Difference between revisions of "Team:Bordeaux/Problem"
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<h6 align="justify"> Infection Mode of Downy Mildew </h6> | <h6 align="justify"> Infection Mode of Downy Mildew </h6> | ||
− | <p align="justify" style="text-indent: 3vw;"> In winter, <i> Plasmopara viticola </i> is present on dead leaves on the ground as oospores. They are inactive and do not produce any symptoms. When rain falls during spring, these eggs grow and release zoospores when the temperature exceeds 11 degrees. The zoospores will be able to spread and infect the plant | + | <p align="justify" style="text-indent: 3vw;"> In winter, <i> Plasmopara viticola </i> is present on dead leaves on the ground as oospores. They are inactive and do not produce any symptoms. When rain falls during spring, these eggs grow and release zoospores when the temperature exceeds 11 degrees. The zoospores will be able to spread and infect the plant upper tissues through rainwater splashes. [5] </p> |
− | <p align="justify" style="text-indent: 3vw;">The <b> primary contamination </b> begins by the emission of a filament through the stomatal area where the parasite begins to <b> develop sinkers </b> from which is formed the mycelial network. These sinkers <b> help to feed <i>Plasmopara viticola </i> by stealing the plant | + | <p align="justify" style="text-indent: 3vw;">The <b> primary contamination </b> begins by the emission of a filament through the stomatal area where the parasite begins to <b> develop sinkers </b> from which is formed the mycelial network. These sinkers <b> help to feed <i>Plasmopara viticola </i> by stealing the plant nutrients, </b> which creates discolored and yellowish areas on the leaves called “oil stains”. After, on leaves bottom, conidiophores and conidia are formed. These symptoms cause damages to the leave tissues and affect the plant photosynthetic ability, which slows down the maturity of the plant.</p> |
<p align="justify" style="text-indent: 3vw;">During the <b> secondary contamination </b>, the conidia are transformed into zoospores that <b>contaminate the surrounding tissues</b>, weakening the plant even more and creating <b> unreparable lesions </b>. </p> | <p align="justify" style="text-indent: 3vw;">During the <b> secondary contamination </b>, the conidia are transformed into zoospores that <b>contaminate the surrounding tissues</b>, weakening the plant even more and creating <b> unreparable lesions </b>. </p> | ||
<p class="reference" align="left"> <b>Literature Cited: </b> </p> | <p class="reference" align="left"> <b>Literature Cited: </b> </p> | ||
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− | <!-- ---------------------------------------- PLANT | + | <!-- ---------------------------------------- PLANT NATURAL DEFENSES ---------------------------------------------------------- --> |
<div class="col-lg-10 col-lg-offset-1"> | <div class="col-lg-10 col-lg-offset-1"> | ||
− | <h6 align="justify"> | + | <h6 align="justify"> Plant natural defenses </h6> |
− | <p align="justify" style="text-indent: 3vw;"> Plant | + | <p align="justify" style="text-indent: 3vw;"> Plant immunization is based on the same principle as human immunization: activating its natural defenses before contamination by an infectious agent. The concept is simple; putting the plant in contact with a molecule able to activate it's natural defenses: <b> an elicitor </b> . In nature, there are many elicitors produced by micro-organisms (exogenous elicitors) or by the plant itself when it is attacked (endogenous elicitors). The presence of an elicitor in the plant triggers a series of cellular reactions including the <b> production of molecules to strengthen the resistance of cell walls </b>, but also the <b> production of plant antibiotics </b> such as <b>phytoalexins</b> or <b>defense proteins</b>. These compounds have antifungal and antibacterial properties. The external application of a natural elicitor or a similar synthetic molecule thus results in the production of phytoalexins or defense proteins in the absence of any pathogen. The "immunized" plant is ready to fight back if attacked. </p> |
<p align="justify" style="text-indent: 3vw;"> First, the cell wall forms a physical barrier which prevents the penetration of most microbes. Then, if some pathogens are able to cross this wall, the infection depends on the ability of the plant to perceive and to trigger defense reactions that would prevent the development of the disease. This recognition is done with certain compounds, known as elicitors from the pathogen or plant. <b> The fixing of an elicitor to a plant cell receptor initiates a cascade of events that leads to the synthesis of defense compounds </b>. The best known are antimicrobial compounds such as <b> phytoalexins </b> and <b> Pathogenesis Related proteins </b>. </p> | <p align="justify" style="text-indent: 3vw;"> First, the cell wall forms a physical barrier which prevents the penetration of most microbes. Then, if some pathogens are able to cross this wall, the infection depends on the ability of the plant to perceive and to trigger defense reactions that would prevent the development of the disease. This recognition is done with certain compounds, known as elicitors from the pathogen or plant. <b> The fixing of an elicitor to a plant cell receptor initiates a cascade of events that leads to the synthesis of defense compounds </b>. The best known are antimicrobial compounds such as <b> phytoalexins </b> and <b> Pathogenesis Related proteins </b>. </p> | ||
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<p class="reference" align="left"> <b>Literature Cited: </p> | <p class="reference" align="left"> <b>Literature Cited: </p> | ||
− | <p class="reference" align="left"> [7] | + | <p class="reference" align="left"> [7] Les Stimulateurs naturels de défense (SDN) de la Vigne <i> Chambre d'agriculture Indre et Loire </i></p> |
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Latest revision as of 02:03, 19 September 2015