谷胱甘肽在植物抗逆中的作用

在简要总结谷胱甘肽(GSH)的结构、分布、代谢和调控的基础上,概述了GSH在植物抗逆性方面的 作用,认为GSH通过植物体内螯合肽合成酶催化下聚合形成植物螯合肽来抵抗重金属的胁迫,作为抗氧化剂 参与低温伤害的保护,以亲核进攻一结合反应方式进行生物解毒等。讨论了GSH在植物抗逆性功能中的机 制,并就GSH今后在该方面的研究前景进行了展望。     

不饱和脂肪酸及其衍生物在植物抗逆反应中的作用

不饱和脂肪酸及其衍生物在植物抗逆反应中发挥着重要的生理功能,该文概述了这类物质生物功能的最新研究进展,并对不饱和脂肪酸及其衍生物的研究方向作了简单论述.     

DREB转录因子及其在植物抗逆中的作用

介绍了DREB(dehydration responsive element binding)转录因子及其在植物抗逆作用中的研究进展.DREB转录因子由逆环境胁迫诱导产生后,可激活其他多达12个依赖DRE顺式作用元件的抗逆功能基因,引起脯氨酸及蔗糖含量提高,从而增强植株对多种逆境(旱、冻及盐)的抵抗性.     

RNA干扰在植物中的作用机理及其应用研究进展

RNA干扰(RNAi)是广泛存在于生物中的一种现象,它是小干扰RNA诱导的转录后基因沉默,是生物抵抗异常DNA的一种保护机制,同时在生物生长发育过程中调控基因的表达.本文综述了近年来有关RNA干扰的发现、作用过程及其机理,分析了它与反义寡核苷酸、核酶、脱氧核酶的小同,并介绍了RNA干扰在植物基因功能、植物抗病毒、作物品种改良等方面的应用,为siRNA干扰的进一步利用提供参考资料.     

研究性教学模式在"植物的抗逆生理"教学中的应用

阐述了研究性教学的内涵及将之引入"植物的抗逆生理"教学的必要性,并介绍了开展研究性教学活动过程,评价了其教学效果.在此基础上就研究性教学模式下研究专题的选择、学生的成绩考核指标及教师扮演的角色等内容进行了讨论.     

脊椎动物病毒与微RNA

抗病毒作用是RNA干扰(RNAi)在植物及低等动物中的一个重要功能。一方面,宿主细胞编码并表达短干扰RNA(siRNA),对入侵细胞的病毒产生抑制作用;另一方面,病毒编码并表达特定的RNA或蛋白质,以对抗宿主细胞的RNAi。在部分脊椎动物病毒中已经发现多种由病毒编码的微RNA(miRNA),它们对病毒及细胞基因的表达有重要的调节作用。同时,某些细胞miRNA也可影响脊椎动物病毒的复制。然而,RNAi在脊椎动物细胞中是否具有广谱抗病毒活性、脊椎动物病毒又是否普遍编码miRNA及普遍具备拮抗RNAi的机制?目前尚无定论,有待于进一步的研究加以阐明。     

植物对水分胁迫响应的分子机制与抗逆基因工程的研究进展（综述）

对近年来植物对水分胁迫（包括干旱、盐害和低温）响应的分子机制的研究进展以及水分胁迫中诱导的植物基因产物的种类、功能及其相关的基因工程作一简要的综述,同时对今后的研究方向提出了一些看法。     

植物中的非编码RNA及其作用机制

非编码RNA(non-codingRNA,ncRNA)是近年来发现的一类能够转录但不能编码蛋白质、具有特定功能的RNA分子。ncRNA参与了生命过程中的许多重要环节。该文主要介绍植物中的非编码RNA的类型、研究方法以及功能。     

