多胺与环境胁迫关系研究进展

多胺是植物对胁迫响应的重要物质,可以抵消胁迫引起的负效应.多胺预处理可缓解胁迫引起的伤害,通过转基因技术过量表达多胺可提高植物胁迫耐性.本文综述了生物胁迫和非生物胁迫条件下,多胺的合成、代谢、功能及其作为抗氧化剂减少胁迫诱导氧化损伤的研究现状.重点综述了病虫胁迫、盐胁迫、重金属胁迫、渗透胁迫,也简要的综述了其它胁迫如低氧胁迫、冷胁迫、酸胁迫、辐射胁迫等条件下植物体内多胺合成的变化及功能.     

氮代谢参与植物逆境抵抗的作用机理研究进展

近年来,植物所受到的诸如干旱、盐、高温、低氧、重金属胁迫和营养元素缺乏等环境胁迫越来越多,严重影响了植物的生长发育及作物的质量和产量。氮素是植物生长发育所需的必需营养元素,同时也是核酸、蛋白质和叶绿素的重要组成成分,其代谢过程与植物抵抗逆境的能力息息相关。氮代谢是指植物对氮素的吸收、同化和利用的全过程,是植物体内基础代谢途径之一。氮代谢主要从氮素吸收、同化及氨基酸代谢等方面参与植物的抗逆性,并通过调节离子吸收和转运、稳定细胞形态和蛋白质结构、维持激素平衡和细胞代谢水平、减少体内活性氧(reactive oxygen species,ROS)生成以及促进叶绿素合成等生理机制来影响植物抵抗非生物胁迫的能力。因此,提高植物在逆境下的氮代谢水平是减轻外界胁迫对其损伤的一种潜在途径。该文从氮素同化的基本途径出发,分别阐述了氮代谢在干旱胁迫、盐胁迫和高温胁迫等多个方面的逆境抵抗过程中的作用机理,为氮代谢参与植物抗逆性研究提供了有利参考。     

外源γ-氨基丁酸（GABA）对低氧胁迫下甜瓜幼苗根系GABA代谢及氨基酸含量的影响

采用水培法,通过准确控制营养液溶氧浓度,研究了外源γ-氨基丁酸（GABA）对低氧胁迫0~8 d ‘西域一号’甜瓜幼苗根系GABA代谢及氨基酸含量的影响.结果表明：与通气对照相比,低氧处理的甜瓜幼苗正常生长受到严重抑制,其根系谷氨酸脱羧酶（GAD）、谷氨酸脱氢酶（GDH）、谷氨酸合成酶（GOGAT）、谷氨酰胺合成酶（GS）、丙氨酸氨基转移酶（ALT）、天门冬氨酸氨基转移酶（AST）活性以及GABA、丙酮酸、丙氨酸、天冬氨酸含量均显著提高,而谷氨酸和α 酮戊二酸含量在处理4~8 d均显著降低.与低氧处理相比,外源GABA处理有效缓解了低氧胁迫对幼苗根系生长的抑制作用,同时甜瓜根系内源GABA、谷氨酸、α-酮戊二酸、天冬氨酸含量显著提高,但GAD、GDH、GOGAT、GS、ALT、AST活性在整个处理过程中均显著降低,丙酮酸和丙氨酸含量也显著降低.低氧同时添加GABA和γ-乙烯基 γ-氨基丁酸（VGB）处理显著降低了低氧胁迫下GABA的缓解效应.低氧胁迫下外源GABA被植物根系吸收后,通过反馈抑制GAD活性维持较高的Glu含量,保持植物体内碳、氮代谢平衡,维持正常生理代谢,从而缓解低氧胁迫对甜瓜幼苗的伤害.     

外源钙对根际低氧胁迫下黄瓜幼苗ADH、LDH活性和同工酶的影响

以‘新泰密刺’黄瓜为材料,采用营养液栽培,外源使用Ca2+、钙离子通道抑制剂La3+与钙调素拮抗剂三氟拉嗪(TFP),研究了钙对根际低氧胁迫下黄瓜幼苗根系ADH、LDH活性和同工酶的影响。结果表明,低氧胁迫诱导产生了新的ADH和LDH同工酶条带。低氧胁迫下,ADH、LDH同工酶丰度和活性显著高于对照;外源增施Ca2+有利于Ca2+信号的形成和逆境信号的传递,营养液添加CaCl2缓解了低氧胁迫对黄瓜植株的伤害,ADH、LDH同工酶丰度和活性接近对照水平;La3+抑制Ca2+的吸收和体内运输,营养液添加LaCl3显著抑制了ADH和LDH同工酶丰度和酶活性,黄瓜幼苗植株生长受到抑制,生物量显著低于低氧处理,表明La3+加重了低氧胁迫对黄瓜幼苗植株的伤害;TFP抑制了低氧逆境胁迫信号的传递,营养液添加TFP抑制了ADH和LDH同工酶丰度和酶活性,ADH和LDH同工酶丰度和酶活性显著低于低氧处理,黄瓜幼苗植株生长受到抑制,黄瓜植株的低氧耐性降低。暗示外源Ca2+参与了低氧胁迫下黄瓜根系无氧呼吸代谢的调节,增强了Ca2+向植物体内的运输,缓解了低氧胁迫对黄瓜幼苗植株的伤害,增强了植物对低氧的耐性。     

