小麦紫黄质脱环氧化酶(VDE)cDNA的克隆及表达(英文)

应用RT-PCR方法从小麦(Triticum aestivum L.cv.Xiaoyan 54)中克隆了紫黄质脱环氧化酶(violaxanthinde-epoxidase,VDE)cDNA,预测的蛋白质序列与拟南芥(Arabidopsis thaliana)、水稻(Oryza sativa)有很高的同源性。Southern杂交结果表明,在小麦中可能存在3个拷贝的紫黄质脱环氧化酶基因。Northern杂交结果表明它在绿色叶片中特异表达,在黄化小麦幼苗变绿过程中其mRNA水平受光诱导,并且强光增加了其mRNA在成熟叶片中的表达。     

小麦紫黄质脱环氧化酶（VDF）cDNA的克隆及表达

应用RT-PCR方法从小麦(Triticum aestivum L．cv．Xiaoyan 54)中克隆了紫黄质脱环氧化酶(violaxanthin de-epoxidase,VDE)cDNA,预测的蛋白质序列与拟南芥(Arabidopsis thaliana)、水稻(Oryza sativa)有很高的同源性。Southern杂交结果表明,在小麦中可能存在3个拷贝的紫黄质脱环氧化酶基因。Northern杂交结果表明它在绿色叶片中特异表达,在黄化小麦幼苗变绿过程中其mRNA水平受光诱导,并且强光增加了其mRNA在成熟叶片中的表达。     

叶黄素循环酶

依赖叶黄素循环的热耗散是一种主要防御光破坏的机制。参与叶黄素循环的酶是紫黄质脱环氧化酶和玉米黄质环氧化酶 ,紫黄质脱环氧化酶已分离纯化 ,其 c DNA已被克隆 ,其活性主要受跨类囊体膜的 p H梯度和抗坏血酸浓度的调节 ;玉米黄质环氧化酶还没有被分离出来 ,但其 c DNA也已被克隆 ;其活性主要与NADPH的浓度、O2 及光等有关。     

紫黄质脱环氧化酶的某些特性和研究方法

紫黄质脱环氧化酶是高等植物体内叶黄素循环的关键酶,它催化紫黄质脱环氧化生成花药黄质和玉米黄质,在这个过程中伴随着过剩光能的热耗散.文中主要对此酶的性质、功能、研究方法以及分子生物学等内容作了简要介绍.     

枸杞紫黄质脱环氧化酶(LcVDE)基因的克隆和分析

目的:克隆枸杞VDE基因的全长cDNA,通过对基因序列的生物信息学分析预测表达产物的结构特征和功能位点并验证其功能,为研究枸杞紫黄质循环的作用机理打下基础。方法:利用cDNA末端快速扩增和RT-PCR方法克隆枸杞VDE基因全长cDNA序列,生物软件分析VDE的生物学信息。构建VDE基因的原核表达载体pET-VDE,转化大肠后用IPTG诱导VDE过量表达;并构建体外反应体系对VDE表达蛋白酶功能进行验证。结果:LcVDE基因的ORF长1 413bp,编码的蛋白由470个氨基酸组成,分子量为53.61kDa,等电点为5.77。SDS-PAGE电泳结果表明,枸杞VDE基因在大肠杆菌中得到了过量表达。克隆基因表达蛋白进行紫黄质的脱环氧化反应,吸收光谱和HPLC的分析结果表明,表达蛋白催化了紫黄质的脱环氧化反应。结论:克隆得到的VDE基因编码的蛋白具有紫黄质脱环氧化酶的的功能与活性。     

天线蛋白和类囊体膜脂对光合系统紫黄质循环的调节作用研究进展

紫黄质循环是紫黄质(V)经过中间物单环氧玉米黄质(A)形成玉米黄质(Z)的可逆转换,是光合系统聚光复合体在低光下的聚光状态与高光下的能量耗散状态之间的转换开关.叶黄素中的玉米黄质可钝化(去激发)激发三线态叶绿素(3Chl*)和激发单线态氧(1O2*),紫黄质循环可直接或间接地通过非光化学淬灭(NPQ)耗散PSⅡ天线蛋白中的过量光能.天线蛋白被认为是依赖玉米黄质(Z)耗散过量光能的部位,天线蛋白通过结合紫黄质循环组分(V,A和Z)来调节紫黄质循环.类囊体膜脂的性质和结构影响紫黄质循环组分(V,A和Z)间的转换,V的脱环氧化速率依赖于V在类囊体膜脂上侧向扩散的速率,紫黄质脱环氧化作用第一步(由V到A的转换)的速度常数是第二步(由A到Z的转换)速度常数的4～6倍.现有的结果表明,天线蛋白和类囊体膜脂是紫黄质循环最基本的调节器.该文对近年来国内外关于紫黄质循环的基本反应及其功能、紫黄质循环酶结构性质和辅因子以及天线蛋白和类囊体膜脂对紫黄质循环的调节作用及其机理等方面的研究进展进行了综述.     

