Adem Getnet D, Roy Stuart J, Huang Yuqing, Chen Zhong-Hua, Wang Feifei, Zhou Meixue, Bowman John P, Holford Paul, Shabala Sergey
School of Land and Food, University of Tasmania, Private Bag 54, Hobart, Tas. 7001, Australia.
Australian Centre for Plant Functional Genomics, Private Mail Bag 1, Glen Osmond, SA 5064, Australia.
Funct Plant Biol. 2017 Nov;44(12):1147-1159. doi: 10.1071/FP17133.
Salinity is a global problem affecting agriculture that results in an estimated US$27 billion loss in revenue per year. Overexpression of vacuolar ATPase subunits has been shown to be beneficial in improving plant performance under saline conditions. Most studies, however, have not shown whether overexpression of genes encoding ATPase subunits results in improvements in grain yield, and have not investigated the physiological mechanisms behind the improvement in plant growth. In this study, we constitutively expressed Arabidopsis Vacuolar ATPase subunit C (AtVHA-C) in barley. Transgenic plants were assessed for agronomical and physiological characteristics, such as fresh and dry biomass, leaf pigment content, stomatal conductance, grain yield, and leaf Na+ and K+ concentration, when grown in either 0 or 300mM NaCl. When compared with non-transformed barley, AtVHA-C expressing barley lines had a smaller reduction in both biomass and grain yield under salinity stress. The transgenic lines accumulated Na+ and K+ in leaves for osmotic adjustment. This in turn saves energy consumed in the synthesis of organic osmolytes that otherwise would be needed for osmotic adjustment.
盐度是一个影响农业的全球性问题,每年造成的收入损失估计达270亿美元。液泡ATP酶亚基的过表达已被证明有助于改善盐胁迫条件下的植物性能。然而,大多数研究尚未表明编码ATP酶亚基的基因过表达是否能提高谷物产量,也未探究植物生长改善背后的生理机制。在本研究中,我们在大麦中组成型表达拟南芥液泡ATP酶亚基C(AtVHA-C)。当在0或300mM NaCl中生长时,对转基因植物的农艺和生理特性进行了评估,如鲜重和干重、叶片色素含量、气孔导度、谷物产量以及叶片Na+和K+浓度。与未转化的大麦相比,在盐胁迫下,AtVHA-C表达大麦品系的生物量和谷物产量下降幅度较小。转基因品系在叶片中积累Na+和K+用于渗透调节。这反过来节省了合成有机渗透剂所需消耗的能量,否则这些能量将用于渗透调节。
