Plant Pathology and Plant-Microbe Biology Section, School of Integrative Plant Science, Cornell AgriTech, Cornell University, Geneva, NY 14456.
Light and Health Research Center, Icahn School of Medicine at Mount Sinai, New York, NY 10029.
Plant Dis. 2024 Aug;108(8):2518-2529. doi: 10.1094/PDIS-12-23-2715-RE. Epub 2024 Aug 5.
Cercospora leaf spot (CLS), caused by the hemibiotrophic fungus , is a destructive disease affecting table beet. Multiple applications of fungicides are needed to reduce epidemic progress to maintain foliar health and enable mechanized harvest. The sustainability of CLS control is threatened by the rapid development of fungicide resistance, the need to grow commercially acceptable yet CLS-susceptible cultivars, and the inability to manipulate agronomic conditions to mitigate disease risk. Nighttime applications of germicidal UV light (UV-C) have recently been used to suppress several plant diseases, notably those caused by ectoparasitic biotrophs such as powdery mildews. We evaluated the efficacy of nighttime applications of UV-C for suppression of CLS in table beet. lethality of UV-C to germinating conidia increased with increasing dose, with complete suppression at 1,000 J/m. Greenhouse-grown table beet tolerated relatively high doses of UV-C without lethal effects despite some bronzing on the leaf blade. A UV-C dose >1,500 J/m resulted in phytotoxicity severities greater than 50%. UV-C exposure to ≤750 J/m resulted in negligible phytotoxicity. Older (6-week-old) greenhouse-grown plants were more susceptible to UV-C damage than younger (2- and 4-week-old) plants. Suppression of CLS by UV-C was greater when applied within 6 days of inoculation than if delayed until 13 days after infection in greenhouse-grown plants. In field trials, there were significant linear relationships between UV-C dose and CLS control and phytotoxicity severity, and a significant negative linear relationship between phytotoxicity and CLS severity at the final assessment. Significant differences between UV-C doses on the severity of CLS and phytotoxicity indicated an efficacious dose near 800 J/m. Collectively, these findings illustrate significant and substantial suppression by nighttime applications of UV-C for CLS control on table beet, with potential for incorporation in both conventional and organic table beet broadacre production systems.
叶斑病(CLS)由半活体真菌引起,是一种破坏性疾病,影响食用甜菜。为了保持叶片健康并实现机械化收获,需要多次应用杀菌剂来减缓病害的流行。杀菌剂抗性的快速发展、商业上可接受但对 CLS 敏感的品种的需求以及无法操纵农业条件以减轻病害风险,这些因素都威胁着 CLS 防治的可持续性。最近,夜间应用杀菌紫外线(UV-C)已被用于抑制多种植物病害,尤其是那些由外寄生活体营养生物引起的病害,如白粉病。我们评估了夜间应用 UV-C 抑制食用甜菜 CLS 的效果。UV-C 对萌发分生孢子的致死性随着剂量的增加而增加,1000 J/m 时完全抑制。温室中生长的食用甜菜能够耐受相对较高的 UV-C 剂量而不会产生致死效应,尽管叶片上有一些青铜色。UV-C 剂量>1500 J/m 会导致超过 50%的植物毒性。UV-C 暴露≤750 J/m 导致的植物毒性可以忽略不计。与较年轻(2 至 4 周龄)的植物相比,较老(6 周龄)的温室植物对 UV-C 损伤更敏感。在温室植物中,与感染后 13 天相比,在感染后 6 天内应用 UV-C 对 CLS 的抑制作用更大。在田间试验中,UV-C 剂量与 CLS 控制和植物毒性严重程度之间存在显著的线性关系,在最终评估时,植物毒性与 CLS 严重程度之间存在显著的负线性关系。UV-C 剂量对 CLS 和植物毒性严重程度的显著差异表明,有效剂量接近 800 J/m。总的来说,这些发现表明夜间应用 UV-C 对食用甜菜的 CLS 具有显著且实质性的抑制作用,这可能适用于常规和有机食用甜菜大田生产系统。
