胁迫应答,Stress response
1)Stress response胁迫应答
1.ASR genes cloning and characterization,roles in stress response and fruit ripening are di.近年来从植物中发现了越来越多的受脱落酸、胁迫、成熟诱导表达的基因,这些 ASR(Abscisic acid, Stress and Ripening inducible)基因参与植物对冷、渗透压、脱落酸处理的胁迫应答已被证实,该类基因也参与植物生命活动的许多方面如果实发育、成熟等。
2.Rdr1 is a transcriptional repressor in budding yeast Saccharomyces cerevisiae,which was supposed to control pleiotropic drug resistance of cell and probably regulate genes involved in stress response.Rdr1是出芽酵母Saccharomyces cerevisiae的一个转录抑制因子,参与控制细胞的多重药物耐受性,并可能与细胞胁迫应答相关。
3.NO induces various processes in plants, including seed germination, root development, inflorescence initiation, stomatal closure and abiotic and biotic stress responses.此外,作为活跃的小分子信号,NO和活性氧相互依赖并相互影响,共同介导了植物的胁迫应答和激素响应过程。
英文短句/例句
1.Bioinformatics Analysis of Salt Overly Sensitive 5 Gene in Rice(Oryza sativa)盐胁迫应答基因Ossos5的生物信息学分析
2.The Cloning and Expression Analysis of Salt Stress Responsive Gene in Yeast酵母盐胁迫应答基因的克隆及表达分析
3.Isolation and Characterization of Responsive Genes Involved in Adversity Stress in Leymus Multicaulis多枝赖草逆境胁迫应答基因的分离与鉴定
4.Analysis of Gene Expression of Brassica Napus under Low Phosphorus Condition;甘蓝型油菜低磷胁迫应答cDNA差异表达分析
5.Cloning and Sequence Analyses of cDNA Fragments Encoding Salt-responding Genes from Wheat;小麦盐胁迫应答基因cDNA的克隆与序列分析
6.Functional Analysis of AtPLC3 and AtPLC4 in Salt Stress Response of Arabidopsis Thaliana;拟南芥AtPLC3和AtPLC4参与盐胁迫应答的功能研究
7.The Screening and Function Analysis of Arabidopsis Osmotic Stress Responsible Genes;拟南芥渗透胁迫应答基因的筛选及功能分析
8.Cloning and Expression Analysis of Drought and Salt Resbonsive Gene in Alternanthera Philoxeroides;水花生干旱、盐胁迫应答基因的克隆及表达分析
9.Function of Nicotianamine Synthase Gene in Plant Iron Stress烟酰胺合成酶基因在植物铁胁迫应答反应中的功能
10.Cloning of Responsive Gene cDNA of Salt Stress from Wheat and Expression Analysis of Transgenic Tabacco;小麦盐胁迫应答基因的分离克隆及转基因烟草表达模式研究
11.Molecular Marker and Response Protein of Winter Wheat during Seedling Stage in the Water Stress Condition;冬小麦幼苗期水分胁迫应答蛋白及其分子标记的研究
12.Establishment of Embryogenic Transformation System in Wheat and Production of Transgenic Wheat with Salt-responsive Gene.;小麦成熟胚转化系统的建立与转盐胁迫应答基因植株的获得
13.Function Analysis of ERF Transcription Factors LeERF2、JERF2 in Responses to Abiotic Stresses;ERF转录因子LeERF2、JERF2在非生物胁迫应答中的功能分析
