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利用碳-11 放射性示踪技术研究根际细菌缓解非生物作物胁迫的效应。

Examining effects of rhizobacteria in relieving abiotic crop stresses using carbon-11 radiotracing.

机构信息

Missouri Research Reactor Center, University of Missouri, Columbia, Missouri, USA.

School of Natural Resources, University of Missouri, Columbia, Missouri, USA.

出版信息

Physiol Plant. 2022 Mar;174(2):e13675. doi: 10.1111/ppl.13675.

DOI:10.1111/ppl.13675
PMID:35316539
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9310733/
Abstract

In agriculture, plant growth promoting bacteria (PGPB) are increasingly used for reducing environmental stress-related crop losses through mutualistic actions of these microorganisms, activating physiological and biochemical responses, building tolerances within their hosts. Here we report the use of radioactive carbon-11 (t 20.4 min) to examine the metabolic and physiological responses of Zea mays to Azospirillum brasilense (HM053) inoculation while plants were subjected to salinity and low nitrogen stresses. Host metabolism of "new" carbon resources (as C) and physiology including [ C]-photosynthate translocation were measured in response to imposed growth conditions. Salinity stress caused shortened, dense root growth with a 6-fold increase in foliar [ C]-raffinose, a potent osmolyte. ICP-MS analyses revealed increased foliar Na levels at the expense of K . HM053 inoculation relieved these effects, reinstating normal root growth, lowering [ C]-raffinose levels while increasing [ C]-sucrose and its translocation to the roots. Na levels remained elevated with inoculation, but K levels were boosted slightly. Low nitrogen stress yielded longer roots possessing high levels of anthocyanins. Metabolic analysis revealed significant shifts in "new" carbon partitioning into the amino acid pool under low nitrogen stress, with significant increases in foliar [ C]-glutamate, [ C]-aspartate, and [ C]-asparagine, a noted osmoprotectant. CO fixation and [ C]-photosynthate translocation also decreased, limiting carbon supply to roots. However, starch levels in roots were reduced under nitrogen limitation, suggesting that carbon repartitioning could be a compensatory action to support root growth. Finally, inoculation with HM053 re-instated normal root growth, reduced anthocyanin, boosted root starch, and returned C-allocation levels back to those of unstressed plants.

摘要

在农业中,植物生长促进细菌(PGPB)越来越多地被用于通过这些微生物的互利作用来减少与环境胁迫相关的作物损失,从而激活生理和生化反应,在宿主内建立耐受性。在这里,我们报告使用放射性碳-11(t 20.4 分钟)来研究玉米对固氮螺菌(HM053)接种的代谢和生理反应,同时植物受到盐度和低氮胁迫。宿主对“新”碳资源(作为 C)的代谢和包括[ C]-光合作用产物转运在内的生理学反应,根据施加的生长条件进行测量。盐度胁迫导致根生长缩短、密集,叶片[ C]-棉子糖增加 6 倍,这是一种有效的渗透调节剂。ICP-MS 分析显示,叶片 Na 水平升高,以牺牲 K 为代价。HM053 接种缓解了这些效应,恢复了正常的根生长,降低了[ C]-棉子糖水平,同时增加了[ C]-蔗糖及其向根部的转运。接种后 Na 水平仍然升高,但 K 水平略有升高。低氮胁迫导致根更长,含有高水平的花青素。代谢分析显示,在低氮胁迫下,“新”碳分配到氨基酸库中发生了显著变化,叶片[ C]-谷氨酸、[ C]-天冬氨酸和[ C]-天冬酰胺显著增加,这是一种著名的渗透保护剂。CO 固定和[ C]-光合作用产物转运也减少,限制了根部的碳供应。然而,氮限制下根部的淀粉水平降低,表明碳再分配可能是支持根生长的补偿作用。最后,HM053 接种恢复了正常的根生长,减少了花青素,增加了根淀粉,并使 C 分配水平恢复到未受胁迫植物的水平。

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