植物的冷调节蛋白

冷害是世界范围内普遍存在的问题。冷驯化是通过低温诱导植物形成抗冷力的过程。冷调节蛋白是植物在冷驯化下产生的特异性蛋白质,与植物的抗冷力密切相关。随着分子生物技术的发展,成为近年来抗冷生理研究的热点之一。本文介绍了植物冷调节蛋白的分布、结构、性质、功能及诱导调控等方面的最新研究进展,并展望了将来的研究方向。     

植物冷驯化相关信号机制

植物经过非致死温度的处理可以获得更强的抗冷能力叫做冷驯化,主要包括寒驯化和冻驯化 .在冷驯化过程中,质膜首先感受冷信号,调节胞质中IP3的含量,诱导胞质Ca2+浓度的升高,从而激活CBF基因的表达.至今已经克隆了大量的冷调控基因,组成了复杂的信号传导网络,其中ICE1-CBF-COR通路在植物的冷驯化过程中起到重要的作用.ICE1基因编码一个MYB类型的碱性螺旋 环-螺旋（bHLH）转录因子,在上游调节CBF和 其它转录因子的表达,提高抗冷性. HOS1蛋白通过泛素化介导的蛋白降解负调控ICE1,另外,CBF还通过转录的自我调控保持恰当的表达水平.基因的分析研究证明,RNA修饰和核质转运在植物的抗冷过程中也具有重要作用.在不依赖于CBF的途径中,转录因子HOS9和HOS10在调节抗冷有关基因的表达和提高抗冷能力方面具有至关重要的作用.     

植物冷驯化的分子机理研究进展

植物冷驯化是一个非常复杂的过程,包括植物将感受到的低温信号转变成生化信号,以激活冷诱导基因的启动子,刺激特定的mRNA的转录,并在特定的组织中合成冷驯化蛋白.冷驯化蛋白通过增强膜脂流动性和阻止胞间冰晶形成等方式,以保护细胞免受低温伤害.冷驯化基因的表达以转录后调控为主,也有转录调控.某些冷诱导基因也可受ABA或其他环境胁迫(如高温、干旱、高盐、脱水等)诱导表达.     

植物ICE1-CBF冷反应通路的激活与调控研究进展

植物细胞可能是通过细胞膜流动性的改变引起胞质Ca2+浓度变化来感受低温信号的。胞质Ca2+浓度升高引起胞内多种钙调节蛋白的活性变化,再经过级联反应激活冷反应基因,增强植物的抗低温能力。目前,已基本清楚,冷反应基因激活的一条主要途径是ICE1-CBF调节通路。概括介绍了近年来植物低温信号感受、转导、冷反应基因的表达激活和调节方面的研究概况,旨在为植物冷驯化的进一步研究奠定理论基础。     

天山雪莲冷调节蛋白基因siCOR转化烟草植株的抗旱性分析

冷调节蛋白(cold regulated proteins, CORPs)是植物在冷驯化下产生的特异性蛋白, 与植物的抗寒性密切相关。然而, 大量研究表明, 绝大多数植物冷诱导基因同样会响应水分胁迫。采用半定量RT-PCR分析天山雪莲(Sasussured involucrata)冷调节蛋白基因siCOR的表达, 结果表明siCOR是一个受干旱胁迫诱导表达的基因。为研究siCOR基因是否与抗旱性相关, 以siCOR转基因烟草为研究材料, 利用水分胁迫处理进行抗旱性分析。结果表明与野生型(wild-type, WT)相比, 转siCOR植株叶片萎蔫较迟且程度较轻, 复水后恢复快且较完全; 其叶片相对含水量和PSII相对量子产率的降低幅度、相对电导率和丙二醛含量的升高幅度均低于野生型烟草植株。采用PEG6000模拟干旱胁迫, 发现转siCOR植株T3代种子的萌发率较高, 主根生长的受抑制程度较野生型轻。以上结果表明, siCOR基因在植物对干旱胁迫的响应中起重要作用。     

