Environmental Ecology and Applied Microbiology (ENdEMIC), Department of Bioscience Engineering, University of Antwerpgrid.5284.b, Antwerp, Belgium.
Research Centre Hoogstraten vzw, Meerle, Belgium.
Microbiol Spectr. 2022 Aug 31;10(4):e0175522. doi: 10.1128/spectrum.01755-22. Epub 2022 Jul 7.
Greenhouses are highly productive environments in which conditions are regulated to optimize plant growth. The enclosed character of greenhouses usually results in reduced microbial diversity, while it is known that a diverse microbiome is important for plant health. Therefore, we explored the phyllosphere microbiome of tomatoes and strawberries grown in greenhouses. We observed that the microbiome of both crops was low in diversity and abundance and varied considerably over time and space. Interestingly, the core taxa of tomatoes were Snodgrasella and Gilliamella, genera typically associated with bumblebees. The same amplicon sequence variants (ASVs) were found on reared bumblebees, indicating that the bumblebees, present in the sampled greenhouses to pollinate flowers, had introduced and dispersed these bacteria in the greenhouses. Overall, we found that 80% of plants contained bumblebee-associated taxa, and on these plants, bumblebee-associated reads accounted for up to a quarter of the reads on tomatoes and a tenth of the reads on strawberries. Furthermore, predatory mites had been introduced for the control of spider mites. Their microbiome was composed of a diverse set of bacteria, which varied between batches ordered at different times. Still, identical ASVs were found on mites and crops, and these belonged to the genera Sphingomonas, Staphylococcus, Methylobacterium, and Pseudomonas. These new insights should now be further explored and utilized to diversify ecosystems that are characterized by low diversity and abundancy of microbes. Greenhouses, though highly effective agricultural environments, are characterized by reduced sources of bacterial diversity and means of dispersal compared to more natural settings. As it is known that plant health and productivity are affected by associated bacteria, improving our knowledge on the bacterial communities on greenhouse crops is key to further innovate in horticulture. Our findings show that tomato and strawberry crops cultivated in greenhouses harbor poor and variable bacterial communities. Furthermore, commonly implemented biological solutions (i.e., those based on living organisms such as bumblebees and predatory mites) are important sources and means of dispersal of bacteria in greenhouses. This study shows that there is great potential in using these biological solutions to enrich the greenhouse microbiome by introducing and dispersing microbes which have beneficial effects on crop production and protection, provided that the dispersed microbes have a beneficial function.
温室是一种高度集约的生产环境,其中的条件受到严格调控以优化植物生长。温室的封闭特性通常会导致微生物多样性减少,而众所周知,多样化的微生物群落对植物健康很重要。因此,我们探索了在温室中种植的番茄和草莓的叶际微生物组。我们观察到,这两种作物的微生物组多样性和丰度都较低,并且随着时间和空间的变化而有很大差异。有趣的是,番茄的核心分类群是与熊蜂有关的 Snodgrasella 和 Gilliamella 属。在饲养的熊蜂中也发现了相同的扩增子序列变异 (ASV),这表明,在采样温室中授粉花朵的熊蜂已经将这些细菌引入并在温室内传播。总的来说,我们发现 80%的植物都含有与熊蜂有关的分类群,在这些植物上,与熊蜂有关的reads 占番茄的四分之一,占草莓的十分之一。此外,还引入了捕食性螨虫来控制红蜘蛛。它们的微生物组由一系列不同的细菌组成,这些细菌在不同时间订购的批次之间有所不同。尽管如此,在螨虫和作物上还是发现了相同的 ASV,它们属于 Sphingomonas、Staphylococcus、Methylobacterium 和 Pseudomonas 属。现在应该进一步探索和利用这些新的发现,以使以微生物多样性低和丰度低为特征的生态系统多样化。虽然温室是一种非常有效的农业环境,但与更自然的环境相比,其细菌多样性的来源和传播方式都有所减少。由于已知植物的健康和生产力受到相关细菌的影响,因此提高我们对温室作物细菌群落的了解是园艺创新的关键。我们的研究结果表明,在温室中种植的番茄和草莓作物拥有贫瘠且多变的细菌群落。此外,常见的生物解决方案(即基于生物的解决方案,例如蜜蜂和捕食性螨虫)是温室中细菌的重要来源和传播方式。这项研究表明,通过引入和传播对作物生产和保护有有益作用的微生物,有很大的潜力可以丰富温室微生物组,前提是分散的微生物具有有益的功能。
