Nivelle Elodie, Verzeaux Julien, Chabot Amélie, Roger David, Spicher Fabien, Lacoux Jérôme, Nava-Saucedo Jose-Edmundo, Catterou Manuella, Tétu Thierry
Ecologie et Dynamique des Systèmes Anthropisés (EDYSAN, FRE 3498 CNRS UPJV), Laboratoire d'Agroécologie, Ecophysiologie et Biologie Intégrative, Université de Picardie Jules Verne, 33 rue St Leu, Amiens, France.
Département Sciences de la Vie et de la Terre, Université de Picardie Jules Verne, 33 rue St Leu, Amiens, France.
PLoS One. 2017 May 26;12(5):e0178342. doi: 10.1371/journal.pone.0178342. eCollection 2017.
The use of nitrogen (N) fertilizer and glyphosate-based herbicides is increasing worldwide, with agriculture holding the largest market share. The agronomic and socioeconomic utilities of glyphosate are well established; however, our knowledge of the potential effects of glyphosate applied in the presence or absence of long-term N fertilization on microbial functional activities and the availability of soil nutrients remains limited. Using an ex situ approach with soils that did (N+) or did not (N0) receive synthetic N fertilization for 6 years, we assessed the impact of different rates (no glyphosate, CK; field rate, FR; 100 × field rate, 100FR) of glyphosate application on biological and chemical parameters. We observed that, after immediate application (1 day), the highest dose of glyphosate (100FR) negatively affected the alkaline phosphatase (AlP) activity in soils without N fertilization history and decreased the cation exchange capacity (CEC) in N0 compared to CK and FR treatments with N+. Conversely, the 100FR application increased nitrate (NO3-) and available phosphorus (PO43-) regardless of N fertilization history. Then, after 8 and 15 days, the N+\100FR and N+\FR treatments exhibited the lowest values for dehydrogenase (DH) and AlP activities, respectively, while urease (URE) activity was mainly affected by N fertilization. After 15 days and irrespective of N fertilization history, the FR glyphosate application negatively affected the degradation of carbon substrates by microbial communities (expressed as the average well color development, AWCD). By contrast, the 100FR treatment positively affected AWCD, increasing PO43- by 5 and 16% and NO3- by 126 and 119% in the N+ and N0 treatments, respectively. In addition, the 100FR treatment resulted in an increase in the average net nitrification rate. Principal component analysis revealed that the 100FR glyphosate treatment selected microbial communities that were able to metabolize amine substrates. Overall, the lack of N fertilization in the 6 past years combined with the highest glyphosate application rate (100FR) induced the highest values of AWCD, functional diversity, NO3-, PO43- and nitrification. We concluded that the intensive use of N fertilization for 6 years may change the non-target effects of glyphosate application on enzyme activities. The functional activities, nitrification and nutrient contents were increased by glyphosate only when applied at 100 times the field application rate.
全球范围内,氮肥和草甘膦类除草剂的使用量不断增加,其中农业领域的市场份额最大。草甘膦的农艺和社会经济效用已得到充分证实;然而,我们对于在长期施肥或不施肥条件下施用草甘膦对微生物功能活性和土壤养分有效性的潜在影响的了解仍然有限。我们采用异位法,对连续6年施用过(N+)或未施用过(N0)合成氮肥的土壤进行研究,评估了不同施用量(不施草甘膦,CK;田间施用量,FR;100倍田间施用量,100FR)的草甘膦对土壤生物学和化学参数的影响。我们观察到,在立即施用(1天)后,最高剂量的草甘膦(100FR)对无施肥历史土壤中的碱性磷酸酶(AlP)活性产生负面影响,与N+处理的CK和FR相比,降低了N0土壤的阳离子交换容量(CEC)。相反,无论施肥历史如何,100FR的施用量均增加了硝酸盐(NO3-)和有效磷(PO43-)的含量。然后,在8天和15天后,N+\100FR和N+\FR处理分别表现出最低的脱氢酶(DH)和AlP活性,而脲酶(URE)活性主要受氮肥影响。15天后,无论施肥历史如何,FR草甘膦施用量对微生物群落碳底物降解产生负面影响(以平均孔颜色变化值,AWCD表示)。相比之下,100FR处理对AWCD产生积极影响,在N+和N0处理中,PO43-分别增加了5%和16%,NO3-分别增加了126%和119%。此外,100FR处理导致平均净硝化率增加。主成分分析表明,100FR草甘膦处理选择了能够代谢胺类底物的微生物群落。总体而言,过去6年未施肥且草甘膦施用量最高(100FR)的处理诱导了最高的AWCD值、功能多样性、NO3-、PO43-和硝化作用。我们得出结论,连续6年大量施用氮肥可能会改变草甘膦施用对酶活性的非靶标效应。只有在以田间施用量的100倍施用草甘膦时,其对功能活性、硝化作用和养分含量才会产生增加作用。
