAs (data not shown).
In this study, the spatial distribution of CHI4D and TL3, two major PR proteins in Pinot noir mature grape berries, and their corresponding transcripts, was investigated during berry maturation and under UV-C exposure. For these studies, if the specificity of the qPCR amplicons and ISH probes could be checked by sequencing (data not shown), the specificity of the antibodies used is still debatable. Chitinases and thaumatin-like proteins are encoded by multigenic families whose members organized within clusters share high sequence similarity in Vitis vinifera genome and it cannot be excluded that the polyclonal antibodies could recognize different isoforms although they were raised against purified proteins and that their specificity was successfully assessed as described by Manteau et al. (2003) . Results based on qRT-PCR and western blot showed that CHI4D and TL3 mRNAs/proteins accumulated from véraison to full maturation and that the regulation occurred at the transcriptional level. Similar patterns of expression were previously observed in Shiraz berry and Muscat of Alexandria , , . In the present work we further showed that UV-C exposure induced CHI4D and TL3 gene expression in Pinot noir berries before véraison. Previous studies also reported that some chitinase and thaumatin-like isoforms were induced by biotic or abiotic stresses , , . In particular, CHI4D and TL3 were induced by powdery mildew unlike VvTL1 . Concerning TL3, western analysis from Pinot noir berries revealed two bands with apparent masses of 22 and 24 kDa (Fig. 1 B and 4 B : 3, 4). The calculated molecular mass of TL3 without signal peptide is 21.2 kDa (http://web.expasy.org/compute_pi/), which corresponds to the lower band. As described above, we cannot exclude that the polyclonal antibodies raised against TL3 recognize another isoform but of higher molecular mass than TL3. However, it is possible that the higher band corresponds to a gycosylated form of the protein as described by Palmisano et al. (2010)  in white wine of cv. Chardonnay. In fact, according to in silico analysis of TL3 amino acids sequence this protein contains two potential N-glycosylation sites (NetNGlyc server). Furthermore, production of TL3 in Pichia pastoris resulted in the same two bands. In that case, PNGase treatment yielded a marked decrease of the larger one (unpublished results) suggesting that the putative glycosylation of the natural proteins cannot be ruled out. Therefore, we favour this second interpretation and assume that this TL3 protein is probably glycosylated in vivo.
Despite the abundant literature on chitinase and thaumatin-like protein expressions during ripening, only few studies have focused on the localization of their expression sites and such studies only related to dissected tissues: skin, pulp and pips. At the transcript level, in mature Shiraz berries, expression of VvChi4/CHI4D was localized in the pulp and skin  while in Cabernet Sauvignon mature berries, Grimplet et al. (2007)  using the Affymetrix GeneChip® approach, showed that CHI4D and TL3 were expressed in the skin, but not in the pulp and that TL3 mRNAs were also detected in the pips. The localization of chitinase and thaumatin-like expression sites could then vary according to the cultivar. Proteome analysis of Cabernet Sauvignon skin also revealed that chitinases accumulated in the exocarp during ripening . Using a similar approach, Negri et al. (2008)  observed a sharp increase of chitinases and thaumatin-like proteins in the exocarp of Barbera cultivar throughout berry maturation.
Using in situ hybridization, we could for the first time in grapevine compare the expression sites of CHI4D and TL3 genes in berry tissues during development and after UV-C stress. Both mRNAs were observed in the exocarp and in the mesocarp mainly around the vascular bundles of ripe berries. In other plants, chitinase and thaumatin-like transcripts were also observed around the vascular elements of various organs (stems, petals, roots) , . Concerning the proteins, CHI4D and TL3 were detected at the same sites as their corresponding mRNAs but they were also observed in the whole mesocarp. The discrepancy between proteins and mRNAs in this tissue could be explained by sufficient amounts of proteins for immunofluorescence detection but insufficient amounts of transcript for in situ hybridization detection. Proteins could also spread via the apoplastic route and diffuse in the whole mesocarp . In silico analysis of both proteins indicated that they contained a N-terminal signal peptide (http://bmbpcu36.leeds.ac.uk/prot_analysis/Signal.html) targeting mature proteins into the secretory pathway (http://www.cbs.dtu.dk/services/TargetP/) which supports this hypothesis. Moreover, in a previous study, chitinase exuded from cowpea roots (Vigna unguiculata) were also localized in the xylem cell wall vessel elements suggesting that the apoplast was a potential pathway to transport these proteins through the root .
