In vivo localization at the cellular level of stilbene fluorescence induced by Plasmopara viticola in grapevine leaves

Accurate localization of phytoalexins is a key for better understanding their role. This work aims to localize stilbenes, the main phytoalexins of grapevine. The cellular localization of stilbene fluorescence induced by Plasmopara viticola, the agent of downy mildew, was determined in grapevine leaves of very susceptible, susceptible, and partially resistant genotypes during infection. Laser scanning confocal microscopy and microspectrofluorimetry were used to acquire UV-excited autofluorescence three-dimensional images and spectra of grapevine leaves 5–6 days after inoculation. This noninvasive technique of investigation in vivo was completed with in vitro spectrofluorimetric studies on pure stilbenes as their fluorescence is largely affected by the physicochemical environment in various leaf compartments. Viscosity was the major physicochemical factor influencing stilbene fluorescence intensity, modifying fluorescence yield by more than two orders of magnitude. Striking differences in the localization of stilbene fluorescence induced by P. viticola were observed between the different genotypes. All inoculated genotypes displayed stilbene fluorescence in cell walls of guard cells and periclinal cell walls of epidermal cells. Higher fluorescence intensity was observed in guard-cell walls than in any other compartment due to increased local viscosity. In addition stilbene fluorescence was found in epidermal cell vacuoles of the susceptible genotype and in the infected spongy parenchyma of the partially resistant genotype. The very susceptible genotype was devoid of fluorescence both in the epidermal vacuoles and the mesophyll. This strongly suggests that the resistance of grapevine leaves to P. viticola is correlated with the pattern of localization of induced stilbenes in host tissues

Radiação solar e susceptibilidade da videira à Plasmopara Viticola

A radiação solar exerce papel importante no desenvolvimento de algumas doenças fúngicas, devido à sua ação direta sobre os microorganismos e também devido ao seu efeito indireto sobre a produção de compostos específicos nas plantas. Este experimento examinou o efeito de dois ambientes de luz (100% e 35% da intensidade máxima) sobre o conteúdo de polifenóis nas folhas da videira e quantificou sua relação com a resistência ao míldio (Plasmopara viticola). As concentrações de polifenóis na epiderme das folhas foram quantificadas de forma não destrutiva, durante a estação de crescimento de 2006, usando o equipamento portátil Dualex, baseado na fluorescência da clorofila. O delineamento experimental consistiu de seis parcelas de 30 videiras e as medidas foram feitas nas 12 plantas centrais. As folhas foram inoculadas com uma suspensão de esporângios com 50.000 esporos de P. viticola por mL e a intensidade da doença foi avaliada depois do aparecimento dos primeiros sintomas. As folhas das plantas mantidas à plena luz solar apresentaram alta concentração de polifenóis e severidade da doença significativamente menor do que as folhas das plantas mantidas sob a tela de sombreamento. Estes resultados indicam uma relação inversa entre os polifenóis produzidos pelas folhas da videira e a severidade do míldio.Solar radiation plays an important role in the development of some fungal diseases due to its direct action on the microorganisms and also its indirect effect on the production of specific plant compounds. This experiment examined the effect of two light environments (100% and 35% of full strength) on the polyphenolic content of grapevine leaves and quantified their relation to resistance to downy mildew (Plasmopara viticola). Leaf epidermal polyphenolic contents were non-destructively measured during the growing season 2006 using the Dualex chlorophyll fluorescence-based portable leaf-clip. The experimental design consisted of six parcels of 30 vines and measurements were performed on the 12 central vines. The leaves were inoculated with a sporangia suspension containing 50,000 sporangia of P. viticola per mL and the disease severity was assessed after the appearance of symptoms. Leaves maintained at 100% sun had high polyphenolic content and significantly lower disease severity compared to leaves under shading nets. These results indicate an inverse relationship between produced polyphenolics and downy mildew severity

Non-Destructive Optical Monitoring of Grape Maturation by Proximal Sensing

A new, commercial, fluorescence-based optical sensor for plant constituent assessment was recently introduced. This sensor, called the Multiplex® (FORCE-A, Orsay, France), was used to monitor grape maturation by specifically monitoring anthocyanin accumulation. We derived the empirical anthocyanin content calibration curves for Champagne red grape cultivars, and we also propose a general model for the influence of the proportion of red berries, skin anthocyanin content and berry size on Multiplex® indices. The Multiplex® was used on both berry samples in the laboratory and on intact clusters in the vineyard. We found that the inverted and log-transformed far-red fluorescence signal called the FERARI index, although sensitive to sample size and distance, is potentially the most widely applicable. The more robust indices, based on chlorophyll fluorescence excitation ratios, showed three ranges of dependence on anthocyanin content. We found that up to 0.16 mg cm−2, equivalent to approximately 0.6 mg g−1, all indices increase with accumulation of skin anthocyanin content. Excitation ratio-based indices decrease with anthocyanin accumulation beyond 0.27 mg cm−2. We showed that the Multiplex® can be advantageously used in vineyards on intact clusters for the non-destructive assessment of anthocyanin content of vine blocks and can now be tested on other fruits and vegetables based on the same model

