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Manoj Banjara,Longfu Zhu,Guoxin Shen,Paxton Payton,Hong Zhang 한국식물생명공학회 2012 Plant biotechnology reports Vol.6 No.1
Salinity is a major environmental stress that affects agricultural productivity worldwide. One approach to improving salt tolerance in crops is through high expression of the Arabidopsis gene AtNHX1, which encodes a vacuolar sodium/proton antiporter that sequesters excess sodium ion into the large intracellular vacuole. Sequestering cytosolic sodium into the vacuoles of plant cells leads to a low level of sodium in cytosol, which minimizes the sodium toxicity and injury to important enzymes in cytosol. In the meantime, the accumulation of sodium in vacuoles restores the correct osmolarity to the intracellular milieu, which favors water uptake by plant root cells and improves water retention in tissues under soils that are high in salt. To improve the yield and quality of peanut under high salt conditions, AtNHX1 was introduced into peanut plants through Agrobacterium-mediated transformation. The AtNHX1-expressing peanut plants displayed increased tolerance of salt at levels up to 150 mM NaCl. When compared to wild-type plants, AtNHX1-expressing peanut plants suffered less damage, produced more biomass, contained more chlorophyll, and maintained higher photosynthetic rates under salt conditions. These data indicate that AtNHX1 can be used to enhance salt tolerance in peanut.
Qin, Hua,Gu, Qiang,Kuppu, Sundaram,Sun, Li,Zhu, Xunlu,Mishra, Neelam,Hu, Rongbin,Shen, Guoxin,Zhang, Junling,Zhang, Yizheng,Zhu, Longfu,Zhang, Xianlong,Burow, Mark,Payton, Paxton,Zhang, Hong 한국식물생명공학회 2013 Plant biotechnology reports Vol.7 No.3
The Arabidopsis gene AVP1 encodes an $H^+$-pyrophosphatase that functions as a proton pump at the vacuolar membranes, generating a proton gradient across vacuolar membranes, which serves as the driving force for many secondary transporters on vacuolar membranes such as $Na^+/H^+$-antiporters. Overexpression of AVP1 could improve drought tolerance and salt tolerance in transgenic plants, suggesting a possible way in improving drought and salt tolerance in crops. The AVP1 was therefore introduced into peanut by Agrobacterium-mediated transformation. Analysis of AVP1-expressing peanut indicated that AVP1-overexpression in peanut could improve both drought and salt tolerance in greenhouse and growth chamber conditions, as AVP1-overexpressing peanuts produced more biomass and maintained higher photosynthetic rates under both drought and salt conditions. In the field, AVP1-overexpressing peanuts also outperformed wild-type plants by having higher photosynthetic rates and producing higher yields under low irrigation conditions.
Huaqin Sun,Qiang Gu,Sundaram Kuppu,Li Sun,Xunlu Zhu,Neelam Mishra,Rongbin Hu,Guoxin Shen,Junling Zhang,Yizheng Zhang,Longfu Zhu,Xianlong Zhang,Mark Burow,Paxton Payton,Hong Zhang 한국식물생명공학회 2013 Plant biotechnology reports Vol.7 No.3
The Arabidopsis gene AVP1 encodes an H?-pyrophosphatase that functions as a proton pump at thevacuolar membranes, generating a proton gradient acrossvacuolar membranes, which serves as the driving force formany secondary transporters on vacuolar membranes suchas Na?/H?-antiporters. Overexpression of AVP1 couldimprove drought tolerance and salt tolerance in transgenicplants, suggesting a possible way in improving drought andsalt tolerance in crops. The AVP1 was therefore introducedinto peanut by Agrobacterium-mediated transformation. Analysis of AVP1-expressing peanut indicated that AVP1-overexpression in peanut could improve both droughtand salt tolerance in greenhouse and growth chamberconditions, as AVP1-overexpressing peanuts producedmore biomass and maintained higher photosynthetic ratesunder both drought and salt conditions. In the field, AVP1-overexpressing peanuts also outperformed wild-type plantsby having higher photosynthetic rates and producing higheryields under low irrigation conditions.