Sodium toxicity and potassium insufficient are important factors affecting the growth and development of soybean in saline soil. As the capacity of plants to maintain a high cytosolic, K^+/Na^+ ratio is the key dete...Sodium toxicity and potassium insufficient are important factors affecting the growth and development of soybean in saline soil. As the capacity of plants to maintain a high cytosolic, K^+/Na^+ ratio is the key determinant of tolerance under salt stress. The aims of the present study were to identify and analyse expression patterns of the soybean K^+ efflux antiporter(KEA) gene and Na^+/H^+ antiporter(NHX) gene family, and to explore their roles under abiotic stress. As a result, 12 soybean Gm KEAs genes and 10 soybean Gm NHXs genes were identified and analyzed from soybean genome. Interestingly, the novel soybean KEA gene Glyma16g32821 which encodes 11 transmembrane domains were extremely up-regulated and remained high level until 48 h in root after the excessive potassium treatment and lack of potassium treatment, respectively. The novel soybean NHX gene Glyma09g02130 which encodes 10 transmembrane domains were extremely up-regulated and remained high level until 48 h in root with Na Cl stress. Imaging of subcellular locations of the two new Glyma16g32821-GFP and Glyma09g02130-GFP fusion proteins indicated all plasma membrane localizations of the two novel soybean genes. The 3D structures indicated that the two soybean novel proteins Glyma09g02130(NHX) and Glyma16g32821(KEA) all belong to the cation/hydrogen antiporter family.展开更多
Populus euphratica and Populuspruinosa, sister species in the Turanga Section (Salicaceae), growing in semi-arid saline areas are known for their high salinity tolerance. In this study, by combining growth level wit...Populus euphratica and Populuspruinosa, sister species in the Turanga Section (Salicaceae), growing in semi-arid saline areas are known for their high salinity tolerance. In this study, by combining growth level with Na+ and K+ contents, the expression level of vacuolar Na+/H+ antiporters was investigated for NaCl-induced changes in P. euphratica and t3. pru- inosa calli. Compared to R euphratica, P. pruinosa calli grew well in 200 mM NaC1 stress from 14. to 21 days. Increasing the stressed time caused an increase in Na+ content concomitant with a decrease in K+ content in P. euphratica calli, whereas, with the presence of 200 mM NaCI, K+ content has a less increase in 14 and 21 days than in 7 days which was detected in R pruinosa calli. The transcript levels of six genes coding for NHX-type Na+/H+ antiporters suggest that vacuolar NHX1-NHX6 antiporters play important roles in responding to salt stress in R pruinosa. Our data suggest that there exists a higher salt tolerance for P. pruinosa than P. euphratica at the cellular level, Na+ avoidance or accumulation is observed in cellular compartments, and that expression of NHX antiporters is linked to the accumulator phenotype.展开更多
Cation exchangers (CAXs) belong to the cation/Ca2+exchanger superfamily which have been extensively investigated in plant tonoplasts over the last decade. Recently, the roles of CAXs involved in heavy metal accumul...Cation exchangers (CAXs) belong to the cation/Ca2+exchanger superfamily which have been extensively investigated in plant tonoplasts over the last decade. Recently, the roles of CAXs involved in heavy metal accumulation and tolerance in plants have been studied for phytoremediation and food security. In this mini review, we summarize the roles of the Ca2+/H+ antiporter in Ca2+ signal transduction, maintaining ion homeostasis and sequestering heavy metals into the vacuole. Moreover, we present a possible role of the plasma membrane Ca2+/H+ antiporter in heavy metal detoxification.展开更多