In pre-véraison stressed berry (UV-C), CHI4D and TL3 mRNAs were detected in the exocarp, around the central and peripheral vascular bundles of the mesocarp, and in the whole mesocarp for TL3. Both proteins localized in the exocarp and in the mesocarp including sites around the peripheral vascular bundles. They were not detected around the central vascular bundles 48 h after UV-C treatment, whereas an induction of both transcripts was observed. The delay of 48 h between stress and sampling analysis may be not sufficient for the production of both proteins. Hence, proteins began to be detected only about 96 h after stress (data not shown). Our results then suggest that both CHI4D and TL3 first accumulate in the exocarp and around the peripheral vascular bundles corresponding to sub-epidermal tissues directly exposed to the radiation. Proteins would accumulate later around the central vascular bundles of berry.
The localization of both proteins in the exocarp and around vascular elements could be strategic to inhibit/limit the penetration and/or the development of pathogenic agents. It is well known that some fungi like Botrytis cinerea could penetrate berries by the exocarp ,  and that some bacteria like Xylella fastidious could propagate by the vessels of plants , . Moreover, PR proteins secreted via the apoplastic route near vascular elements could be exported in the sap , , , . The same temporal and spatial patterns of expression for CHI4D and TL3 suggest that the corresponding proteins have complementary roles in berry. Chitinase and thaumatin-like proteins have been shown to play an important role in the plant defense mechanisms principally against fungi , . In vitro inhibition of mycelial growth and conidia germination of B. cinerea were obtained with chitinase and thaumatin-like proteins extracted from berries of Pinot noir, Moscatel and Semillon , , . Moreover berries at pre-véraison stage are highly susceptible to powdery mildew infection caused by Erysiphe necator, but become resistant to this pathogen during ripening , , as levels of CHI4D and TL3 increase. Transgenic grapevines expressing a rice chitinase exhibit resistance against E. necator and Elisinoe ampelina, the causal agent of anthracnose . More recently, transgenic grapevines overexpressing the thaumatin-like VvTL1 protein showed less severe symptoms to E. necator on the leaves and enhanced rot resistance of ripe berries .
Several studies showed that chitinases and thaumatin-like are accumulated during ripening in a wide variety of fruits like cherimoya, pineapple, cherry, banana, Japanese pear or pepper , , , , , . They could be involved in plant growth processes  and also in fruit maturation , . As suggested by Edreva (2005)  these findings raise the question as to whether PR genes have evolved primarily to limit damage by invading pathogens, or have adapted from other function to serve an accessory protective role.
Owing to their temporal and spatial pattern of expression, chitinase and thaumatin-like could be key enzymes in berry defense mechanisms. Transgenic plants impaired in chitinase and thaumatin-like accumulation or accumulating high basal level of both proteins whatever the developmental stage of berry considered, could help to further characterize their role.
The authors thank the Comité Champagne for the kind permission to collect berry samples and Sophie Barad and Maryline Magnin-Robert for their help during technical qRT-PCR technical improvements.
Conceived and designed the experiments: FB LMD FMG. Performed the experiments: SC DAB LJ LMD FMG. Analyzed the data: SC DAB FB LMD FMG. Contributed reagents/materials/analysis tools: SC DAB LJ CC FB LMD FMG. Wrote the paper: SC DAB LJ CC FB LMD FMG.
- 1. Gianinazzi S, Martin C, Valle JC (1970) Hypersensibilité aux virus, températures et protéines solubles chez le Nicotiana Xanthi-nc. Apparition de nouvelles macromolécules lors de la répression de la synthèse virale. C R Acad Sci 270: 2383–2386.
- 2. van Loon LC, van Kammen A (1970) Polyacrylamide disc electrophoresis of the soluble leaf proteins from Nicotania tabacum var. “Samsun” and “Samsun NN”. II. Changes in protein constitution after infection with tobacco mosaic virus. Virology 40: 199–211.
- 3. Edreva A (2005) Pathogenesis-related proteins: research progress in the last 15 years. Gen Appl Plant Physiology 31: 105–124.
- 4. Castro AJ, Saladin G, Bézier A, Mazeyrat-Gourbeyre F, Baillieul F, et al. (2008) The herbicide flumioxazin stimulates pathogenesis-related gene expression and enzyme activities in Vitis vinifera. Physiol Plant 134: 453–463.
- 5. Davies C, Robinson SP (2000) Differential screening indicates a dramatic change in mRNA profiles during grape berry ripening. Cloning and characterization of cDNAs encoding putative cell wall and stress response protein. Plant Physiol 122: 803–812.
