科学家刚刚利用Plantarray植物逆境生物学研究系统发表了题为“Low Si combined with drought causes reduced transpiration in sorghum Lsi1 mutant”的文章����,文章发表于Plant and Soil(2022)����。这已经是2022年发表的第篇文章��,其余2篇文章是
1��、The potential of dynamic physiological traits in young tomato plants to predict field-yield performance
2��、Diurnal stomatal apertures and density ratioses affect whole-canopy stomatal conductance, water-use efficiency and yield
低硅与干旱共同导致高粱Lsi1突变体蒸腾作用降低
摘要
背景和目标
又高又稳定植物生产力是农业研究的主要目标���。硅肥能提高各种作物在压力下的产量�����。尽管如此��,由于缺乏解释这种效应的机制���,硅的广泛应用受到限制����。
实验系统
为了研究干旱条件下硅在土壤生长植物中的作用��,我们利用了一种缺乏关键硅根通道—低硅1(SbLsi1)的高粱突变体植物�����。Sblsi1突变体植物只吸收野生型植物吸收的1/15的硅��,使其成为在土壤和田间条件下研究硅生理学的合适工具���。
结果
在盆栽条件下生长的突变体植株中���,只有在水分胁迫下����,才发现瞬时和累积的全株蒸腾作用�����、光合作用速率和气孔导度显著降低�����。野生型和Sblsi1植物的根系结构����、根系水力传导率和气孔密度相似��。基因型间叶片含水量相似����,说明水分吸收与蒸腾作用是平衡的����。
结论
在良好条件下���,非胁迫植物中�����,基因型之间��,施硅肥影响轻微或无影响��,支持突变的轻微多效性效应����。在干旱胁迫下��,突变体植株的早期气孔关闭导致蒸腾作用降低���。这种早期反应表明��,硅可能通过减少胁迫信号或反应来延迟干旱生理的发生��。
Low Si combined with drought causes reduced transpiration in sorghum Lsi1 mutant
Oshry Markovich, Nerya Zexer, Boaz Negin, Yotam Zait, Shula Blum, Alon Ben-Gal & Rivka RivkaElbaum
Plant and Soil (2022)
Abstract
Background and aims
High and stable plant productivity is a major aim in agricultural research. Silicon fertilization improves yields of various crops under stress. Nonetheless, broad application of silicon is inhibited by the lack of a mechanism explaining this effect.
Experimental System
To study the role of silicon in soil-grown plants under drought, we utilized a sorghum (Sorghum bicolor) mutant plant lacking the key silicon root channel – Low silicon 1 (SbLsi1). The sblsi1 mutant plants absorb 1/15 of the silicon absorbed by wild type plants, making them a suitable tool to examine silicon physiology in soil and under field conditions.
Results
In mutant plants grown in pots, significant reductions in momentary and accumulated whole plant transpiration, photosynthesis rate, and stomatal conductance were found only under water stress. Root structure, root hydraulic conductance, and stomatal density were similar between wild type and sblsi1 plants. Similar leaf water contents between the genotypes suggested that the water uptake was balanced with transpiration.
Conclusions
The similarity between the genotypes under benign conditions are in accordance with minor to no effects of silicon fertilization in non-stressed plants, and support the minor pleiotropic effects of the mutation. Early stomatal closure in the mutant plants under drought stress caused the reduced transpiration. Thise early response suggests that silicon may delay the onset of drought physiology by either reduced stress signaling or reaction.
Markovich, O., Zexer, N., Negin, B. et al. Low Si combined with drought causes reduced transpiration in sorghum Lsi1 mutant. Plant Soil (2022). http://doi.org/10.1007/s11104-022-05298-4