Etude des composés phénoliques impliqués dans la réponse des feuilles de vigne au mildiou

Maîtriser l impact des maladies sur les cultures est un défi majeur de l agriculture moderne. Cette préoccupation est un aspect important de l optimisation de la productivité, notamment en viticulture. En France, le mildiou de la vigne causé par Plasmopara viticola est une des maladies cryptogamiques responsable des épidémies les plus dévastatrices et les plus redoutées. Les traitements reposent sur l utilisation préventive, systématique et onéreuse de composés chimiques antifongiques dont l utilisation massive constitue un risque à la fois pour l homme et l environnement. La réduction de l utilisation de fongicide implique le développement d outils de diagnostic au champ, qui requiert la compréhension des interactions entre la plante et les agents pathogènes. Les travaux de cette thèse pluridisciplinaire ont porté sur le pathosystème Plasmopara viticola - Vitis vinifera, notamment pour répondre à l intérêt croissant pour un outil de diagnostic en temps réel de la maladie utilisable au vignoble. Les stilbènes sont des phytoalexines impliqués dans la défense de certaines plantes supérieures vis-à-vis de stress biotiques et abiotiques. L autofluorescence de ces composés phénoliques, dont la biosynthèse est induite dans les feuilles de vigne par P. viticola, en fait un potentiel marqueur naturel de l infection. En effet, la faible autofluorescence bleu-verte des feuilles de vigne saines est considérablement renforcée par l autofluorescence violet-bleue des stilbènes à la surface de feuilles de vigne infectée par P. viticola. Cette étude a montré que quelque soit le niveau de résistance du génotype, l autofluorescence violet-bleue des stilbènes induit par l infection est présente au niveau des parois des cellules de l épiderme. En dehors de la concentration, la viscosité s est révélé être la principale variable physico-chimique influençant l intensité de l autofluorescence des stilbènes dans les différents compartiments cellulaires des feuilles de vigne. Ceci explique la fluorescence intense des parois, particulièrement rigides, des cellules de garde (stomates) des feuilles infectées. Le suivi cinétique journalier a révélé la nature transitoire de l autofluorescence des stilbènes lors de l infection. La robustesse et l intérêt de ce signal a également été validée par la mesure à différentes échelles (de la cellule à la feuille entière) et avec différentes méthodes fluorimétriques. Les résultats de ce travail ont permis des avancées sur la connaissance du rôle de composés phénoliques induits et constitutifs dans la défense contre P. viticola. En plus de la localisation de l autofluorescence des stilbènes en surface des feuilles, la microscopie confocale couplée à la microspectrofluorimetrie a révélé différentes localisations de ces phytoalexines dans la profondeur des tissus en corrélation avec le niveau de résistance des génotypes. L utilisation de l autofluorescence des stilbènes comme marqueur de l infection a permis de mettre en évidence : 1) le fait que les flavonols constitutifs des feuilles de V. vinifera retardent le développement de l infection par P. viticola; et 2) le fait que les acides hydroxycinnamiques constitutifs ne semble pas participer à la défense contre P. viticola. Enfin, une nouvelle méthode de diagnostic non-destructive du mildiou sur feuille basée sur l autofluorescence des stilbènes a été développée. Elle a montré une détection pré-symptomatique du mildiou sur les feuilles de vigne entières dès le premier jour après l infection sur la face abaxiale et le troisième jour sur la face adaxiale. Cette méthode de diagnostic du mildiou a été validée au laboratoire notamment grâce à un prototype de capteur proximal développé en collaboration avec la société Force-A. La validation de la méthode au vignoble dans le cadre d infection naturelle est la prochaine étape pour une utilisation de ce capteur optique dans le cadre de l agriculture durable et de la sélection variétale.Controlling the impact of diseases on crops is a major challenge of modern agriculture. This concern is an important aspect of optimizing productivity, notably in viticulture. In France, downy mildew caused by Plasmopara viticola is a fungal disease responsible for the most devastating epidemics. The preventive and systematic treatments are expensive, while the massive use of antifungal chemicals is a risk to both humans and the environment. Reducing the use of fungicide involves the development of diagnostic tools in the field, which requires understanding the interactions between plants and pathogens. The work of this multidisciplinary thesis focused on the pathosystem Plasmopara viticola - Vitis vinifera, especially to meet the growing interest in a real-time diagnostic tool of disease applicable in the vineyard. Stilbenes are phytoalexins involved in the defense of certain higher plants against biotic and abiotic stresses. The autofluorescence of these phenolic compounds, whose biosynthesis is induced in grapevine leaves by P. viticola, makes it a potential marker of natural infection. Indeed, the low blue-green autofluorescence of grapevine leaves is greatly enhanced by the violet-blue autofluorescence of stilbenes on the surface of leaves infected by P. viticola. This study showed that whatever the level of resistance in various genotypes, violet-blue autofluorescence induced by stilbene is present in the walls of epidermal cells. In addition to their concentration, viscosity proved the main physico-chemical variable affecting the intensity of the autofluorescence of stilbenes in different compartments of vine leaves. This explains the intense fluorescence of the walls, particularly rigid, of guard cells (stomata) of infected leaves. Daily monitoring revealed a kinetic with a transient rise of the autofluorescence of stilbenes during infection. The robustness and value of this signal was also validated by measuring at different levels (cellular to whole leaf) and with various fluorimetric methods (imaging, spectroscopy, proximal sensing). These results advance our understanding of the role of constitutive and induced phenolic compounds in plant defence against P. viticola. In addition to a common location of the autofluorescence of stilbenes on the leaf surface, confocal microscopy coupled with microspectrofluorometry revealed distinctive localizations of these phytoalexins in the deep tissue correlated with the level of resistance in genotypes. This aspect no doubt needs broader testing. The use of autofluorescence of stilbene as a marker of infection allowed us to ascertain that: 1) constitutive flavonols of the leaves of V. vinifera retard the development of infection by P. viticola and 2) the constitutive hydroxycinnamic acids do not seem to participate in the defence against P. viticola. Finally, a new method for the non-destructive diagnosis of leaf infection based on the autofluorescence of stilbenes has been developed. We have demonstrated a pre-symptomatic detection of downy mildew on whole grape leaves from the first day after infection on the abaxial surface and from the third day on the adaxial surface. This method of diagnosis has been validated in the laboratory thanks to a proximal sensor prototype developed in collaboration with the company Force-A. The validation of the method in the vineyard in a context of natural infections is the next step for use of this optical sensor as a tool for sustainable agriculture and for genetic screening.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Etude de l'autofluorescence des feuilles de blé (triticum aestivum L.)