- 6. Derckel JP, Legendre L, Audran JC, Haye B, Lambert B (1996) Chitinases of the grapevine (Vitis vinifera L.): five isoforms induced in leaves by salicylic acid are constitutively expressed in other tissues. Plant Sci 119: 31–37.
- 7. Jacobs AK, Dry IB, Robinson SP (1999) Induction of different pathogenesis-related cDNAs in grapevine infected with powdery mildew and treated with ethephon. Plant Pathol 48: 325–336.
- 8. van Loon LC, Rep M, Pieterse CM (2006) Significance of inducible defense-related proteins in infected plants. Annu Rev Phytopathol 44: 135–162.
- 9. Tattersall DB, van Heeswijck R, Høj PB (1997) Identification and characterization of a fruit-specific, thaumatin-like protein that accumulates at very high level in conjunction with the onset of sugar accumulation and berry softening in grapes. Plant Physiol 114: 759–769.
- 10. Negri A, Prinsi B, Rossoni M, Failla O, Scienza A, et al. (2008) Proteome changes in the skin of the grape cultivar Barbera among different stages of ripening. BMC Genomics 9: 378–396.
- 11. Sarry JE, Sommerer N, Sauvage FX, Bergoin A, Rossignol M, et al. (2004) Grape berry biochemistry revisited upon proteomic analysis of the mesocarp. Proteomics 4: 201–215.
- 12. Manteau S (2003) Etude des facteurs de virulence de Botrytis cinerea et des protéines de défense de la baie: Thèse, Université de Reims Champagne-Ardenne. 152 p.
- 13. Manteau S, Lambert B, Jeandet P, Legendre L (2003) Changes in chitinase and thaumatin-like pathogenesis-related proteins of grape berries during the champagne winemaking process. Am J Enol Vitic 54: 267–272.
- 14. Pocock KF, Hayasaka Y, McCarthy MG, Waters EJ (2000) Thaumatin-like proteins and chitinases, the haze-forming proteins of wine, accumulate during ripening of grape (Vitis vinifera) berries and drought stress does not affect the final levels per berry at maturity. J Agric Food Chem 48: 1637–1643.
- 15. Pocock KF, Hayasaka Y, Peng Z, Williams PJ, Waters EJ (1998) The effect of mechanical harvesting and long-distance transport on the concentration of haze-forming proteins in grape juice. Aust J Grape Wine R 4: 23–29.
- 16. Waters EJ, Hayasaka Y, Tattersall DB, Adams KS, Williams PJ (1998) Sequence analysis of grape (Vitis vinifera) berry chitinases that cause haze formation in wines. J Agric Food Chem 46: 4950–4957.
- 17. Waters EJ, Shirley NJ, Williams PJ (1996) Nuisance proteins of wine are grape pathogenesis-related proteins. J Agric Food Chem 44: 3–5.
- 18. Derckel JP, Audran J, Haye B, Lambert B, Legendre L (1998) Characterization, induction by wounding and salicylic acid and activity against Botrytis cinerea of chitinases and β-1,3-glucanases of ripening grape berries. Physiol Plant 104: 56–64.
- 19. Zenoni S, Ferrarini A, Giacomelli E, Xumerle L, Fasoli M, et al. (2010) Characterization of transcriptional complexity during berry development in Vitis vinifera using RNA-seq. Plant Physiol 152: 1787–1795.
- 20. Monteiro S, Picarra-Pereira MA, Teixeira AR, Loureiro VB, Ferreira RB (2003) Environmental conditions during vegetative growth determine the major proteins that accumulate in mature grapes. J Agric Food Chem 51: 4046–4053.
- 21. Robinson SP, Jacobs AK, Dry IB (1997) A Class IV chitinase is highly expressed in grape berries during ripening. Plant Physiol 114: 771–778.
- 22. Monteiro S, Barakat M, Piçarra-Pereira MA, Teixeira AR, Ferreira RB (2003) Osmotin and thaumatin from grape: a putative general defense mechanism against pathogenic fungi. Phytopathology 93: 1505–1512.
- 23. Salzman RA, Tikhonova I, Bordelon BP, Hasegawa PM, Bressan RA (1998) Coordinate accumulation of antifungal proteins and hexoses constitutes a developmentally controlled defense response during fruit ripening in grape. Plant Physiol 117: 465–472.
- 24. Graham LS, Sticklen MB (1994) Plant chitinases. Can J Bot 72: 1057–1083.
- 25. Mauch F, Staehelin LA (1989) Functional implications of the subcellular localization of ethylene-induced chitinase and β-1,3-glucanase in bean leaves. Plant Cell 1: 447–457.
