NaCl对拟南芥野生型和agb1异源三聚体G蛋白突变体植株气孔开放的影响。
The effect of NaCl on stomatal opening in Arabidopsis wild type and agb1 heterotrimeric G-protein mutant plants.
作者信息
Yu Yunqing, Assmann Sarah M
机构信息
a Biology Department ; Pennsylvania State University ; University Park , PA USA.
出版信息
Plant Signal Behav. 2016;11(2):e1085275. doi: 10.1080/15592324.2015.1085275.
Abstract
Salinity is a major agricultural problem that affects crop yield. Na(+) is transported to the shoot through the transpiration stream. The mutant of the sole Arabidopsis heterotrimeric G protein β subunit, agb1, is hypersensitive to salinity in part due to a higher transpiration rate. Here, we investigated the direct effect of Na(+) on stomatal opening using detached epidermal peels of wild type and agb1 plants. In both genotypes, NaCl is equally as effective as KCl in mediating stomatal opening at the concentrations tested. In both genotypes, ABA is less effective in inhibiting Na(+) mediated stomatal opening than K(+) mediated stomatal opening. The agb1 mutant is hyposensitive to ABA inhibition of K(+)-mediated but not Na(+)-mediated stomatal opening. These results suggest that the greater transpiration observed in agb1 plants grown in saline conditions is likely not mediated by differential genotypic direct effects of Na(+) on stomatal apertures.
摘要
盐度是影响作物产量的一个主要农业问题。Na(+) 通过蒸腾流运输到地上部。拟南芥唯一的异源三聚体G蛋白β亚基的突变体agb1对盐度高度敏感,部分原因是蒸腾速率较高。在这里,我们使用野生型和agb1植株的离体表皮条研究了Na(+) 对气孔开放的直接影响。在两种基因型中,在所测试的浓度下,NaCl在介导气孔开放方面与KCl同样有效。在两种基因型中,脱落酸(ABA)在抑制Na(+) 介导的气孔开放方面比K(+) 介导的气孔开放效果更差。agb1突变体对ABA抑制K(+) 介导的气孔开放不敏感,但对Na(+) 介导的气孔开放敏感。这些结果表明,在盐胁迫条件下生长的agb1植株中观察到的更大蒸腾作用可能不是由Na(+) 对气孔孔径的不同基因型直接效应介导的。
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