水稻叶片早衰成因及分子机理研究进展

植物叶片衰老是叶片发育的最终阶段,也是植物在长期进化过程中形成的适应性机制。水稻(Oryza sativa)叶片的衰老对其产量和品质影响极大,相关研究主要集中在早衰。该文综述了水稻早衰及其调控基因的研究进展,尤其对水稻叶片早衰的形成原因、发生过程、生理变化及防治措施进行了阐述,以期为深入解析水稻早衰的分子机制奠定理论基础,同时为水稻育种提供参考。     

转ipt和反义ACO基因番茄的叶片衰老相关特性

以ipt和反义ACO转化的两类转基因番茄纯系为材料,研究在植株不同生长发育阶段,不同叶位中,与叶片衰老相关的生理生化指标.结果表明:两类基因导入番茄后,均可增强内源iPA和IAA表达水平,增加或保持番茄叶片的叶绿素含量、提高光合效率,进而明显地延缓植株的叶片衰老,提高单株果实产量.但它们调控叶片衰老的途径不同,ipt主要通过提高CTK的水平延缓叶片衰老,而反义ACO则主要是通过抑制乙烯生成,间接提高IAA的水平来实现.     

大豆microRNA基因GmMIR160A负调控植物叶片衰老进程

:叶片衰老是受内外多种因子影响的遗传发育进程.生长素、细胞分裂素和乙烯等多种植物激素是调 控叶片衰老的重要内部因子,它们通过长或短距离运输形成叶片组织内特定的区域分布和浓度梯度,从而直 接或间接参与植物叶片衰老过程.分子遗传学表明,细胞分裂素和乙烯分别是叶片衰老的抑制子和正调节 子,而生长素如何参与叶片衰老的分子机制目前还不清晰.植物体内成熟小分子RNA 由小RNA 基因转录 并通过特定酶加工形成的２１~２３bp的双链RNA分子.这些小分子通过不完全配对方式抑制其靶基因转录 和/或表达,参与植物生长发育多个过程,然而这类小RNA 分子如何调控植物叶片衰老发育过程目前则还鲜 有报告.大豆是重要的油料作物,具有典型的单次结实性衰老特征.研究大豆叶片衰老具有重要的科学意义 和深远的应用价值.该文采用实时荧光定量PCR(qPCR)技术分析大豆(Glycinemax)microRNA基因Gm- MIR１６０A 的表达模式,发现大豆第一复叶中GmMIR１６０A 表达受外源生长素和黑暗处理的诱导,暗示该基 因是生长素快速响应的叶片衰老相关基因.为进一步探究GmMIR１６０A 在大豆叶片发育中的功能,构建了 肾上腺皮质激素(Glucocorticoid,GR)类似物地塞米松(Dexamethasone,DEX)诱导表达GmMIR１６０A 双元表 达载体并通过农杆菌介导的子叶节方法转化野生型大豆.通过抗性筛选和基因组PCR 鉴定并结合表型分 析,共获得了４株诱导表达的稳定遗传转基因植株(株系OXＧ３、OXＧ５、OXＧ７和OXＧ８).GmMIR１６０A 过表达 植株根、茎、叶、花和果实在形态学上与野生型相比无显著差异,但叶片的叶绿素含量增加、最大光量子效率 (Fv/Fm)增强.进一步分子分析发现,转基因大豆叶片中GmARFs 和衰老标记基因(GmCYSP１)表达明显下 降,表明大豆Gma-miR１６０通过抑制靶基因GmARFs 的表达来负调控植物叶片的衰老进程.该文揭示了生 长素通过小分子RNA调控叶片发育一条新途径,为研究植物激素调控植物叶片衰老提供了新的思路.     