- 26. Abad LR, D’Urzo MP, Liu D, Narasimhan ML, Reuveni M, et al. (1996) Antifungal activity of tobacco osmotin has specificity and involves plasma membrane permeabilization. Plant Sci 118: 11–23.
- 27. Anžlovar S, Dermastia M (2003) The comparative analysis of osmotins and osmotin-like PR-5 proteins. Plant Biol 5: 116–124.
- 28. Grenier J, Potvin C, Trudel J, Asselin A (1999) Some thaumatin-like proteins hydrolyse polymeric β-1,3-glucans. Plant J 19: 473–480.
- 29. Kasprzewska A (2003) Plant chitinases – regulation and function. Cell Mol Biol Lett 8: 809–824.
- 30. Libantová J, Kämäräinen T, Moravčíková J, Matušíková I, Salaj J (2009) Detection of chitinolytic enzymes with different substrate specificity in tissues of intact sundew (Drosera rotundifolia L.). Mol Biol Rep 36: 851–856.
- 31. Liljeroth E, Marttila S, von Bothmer R (2005) Immunolocalization of defence-related proteins in the floral organs of barley (Hordeum vulgare L.). J Phytopathol 153: 702–709.
- 32. Liu JJ, Sturrock R, Ekramoddoullah A (2010) The superfamily of thaumatin-like proteins: its origin, evolution, and expression towards biological function. Plant Cell Rep 29: 419–436.
- 33. Seo PJ, Lee AK, Xiang F, Park CM (2008) Molecular and functional profiling of Arabidopsis pathogenesis-related genes: insights into their roles in salt response of seed germination. Plant Cell Physiol 49: 334–344.
- 34. Meier U (2001) Growth stages of mono-and dicotyledonous plants. BBCH Monograph. In: Meier U, editor. Grapevine. Berlin: Blackwell Wissenschafts-verlag. 93–95.
- 35. Petit AN, Baillieul F, Vaillant GN, Jacquens L, Conreux A, et al. (2009) Low responsiveness of grapevine flowers and berries at fruit set to UV-C irradiation. J Exp Bot 60: 1155–1162.
- 36. Colas S, Jacquens L, Manteau S, Devy J, Conéjéro G, et al. (2010) Expression analysis in grapevine by in situ hybridization and immunohistochemistry. In: Delrot S, Medrano H, Or E, Bavaresco L, Grando S, editors. Methodologies and Results in Grapevine Research. 361–374.
- 37. Castro AJ, Carapito C, Zorn N, Magné C, Leize E, et al. (2005) Proteomic analysis of grapevine (Vitis vinifera L.) tissues subjected to herbicide stress. J Exp Bot 56: 2783–2795.
- 38. Fey SJ, Nawrocki A, Larsen MR, Görg A, Roepstorff P, et al. (1997) Proteome analysis of Saccharomyces cerevisiae: A methodological outline. Electrophoresis 18: 1361–1372.
- 39. Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227: 680–685.
- 40. Robert N, Roche K, Lebeau Y, Breda C, Boulay M, et al. (2002) Expression of grapevine chitinase genes in berries and leaves infected by fungal or bacterial pathogens. Plant Sci 162: 389–400.
- 41. Palmisano G, Antonacci D, Larsen MR (2010) Glycoproteomic profile in wine: a “sweet” molecular renaissance. J Proteome Res 9: 6148–6159.
- 42. Grimplet J, Deluc L, Tillett R, Wheatley M, Schlauch K, et al. (2007) Tissue-specific mRNA expression profiling in grape berry tissues. BMC Genomics 8: 187–209.
- 43. Deytieux C, Geny L, Lapaillerie D, Claverol S, Bonneu M, et al. (2007) Proteome analysis of grape skins during ripening. J Exp Bot 58: 1851–1862.
- 44. Kavroulakis N, Papadopoulou KK, Ntougias S, Zervakis GI, Ehaliotis C (2006) Cytological and other aspects of pathogenesis-related gene expression in tomato plants grown on a suppressive compost. Ann Bot 98: 555–564.
- 45. Nóbrega FM, Santos IS, Cunha MD, Carvalho AO, Gomes VM (2005) Antimicrobial proteins from cowpea root exudates: inhibitory activity against Fusarium oxysporum and purification of a chitinase-like protein. Plant Soil 272: 223–232.
- 46. Elad Y, Williamson B, Tudzynski P, Delen N (2004) Botrytis: biology, pathology and control. Dordrecht, The Netherlands: Kluwer Academic. 404 p.
