植物叶片衰老的表观遗传调控

叶片是植物重要的光合器官, 它的衰老由外界环境刺激和内源发育信号所启动, 复杂的基因调控网络参与衰老过程的精确调控。最新研究表明, 植物通过对基因表达的重编程, 在表观遗传水平上调节着叶片衰老过程。该文简要介绍了表观遗传的分子机制, 在此基础上重点综述了组蛋白修饰、染色质重塑、DNA甲基化及小RNAs途径对叶片衰老调控的最新研究进展, 同时讨论了该领域存在的问题和未来研究方向。     

叶片衰老过程中的蛋白激酶和蛋白磷酸酶

衰老是受遗传程序严格控制的植物个体发育过程中的一个必经阶段,由特殊发育信号通过一定的信号传导路径来启动和控制。研究发现,蛋白激酶和蛋白磷酸酶所介导的可逆磷酸化反应在叶片衰老信号传递和衰老的启动和进程控制过程中发挥了重要作用。本文对近年参与叶片衰老调控的蛋白激酶和蛋白磷酸酶基因的分离鉴定及功能研究进行了综述。     

生长素与植物叶片衰老调控

作为植物叶片发育的最后一个阶段,叶片衰老的启动和进程由遗传程序严格控制,并受到内外源不同因子的协同调控.多种植物激素对叶片的衰老发挥重要的调控作用,目前认为乙烯、脱落酸、水杨酸、茉莉酸和油菜素甾醇等激素促进植物叶片衰老,而细胞分裂素和赤霉素则抑制植物叶片衰老.传统观念曾认为生长素对植物叶片衰老起负调节作用,但近年来越来越多的实验证据表明生长素是叶片衰老的正调节因子.本文旨在对生长素在叶片衰老调控中的功能和研究历程进行简要综述,为进一步理解植物叶片衰老调控中的激素功能奠定基础.     

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。     

植物衰老过程中的表观遗传学调控

植物衰老是由内外环境因子共同调节的,发生在细胞、组织、器官和个体等多个层面上的衰退和死亡过程,涉及基因表达、蛋白翻译和修饰水平变化以及多种细胞结构和代谢途径的变化,并与激素和生物/非生物胁迫的应答等过程形成复杂的调控网络。近年的研究表明,表观遗传修饰参与了对植物衰老过程的调节,是除经典遗传学以研究基因序列影响生物学功能之外在非核酸序列改变的情况下导致可遗传的基因表达变化的机制。本文综述了植物衰老过程中表观遗传调控的机理,包括染色质构象变化、DNA甲基化、组蛋白修饰、ATP依赖的重构因子和非编码RNA介导的调控等,并对这一领域今后的发展方向进行了展望。     

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.     

植物细胞分化过程中DNA甲基化及组蛋白修饰调控研究

在植物发育过程中,除了遗传调控激活或抑制基因表达来促进植物发育过程中细胞分化外,表观遗传学是另外一个重要的、复杂的调控层面,在该过程中通过DNA特异位点的甲基化,组蛋白的翻译后修饰改变染色质的状态,进而时空性调控植物发育调控因子的表达。分化细胞提供了一个研究组蛋白密码如何影响细胞命运功能强大的系统。本研究重点综述了表观遗传调控中DNA甲基化、组蛋白甲基化及组蛋白乙酰化在植物细胞分化中的调控作用。     

衰老的表观遗传调控机制北大核心CSCD

表观遗传通过调控基因表达影响众多生命过程。大量的证据表明,表观遗传在衰老调控中也发挥重要的作用。本文介绍表观遗传的3种主要机制对衰老的调控作用,及其对衰老的2个主要特征的影响。同时,介绍热量限制介导的抗衰老作用的表观遗传的调控机制,和3种重要的抗衰老活性小分子及其如何通过表观遗传相关机制发挥抗衰老作用。本文结果为进一步研究表观遗传在衰老调控中的作用,以及发展抗衰老干预措施提供了理论依据和重要的参考资料。     

衰老的表观遗传调控机制

表观遗传通过调控基因表达影响众多生命过程。大量的证据表明,表观遗传在衰老调控中也发挥重要的作用。本文介绍表观遗传的3种主要机制对衰老的调控作用,及其对衰老的2个主要特征的影响。同时,介绍热量限制介导的抗衰老作用的表观遗传的调控机制,和3种重要的抗衰老活性小分子及其如何通过表观遗传相关机制发挥抗衰老作用。本文结果为进一步研究表观遗传在衰老调控中的作用,以及发展抗衰老干预措施提供了理论依据和重要的参考资料。     

胎盘发生中的表观遗传学

胚外组织尤其是胎盘的正常发生对于维持哺乳动物胎儿在子宫中的发育和生长是必须的。胎盘发生是一个复杂的基因表达调控的过程,近年来的研究表明表观遗传在该过程中也起着重要作用。表观遗传调控在胎盘发生过程的几个主要事件中发挥作用,包括表观遗传对滋养层细胞分化和发育的调控、印记基因对胎盘发生和营养转运的调控、胎盘中的X染色体失活,以及胎盘表观遗传调控异常所导致的妊娠相关疾病。     

Epigenetic and small RNA regulation of senescence

Leaf senescence is regulated through a complex regulatory network triggered by internal and external signals for the reprogramming of gene expression. In plants, the major developmental phase transitions and stress responses are under epigenetic control. In this review, the underlying molecular mechanisms are briefly discussed and evidence is shown that epigenetic processes are also involved in the regulation of leaf senescence. Changes in the chromatin structure during senescence, differential histone modifications determining active and inactive sites at senescence-associated genes and DNA methylation are addressed. In addition, the role of small RNAs in senescence regulation is discussed.     

