Brulé Daphnée, Héloir Marie-Claire, Roudaire Thibault, Villette Jérémy, Bonnet Silvère, Pascal Yoann, Darblade Benoît, Crozier Philippe, Hugueney Philippe, Coma Véronique, Poinssot Benoit
UMR Agroécologie, INRAE, Institut Agro Dijon, Université de Bourgogne, Dijon, France.
Elicityl, Crolles, France.
Front Plant Sci. 2024 Feb 7;15:1360254. doi: 10.3389/fpls.2024.1360254. eCollection 2024.
The European Green Deal aims to reduce the pesticide use, notably by developing biocontrol products to protect crops from diseases. Indeed, the use of significant amounts of chemicals negatively impact the environment such as soil microbial biodiversity or groundwater quality, and human health. Grapevine () was selected as one of the first targeted crop due to its economic importance and its dependence on fungicides to control the main damaging diseases worldwide: grey mold, downy and powdery mildews. Chitosan, a biopolymer extracted from crustacean exoskeletons, has been used as a biocontrol agent in many plant species, including grapevine, against a variety of cryptogamic diseases such as downy mildew (), powdery mildew () and grey mold (). However, the precise molecular mechanisms underlying its mode of action remain unclear: is it a direct biopesticide effect or an indirect elicitation activity, or both? In this study, we investigated six chitosans with diverse degrees of polymerization (DP) ranging from low to high DP (12, 25, 33, 44, 100, and 470). We scrutinized their biological activities by evaluating both their antifungal properties and their abilities to induce grapevine immune responses. To investigate their elicitor activity, we analyzed their ability to induce MAPKs phosphorylation, the activation of defense genes and metabolite changes in grapevine. Our results indicate that the chitosans with a low DP are more effective in inducing grapevine defenses and possess the strongest biopesticide effect against and . We identified chitosan with DP12 as the most efficient resistance inducer. Then, chitosan DP12 has been tested against downy and powdery mildews in the vineyard trials performed during the last three years. Results obtained indicated that a chitosan-based biocontrol product could be sufficiently efficient when the amount of pathogen inoculum is quite low and could be combined with only two fungicide treatments during whole season programs to obtain a good protection efficiency. On the whole, a chitosan-based biocontrol product could become an interesting alternative to meet the chemicals reduction targeted in sustainable viticulture.
欧洲绿色协议旨在减少农药使用,特别是通过开发生物防治产品来保护作物免受病害侵袭。事实上,大量使用化学物质会对环境(如土壤微生物多样性或地下水质量)和人类健康产生负面影响。葡萄因其经济重要性以及对杀菌剂的依赖(用于控制全球主要破坏性病害:灰霉病、霜霉病和白粉病)而被选为首批目标作物之一。壳聚糖是一种从甲壳类动物外骨骼中提取的生物聚合物,已在包括葡萄在内的许多植物物种中用作生物防治剂,以对抗多种隐花植物病害,如霜霉病、白粉病和灰霉病。然而,其作用方式背后的确切分子机制仍不清楚:是直接的生物农药效应还是间接的诱导活性,或者两者皆有?在本研究中,我们研究了六种聚合度(DP)不同的壳聚糖,其DP范围从低到高(12、25、33、44、100和470)。我们通过评估它们的抗真菌特性以及诱导葡萄免疫反应的能力来仔细研究它们的生物活性。为了研究它们的诱导活性,我们分析了它们诱导丝裂原活化蛋白激酶(MAPKs)磷酸化、防御基因激活以及葡萄中代谢物变化的能力。我们的结果表明,低DP的壳聚糖在诱导葡萄防御方面更有效,并且对霜霉病和白粉病具有最强的生物农药效应。我们确定DP12的壳聚糖是最有效的抗性诱导剂。然后,在过去三年进行的葡萄园试验中,对DP12的壳聚糖进行了抗霜霉病和白粉病的测试。获得的结果表明,当病原菌接种量相当低时,可以充分有效地使用基于壳聚糖的生物防治产品,并且在整个季节的方案中仅与两次杀菌剂处理相结合,即可获得良好的保护效果。总体而言,基于壳聚糖的生物防治产品可能成为满足可持续葡萄栽培中减少化学物质使用目标的一个有趣替代方案。