十字花科黑腐病菌中一个与抗逆有关的小RNA的鉴定

十字花科黑腐病菌(Xanthomonas campestris pathovar campestris,Xcc),是引起十字花科植物黑腐病的病原菌。Xcc要经历寄生、腐生等多种环境变化,为适应这些环境变化,需要调控相应基因的表达。除蛋白外,小RNA在基因表达调控中也起到关键作用。本实验室前期实验从Xcc 8004中鉴定出数百个小RNA,但是绝大多数小RNA的功能仍然未知。本研究通过构建一个小RNA(sRNA3843)的过量表达株来研究其生物学功能。确定该小RNA过量表达后,对其过量表达株OE3843进行了一系列的表型检测。结果发现,s RNA3843过量表达株OE3843对金属离子Cu^2+、Zn^2+、Cd^2+及蛋白变性剂SDS的耐受能力明显下降,表明s RNA3843与Xcc的抗逆有关。本研究的实验结果为深入研究小RNA在Xcc抗逆中所起的作用及其作用机理打下基础。     

微小RNA在心肌重塑中的作用

微小RNA (microRNA, miRNA)是一类含有约22个核苷酸的内源性非编码RNA, 通过与靶mRNA的3′非翻译区(3′ UTR)互补配对, 抑制翻译或促进靶mRNA的降解介导转录后基因调控,涉及多种生物学过程.目前研究表明,miRNA参与了心脏的发育、病理性心肌肥大等过程,表明miRNA可作为新的治疗心肌肥大的靶向分子.本文就新近有关miRNA在心肌重塑中的研究进展予以综述.     

The role of microRNA in abiotic stress response in plants

Regulation of gene expression via microRNA is the key mechanism of response to biotic and abiotic stresses in plants. There are a lot of experimental data on the biological function of microRNAs in response to different stresses in various plant species. This review contains up-to-date information on molecular mechanisms of microRNA action in plants in response to abiotic stresses, including drought, salinity, mineral nutrient deficiency or imbalance.     

The roles of microRNA in cancer and apoptosis

microRNAs (miRNAs) are highly conserved, non-protein-coding RNAs that function to regulate gene expression. In mammals this regulation is primarily carried out by repression of translation. miRNAs play important roles in homeostatic processes such as development, cell proliferation and cell death. Recently the dysregulation of miRNAs has been linked to cancer initiation and progression, indicating that miRNAs may play roles as tumour suppressor genes or oncogenes. The role of miRNAs in apoptosis is not fully understood, however, evidence is mounting that miRNAs are important in this process. The dysregulation of miRNAs involved in apoptosis may provide a mechanism for cancer development and resistance to cancer therapy. This review examines the biosynthesis of miRNA, the mechanisms of miRNA target regulation and the involvement of miRNAs in the initiation and progression of human cancer. It will include miRNAs involved in apoptosis, specifically those miRNAs involved in the regulation of apoptotic pathways and tumour suppressor/oncogene networks. It will also consider emerging evidence supporting a role for miRNAs in modulating sensitivity to anti-cancer therapy.     

The developmental role of microRNA in plants

MicroRNAs (miRNAs) are single-stranded RNA molecules of around 22 nucleotides (nt) in length that are associated with the RNA-induced silencing complex (RISC). They play an important role in plant development, either by targeting mRNA for cleavage or by inhibiting translation. Over the past year, the list of known miRNAs, confirmed targets and developmental effects has expanded, as has the realization that they are conserved during evolution and that small RNAs can play a direct role in cell-cell signaling.     