干扰HD-ZipⅢ家族成员OsHox33的表达加速水稻叶片的衰老

HD-ZipⅢ基因家族成员在植物生长发育中起重要作用,主要涉及调控植物胚的发育模式、茎顶端分生组织的形成、叶片极性的形成、维管系统的发育等多个方面.尤其在植物叶片的发育中起重要作用.尽管HD-ZipⅢ家族成员在陆生植物中高度保守,但基于拟南芥多重突变体的遗传分析揭示了HD-ZipⅢ家族的功能在进化过程中已有所分化.本文报道了一个HD-ZipⅢ家族成员OsHox33,并分析了其功能,研究结果表明,其在水稻叶片衰老中起重要作用.为了揭示OsHox33的功能,本研究构建两个特异的RNAi载体(一个干涉片段来自OsHox33的5′端,另一个来自OsHox33的3′非翻译区)干扰OsHox33的表达,结果表明,两个载体的转基因植株都展示了叶片早衰的相似表型,表明干扰OsHox33的表达加速了水稻叶片的衰老.pOsHox33::GUS及RT-PCR分析表明,OsHox33在水稻幼嫩的器官中有较高的表达,尤其在茎顶端分生组织、居间分生组织及愈伤等幼嫩组织有较高的表达.不同时期叶片实时定量PCR分析表明,OsHox33在水稻幼叶中有较高的表达,但在衰老叶片中表达降低.另外,不同时期叶片叶绿体电子显微镜超微结构显示,OsHox33 RNAi转基因植株加速了叶绿体结构的降解,与OsHox33 RNAi转基因植株的表型相一致.基因表达调控结果显示,OsHox33可以调控水稻叶片衰老特性基因GS1和GS2的表达,干扰OsHox33的表达降低了GS1的表达,但增加了GS2的表达.本文对于HD-ZipⅢ家族在植物生长发育中的功能提供了新的理解.     

烟草叶片衰老期过程中的蛋白质组学分析

大田烟叶生产过程中因打顶打叉的处理,改变了烟叶正常的衰老模式。为研究这一特殊的衰老机制,我们自旺长期开始,对‘云烟87’不同发育阶段烟株的中部叶片,进行形态观测、生理生化分析及蛋白质组学检测。结果显示：随着烟叶的逐渐成熟和衰老,烟草的叶色逐渐变黄,叶片逐渐变短、变窄,厚度减少;解剖结构清晰看到栅栏组织和海绵组织从最初的整齐排列到逐渐排列紊乱,组织细胞间轮廓不明显,细胞间隙明显增大;亚显微观测表明,淀粉粒在叶绿体中逐渐积累,类囊体片层结构被挤散,叶绿体膜被撑破。生理与生化分析表明衰老过程伴随着光合作用速率下降,光合色素降解加速,呼吸代谢的增加,这可能与衰老叶片中叶绿体逐渐崩塌和细胞膜透性增加相一致。iTRAQ标记方法共检测到不同发育阶段432个差异表达蛋白质,其中注释到308个与多种生命过程相关。蛋白差异富集分析表明,烟草叶片衰老过程中与光合作用等合成代谢相关蛋白多下调表达,而逆境反应及呼吸作用等分解代谢相关蛋白多上调表达。     

miRNA对水稻生长发育的调控

MicroRNA(miRNA)是一类小的非编码RNA,它们主要在转录后水平对靶mRNA进行切割或抑制mRNA的翻译来调控基因的表达. miRNA通过对靶基因的调控参与植物的生长发育、胁迫应答和代谢过程.在水稻中,已经发现并初步验证了许多与生长发育相关的miRNA,它们对水稻不同器官和形态发育发挥着重要作用.本文综述了水稻miRNA的发生和调控机制、靶基因的预测,重点介绍了miRNA对水稻生长发育和形态建成的研究进展,并对研究过程中存在的问题进行了讨论.为更好地了解miRNA及其靶基因在提高水稻产量和品质方面的作用,进一步解析miRNA在水稻中的调控机制提供参考.     