PARIS-BIUSJ-Thèses (751052125) / SudocPARIS-BIUSJ-Physique recherche (751052113) / SudocSudocFranceF

Predicting Key Agronomic Soil Properties with UV-Vis Fluorescence Measurements Combined with Vis-NIR-SWIR Reflectance Spectroscopy: A Farm-Scale Study in a Mediterranean Viticultural Agroecosystem

For adequate crop and soil management, rapid and accurate techniques for monitoring soil properties are particularly important when a farmer starts up his activities and needs a diagnosis of his cultivated fields. This study aimed to evaluate the potential of fluorescence measured directly on 146 whole soil solid samples, for predicting key soil properties at the scale of a 6 ha Mediterranean wine estate with contrasting soils. UV-Vis fluorescence measurements were carried out in conjunction with reflectance measurements in the Vis-NIR-SWIR range. Combining PLSR predictions from Vis-NIR-SWIR reflectance spectra and from a set of fluorescence signals enabled us to improve the power of prediction of a number of key agronomic soil properties including SOC, Ntot, CaCO3, iron, fine particle-sizes (clay, fine silt, fine sand), CEC, pH and exchangeable Ca2+ with cross-validation RPD ≥ 2 and R² ≥ 0.75, while exchangeable K+, Na+, Mg2+, coarse silt and coarse sand contents were fairly predicted (1.42 ≤ RPD < 2 and 0.54 ≤ R² < 0.75). Predictions of SOC, Ntot, CaCO3, iron contents, and pH were still good (RPD ≥ 1.8, R² ≥ 0.68) when using a single fluorescence signal or index such as SFR_R or FERARI, highlighting the unexpected importance of red excitations and indices derived from plant studies. The predictive ability of single fluorescence indices or original signals was very significant for topsoil: this is very important for a farmer who wishes to update information on soil nutrient for the purpose of fertility diagnosis and particularly nitrogen fertilization. These results open encouraging perspectives for using miniaturized fluorescence devices enabling red excitation coupled with red or far-red fluorescence emissions directly in the field