光温交叉胁迫对菜豆幼苗叶黄素循环启动的影响

弱光下,温度胁迫很难启动叶黄素循环,仅在高温下生成少量玉米黄质。随光强的上升,玉米黄质的生成量增加,紫黄质脱环化状态相应增大。强光高温最大程度上启动叶黄素循环。紫黄质脱环化抑制剂二硫苏糖醇的引入抑制玉米黄质的形成,但紫黄质的脱环化状态仍可由于环氧玉米黄质的形成而增加。     

低温强光下籼粳稻紫黄质脱环氧化酶活性和类囊体膜脂不饱和度的变化

为了阐明籼稻(oryza sativa L.spp.indica)、粳稻(O.sativa L.spp.japonica)对低温强光敏感性的差异,着重研究了低温强光下水稻类囊体膜脂不饱和度与叶黄素循环的变化.随着低温强光处理时间的延长,类囊体膜脂不饱和脂肪酸含量降低,饱和脂肪酸含量增加,因而膜脂不饱和指数(IUFA)下降.同时,叶黄素循环的关键酶--紫黄质脱环氧化酶(VDE)活性降低,叶黄素循环组分中紫黄质(V)含量增加,而单环氧玉米黄质(A)和下米黄质(Z)的含量减少,表现为(A+Z)/(A+Z+V)比值下降.Arrhenius分析证明,VDE对低温和膜脂不饱和度都敏感.相关分析表明,类囊体IUFA分别与VDE活性、(A+Z)/(A +Z+V)和D1蛋白量呈显著的正相关.与粳稻9516相比,籼稻油优63类囊体膜的IUFA较低,低温下类囊体膜脂流动性和稳定性较差,VDE活性和(A+Z)/(A+Z+V)比值较低.     

低温强光下籼粳稻紫黄质脱环氧化酶活性和类囊体膜脂不饱和度的变化

为了阐明籼稻(Oryza sativa L.spp.indica)、粳稻(O.sativa L.spp.japonica)对低温强光敏感件的差异,着重研究了低温强光下水稻类囊体膜脂不饱和度与叶黄素循环的变化。随着低温强光处理时间的延长,类囊体膜脂不饱和脂肪酸含量降低,饱和脂肪酸含量增加,因而膜脂不饱和指数(IUFA)下降。同时,叶黄素循环的关键酶——紫黄质脱环氧化酶(VDE)活性降低,叶黄素循环组分中紫黄质(V)含量增加,而单环氧玉米黄质(A)和玉米黄质(Z)的含量减少,表现为(A Z)／(A Z V)比值下降。Arrhenius分析证明,VDE对低温和膜脂不饱和度都敏感。相关分析表明,类囊体IUFA分别与VDE活性、(A Z)／(A Z V)和D1蛋白量呈显著的正相关。与粳稻9516相比,籼稻汕优63类囊体膜的IUFA较低,低温下类囊体膜脂流动性和稳定性较筹,VDE活性和(A Z)／(A Z V)比值较低。     

非洲菊亲环素家族基因GCyP的克隆与生物信息学分析

亲环素(Cyclophilins,CyPs)具有肽脯氨酰顺反异构酶活性,催化蛋白质折叠过程,并且起着分子伴侣的作用,同时参与mRNA加工和信号转导等生物学过程.本研究在抑制性消减杂交获得表达序列标签(EST)的基础上,通过生物信息学方法获得了非洲菊亲环素家族基因GCyP的cDNA.进而设计特异引物,以非洲菊舌状花为材料,通过RT-PCR扩增并经T-A克隆后测序,获得一条长度为732 bp的序列.该序列经生物信息学分析确认其为GCyP,编码的GCyP含172个氨基酸残基,属于单结构域胞质型亲环素.GCyP序列提交GenBank后接收,登录号为EU1269167.     