植物冷驯化相关基因研究进展

摘要 冷驯化是与提高植物抗冷性有关的生物化学及生理学过程, 主要包括寒驯化(cool acclimation)和冻驯化(freezing acdimation)。在冷驯化过程中, 植物体内许多基因在转录水平上的表达受到影响, 已经克隆了大量的相关基因,它们组成复杂的分子调控网络。目前研究表明不依赖ABA的低温信号转导途径是植物冷驯化机制的重要组成部分, 其中CBF/DREB1是该调控过程的关键转录因子, 与植物通过冷驯化而提高冰冻耐受能力密切相关。进一步利用转基因技术, 可有效地改善作物的耐冷性状。     

植物冷驯化相关基因研究进展

冷驯化是与提高植物抗冷性有关的生物化学及生理学过程,主要包括寒驯化（cool acclimation）和冻驯化（freezing acdimation）。在冷驯化过程中,植物体内许多基因在转录水平上的表达受到影响,已经克隆了大量的相关基因,它们组成复杂的分子调控网络。目前研究表明不依赖ABA的低温信号转导途径是植物冷驯化机制的重要组成部分,其中CBF/DREB1是该调控过程的关键转录因子,与植物通过冷驯化而提高冰冻耐受能力密切相关。进一步利用转基因技术,可以有效地改善作物的耐冷性状。     

植物耐冷性分子机理的研究进展

近年来对植物耐冷性分子机理的研究不断深入。主要体现在以下4个方面：植物的冷敏感性可以通过调节膜脂的不饱和脂肪酸水平得到调控,调节的途径是通过酰脂去饱和酶和甘油-3-磷酸酰基转移酶的作用;利用转基因技术在植物中超表达抗氧化酶基因,如编码SOD、APX、CAT和GR等的基因,可望提高耐冷性;植物低温逆境信号转导的研究表明,ABA不仅是重要的低温逆境信号,而且可调节冷害下基因的表达,Ca^2 是一个主要的第二信使,蛋白激酶途径也参与了植物冷害的信号转导;低温诱导的蛋白或酶类主要有脱水蛋白和热稳定蛋白。     

植物细胞中的抗寒物质及其与植物抗冷性的关系

论述存在于植物细胞中的抗寒物质,着重介绍植物细胞内的信使物质,并对胞内信使Ｃａ＾２＋与植物抗冷性的关系进行了讨论,指出Ｃａ＾２＋在抗冷力形成中的作用,以及研究胞内信使在调节植物抗冷性机理中尚存在的困难及必须解决的问题。     

植物耐冷性分子机理的研究进展

近年来对植物耐冷性分子机理的研究不断深入。主要体现在以下4个方面：植物的冷敏感性可以通过调节膜脂的不饱和脂肪酸水平得到调控,调节的途径是通过酰脂去饱和酶和甘油-3-磷酸酰基转移酶的作用;利用转基因技术在植物中超表达抗氧化酶基因,如编码SOD、 APX、CAT和GR等的基因,可望提高耐冷性;植物低温逆境信号转导的研究表明,ABA不仅是重要的低温逆境信号,而且可调节冷害下基因的表达,Ca2+是一个主要的第二信使,蛋白激酶途径也参与了植物冷害的信号转导;低温诱导的蛋白或酶类主要有脱水蛋白和热稳定蛋白。     

Using community-owned resource persons to provide early diagnosis and treatment and estimate malaria burden at community level in north-eastern Tanzania