植物应答非生物胁迫的代谢组学研究进展

代谢组学技术是研究植物代谢的理想平台, 通过现代检测分析技术对胁迫环境下植物中代谢产物进行定性和定量分析, 可以监测其随时间变化的规律。而各种组学平台包括基因组学、转录组学及代谢组学的整合, 更是一个强有力的工具箱, 将所获得的不同组学的信息联系起来, 有利于从整体研究生物系统对基因或环境变化的响应, 如可判断代谢物的变化是从哪一个层面开始发生的, 帮助人们揭开复杂的植物胁迫应答机制。该文对近期代谢组学技术及其与蛋白质组学、基因组学技术相结合探索植物应答非生物胁迫的研究进行了综述。代谢组学的应用, 拓展了对植物耐受非生物胁迫分子机制的认识, 开展更多这方面的研究, 再通过植物代谢组学、转录组学、蛋白质组学和基因组学整合, 有助于从整体水平上把握植物胁迫应答机制。     

植物淹水胁迫的生理学机制研究进展

淹水胁迫引起弱光环境,使气体扩散受限,叶片细胞膜脂过氧化加剧,体内保护酶系统受损,叶绿素降解,丙二醛含量积累,光合速率下降。为了适应淹水环境,植物通过生理生化机制的调节来保证淹水条件下的生命活动。如细胞通过调节渗透物质的含量来保持渗透势的平衡;细胞内各种抗氧化酶活性增加,以清除自由基,避免或者减轻细胞受到伤害;改变代谢途径和激素调节以保持能量储备和低的代谢速率。本文综述了淹水胁迫对细胞膜系统及功能、植物光合作用、植物呼吸、激素、生理代谢、基因调控的影响和淹水结束后植物的生理生态学变化,介绍了植物适应淹水胁迫的机制,并指出植物耐淹响应的分子机理,环境因素对淹没植物的影响,森林淹水胁迫的定位观测是今后需要研究的方面。     

外源γ-氨基丁酸对低氧胁迫下甜瓜幼苗活性氧代谢的影响

以甜瓜品种‘西域一号’幼苗为材料,采用营养液水培方法,设置正常通气(对照)、正常通气+GABA(5mmol.L-1)、低氧胁迫、低氧胁迫+GABA(5mmol.L-1)4个处理,研究了外源γ-氨基丁酸(GABA)对正常通气和低氧胁迫下甜瓜幼苗活性氧代谢的影响。结果表明:与正常通气处理相比,低氧胁迫处理导致甜瓜幼苗体内O2.-产生速率和H2O2、MDA含量显著增加,同时SOD、POD、CAT、APX、GR等抗氧化酶活性和抗氧化物质AsA、GSH含量显著提高。低氧胁迫下外源GABA能显著提高甜瓜幼苗叶片SOD、CAT、APX、GR等酶活性和AsA、GSH含量,降低了植株体内O2.-产生速率和H2O2、MDA含量;而正常通气条件下添加外源GABA处理对甜瓜幼苗活性氧代谢的影响较小,仅CAT、GR活性和AsA、GSH含量显著提高,而H2O2、MDA含量显著降低。结果证明,添加外源GABA可以通过显著提高低氧胁迫下抗氧化酶活性和抗氧化物质含量来降低甜瓜幼苗活性氧积累,维持其细胞膜结构稳定性,从而有效减轻低氧胁迫对甜瓜幼苗的伤害。     

根际低氧胁迫对黄瓜幼苗根系呼吸代谢的影响

采用营养液栽培方法,研究了低氧胁迫对两个耐低氧能力不同的黄瓜品种根系呼吸代谢的影响.结果表明：低氧胁迫下,两个黄瓜品种根系三羧酸循环显著受阻,无氧呼吸代谢被促进.与耐低氧能力较弱的中农8号相比,耐低氧能力较强的绿霸春4号根系琥珀酸脱氢酶和异柠檬酸脱氢酶活性的降低幅度较小,乳酸脱氢酶活性、乳酸和丙酮酸含量的增加幅度较小,而丙酮酸脱羧酶、乙醇脱氢酶活性及乙醇、丙氨酸含量的增加幅度较大;低氧胁迫8 d时,与相应对照相比,绿霸春4号根系乙醇脱氢酶活性及乙醇和丙氨酸含量分别增加了409.30%、112.13%和30.64%,中农8号根系分别增加了110.42%、31.84%和4.78%,这是两个黄瓜品种耐低氧能力差异的主要生理原因.两品种幼苗根系丙氨酸氨基转移酶活性和乙醛含量没有显著差异.表明低氧胁迫下黄瓜根系乙醇发酵代谢途径的增强和丙氨酸的积累有利于防御低氧伤害.     