Salt stress contains osmotic and ionic stress, while iso-osmotic polyethylene glycol (PEG) has only osmotic stress. This study aimed to compare the different effects on the activity of H+-ATPase, proton pump and Na...Salt stress contains osmotic and ionic stress, while iso-osmotic polyethylene glycol (PEG) has only osmotic stress. This study aimed to compare the different effects on the activity of H+-ATPase, proton pump and Na+/H+antiport in Malus seedlings between osmotic and ionic stress. Species of salt tolerant Malus zumi, middle salt tolerant Malus xiaojinensis and salt sensitive Malus baccata were used as experimental materials. Malus seedlings were treated with NaCl and iso-osmotic PEG stress. The activity of H+-ATPase, proton pump and Na+/H+antiport of plasmolemma and tonoplast in Malus seedlings were obviously increased under salt stress, and those in salt-tolerant species increased more. Under the same NaCl concentration, the activity of H+-ATPase, proton pump and Na+/H+antiport of plasmolemma and tonoplast in salt-tolerant species were all obviously higher than those in salt-sensitive one. Higher Na+/H+antiport activity of plasmolemma and tonoplast in salt-tolerant species could help to extrude and compartmentalize sodium in roots under salt stress. The ascent rate of activity of H+-ATPase, proton pump and Na+/H+antiport in Malus seedlings under the three salt concentration stress was all obviously higher than that under the iso-osmotic PEG stress. It indicated that the sodium ion effect had more stimulation on the activity of H+-ATPase, proton pump and Na+/H+antiport in salt-tolerant species, and salt-tolerant species has higher capability of sodium extrusion and compartmentalization in roots and is therefore more salt tolerant.展开更多
The liver has many significant functions,such as detoxification,the urea cycle,gluconeogenesis,and protein synthesis.Systemic diseases,hypoxia,infections,drugs,and toxins can easily affect the liver,which is extremely...The liver has many significant functions,such as detoxification,the urea cycle,gluconeogenesis,and protein synthesis.Systemic diseases,hypoxia,infections,drugs,and toxins can easily affect the liver,which is extremely sensitive to injury.Systemic infection of severe acute respiratory syndrome coronavirus 2 can cause liver damage.The primary regulator of intracellular pH in the liver is the Na+/H+exchanger(NHE).Physiologically,NHE protects hepatocytes from apoptosis by making the intracellular pH alkaline.Severe acute respiratory syndrome coronavirus 2 increases local angiotensin II levels by binding to angiotensinconverting enzyme 2.In severe cases of coronavirus disease 2019,high angiotensin II levels may cause NHE overstimulation and lipid accumulation in the liver.NHE overstimulation can lead to hepatocyte death.NHE overstimulation may trigger a cytokine storm by increasing proinflammatory cytokines in the liver.Since the release of proinflammatory cytokines such as interleukin-6 increases with NHE activation,the virus may indirectly cause an increase in fibrinogen and D-dimer levels.NHE overstimulation may cause thrombotic events and systemic damage by increasing fibrinogen levels and cytokine release.Also,NHE overstimulation causes an increase in the urea cycle while inhibiting vitamin D synthesis and gluconeogenesis in the liver.Increasing NHE3 activity leads to Na+loading,which impairs the containment and fluidity of bile acid.NHE overstimulation can change the gut microbiota composition by disrupting the structure and fluidity of bile acid,thus triggering systemic damage.Unlike other tissues,tumor necrosis factor-alpha and angiotensin II decrease NHE3 activity in the intestine.Thus,increased luminal Na+leads to diarrhea and cytokine release.Severe acute respiratory syndrome coronavirus 2-induced local and systemic damage can be improved by preventing virus-induced NHE overstimulation in the liver.展开更多
1 Introduction Dunaliella Salina,which taxi Dunaliella,Volvocales,Chlorophyceae Chlorophyta,is unicell algae with double flagllum at top,and cup shaped chloroplast without cell wall.Dunaliella Salina is the most salt ...1 Introduction Dunaliella Salina,which taxi Dunaliella,Volvocales,Chlorophyceae Chlorophyta,is unicell algae with double flagllum at top,and cup shaped chloroplast without cell wall.Dunaliella Salina is the most salt tolerance eucaryotes.It can grow at the range of salt concentration展开更多