The red light controlled production of gibberellin in etiolated wheat leaves

Summary Most of the gibberellin activity detectable in extracts of etiolated wheat leaf tissue occurs in a bound form. There is a rapid increase in extractable gibberellin-like substances following exposure of the tissue to red light with a concomitant fall in the amount of bound gibberellin. Actinomycin-D and AMo 1618 do not inhibit this initial phase of red light stimulated gibberellin production.It is concluded that red light stimulated gibberellin production in etiolated wheat leaf tissue is due to release from a bound form and to synthesis.Holder of a Science Research Council Studentship.     

Phytochrome and hormonal control of expansion and greening of etiolated wheat leaves

Summary Unrolling of etiolated wheat leaf segments is stimulated by short periods of exposure to red light. Both gibberellic acid and kinetin will stimulate unrolling in the dark, whereas abscisic acid (ABA) inhibits the unrolling response to these two hormones and to red light. Exposure to 5 minutes of red light leads to a rapid increase in endogenous gibberellin levels in etiolated wheat leaves, and this increase is followed by a rapid decline. Pre-treatment with ABA inhibits the increase in gibberellin levels in response to red light, but the ihibitory effect of ABA on unrolling cannot be ascribed only to its effect on gibberellin levels. Pre-treatment with red light reduces the lag-phase in chlorophyll development when wheat leaf segments are subsequently exposed to white light; the effect of red light may be replaced by pre-treatment with kinetin, but gibberellic acid is relatively ineffective in this respect.     

EFFECTS OF TEMPERATURE AND LIGHT TREATMENT ON VIOLAXANTHIN DE-EPOXIDASE ACTIVITY AND XANTHOPHYLL CYCLE-DEPENDENT ENERGY DISSIPATION IN WHEAT LEAVES

 为了探讨温度和光强是如何影响离体紫黄质脱环氧化酶(VDE)活性, 阐明依赖叶黄素循环的热耗散与VDE活性关系, 该文以小麦(Triticum aestivum)为材料, 研究了不同光强(200、500、900和1 200 μmol&;#8226;m^–2&;#8226;s^–1)和不同温度(4、25、38和45 ℃) 交叉处理对小麦叶片VDE活性以及依赖叶黄素循环热耗散能力的影响。结果表明: 小麦叶片VDE活性在30 ℃最高, 说明30 ℃是小麦叶片VDE体外条件下的最适温度; 不同光强处理下小麦叶片VDE活性基本一致。与室温(25 ℃)处理的叶片相比, 低温(4 ℃)处理的叶片VDE活力没有明显下降, 而高温(45 ℃)处理则导致了叶片VDE活性急剧下降。小麦叶片热耗散(NPQ)以及依赖叶黄素循环的热耗散(qE)均随着处理光强的增加不断上升, 而qE/NPQ则随光强增加略微下降, 在1 200 μmol&;#8226;m^–2&;#8226;s^–1光强条件下qE/NPQ则急剧下降。该研究揭示VDE活性与依赖叶黄素循环热耗散能力的指标qE/NPQ的变化有一定的相关性, 但不完全一致。并针对此问题进行了讨论。     

Influence of Cell Age on Chlorophyll Formation in Light-grown and Etiolated Wheat Seedlings

A method is described for relating the age of a cereal leaf cell to its distance from the leaf base. The rates of chlorophyll synthesis per plastid in the first leaf of light-grown and of greening etiolated seedlings of wheat (Triticum aestivum, var. Maris Dove) increase with cell age. Normally developing plastids of light-grown wheat take over 24 hours to reach the chlorophyll a/b ratio characteristic of mature wheat chloroplasts (4.5), but mature etioplasts need only 8 hours light to achieve this a/b ratio. Plastid greening potential depends only on cell age, whereas the chlorophyll a/b ratio is influenced both by cell age and by light.     

