Comparative Study on Growth Performance of Transgenic(Over-Expressed OsNHX1) and Wild-Type Nipponbare under Different Salinity Regimes 被引量：3

Comparative Study on Growth Performance of Transgenic(Over-Expressed OsNHX1) and Wild-Type Nipponbare under Different Salinity Regimes

下载PDF

导出

摘要 Transgenic Nipponbare which over-expressed a Na＋/H~ antiporter gene OsNHX1 was used to compare its growth performance, water status and photosynthetic efficiency with its wild type under varying salinity regimes. Chlorophyll content, quantum yield and photosynthetic rate were measured to assess the impact of salinity stress on photosynthetic efficiency for transgenic and wild-type Nipponbare. Effects of salinity on water status and gas exchange to both lines were studied by measuring water use efficiency, instantaneous transpiration rate and stomatal conductance. Dry shoot weight and leaf area were determined after three months of growth to assess the impacts of salinity on the growth of those two lines. Our study showed that both lines were affected by salinity stress, however, the transgenic line showed higher photosynthetic efficiency, better utilization of water, and better growth due to low transpiration rate and stomatal conductance. Reduction of photosynthetic efficiency exhibited by the wild-type Nipponbare was correlated to its poor growth under salinity stress. Transgenic Nipponbare which over-expressed a Na＋/H~ antiporter gene OsNHX1 was used to compare its growth performance, water status and photosynthetic efficiency with its wild type under varying salinity regimes. Chlorophyll content, quantum yield and photosynthetic rate were measured to assess the impact of salinity stress on photosynthetic efficiency for transgenic and wild-type Nipponbare. Effects of salinity on water status and gas exchange to both lines were studied by measuring water use efficiency, instantaneous transpiration rate and stomatal conductance. Dry shoot weight and leaf area were determined after three months of growth to assess the impacts of salinity on the growth of those two lines. Our study showed that both lines were affected by salinity stress, however, the transgenic line showed higher photosynthetic efficiency, better utilization of water, and better growth due to low transpiration rate and stomatal conductance. Reduction of photosynthetic efficiency exhibited by the wild-type Nipponbare was correlated to its poor growth under salinity stress.

作者 Nurul Kahrani ISHAK Zohrah SULAIMAN Kushan U.TENNAKOON

机构地区 Environmental and Life Sciences Institut Teknologi Brunei

出处《Rice science》 SCIE CSCD 2015年第6期275-282,共8页 水稻科学（英文版）

基金 funded by University Brunei Darussalam’s Graduate Research Scholarship

关键词 growth performance salinity stress Na＋/H＋ antiporter gene OsNHX1 transgenic rice photosynthetic efficiency water status growth performance salinity stress Na＋/H＋ antiporter gene OsNHX1 transgenic rice photosynthetic efficiency water status

分类号 S511 [农业科学—作物学] S828.5 [农业科学—畜牧学]

引文网络
相关文献

参考文献46

1Andriolo J L, Luz G L D, Witter M H, Godoi R D S, Barros G T, Bortolotto O C. 2005. Growth and yield of lettuce plants under salinity. Hort Bras, 23(4): 931-934.
2Aslam M, Qureshi R H, Ahmed N. 1993. A rapid screening technique for salt tolerance in rice (Oryza sativa L.). Plant Soil, 150(1): 99-107.
3Bao A K, Wang Y W, Xi J J, Liu C, Zhang J L, Wang S M. 2014. Co-expression of xerophyte Zygophyllum xanthoxylum ZxNHX and ZxVPI-1 enhances salt and drought tolerance in transgenic Lotus corniculatus by increasing cations accumulation. Funet Plant Biol, 41(2): 203-214.
4Bjorkman O, Demmig B. 1987. Photon yield of 02 evolution and chlorophyll fluorescence characteristics at 77 K among vascular plants of diverse origins. Planta, 170: 489-504.
5Blumwald E, Aharon G S, Apse M P. 2000. Sodium transport in plant cells. Biochim Biophys Aeta Biom, 1465:140-151.
6Bresson J, Vasseur F, Dauzat M, Koch G, Granier C, Vile D. 2015. Quantifying spatial heterogeneity of chlorophyll fluorescence during plant growth and in response to water stress. Plant Methods, 11(1): 23.
7Cha-um S, Trakulyingcharoen T, Smitamana P, Kirdmanee C. 2009. Salt tolerance in two rice cultivars differing salt tolerant abilities in responses to iso-osmotic stress. Aust J Crop Sci, 3:221-230.
8Chen H, An R, Tang J H, Cui X H, Hao F S, Chen J, Wang X C. 2007. Over-expression of a vacuolar Na+/H+ antiporter gene improves salt tolerance in an upland rice. Mol Breeding, 19: 215-225.
9Chen M X, Cao L, Song X Z, Wang X Y, Qian Q P, Liu W. 2014. Effect of iron plaque and selenium on cadmium uptake and translocation in rice seedlings (Oryza sativa) grown in solution culture. Int J Agric Biol, 16(6): 1159-1164.
10Chowdhury M A M, Moseki B, Bowling D J F. 1995. A method for screening rice plants for salt tolerance. Plant Soil, 171:317-322.