基金supported by the National Natural Science Foundation of China(31401407)the Natural Science Foundation of Jiangsu Province,China(BK2012374)+1 种基金the Open Project of the State Key Laboratory of Crop Genetics and Germplasm Enhancement,China(ZW2013007)the Jiangsu Science and Technology Support Program,China(BE2013350)
文摘Sodium toxicity and potassium insufficient are important factors affecting the growth and development of soybean in saline soil. As the capacity of plants to maintain a high cytosolic, K^+/Na^+ ratio is the key determinant of tolerance under salt stress. The aims of the present study were to identify and analyse expression patterns of the soybean K^+ efflux antiporter(KEA) gene and Na^+/H^+ antiporter(NHX) gene family, and to explore their roles under abiotic stress. As a result, 12 soybean Gm KEAs genes and 10 soybean Gm NHXs genes were identified and analyzed from soybean genome. Interestingly, the novel soybean KEA gene Glyma16g32821 which encodes 11 transmembrane domains were extremely up-regulated and remained high level until 48 h in root after the excessive potassium treatment and lack of potassium treatment, respectively. The novel soybean NHX gene Glyma09g02130 which encodes 10 transmembrane domains were extremely up-regulated and remained high level until 48 h in root with Na Cl stress. Imaging of subcellular locations of the two new Glyma16g32821-GFP and Glyma09g02130-GFP fusion proteins indicated all plasma membrane localizations of the two novel soybean genes. The 3D structures indicated that the two soybean novel proteins Glyma09g02130(NHX) and Glyma16g32821(KEA) all belong to the cation/hydrogen antiporter family.
基金Financial support for this research was provided by the Program for New Century Excellent Talents in the Ministry of Education in China(NCET-09-0446),NSFC(31370396,30800865) and lzujbky-2012-k22 to YuXia Wu
文摘Populus euphratica and Populuspruinosa, sister species in the Turanga Section (Salicaceae), growing in semi-arid saline areas are known for their high salinity tolerance. In this study, by combining growth level with Na+ and K+ contents, the expression level of vacuolar Na+/H+ antiporters was investigated for NaCl-induced changes in P. euphratica and t3. pru- inosa calli. Compared to R euphratica, P. pruinosa calli grew well in 200 mM NaC1 stress from 14. to 21 days. Increasing the stressed time caused an increase in Na+ content concomitant with a decrease in K+ content in P. euphratica calli, whereas, with the presence of 200 mM NaCI, K+ content has a less increase in 14 and 21 days than in 7 days which was detected in R pruinosa calli. The transcript levels of six genes coding for NHX-type Na+/H+ antiporters suggest that vacuolar NHX1-NHX6 antiporters play important roles in responding to salt stress in R pruinosa. Our data suggest that there exists a higher salt tolerance for P. pruinosa than P. euphratica at the cellular level, Na+ avoidance or accumulation is observed in cellular compartments, and that expression of NHX antiporters is linked to the accumulator phenotype.
基金supported by grants from the National Science Foundation of China (Grant No.20977084)the Natural Science Foundation of Zhejiang Province,China (Grant No. R507719)a Project of the National Key Basic Research and Development of China (Grant No. 2007CB109305)
文摘Cation exchangers (CAXs) belong to the cation/Ca2+exchanger superfamily which have been extensively investigated in plant tonoplasts over the last decade. Recently, the roles of CAXs involved in heavy metal accumulation and tolerance in plants have been studied for phytoremediation and food security. In this mini review, we summarize the roles of the Ca2+/H+ antiporter in Ca2+ signal transduction, maintaining ion homeostasis and sequestering heavy metals into the vacuole. Moreover, we present a possible role of the plasma membrane Ca2+/H+ antiporter in heavy metal detoxification.