Androgenesis: Affecting the fate of the male gametophyte

Natural leaf senescence proceeds through an orderly program of events referred to, generally, as the 'senescence syndrome'. Leaf senescence consists of primarily, but not exclusively, a set of degradative and remobilization activities that salvage valuable nutrients by reallocation to the seeds or other viable parts of the plant. The program requires changes in gene expression and eventually culminates in death of the leaf or whole plant. Leaf/whole plant senescence has now been scrutinized extensively using molecular genetic approaches and a clearer picture of the events that comprise the developmental program is beginning to emerge. However, while understandings of the phenomenological aspects of the program have become apparent, the mechanistic aspects, particularly with regard to the processes required for induction and regulation of the program, are still far from clear. Molecular evidence suggests the process is complex in terms of the wide array of genes and activities expressed, and in terms of the overall regulation of progression of the events of the syndrome. This article attempts to review our current understanding of leaf senescence and includes a brief discussion of aspects of the process that require clarification if we are to more fully understand this complex developmental program.     

Natural developmental variations in leaf and plant senescence in Arabidopsis thaliana

Leaf senescence is a developmentally regulated process that contributes to nutrient redistribution during reproductive growth and finally leads to tissue death. Manipulating leaf senescence through breeding or genetic engineering may help to improve important agronomic traits, such as crop yield and the storage life of harvested organs. Here, we studied natural variations in the regulation of plant senescence among 16 Arabidopsis thaliana accessions. Chlorophyll content and the proportion of yellow leaves were used as indicator parameters to determine leaf and plant senescence respectively. Our study indicated significant genotype effects on the onset and development of senescence. We selected three late- and five early-senescence accessions for further physiological studies. The relationship between leaf and plant senescence was accession-dependent. There was a significant correlation between plant senescence and the total number of leaves, siliques and plant bolting age. We monitored expression of two senescence marker genes, SAG12 and WRKY53 , to evaluate progression of senescence. Our data revealed that chlorophyll content does not fully reflect leaf age, because even fully green leaves had already commenced senescence at the molecular level. Integrating senescence parameters, such as the proportion of senescent leaves, at the whole plant level provided a better indication of the molecular status of the plant than single leaf senescence parameters.     

Hormonal regulation of leaf senescence through integration of developmental and stress signals

Leaf senescence is a genetically controlled dismantling programme that enables plants to efficiently remobilise nutrients to new growing sinks. It involves substantial metabolic reprogramming whose timing is affected by developmental and environmental signals. Plant hormones have long been known to affect the timing of leaf senescence, but they also affect plant development and stress responses. It has therefore been difficult to tease apart how the different hormones regulate the onset and progression of leaf senescence, i.e., whether they directly affect leaf senescence or affect it indirectly by altering the developmental programme or by altering plants’ response to stress. Here we review research on hormonal regulation of leaf senescence and propose that hormones affect senescence through differential responses to developmental and environmental signals. We suggest that leaf senescence strictly depends on developmental changes, after which senescence can be induced, depending on the type of hormonal and environmental cues.     

Carbon/Nitrogen Imbalance Associated with Drought-Induced Leaf Senescence in Sorghum bicolor

Drought stress triggers mature leaf senescence, which supports plant survival and remobilization of nutrients; yet leaf senescence also critically decreases post-drought crop yield. Drought generally results in carbon/nitrogen imbalance, which is reflected in the increased carbon:nitrogen (C:N) ratio in mature leaves, and which has been shown to be involved in inducing leaf senescence under normal growth conditions. Yet the involvement of the carbon/nitrogen balance in regulation of drought-induced leaf senescence is unclear. To investigate the role of carbon/nitrogen balance in drought-induced senescence, sorghum seedlings were subjected to a gradual soil drought treatment. Leaf senescence symptoms and the C:N ratio, which was indicated by the ratio of non-structural carbohydrate to total N content, were monitored during drought progression. In this study, leaf senescence developed about 12 days after the start of drought treatment, as indicated by various senescence symptoms including decreasing photosynthesis, photosystem II photochemistry efficiency (Fv/Fm) and chlorophyll content, and by the differential expression of senescence marker genes. The C:N ratio was significantly enhanced 10 to 12 days into drought treatment. Leaf senescence occurred in the older (lower) leaves, which had higher C:N ratios, but not in the younger (upper) leaves, which had lower C:N ratios. In addition, a detached leaf assay was conducted to investigate the effect of carbon/nitrogen availability on drought-induced senescence. Exogenous application of excess sugar combined with limited nitrogen promoted drought-induced leaf senescence. Thus our results suggest that the carbon/nitrogen balance may be involved in the regulation of drought-induced leaf senescence.