植物叶片衰老过程中基因的表达与调控

从衰老相关基因的分离、克隆、表达、调控及叶片衰老延缓几个方面,介绍叶片衰老过程中基因表达调控的研究进展。     

大豆microRNA基因GmMIR160A负调控植物叶片衰老进程

叶片衰老是受内外多种因子影响的遗传发育进程。生长素、细胞分裂素和乙烯等多种植物激素是调控叶片衰老的重要内部因子,它们通过长或短距离运输形成叶片组织内特定的区域分布和浓度梯度,从而直接或间接参与植物叶片衰老过程。分子遗传学表明,细胞分裂素和乙烯分别是叶片衰老的抑制子和正调节子,而生长素如何参与叶片衰老的分子机制目前还不清晰。植物体内成熟小分子RNA由小RNA基因转录并通过特定酶加工形成的21~23bp的双链RNA分子。这些小分子通过不完全配对方式抑制其靶基因转录和/或表达,参与植物生长发育多个过程,然而这类小RNA分子如何调控植物叶片衰老发育过程目前则还鲜有报告。大豆是重要的油料作物,具有典型的单次结实性衰老特征。研究大豆叶片衰老具有重要的科学意义和深远的应用价值。该文采用实时荧光定量PCR(qPCR)技术分析大豆(Glycine max)micro RNA基因GmMIR160A的表达模式,发现大豆第一复叶中GmMIR160A表达受外源生长素和黑暗处理的诱导,暗示该基因是生长素快速响应的叶片衰老相关基因。为进一步探究GmMIR160A在大豆叶片发育中的功能,构建了肾上腺皮质激素(Glucocorticoid,GR)类似物地塞米松(Dexamethasone,DEX)诱导表达GmMIR160A双元表达载体并通过农杆菌介导的子叶节方法转化野生型大豆。通过抗性筛选和基因组PCR鉴定并结合表型分析,共获得了4株诱导表达的稳定遗传转基因植株(株系OX-3、OX-5、OX-7和OX-8)。GmMIR160A过表达植株根、茎、叶、花和果实在形态学上与野生型相比无显著差异,但叶片的叶绿素含量增加、最大光量子效率(Fv/Fm)增强。进一步分子分析发现,转基因大豆叶片中GmARFs和衰老标记基因(GmCYSP1)表达明显下降,表明大豆Gma-miR160通过抑制靶基因GmARFs的表达来负调控植物叶片的衰老进程。该文揭示了生长素通过小分子RNA调控叶片发育一条新途径,为研究植物激素调控植物叶片衰老提供了新的思路。     

水稻叶片衰老过程中氨肽酶活性的变化

水稻叶片中存在着氨肽酶,其最适反应pH和最适反应温度分别为8.2℃和40℃,酶促反应的产物量在最初30min内与时间呈直线相关。 水稻叶片衰老过程中叶绿素和蛋白质含量下降,而氨肽酶比活上升;用植物激素延缓或促进叶片衰老蛋白质降解的同时也抑制或促进了氨肽酶比活的上升,说明氨肽酶在水稻叶片衰老蛋白质降解过程中起一定的作用。根据水稻叶片衰老过程中大分子化合物和叶片外部形态的变化,可将叶片衰老过程划分为缓衰期、急衰期和竭衰期。     

玉米叶片持绿性研究进展与对策

叶片持绿性(stay green或non-senescence)与植物叶片衰老相关,影响植物生长及生物产量。叶片持绿性相关研究主要集中于拟南芥等模式植物,玉米中的研究相对落后,但该研究对玉米产量、品质、抗病等具有重要意义。本文对玉米叶片持绿性的研究进展进行了综述,包括玉米叶片持绿性概念、评价指标、生理生化特性、遗传特性、基因/QTL定位等。提出了玉米持绿性研究存在的问题与相关对策。     

Relationship of Nitrogen Deficiency-Induced Leaf Senescence with ROS Generation and ABA Concentration in Rice Flag Leaves

Nitrogen (N) deficiency is one of the critical environmental factors that induce leaf senescence, and its occurrence may cause the shorten leaf photosynthetic period and markedly lowered grain yield. However, the physiological metabolism underlying N deficiency-induced leaf senescence and its relationship with the abscisic acid (ABA) concentration and reactive oxygen species (ROS) burst in leaf tissues are not well understood. In this paper, the effect of N supply on several senescence-related physiological parameters and its relation to the temporal patterns of ABA concentration and ROS accumulation during leaf senescence were investigated using the premature senescence of flag leaf mutant rice (psf) and its wild type under three N treatments. The results showed that N deficiency hastened the initiation and progression of leaf senescence, and this occurrence was closely associated with the upregulated expression of 9-cis-epoxycarotenoiddioxygenase genes (NCEDs) and with the downregulated expression of two ABA 8′-hydroxylase isoform genes (ABA8ox2 and ABA8ox3) under LN treatment. Contrarily, HN supply delayed the initiation and progression of leaf senescence, concurrently with the suppressed ABA biosynthesis and relatively lower level of ABA concentration in leaf tissues. Exogenous ABA incubation enhanced ROS generation and MDA accumulation in a dose-dependent manner, but it decreased the activities of glutamine synthetase (GS) and glutamate dehydrogenase (GDH) in detached leaf. These results suggested that the participation of ABA in the regulation of ROS generation and N assimilating/remobilizing metabolism in rice leaves was strongly responsible for induction of leaf senescence by N deficiency.