基金the financial support from the National Natural Science Foundation of China (39740027)the Special Fund for Agro-Scientific Research in the Public Interest of China (201203075)
文摘Salt stress contains osmotic and ionic stress, while iso-osmotic polyethylene glycol (PEG) has only osmotic stress. This study aimed to compare the different effects on the activity of H+-ATPase, proton pump and Na+/H+antiport in Malus seedlings between osmotic and ionic stress. Species of salt tolerant Malus zumi, middle salt tolerant Malus xiaojinensis and salt sensitive Malus baccata were used as experimental materials. Malus seedlings were treated with NaCl and iso-osmotic PEG stress. The activity of H+-ATPase, proton pump and Na+/H+antiport of plasmolemma and tonoplast in Malus seedlings were obviously increased under salt stress, and those in salt-tolerant species increased more. Under the same NaCl concentration, the activity of H+-ATPase, proton pump and Na+/H+antiport of plasmolemma and tonoplast in salt-tolerant species were all obviously higher than those in salt-sensitive one. Higher Na+/H+antiport activity of plasmolemma and tonoplast in salt-tolerant species could help to extrude and compartmentalize sodium in roots under salt stress. The ascent rate of activity of H+-ATPase, proton pump and Na+/H+antiport in Malus seedlings under the three salt concentration stress was all obviously higher than that under the iso-osmotic PEG stress. It indicated that the sodium ion effect had more stimulation on the activity of H+-ATPase, proton pump and Na+/H+antiport in salt-tolerant species, and salt-tolerant species has higher capability of sodium extrusion and compartmentalization in roots and is therefore more salt tolerant.
文摘The liver has many significant functions,such as detoxification,the urea cycle,gluconeogenesis,and protein synthesis.Systemic diseases,hypoxia,infections,drugs,and toxins can easily affect the liver,which is extremely sensitive to injury.Systemic infection of severe acute respiratory syndrome coronavirus 2 can cause liver damage.The primary regulator of intracellular pH in the liver is the Na+/H+exchanger(NHE).Physiologically,NHE protects hepatocytes from apoptosis by making the intracellular pH alkaline.Severe acute respiratory syndrome coronavirus 2 increases local angiotensin II levels by binding to angiotensinconverting enzyme 2.In severe cases of coronavirus disease 2019,high angiotensin II levels may cause NHE overstimulation and lipid accumulation in the liver.NHE overstimulation can lead to hepatocyte death.NHE overstimulation may trigger a cytokine storm by increasing proinflammatory cytokines in the liver.Since the release of proinflammatory cytokines such as interleukin-6 increases with NHE activation,the virus may indirectly cause an increase in fibrinogen and D-dimer levels.NHE overstimulation may cause thrombotic events and systemic damage by increasing fibrinogen levels and cytokine release.Also,NHE overstimulation causes an increase in the urea cycle while inhibiting vitamin D synthesis and gluconeogenesis in the liver.Increasing NHE3 activity leads to Na+loading,which impairs the containment and fluidity of bile acid.NHE overstimulation can change the gut microbiota composition by disrupting the structure and fluidity of bile acid,thus triggering systemic damage.Unlike other tissues,tumor necrosis factor-alpha and angiotensin II decrease NHE3 activity in the intestine.Thus,increased luminal Na+leads to diarrhea and cytokine release.Severe acute respiratory syndrome coronavirus 2-induced local and systemic damage can be improved by preventing virus-induced NHE overstimulation in the liver.
基金supported by Natioal Natural Science Foundation of China(40772065)the Open project from the key lab of saline lake resources and environments,MLR (2010-SYS-06)
文摘1 Introduction Dunaliella Salina,which taxi Dunaliella,Volvocales,Chlorophyceae Chlorophyta,is unicell algae with double flagllum at top,and cup shaped chloroplast without cell wall.Dunaliella Salina is the most salt tolerance eucaryotes.It can grow at the range of salt concentration