光对小麦幼叶脂氧合酶活性及膜脂过氧化作用的影响

选用抗旱型小麦品种陕合６号和水分敏感型小麦品种郑引１号的黄化幼苗为材料,研究了光处理对小麦幼叶脂氧合酶活性和膜脂氧化作用的影响。结果表明：光处理后黄叶变绿,叶片中的ＬＯＸ活性降低,丙二醛含量和叶绿素含量增加,膜透性升高,ＩＵＦＡ升高。ＬＯＸ活性与光抑制过程的恢复,光保护过程及膜脂过氧化作用有关。光诱导产生的膜脂过氧化作用是一种“准膜脂过氧化作用”。     

The hormonal control of wheat leaf unrolling

Summary The unrolling of etiolated wheat leaf sections in the dark is stimulated by the application of gibberellic acid (GA₃). GA₃ is most effective if applied for a short time at the beginning of incubation. Kinetin also stimulated leaf unrolling in the dark. AMO1618 and CCC inhibit red light and kinetin-stimulated unrolling. Gibberellin-like substances extracted from red light-treated leaf tissue are effective in stimulating leaf unrolling.Ethylene production in leaf sections is stimulated by IAA, GA₃ and kinetin and inhibited by ABA. A brief exposure to red light decreases the ability of the tissue to produce ethylene. It is concluded that ethylene plays no important role in the control of leaf unrolling by red light or by the application of hormones.Holder of a Science Research Council Studentship.     

Changes to the Stoichiometry of Glycine Decarboxylase Subunits during Wheat (Triticum aestivum L.) and Pea (Pisum sativum L.) Leaf Development

Changes in the levels of the four subunits of the mitochondrial enzyme glycine decarboxylase (EC 2.1.2.10) have been investigated during development in the 8 day old primary leaf of wheat (Triticum aestivum L.). Proteins were extracted from wheat leaf sections between the basal meristem and 8.5 centimeters. The individual glycine decarboxylase subunits were detected by Western blotting, using subunit-specific polyclonal antibodies, and quantified by laser densitometry. P, T, and H subunits showed similar developmental patterns along the leaf. All were below the level of detection up to 1.5 centimeters from the meristem, but then increased over the leaf length examined. In contrast, the increase in the L protein (lipoamide dehydrogenase) was more gradual, and levels in the youngest regions of the leaf were maintained at approximately 14% of those at 8.5 centimeters. In a complementary study, levels of the four subunits in light-grown leaf tissues were compared to those in etiolated leaves from wheat and pea (Pisum sativum L.), using the activity of the mitochondrial marker enzyme fumarase as the basis for comparison. For both wheat and pea, levels of P, T, and H proteins in etiolated tissues were between 25 and 30% of those in lightgrown tissue. However, in etiolated tissues L protein was present at levels of 60 to 70% of that in light-grown tissues. The results indicate that discrete mechanisms may control the synthesis of L, as compared to P, T, and H proteins.     

Apoptosis in Wheat Seedlings Grown under Normal Daylight

Apoptosis was observed in the coleoptile and initial leaf in 5-8-day-old wheat seedlings grown under normal daylight. Apoptosis is an obligatory event in early wheat plant ontogenesis, and it is characterized by cytoplasmic structural reorganization and fragmentation, in particular, with the appearance in vacuoles of specific vesicles containing intact organelles, chromatin condensation and margination in the nucleus, and internucleosomal fragmentation of nuclear DNA. The earliest signs of programmed cell death (PCD) were observed in the cytoplasm, but the elements of apoptotic degradation in the nucleus appeared later. Nuclear DNA fragmentation was detected after chromatin condensation and the appearance in vacuoles of specific vesicles containing mitochondria. Two PCD varieties were observed in the initial leaf of 5-day-old seedlings grown under normal daylight: a proper apoptosis and vacuolar collapse. On the contrary, PCD in coleoptiles under various growing (light) conditions and in the initial leaf of etiolated seedlings is only a classical plant apoptosis. Therefore, various tissue-specific and light-dependent PCD forms do exist in plants. Amounts of O2*- and H2O2 evolved by seedlings grown under normal daylight are less than that evolved by etiolated seedlings. The amount of H2O2 formed in the presence of sodium salicylate or azide by seedlings grown under normal daylight was increased. Contrary to etiolated seedlings, the antioxidant BHT (ionol) did not inhibit O2*- formation and apoptosis and it had no influence on ontogenesis in the seedlings grown under normal daylight. Thus, in plants grown under the normal light regime the powerful system controlling the balance between formation and inactivation of reactive oxygen species (ROS) does exist and it effectively functions. This system is responsible for maintenance of cell homeostasis, and it regulates the crucial ROS level controlling plant growth and development. In etiolated plants, this system seems to be absent, or it is much less effective.