同被引文献13

1李娟,章明清,林琼,陈子冲,谢光球,彭嘉桂,熊德中.钾、钙、镁交互作用对烤烟生长和养分吸收的影响[J].安徽农业大学学报,2005,32(4):529-533. 被引量：46
2Deyun Qiu Jun Xiao Weibo Xie Hongbo Liu Xianghua Li Lizhong Xiong Shiping Wang.Rice Gene Network Inferred from Expression Profiling of Plants Overexpressing OsWRKY13, a Positive Regulator of Disease Resistance[J].Molecular Plant,2008,1(3):538-551. 被引量：40
3王佳丽,黄贤金,钟太洋,陈志刚.盐碱地可持续利用研究综述[J].地理学报,2011,66(5):673-684. 被引量：388
4吴霞,吴长艾,上官小霞,马燕斌,翟晓菊,李燕娥.转耐盐基因GhNHX1棉花株系耐盐性初步鉴定[J].山西农业科学,2012,40(1):16-17. 被引量：9
5HUANG Ying,ZHANG Xiao-xia,LI Yi-hong,DING Jian-zhou,DU Han-mei,ZHAO Zhuo,ZHOU Li-na,LIU Chan,GAO Shi-bin,CAO Mo-ju,LU Yan-li,ZHANG Su-zhi.Overexpression of the Suaeda salsa SsNHX1 gene confers enhanced salt and drought tolerance to transgenic Zea mays[J].Journal of Integrative Agriculture,2018,17(12):2612-2623. 被引量：9
6唐秀英,万建林,王会民.差异蛋白质组学在水稻响应逆境胁迫中的应用[J].江西农业大学学报,2014,36(6):1196-1201. 被引量：4
7谢留杰,段敏,潘晓飚,唐兴国,朱长志,黄善军.不同类型水稻品系苗期和全生育期耐盐性鉴定与分析[J].江西农业大学学报,2015,37(3):404-410. 被引量：21
8徐璐,郭善利,尹海波.Na^+/H^+逆向转运蛋白与植物耐盐性研究[J].湖北农业科学,2016,55(11):2727-2730. 被引量：7
9安国勇,董发才,胡楠,宋纯鹏.盐胁迫条件下钙对小麦根细胞膜电位和钾离子吸收的影响[J].河南大学学报（自然科学版）,2002,32(3):25-28. 被引量：17
10卢世雄,许春苗,何红红,梁国平,王萍,陈佰鸿,毛娟.葡萄NHX基因家族的鉴定和表达分析[J].果树学报,2019,36(3):266-276. 被引量：10

引证文献3

1吴延寿,王萍,熊运华,尹建华,陈竹林.钙对盐胁迫水稻生长和营养元素吸收的影响[J].江西农业大学学报,2016,38(6):1023-1028. 被引量：7
2Inja Naga Bheema Lingeswara REDDY,Beom-Ki KIM,In-Sun YOON,Kyung-Hwan KIM,Taek-Ryoun KWON.Salt Tolerance in Rice: Focus on Mechanisms and Approaches[J].Rice science,2017,24(3):123-144. 被引量：15
3李淼,李桂祥,刘伟,高晓兰,王孝友,张安宁.桃NHX基因家族的全基因组鉴定与表达分析[J].山东农业科学,2021,53(12):8-16. 被引量：1

