Grunert Oliver, Hernandez-Sanabria Emma, Buysens Saskia, De Neve Stefaan, Van Labeke Marie-Christine, Reheul Dirk, Boon Nico
Greenyard, Skaldenstraat 7a, Desteldonk, Belgium.
Agaris, Desteldonk, Belgium.
Front Plant Sci. 2020 Nov 5;11:520834. doi: 10.3389/fpls.2020.520834. eCollection 2020.
As soil and soilless culture systems are highly dynamic environments, the structure of rhizosphere microbial communities is consistently adapting. There is a knowledge gap between the microbial community structure of soil based and soilless culture systems and thus we aimed at surveying their impact on diversity and composition of bacterial communities across a 10-month period in a tomato cultivation system. We compared community metrics between an soil based culture system fertilized with malt sprouts and blood meal, known for its slow and high mineralization rate, respectively and a soilless culture system fertilized with fish effluent or supplemented with an liquid organic fertilizer. Bacterial and fungal community composition was followed over time using two complementary techniques, phospholipid fatty acid analysis and 16S rRNA amplicon sequencing. Nitrogen dynamics and plant performance were assessed to provide insight on how bacterial diversity of soil and soilless microbial communities ultimately impacts productivity. Similar plant performance was observed in soilless culture systems and soil based system and yield was the highest with the aquaponics-derived fertilizer. Soil and soilless cultivating systems supplemented with different nitrogen-rich fertilizers differed on its characteristics throughout the experimental period. Fast-paced fluctuations in pH(HO) and nutrient cycling processes were observed in growing medium. Physicochemical characteristics changed over time and interacted with bacterial community metrics. Multivariate analysis showed that plant length, pH, , phosphorus, chloride, ammonium, potassium, calcium, magnesium, sodium, electrical conductivity, nitrate, sulfate, and the bacterial genera , , , , , , were the most significant factors discriminating between natural soils supplemented with animal and plant by-products. Long-term fertilizer regimes significantly changed the PLFA fingerprints in both the soilless culture and soil based culture system. The use of these by-products in the soil was positively associated with arbuscular mycorrhizal fungi (AMF), which may influence rhizosphere communities through root exudates and C translocation. Community structure was distinct and consistently different over time, despite the fertilizer supplementation. The fungal microbial community composition was less affected by pH, while the composition of the bacterial communities (Actinomycetes, Gram-negative bacteria, and Gram-positive bacteria) was closely defined by soil pH, demonstrating the significance of pH as driver of bacterial community composition. Fertilizer application may be responsible for variations over time in the ecosystem. Knowledge about the microbial interactions in tomato cultivating systems opens a window of opportunity for designing targeted fertilizers supporting sustainable crop production.
由于土壤和无土栽培系统是高度动态的环境,根际微生物群落的结构一直在不断适应。基于土壤的栽培系统和无土栽培系统的微生物群落结构之间存在知识差距,因此我们旨在研究在番茄种植系统中,它们在10个月的时间里对细菌群落多样性和组成的影响。我们比较了以麦芽芽和血粉为肥料的基于土壤的栽培系统(分别以其缓慢和高矿化率而闻名)与以鱼废水施肥或补充液体有机肥的无土栽培系统之间的群落指标。使用两种互补技术,即磷脂脂肪酸分析和16S rRNA扩增子测序,随时间跟踪细菌和真菌群落组成。评估了氮动态和植物性能,以深入了解土壤和无土微生物群落的细菌多样性如何最终影响生产力。在无土栽培系统和基于土壤的系统中观察到相似的植物性能,并且使用水产养殖衍生肥料时产量最高。在整个实验期间,补充不同富氮肥料的土壤和无土栽培系统在其特性上存在差异。在生长介质中观察到pH(HO)和养分循环过程的快速波动。物理化学特性随时间变化,并与细菌群落指标相互作用。多变量分析表明,植物长度、pH、磷、氯、铵、钾、钙、镁、钠、电导率、硝酸盐、硫酸盐以及细菌属、、、、、、是区分添加动植物副产品的天然土壤的最重要因素。长期施肥制度在无土栽培和基于土壤的栽培系统中均显著改变了磷脂脂肪酸指纹图谱。在土壤中使用这些副产品与丛枝菌根真菌(AMF)呈正相关,AMF可能通过根系分泌物和碳转运影响根际群落。尽管添加了肥料,但群落结构随时间明显且持续不同。真菌微生物群落组成受pH的影响较小,而细菌群落(放线菌、革兰氏阴性菌和革兰氏阳性菌)的组成则由土壤pH密切定义,这表明pH作为细菌群落组成驱动因素的重要性。施肥可能是生态系统随时间变化的原因。关于番茄种植系统中微生物相互作用的知识为设计支持可持续作物生产的靶向肥料打开了一扇机会之窗。