微小RNA在tau蛋白过度磷酸化中的作用

阿尔茨海默病(Alzheimer’s Disease, AD)是一种慢性神经系统退行性疾病,AD的主要病理表现为脑组织中的老年斑和神经纤维缠结,老年斑的主要成分是异常积聚的β-淀粉样蛋白,过度磷酸化的tau蛋白是神经纤维缠结的主要成分。研究发现AD患者脑内微小RNA表达异常,且证据表明微小RNA参与β-淀粉样蛋白过量生成和tau蛋白过度磷酸化等Alzheimer样病理机制,在AD的发病中起着重要作用。本文就微小RNA在tau蛋白过度磷酸化中的作用及机制进行概述。     

植物根边缘细胞的抗逆性研究进展

综述了近几年来国内外有关植物根边缘细胞抗逆性方面的研究,重点概述植物根边缘细胞对生物与非生物胁迫的响应及其相应的抗性机理。在生物胁迫下,边缘细胞能吸引和固定病原根结线虫,排斥或约束致病性细菌,可作为真菌感染的假目标,减少或避免各种病原菌对根尖的伤害。在非生物胁迫下,边缘细胞通过分泌粘液、诱导ROS产生刺激细胞死亡以抵抗铝毒,并通过其数量的改变来调节高温、高浓度CO2等多种生理反应。最后在当前植物根边缘细胞研究的基础上,提出了今后的研究方向。     

Role of cytokinins in stress resistance of plants

The facts of both positive and negative influences of cytokinins on stress resistance of plants are known today. Without pretending to a final choice between these points of view, we have made an attempt to analyze the details of the experiments that gave rise to conclusions about the nature of the effect of cytokinins on the resistance to stress-causing influences with a focus on their intensity and duration. The review deals with the data concerning the influence of different adverse factors on the content of endogenous cytokinins and transduction of cytokinin signals, examines the influence on plant resistance of treatment with exogenous hormone, and the effects of genetic modifications causing changes in cytokinin content and signaling. Resistance is considered not only as a mean of plant survival under severe stress but also as an instrument of maintaining growth rate in plants exposed to moderate stress. Literature data and our own results make it possible to conclude that cytokinins play an important role in formation of plant resistance to adverse influences; however, the effect of these hormones depends on stress intensity. Under moderate stress, cytokinins ensure maintenance of plant growth, whereas a drop in cytokinins hampers growth under a strong influence of adverse factors, which is a prerequisite for mobilization of limited resources characteristic of severe stress and ensures preservation of plant viability.     

茉莉酸在植物抗逆性中的研究进展

茉莉酸(jasmonic acid, JA)是一种植物内源合成的脂类激素，在植物响应胁迫的调控中发挥着重要作用。本文概括了JA的生物合成与代谢途径及其调控机制；总结了JA信号的传导通路；系统归纳了JA在植物响应生物和非生物胁迫应答中的作用机制和调控网络，重点关注了最新的研究进展。此外，本文梳理了JA与其他植物激素在植物抗逆性调节过程中的信号交流。最后讨论了JA信号通路介导的植物抗逆性研究中亟待解决的问题，并展望了新的分子生物学技术在调控JA信号通路增强作物抗性中的应用前景，以期为植物的抗逆性研究和改良提供参考。     

Ammonium enhances resistance to salinity stress in citrus plants

In this work, we demonstrate that NH?? nutrition in citrange Carrizo plants acts as an inducer of resistance against salinity conditions. We investigated its mode of action and provide evidence that NH?? confers resistance by priming abscisic acid and polyamines, and enhances H?O? and proline basal content. Moreover, we observed reduced Cl? uptake as well as enhanced PHGPx expression after salt stress. Control and N-NH?? plants showed optimal growth. However, N-NH?? plants displayed greater dry weight and total lateral roots than control plants, but these differences were not observed for primary root length. Our results revealed that N-NH?? treatment induces a similar phenotypical response to the recent stress-induced morphogenetic response (SIMRs). The hypothesis is that N-NH?? treatment triggers mild chronic stress in citrange Carrizo plants, which might explain the SIMR observed. Moreover, we observed modulators of stress signaling, such as H?O? in N-NH?? plants, which could acts as an intermediary between stress and the development of the SIMR phenotype. This observation suggests that NH?? treatments induce a mild stress condition that primes the citrange Carrizo defense response by stress imprinting and confers protection against subsequent salt stress.