二级引证文献23

1廖莎,谭雪明,李木英,胡凯,潘晓华,石庆华.稻草基质育秧不同芸苔素内酯处理对水稻秧苗生长的影响[J].江西农业大学学报,2017,39(5):851-858. 被引量：9
2高宁宁,常高正,康利允,李晓慧,梁慎,李海伦,赵卫星.基于SRAP标记的甜瓜耐盐种质资源遗传多样性分析[J].西北植物学报,2019,39(1):68-75. 被引量：7
3Wilson F.AALA Jr,Glenn B.GREGORIO.Morphological and Molecular Characterization of Novel Salt-Tolerant Rice Germplasms from the Philippines and Bangladesh[J].Rice science,2019,26(3):178-188.
4LIU Ling,CHEN Jin,TAN Yanning,ZHOU Tianshun,OUYANG Ning,ZENG Jia,YUAN Dingyang,DUAN Meijuan.Increasing Fatty Acids in Rice Root Improves Silence of Rice Seedling to Salt Stress[J].Rice science,2019,26(6):339-342. 被引量：2
5孟楠,王萌,雷小琴,陈莉,郑涵,陈世宝.基于物种敏感性分布(SSD)的耐盐与Pb低吸收小麦筛选研究及应用[J].应用基础与工程科学学报,2019,37(5):947-956. 被引量：2
6黄洁,白志刚,钟楚,金千瑜,朱练峰,曹小闯,朱春权,张均华.水稻耐盐生理及分子调节机制[J].核农学报,2020,34(6):1359-1367. 被引量：23
7Tarun Bhatt,Aditi Sharma,Sanjeev Puri,Anu Priya Minhas.Salt Tolerance Mechanisms and Approaches:Future Scope of Halotolerant Genes and Rice Landraces[J].Rice science,2020,27(5):368-383. 被引量：7
8殷萍,陈秋生,张强,刘烨潼,张玺.微波消解—电感耦合等离子体质谱法测定水稻各部位15种元素的含量[J].天津农业科学,2020,26(8):56-60. 被引量：4
9卢维宏,张乃明,苏友波,李懋松,熊润忠,秦太峰.联合施肥对复合污染农田水稻As、Cd吸收的影响[J].农业环境科学学报,2020,39(10):2217-2226. 被引量：9
10谢换换,叶志鸿.湿地植物根形态结构和泌氧与盐和重金属吸收、积累、耐性关系的研究进展[J].生态学杂志,2021,40(3):864-875. 被引量：16

1郭大龙,吴正景,郑玉萍,韩璐,齐庆智.苦瓜SRAP反应体系的建立与优化[J].安徽农业科学,2008,36(18):7583-7585. 被引量：19
2Muaz M.Abdellatif,Bashir Salim,Awad A.Ibrahim,Tigani Asil,Abdelmalik I.Khalafalla.Analysis of TK and C18L Genes of Wild-type and Cell Culture Passaged Camelpox Virus[J].Virologica Sinica,2013,28(4):239-241.
3朱泽远,杨杰,施用晖,乐国伟.SYBR GreenⅠ实时荧光定量PCR法测定中华绒螯蟹基因组大小[J].江苏农业科学,2007,35(5):164-166. 被引量：3
4高林,陈春丽.NaCl胁迫对水稻品种中花11幼苗根系生长发育的影响[J].种子,2012,31(7):7-12. 被引量：3
5Yao Na,Lai Zhiqiang,Shi Jing,Yang Qisheng,Zeng Fanquan.Effect of Pennisetum purpureum Schum cv. Guiminyin on Growth Performance of Geese[J].Animal Husbandry and Feed Science,2016,8(6):361-363.
6Peng Shen Rong Wang Wen Jing Wenhua Zhang.Rice Phospholipase Dαis Involved in Salt Tolerance by the Mediation of H^+-ATPase Activity and Transcription[J].Journal of Integrative Plant Biology,2011,53(4):289-299. 被引量：9
7MinZHUO Zhan-PengHUANG HuiZHOU Liang-HuQU.SESSION 5： rRNA ＆ tRNA——Mapping and Comparative Study of 2＇-O-Ribose Methylated Nucleotides in Rice 18S rRNA[J].Acta Biochimica et Biophysica Sinica,2004,36(2):158-159.
8HE Jun-Yu,ZHU Cheng,REN Yan-Fang,YAN Yu-Ping,CHENG Chang,JIANG De-An,SUN Zong-Xiu.Uptake, Subcellular Distribution, and Chemical Forms of Cadmium in Wild-Type and Mutant Rice[J].Pedosphere,2008,18(3):371-377. 被引量：37
9严定春.不同栽培方式下水稻形态发生比较研究(英文)[J].Agricultural Science & Technology,2012,13(11):2424-2428.
10侯桂兰,李云侠,张军辉,陈颖.干旱胁迫对冷季型草坪草地上部影响的研究[J].东北农业大学学报,1999,30(3):249-253. 被引量：12

Rice science

2015年第6期

浏览历史

内容加载中请稍等...

Comparative Study on Growth Performance of Transgenic(Over-Expressed OsNHX1) and Wild-Type Nipponbare under Different Salinity Regimes 被引量：3

参考文献46

同被引文献13

引证文献3

二级引证文献23

相关作者

相关机构

相关主题

浏览历史