Iriart Veronica, Rarick Elizabeth M, Ashman Tia-Lynn
Department of Biological Sciences, University of Pittsburgh, Pittsburgh, Pennsylvania, USA.
Ecology. 2024 Dec;105(12):e4426. doi: 10.1002/ecy.4426. Epub 2024 Oct 23.
Symbiotic mutualisms provide critical ecosystem services throughout the world. Anthropogenic stressors, however, may disrupt mutualistic interactions and impact ecosystem health. The plant-rhizobia symbiosis promotes plant growth and contributes to the nitrogen (N) cycle. While off-target herbicide exposure is recognized as a significant stressor impacting wild plants, we lack knowledge about how it affects the symbiotic relationship between plants and rhizobia. Moreover, we do not know whether the impact of herbicide exposure on symbiotic traits or plant fitness might be ameliorated by plant or rhizobial genetic variation. To address these gaps, we conducted a greenhouse study where we grew 17 full-sibling genetic families of red clover (Trifolium pratense) either alone (uninoculated) or in symbiosis with one of two genetic strains of rhizobia (Rhizobium leguminosarum) and exposed them to a concentration of the herbicide dicamba that simulated "drift" (i.e., off-target atmospheric movement) or a control solution. We recorded responses in immediate vegetative injury, key features of the plant-rhizobia mutualism (nodule number, nodule size, and N fixation), mutualism outcomes, and plant fitness (biomass). In general, we found that rhizobial variation more than plant variation determined outcomes of mutualism and plant fitness in response to herbicide exposure. Herbicide damage response depended on plant family, but also whether plants were inoculated with rhizobia and if so, with which strain. Rhizobial strain variation determined nodule number and size, but this was herbicide treatment-dependent. In contrast, strain and herbicide treatment independently impacted symbiotic N fixation. And while herbicide exposure significantly reduced plant fitness, this effect depended on inoculation state. Furthermore, the differential fitness benefits that the two rhizobial strains provided plants seemed to diminish under herbicidal conditions. Altogether, these findings suggest that exposure to low levels of herbicide impact key components of the plant-rhizobia mutualism as well as plant fitness, but genetic variation in the partners determines the magnitude and/or direction of these effects. In particular, our results highlight a strong role of rhizobial strain identity in driving both symbiotic and plant growth responses to herbicide stress.
共生互利关系在全球范围内提供关键的生态系统服务。然而,人为压力源可能会破坏互利互动并影响生态系统健康。植物与根瘤菌的共生关系促进植物生长并有助于氮循环。虽然非靶标除草剂暴露被认为是影响野生植物的一个重要压力源,但我们尚不清楚它如何影响植物与根瘤菌之间的共生关系。此外,我们也不知道植物或根瘤菌的遗传变异是否能改善除草剂暴露对共生性状或植物适应性的影响。为了填补这些空白,我们进行了一项温室研究,种植了17个红三叶草(Trifolium pratense)的全同胞遗传家系,它们要么单独生长(未接种),要么与两种根瘤菌(Rhizobium leguminosarum)遗传菌株之一共生,并将它们暴露于模拟“漂移”(即非靶标大气移动)的除草剂麦草畏浓度或对照溶液中。我们记录了即时营养损伤反应、植物 - 根瘤菌共生关系的关键特征(根瘤数量、根瘤大小和固氮作用)、共生结果以及植物适应性(生物量)。总体而言,我们发现根瘤菌的变异比植物变异更能决定共生关系的结果以及植物在除草剂暴露下的适应性。除草剂损伤反应取决于植物家系,也取决于植物是否接种了根瘤菌,如果接种了,接种的是哪种菌株。根瘤菌菌株变异决定了根瘤数量和大小,但这取决于除草剂处理。相比之下,菌株和除草剂处理分别影响共生固氮作用。虽然除草剂暴露显著降低了植物适应性,但这种影响取决于接种状态。此外,两种根瘤菌菌株为植物提供的不同适应性益处似乎在除草剂条件下会减弱。总之,这些发现表明,低水平除草剂暴露会影响植物 - 根瘤菌共生关系的关键组成部分以及植物适应性,但共生伙伴的遗传变异决定了这些影响的程度和/或方向。特别是,我们的结果突出了根瘤菌菌株特性在驱动共生和植物生长对除草剂胁迫反应方面的重要作用。