- 47. Pezet R, Viret O, Gindro K (2004) Plant-microbe interaction: the Botrytis grey mould of grapes – biology, biochemistry, epidemiology and control management. Adv Plant Physiol 7: 71–116.
- 48. Chatelet DS, Wistrom CM, Purcell AH, Rost TL, Matthews MA (2011) Xylem structure of four grape varieties and 12 alternative hosts to the xylem-limited bacterium Xylella fastidious. Ann Bot 108: 73–85.
- 49. Roper MC (2011) Pantoea stewartii subsp. stewartii: Lessons learned from a xylem-dwelling pathogen of sweet corn. Mol Plant Pathol 12: 628–637.
- 50. Aguero CB, Thorne ET, Ibanez AM, Gubler WD, Dandekar AM (2008) Xylem sap proteins from Vitis vinifera L. Chardonnay. Am J Enol Vitic 59: 306–311.
- 51. Dafoe NJ, Gowen BE, Constabel CP (2010) Thaumatin-like proteins are differentially expressed and localized in phloem tissues of hybrid poplar. BMC Plant Biol 10: 191–201.
- 52. Dafoe NJ, Constabel CP (2009) Proteomic analysis of hybrid poplar xylem sap. Phytochemistry 70: 856–853.
- 53. Rep M, Dekker HL, Vossen JH, de Boer AD, Houterman PM, et al. (2002) Mass spectrometric identification of isoforms of PR proteins in xylem sap of fungus-infected tomato. Plant Physiol 130: 904–917.
- 54. ten Have A, Espino JJ, Dekkers E, Van Sluyter SC, Brito N, et al. (2010) The Botrytis cinerea aspartic proteinase family. Fungal Genet Biol 47: 53–65.
- 55. Chellemi DO, Marois JJ (1992) Influence of leaf removal, fungicide applications, and fruit maturity on incidence and severity of grape powdery mildew. Am J Enol Vitic 43: 53–57.
- 56. Delp CJ (1954) Effect of temperature and humidity on the grape powdery mildew fungus. Phytopathology 44: 615–626.
- 57. Yamamoto T, Iketani H, Ieki H, Nishizawa Y, Notsuka K, et al. (2000) Transgenic grapevine plants expressing a rice chitinase with enhanced resistance to fungal pathogens. Plant Cell Rep 19: 639–646.
- 58. Dhekney SA, Li ZT, Gray DJ (2011) Grapevines engineered to express cisgenic Vitis vinifera thaumatin-like protein exhibit fungal disease resistance. In Vitro Cell Dev Biol Plant 47: 458–466.
- 59. Barre A, Peumans WJ, Menu-Bouaouiche L, van Damme EJM, May GD, et al. (2000) Purification and structural analysis of an abundant thaumatin-like protein from ripe banana fruit. Planta 211: 791–799.
- 60. Fils-Lycaon BR, Wiersma PA, Eastwell KC, Sautiere P (1996) A cherry protein and its gene, abundantly expressed in ripening fruit, have been identified as thaumatin-Like. Plant Physiol 111: 269–273.
- 61. Goñi O, Sanchez-Ballesta MT, Merodio C, Escribano MI (2009) Ripening-related defense proteins in Annona fruit. Postharvest Biol Technol 55: 169–173.
- 62. Kim YS, Park JY, Kim KS, Ko MK, Cheong SJ, et al. (2002) A thaumatin-like gene in nonclimacteric pepper fruits used as molecular marker in probing disease resistance, ripening, and sugar accumulation. Plant Mol Biol 49: 125–135.
- 63. Sassa H, Hirano H (1998) Style-specific and developmentally regulated accumulation of a glycosylated thaumatin/PR5-like protein in Japanese pear (Pyrus serotina Rehd.). Planta 205: 514–521.
- 64. Taira T, Toma N, Ichi M, Takeuchi M, Ishihara M (2005) Tissue distribution, synthesis stage, and ethylene induction of pineapple (Ananas comosus) chitinases. Biosci Biotechnol Biochem 69: 852–854.
- 65. Peumans WJ, Barre A, Derycke V, Rougé P, Zhang W, et al. (2000) Purification, characterization and structural analysis of an abundant β-1,3-glucanase from banana fruit. Eur J Biochem 267: 1188–1195.
- 66. Roy Choudhury S, Roy S, Sengupta D (2009) Characterization of cultivar differences in β-1,3-glucanase gene expression, glucanase activity and fruit pulp softening rates during fruit ripening in three naturally occurring banana cultivars. Plant Cell Rep 28: 1641–1653.