Konvalinková Tereza, Jansa Jan
Laboratory of Fungal Biology, Institute of Microbiology, The Czech Academy of SciencesPrague, Czech Republic; Department of Experimental Plant Biology, Faculty of Science, Charles University in PraguePrague, Czech Republic.
Laboratory of Fungal Biology, Institute of Microbiology, The Czech Academy of Sciences Prague, Czech Republic.
Front Plant Sci. 2016 Jun 6;7:782. doi: 10.3389/fpls.2016.00782. eCollection 2016.
Plants are often exposed to shade over different time scales and this may substantially affect not only their own growth, but also development and functioning of the energetically dependent organisms. Among those, the root symbionts such as arbuscular mycorrhizal (AM) fungi and rhizobia represent particularly important cases-on the one hand, they consume a significant share of plant carbon (C) budget and, on the other, they generate a number of important nutritional feedbacks on their plant hosts, often resulting in a net positive effect on their host growth and/or fitness. Here we discuss our previous results comparing mycorrhizal performance under different intensities and durations of shade (Konvalinková et al., 2015) in a broader context of previously published literature. Additionally, we review publicly available knowledge on the root colonization and mycorrhizal growth responses in AM plants under light deprivation. Experimental evidence shows that sudden and intensive decrease of light availability to a mycorrhizal plant triggers rapid deactivation of phosphorus transfer from the AM fungus to the plant already within a few days, implying active and rapid response of the AM fungus to the energetic status of its plant host. When AM plants are exposed to intensive shading on longer time scales (weeks to months), positive mycorrhizal growth responses (MGR) are often decreasing and may eventually become negative. This is most likely due to the high C cost of the symbiosis relative to the C availability, and failure of plants to fully compensate for the fungal C demand under low light. Root colonization by AM fungi often declines under low light intensities, although the active role of plants in regulating the extent of root colonization has not yet been unequivocally demonstrated. Quantitative information on the rates and dynamics of C transfer from the plant to the fungus is mostly missing, as is the knowledge on the involved molecular mechanisms. Therefore, these subjects deserve particular attention in the future.
植物常常在不同的时间尺度下受到遮荫影响,这不仅可能极大地影响其自身生长,还会影响依赖能量的生物体的发育和功能。其中,根共生体如丛枝菌根(AM)真菌和根瘤菌是特别重要的例子——一方面,它们消耗植物碳(C)预算的很大一部分,另一方面,它们对其植物宿主产生许多重要的营养反馈,常常对宿主生长和/或适合度产生净积极影响。在此,我们在先前发表文献的更广泛背景下讨论我们之前比较不同遮荫强度和持续时间下菌根性能的结果(Konvalinková等人,2015年)。此外,我们回顾了关于缺光条件下AM植物根系定殖和菌根生长反应的公开可用知识。实验证据表明,菌根植物光照可用性的突然和强烈降低会在几天内迅速触发从AM真菌到植物的磷转移失活,这意味着AM真菌对其植物宿主的能量状态有积极且快速的反应。当AM植物在较长时间尺度(数周数月)下受到强烈遮荫时,积极的菌根生长反应(MGR)往往会降低,最终可能变为消极。这很可能是由于共生关系相对于碳可用性的高碳成本,以及植物在低光照下无法完全补偿真菌的碳需求。在低光照强度下,AM真菌的根系定殖通常会下降,尽管植物在调节根系定殖程度方面的积极作用尚未得到明确证明。关于从植物到真菌的碳转移速率和动态的定量信息大多缺失,关于所涉及分子机制的知识也是如此。因此,这些主题在未来值得特别关注。
