Department of Biosystems, KU Leuven, Leuven, Belgium.
Leuven Plant Institute, KU Leuven, Leuven, Belgium.
Appl Environ Microbiol. 2023 Apr 26;89(4):e0021523. doi: 10.1128/aem.00215-23. Epub 2023 Apr 3.
biovar 1 is a soilborne plant pathogen with the ability to colonize the irrigation system of greenhouses, causing hairy root disease (HRD). Currently, management focuses on using hydrogen peroxide to disinfect the nutrient solution, but due to the emergence of resistant strains, its efficacy and sustainability are questioned. Using a relevant collection of pathogenic biovar 1 strains, OLIVR1 to 6, six phages specific to this pathogen and belonging to three different genera were isolated from biovar 1-infected greenhouses. All phages were named OLIVR, referring to their location of isolation, nze-eve-ouwe-Waver, and were characterized by whole-genome analysis, confirming their strictly lytic lifestyle. They remained stable under greenhouse-relevant conditions. To assess the efficacy of the phages, their ability to disinfect greenhouse nutrient solution inoculated with agrobacteria was tested. Each of the phages infected their host, but their ability to decrease the bacterial concentration differed. For instance, OLIVR1 reduced the bacterial concentration with 4 log units without phage resistance emerging. While OLIVR4 and OLIVR5 were also infectious in nutrient solution, they did not always decrease the bacterial load below the limit of detection, and phage resistance emerged. Finally, the mutations causing phage resistance by receptor modification were identified. For OLIVR4-resistant isolates, but not for OLIVR5-resistant isolates, motility decreased. Together, these data show the potential of some of these phages as disinfectant of nutrient solution, and they might be a valuable tool to tackle HRD. Hairy root disease, caused by rhizogenic biovar 1 is a rapidly emerging bacterial disease worldwide. It affects tomatoes, cucumbers, eggplant, and bell pepper, causing high yield losses in hydroponic greenhouses. Recent findings suggest that the current management practices, mainly focusing on UV-C and hydrogen peroxide to disinfect contaminated water, have a questionable efficacy. Hence, we investigate the potential of phages as a biological means of preventing this disease. Using a diverse collection of biovar 1, we isolated three different phage species that together infect 75% of the collection. Since these phages are strictly lytic, while remaining both stable and infectious under greenhouse-relevant conditions, they might be suitable candidates for biological control.
生物变种 1 是一种土传植物病原体,能够定植于温室灌溉系统,引发根毛病(HRD)。目前,管理措施侧重于使用过氧化氢对营养液进行消毒,但由于抗性菌株的出现,其效果和可持续性受到质疑。使用相关的生物变种 1 病原菌菌株集合,我们从感染温室的生物变种 1 中分离到了 6 种专门针对该病原体的噬菌体,它们属于三个不同的属。所有噬菌体都被命名为 OLIVR,这是指它们的分离地点,nze-eve-ouwe-Waver,并通过全基因组分析进行了特征描述,证实了它们严格的裂解生活方式。它们在温室相关条件下保持稳定。为了评估噬菌体的功效,我们测试了它们对接种农杆菌的温室营养液进行消毒的能力。每种噬菌体都感染了它们的宿主,但它们降低细菌浓度的能力有所不同。例如,OLIVR1 在没有出现噬菌体抗性的情况下将细菌浓度降低了 4 个对数单位。虽然 OLIVR4 和 OLIVR5 也能在营养液中感染,但它们并不总能将细菌负荷降低到检测限以下,而且出现了噬菌体抗性。最后,确定了通过受体修饰引起噬菌体抗性的突变。对于 OLIVR4 抗性分离株,但不是 OLIVR5 抗性分离株,运动性降低。总的来说,这些数据表明了其中一些噬菌体作为营养液消毒剂的潜力,它们可能是解决 HRD 的一种有价值的工具。根毛病由根生性生物变种 1 引起,是一种在全球范围内迅速出现的细菌性疾病。它影响番茄、黄瓜、茄子和甜椒,导致水培温室的产量损失很高。最近的研究结果表明,目前的管理措施主要侧重于使用紫外线-C 和过氧化氢对受污染的水进行消毒,其效果存在疑问。因此,我们研究了噬菌体作为预防这种疾病的生物手段的潜力。使用多样化的生物变种 1 集合,我们分离到了三种不同的噬菌体物种,它们共同感染了集合的 75%。由于这些噬菌体是严格的裂解,并且在温室相关条件下保持稳定和感染性,它们可能是生物防治的合适候选者。