     

Overexpression of OsRab7B3, a small GTP-binding protein gene, enhances leaf senescence in transgenic rice

Rab family proteins are small GTP-binding proteins involved in intracellular trafficking. They play critical roles in several plant development processes. Different expression patterns of 46 Rabs in the rice genome were examined in various rice tissues and in leaves treated with plant growth regulators and under senescence conditions. One of the OsRab genes, OsRab7B3, closely associated with senescence in expression pattern, was chosen for functional analysis. Expression of sGFP under the control of the OsRab7B3 promoter increased in leaves when ABA and NaCl were applied or when kept in dark. In transgenic rice overexpressing OsRab7B3, the senescence-related genes were upregulated and leaf senescence was significantly enhanced under dark conditions. Moreover, leaf yellowing occurred earlier in the transgenic plants than in the wild type at the ripening stage. Hence it is suggested that OsRab7B3 act as a stress-inducible gene that plays an important role in the leaf senescence process.     

Identification of early senescence-associated genes in rice flag leaves

Leaf senescence is one of the key stages of plant leaf development. It is a highly complex but ordered process involving expression of large scale senescence associated genes, and its molecular mechanisms still remain unclear. By using suppression subtractive hybridization, 815 ESTs that are up-regulated at the onset of rice flag leaf senescence have been isolated. A total of 533 unigenes have been confirmed by macroarray detection and sequencing. 183 of these unigenes have GO annotations, involved in macromolecule metabolism, protein biosynthesis regulation, energy metabolism, gene expression regulations, detoxification, pathogenicity and stress, cytoskeleton organization and flower development. Another 121 unigenes co-localized with previously reported known stay-green QTLS. RT-PCR analysis on the other novel genes indicated that they can be up-regulated in natural early senescence and induced by hormone. Our results indicate that senescence is closely related to various metabolic pathways, thus providing new insight into the onset of leaf senescence mechanism. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Premature leaf senescence 3, encoding a methyltransferase,is required for melatonin biosynthesis in rice

Premature leaf senescence in rice is one of the most common factors affecting the plant's development and yield. Although methyltransferases are involved in diverse biological functions, their roles in rice leaf senescence have not been previously reported. In this study, we identified the premature leaf senescence 3 (pls3) mutant in rice, which led to early leaf senescence and early heading date. Further investigations revealed that premature leaf senescence was triggered by the accumulation of reactive oxygen species. Using physiological analysis, we found that chlorophyll content was reduced in the pls3 mutant leaves, while hydrogen peroxide (H₂O₂) and malondialdehyde levels were elevated. Consistent with these findings, the pls3 mutant exhibited hypersensitivity to exogenous hydrogen peroxide. The expression of other senescence‐associated genes such as Osh36 and RCCR1 was increased in the pls3 mutant. Positional cloning indicated the pls3 phenotype was the result of a mutation in OsMTS1, which encodes an O‐methyltransferase in the melatonin biosynthetic pathway. Functional complementation of OsMTS1 in pls3 completely restored the wild‐type phenotype. We found leaf melatonin content to be dramatically reduced in pls3, and that exogenous application of melatonin recovered the pls3 mutant's leaf senescence phenotype to levels comparable to that of wild‐type rice. Moreover, overexpression of OsMTS1 in the wild‐type plant increased the grain yield by 15.9%. Our results demonstrate that disruption of OsMTS1, which codes for a methyltransferase, can trigger leaf senescence as a result of decreased melatonin production.     

Overexpression of OsRab7B3, a Small GTP-Binding Protein Gene,Enhances Leaf Senescence in Transgenic Rice

Rab family proteins are small GTP-binding proteins involved in intracellular trafficking. They play critical roles in several plant development processes. Different expression patterns of 46 Rabs in the rice genome were examined in various rice tissues and in leaves treated with plant growth regulators and under senescence conditions. One of the OsRab genes, OsRab7B3, closely associated with senescence in expression pattern, was chosen for functional analysis. Expression of sGFP under the control of the OsRab7B3 promoter increased in leaves when ABA and NaCl were applied or when kept in dark. In transgenic rice overexpressing OsRab7B3, the senescence-related genes were upregulated and leaf senescence was significantly enhanced under dark conditions. Moreover, leaf yellowing occurred earlier in the transgenic plants than in the wild type at the ripening stage. Hence it is suggested that OsRab7B3 act as a stress–inducible gene that plays an important role in the leaf senescence process.     

Leaf senescence in rice plants: cloning and characterization of senescence up-regulated genes.

To identify senescence-associated genes (SAGs) in rice leaves, senescence was induced by transferring rice seedlings into darkness. Senescence up-regulated cDNAs were obtained by PCR-based subtractive hybridization. Among 14 SAG clones characterized, 11 were found to be associated with both dark-induced and natural leaf senescence. Three clones were associated only with dark-induced leaf senescence. The possible physiological roles of these SAGs during rice leaf senescence are discussed.