根际低氧胁迫对黄瓜幼苗根系呼吸代谢的影响

采用营养液栽培方法,研究了低氧胁迫对两个耐低氧能力不同的黄瓜品种根系呼吸代谢的影响.结果表明：低氧胁迫下,两个黄瓜品种根系三羧酸循环显著受阻,无氧呼吸代谢被促进.与耐低氧能力较弱的中农8号相比,耐低氧能力较强的绿霸春4号根系琥珀酸脱氢酶和异柠檬酸脱氢酶活性的降低幅度较小,乳酸脱氢酶活性、乳酸和丙酮酸含量的增加幅度较小,而丙酮酸脱羧酶、乙醇脱氢酶活性及乙醇、丙氨酸含量的增加幅度较大;低氧胁迫8d时,与相应对照相比,绿霸春4号根系乙醇脱氢酶活性及乙醇和丙氨酸含量分别增加了409.30%、112.13%和30.64%,中农8号根系分别增加了110.42%、31.84%和4.78%,这是两个黄瓜品种耐低氧能力差异的主要生理原因.两品种幼苗根系丙氨酸氨基转移酶活性和乙醛含量没有显著差异.表明低氧胁迫下黄瓜根系乙醇发酵代谢途径的增强和丙氨酸的积累有利于防御低氧伤害.     

蛋白质组学在植物水分胁迫应答中的应用研究进展

水分胁迫是影响植物生长发育的主要生长因子。通过蛋白质组学技术可对水分胁迫下植物差异变化的蛋白和基因进行挖掘,在研究植物抗旱生理机制方面意义重大。总结了植物蛋白质组学的基本方法与关键技术,同时从光合与碳代谢相关蛋白、抗氧化系统、渗透调节蛋白、热激蛋白、胚胎发育晚期丰富蛋白、转录因子等方面综述了近几年国际上在植物水分胁迫蛋白质组研究方面的进展,并展望了今后蛋白质组学技术发展的方向。     

低氧胁迫下钙对网纹甜瓜幼苗多胺含量及多胺氧化酶活性的影响

以低氧性敏感的网纹甜瓜(Cucumis melo var. raticulalus)品种`西域一号'(Xiyu 1)为材料,研究了钙对低氧胁迫下幼苗生长、游离态、结合态和束缚态的腐胺(Put)、亚精胺(Spd)、精胺(Spm)含量、二胺氧化酶(DAO)和多胺氧化酶(PAO)活性、H₂O₂含量的影响。结果表明:与通气对照相比,低氧胁迫处理幼苗鲜重和干重显著降低,根、叶中3种形态的Put、Spd、Spm含量显著增加,DAO和PAO活性、H₂O₂含量显著提高;营养液加钙处理不但缓解了低氧胁迫对幼苗生长的抑制作用,而且幼苗游离态、结合态和束缚态Put、Spd、Spm含量显著高于单纯低氧胁迫处理,DAO和PAO活性、H₂O₂含量显著低于低氧胁迫处理;低氧胁迫下缺钙处理加重了低氧胁迫对网纹甜瓜幼苗的伤害。表明在低氧胁迫下,钙参与了网纹甜瓜幼苗多胺的代谢过程,对增强幼苗耐低氧性起着重要的作用。     

Global gene expression responses to waterlogging in roots of sesame (Sesamum indicum L.)

Waterlogging stress lowers yields in sesame (Sesamum indicum L.). A major component of waterlogging stress is the lack of oxygen available to submerged tissues. Although the morphology and physiology of plants grown under anaerobic conditions have been studied in detail, limited work has been done to elucidate adaptations at the molecular level. To gain comprehensive insight into how sesame responds to hypoxia at the genome level, we performed gene expression profiling at two time points during a 36-h period following hypoxic treatment using a whole-genome RNA-Seq analysis. We identified sets of significantly positively and negatively expressed genes (induced and repressed, respectively) in response to hypoxia with distinct temporal profiles. The genes that were affected were associated with glycolysis, nitrogen metabolism, starch and sucrose metabolism and plant hormone signal transduction and indicated the upregulation of particular pathways (glycolysis/glycogenesis) in the Kyoto Encyclopedia of Genes and Genomes. Moreover, significant changes in the expression of genes were found for pathways, including flavone and flavonol biosynthesis, steroid biosynthesis, photosynthesis, cysteine and methionine metabolism, glutathione metabolism, as well as phenylpropanoid biosynthesis, spliceosome, circadian rhythm. This study helps in elucidating the molecular mechanisms of waterlogging tolerance and provides a basis for the genetic engineering of sesame.     