14.The Physiological Mechanisms of Alkalibacterium sp.F26 to Oxidative Stress;氧化胁迫下Alkalibacterium sp.F26的生理应答机制
15.Study on Pugionium Gaertn. Vernalization Characteristics and Reaction of Low-Temperature Stresson;沙芥属蔬菜低温胁迫生理应答及春化特性研究
16.Research Progress on Proteomics to Uncover Biotic Stress Tolerance Mechanisms in Plant植物应答生物胁迫的蛋白质组学研究进展
17.Advances on Proteomics of Plants Under Stresses植物应答逆境胁迫的蛋白质组学研究进展
18.Antioxidant Responses to NaCl Stress in Brassica Rapeseed Seedlings甘蓝型油菜幼苗对NaCl胁迫的抗氧化应答
相关短句/例句
salt stress responsive cDNA盐胁迫应答cDNA
3)stress_responsive genes胁迫应答基因
4)salt-responsive genes盐胁迫应答基因
5)Water Stress D-response protein水分胁迫D-应答蛋白
6)stress response胁迫响应
1.It concluded that information on biochemistry and molecular biology of PAHstress responses in plants was lacking,and the existing methods of plant-based bioremediation lack of biomass,pertinency,and efficiency.分析认为,目前的研究缺乏植物对PAHs胁迫响应的生物化学、分子机制的新途径,且现有的植物修复方法存在生物量较低、针对性不强、效率不高等缺点。
2.The R2R3 subfamily with two adjacent MYB domains contains the largest number of MYB genes,which plays various roles in many aspects,such as secondary metabolism,cell morphogenesis,stress responses,meristem formation and the cell cycle and so on.近年来,R2R3-MYB在植物逆境胁迫中的作用引起了广泛关注,本文综述了拟南芥R2R3-MYB蛋白在环境胁迫响应中作用的研究进展。
延伸阅读
水分胁迫水分胁迫water stress水分胁迫(wate:stress)植物水分散失l超过水分吸收t,使含水t下降,膨压降低.正常代谢失调的现象.植物除因土城中缺水引起水分胁迫外,干早、淹水、冰冻、高温或盐演条件等不良环境作用于植物体时,都可能引起水分胁迫.不同植物及品种对水分胁迫的敏感性不同,影响不一。在淹水条件下,有氧呼吸受抑制,影响水分吸收,也会导致细胞缺水失去膨压,冰冻引起细胞间隙结冰,特别是在严重冰冻后遇晴天,细胞间隙的冰晶体融化后又因燕腾大t失水,易引起水分失去平衡而姜蔫.高温及盐演条件下亦易引起植物水分代谢失去平衡,发生水分胁迫.干旱缺水引起的水分胁迫是最常见的,也是对植物产量影响最大的.水分胁迫对植物祝谢的影响在植物水分亏缺时,反应最快的是细胞伸长生长受抑制,因为细胞膨压降低就使细胞伸长生长受阻,因而叶片较小,光合面积减小;随着胁迫程度的增高,水势明显降低,且细胞内脱落酸(ABA)含量增高,使净光合率亦随之下降,另一方面,水分亏缺时细胞合成过程减弱而水解过程加强,淀粉水解为糖,蛋白质水解形成氨基酸,水解产物又在呼吸中消耗;水分亏缺初期由于细胞内淀粉、蛋白质等水解产物增亥,吸呼底物增加,促进了呼吸,时间稍长,呼吸底物减少,呼吸速度即降低,且因氧化碑酸化解联,形成无效呼吸,导致正常代谢进程紊乱,代谢失调。水分胁迫对植物的严重影!栩王由于水分胁迫引起植物脱水,导致细胞膜结构破坏.在正常情况下,由于细胞膜结构的存在,植物细胞内有一定的区域化(compartmentation),不同的代谢过程在不同的部位进行而彼此又相互联系;如果膜结构破坏就引起代谢紊乱。不同植物或品种对水分胁迫的反应不同植物或品种在干早条件下的反应不同.早生植物长期生活在干早的环境中,在生理或形态上具有一定的适应特性.例如具有强大的根系,燕腾量高时.可吸收深层土中的水分,这是一种积极的抗旱方式。有的角质层发达,避免水分过多散失或气孔夜开昼闭等避免水分散失.如仙人掌,白天气孔关闭减少水分消耗量,夜间气孔张开,吸收的CO:,固定于苹果酸中,白天又释放出CO:用于光合作用中。栽培植物的抗早性虽不及早生植物,但不同植物或品种之间对水分胁迫的敏感性亦不同,一般C.植物比C:植物的水分利用率高,抗早性亦较强,C;植物中高粱的抗旱性又比玉米强。在水分亏缺时,高粱叶片中的ABA含量明显低于玉米,干早后复水,高粱亦较玉米易于恢复正常。在生产上应注意合理施肥,提高植物杭早性的间题,例如钾有渗透调节功能,在施肥时应适当配合钾肥,发挥其渗透调节功能,提高作物抗早性.(饶立华)