Low levels of pyrophosphate in transgenic potato plants expressing E. coli pyrophosphatase lead to decreased vitality under oxygen deficiency

BACKGROUND AND AIMS: The aim of this study was to investigate the importance of pyrophosphate (PPi) for plant metabolism and survival under low oxygen stress. Responses of roots of wild-type potato plants were compared with roots of transgenic plants containing decreased amounts of PPi as a result of the constitutive expression of Escherichia coli pyrophosphatase in the cytosol. METHODS: For the experiments, roots of young wild-type and transgenic potato plants growing in nutrient solution were flushed for 4 d with nitrogen, and subsequently metabolite contents as well as enzyme activities of the glycolytic pathway were determined. KEY RESULTS AND CONCLUSIONS: In roots of transgenic plants containing 40% less PPi, UDPglucose accumulated while the concentrations of hexose-6-phosphate, other glycolytic intermediates and ATP were decreased, leading to a growth retardation in aerated conditions. Apart from metabolic alterations, the activity of sucrose synthase was increased to a lower extent in the transgenic line than in wild type during hypoxia. These data suggest that sucrose cleavage was inhibited due to PPi deficiency already under aerated conditions, which has severe consequences for plant vitality under low oxygen. This is indicated by a reduction in the glycolytic activity, lower ATP levels and an impaired ability to resume growth after 4 d of hypoxia. Interestingly, the phosphorylation of fructose-6-phosphate via PPi-dependent phosphofructokinase was not altered in roots of transgenic plants. Nevertheless, our data provide some evidence for the importance of PPi to maintain plant growth and metabolism under oxygen deprivation.     

Prolonged root hypoxia effects on enzymes involved in nitrogen assimilation pathway in tomato plants

In order to investigate the effects of root hypoxia (1–2% oxygen) on the nitrogen (N) metabolism of tomato plants (Solanum lycopersicum L. cv. Micro-Tom), a range of N compounds and N-assimilating enzymes were performed on roots and leaves of plants submitted to root hypoxia at the second leaf stage for three weeks. Obtained results showed that root hypoxia led to a significant decrease in dry weight (DW) production and nitrate content in roots and leaves. Conversely, shoot to root DW ratio and nitrite content were significantly increased. Contrary to that in leaves, glutamine synthetase activity was significantly enhanced in roots. The activities of nitrate and nitrite reductase were enhanced in roots as well as leaves. The higher increase in the NH₄⁺ content and in the protease activities in roots and leaves of hypoxically treated plants coincide with a greater decrease in soluble protein contents. Taken together, these results suggest that root hypoxia leaded to higher protein degradation. The hypoxia-induced increase in the aminating glutamate dehydrogenase activity may be considered as an alternative N assimilation pathway involved in detoxifying the NH₄⁺, accumulated under hypoxic conditions. With respect to hypoxic stress, the distinct sensitivity of the enzymes involved in N assimilation is discussed.Key words: tomato, hypoxia, nitrogen, glutamine synthetase, protease, glutamate dehydrogenase     

An assessment of the biotechnological use of hemoglobin modulation in cereals

Non‐symbiotic hemoglobin (nsHb) genes are ubiquitous in plants, but their biological functions have mostly been studied in model plant species rather than in crops. nsHb influences cell signaling and metabolism by modulating the levels of nitric oxide (NO). Class 1 nsHb is upregulated under hypoxia and is involved in various biotic and abiotic stress responses. Ectopic overexpression of nsHb in Arabidopsis thaliana accelerates development, whilst targeted overexpression in seeds can increase seed yield. Such observations suggest that manipulating nsHb could be a valid biotechnological target. We studied the effects of overexpression of class 1 nsHb in the monocotyledonous crop plant barley (Hordeum vulgare cv. Golden Promise). nsHb was shown to be involved in NO metabolism in barley, as ectopic overexpression reduced the amount of NO released during hypoxia. Further, as in Arabidopsis, nsHb overexpression compromised basal resistance toward pathogens in barley. However, unlike Arabidopsis, nsHb ectopic overexpression delayed growth and development in barley, and seed specific overexpression reduced seed yield. Thus, nsHb overexpression in barley does not seem to be an efficient strategy for increasing yield in cereal crops. These findings highlight the necessity for using actual crop plants rather than laboratory model plants when assessing the effects of biotechnological approaches to crop improvement.