ABSTRACT: BACKGROUND: Although early diagnosis and prompt treatment is an important strategy for control of malaria, using fever to initiate presumptive treatment with expensive artemisinin combination therapy is a major challenge; particularly in areas with declining burden of malaria. This study was conducted using community-owned resource persons (CORPs) to provide early diagnosis and treatment of malaria, and collect data for estimation of malaria burden in four villages of Korogwe district, north-eastern Tanzania. METHODS: In 2006, individuals with history of fever within 24 hours or fever (axillary temperature [greater than or equal to]37.5degreesC) at presentation were presumptively treated using sulphadoxine/pyrimethamine. Between 2007 and 2010, individuals aged five years and above, with positive rapid diagnostic tests (RDTs) were treated with artemether/lumefantrine (AL) while under-fives were treated irrespective of RDT results. Reduction in anti-malarial consumption was determined by comparing the number of cases that would have been presumptively treated and those that were actually treated based on RDTs results. Trends of malaria incidence and slide positivity rates were compared between lowlands and highlands. RESULTS: Of 15,729 cases attended, slide positivity rate was 20.4% and declined by >72.0% from 2008, reaching <10.0% from 2009 onwards; and the slide positivity rates were similar in lowlands and highlands from 2009 onwards. Cases with fever at presentation declined slightly, but remained at >40.0% in under-fives and >20.0% among individuals aged five years and above. With use of RDTs, cases treated with AL decreased from <58.0% in 2007 to <11.0% in 2010 and the numbers of adult courses saved were 3,284 and 1,591 in lowlands and highlands respectively. Malaria incidence declined consistently from 2008 onwards; and the highest incidence of malaria shifted from children aged <10 years to individuals aged 10-19 years from 2009. CONCLUSIONS: With basic training, supervision and RDTs, CORPs successfully provided early diagnosis and treatment and reduced consumption of anti-malarials. Progressively declining malaria incidence and slide positivity rates suggest that all fever cases should be tested with RDTs before treatment. Data collected by CORPs was used to plan phase 1b MSP3 malaria vaccine trial and will be used for monitoring and evaluation of different health interventions. The current situation indicates that there is a remarkable changing pattern of malaria and these areas might be moving from control to pre-elimination levels.     

Alterations in Membrane Protein-Profile during Cold Treatment of Alfalfa

Changes in pattern of membrane proteins during cold acclimation of alfalfa have been examined. Cold acclimation for 2 to 3 days increases membrane protein content. Labeling of membrane proteins in vivo with [³⁵S]methionine indicates increases in the rate of incorporation as acclimation progresses. Cold acclimation induces the synthesis of about 10 new polypeptides as shown by SDS-PAGE and fluorography of membrane proteins labeled in vivo.     

昆虫冷驯化机制研究进展

昆虫耐寒性强弱决定其种群的发生、扩散和分布,因此低温胁迫下昆虫的抗寒对策成为近期研究的热点领域。冷驯化作为一种非常有效的耐寒策略,可显著增强昆虫的耐寒性。本文论述了冷驯化的2种基本形式:快速冷驯化和长时冷驯化,明确了二者在提升昆虫耐寒性中的作用;并从宏观到微观的角度概述了冷驯化的作用机制,如组织和细胞水平的特异性,低分子量抗冻保护剂的产生,热休克蛋白的表达及功能,以及阻止细胞程序性死亡的潜在机理等;讨论了不同研究方法所引起的结果差异性,并强调了冷驯化作用机制的整体效益和综合效益。最后通过分析2种冷驯化形式的联系与区别,以期较为全面地阐明昆虫冷驯化的潜在机制。     

Fixation methods for the study of lipid droplets by immunofluorescence microscopy.

The study of proteins associated with lipid droplets in adipocytes and many other cells is a rapidly developing area of inquiry. Although lipid droplets are easily visible by light microscopy, few standardized microscopy methods have been developed. Several methods of chemical fixation have recently been used to preserve cell structure before visualization of lipid droplets by light microscopy. We tested the most commonly used methods to compare the effects of the fixatives on cellular lipid content and lipid droplet structure. Cold methanol fixation has traditionally been used before visualization of cytoskeletal elements. We found this method unacceptable for study of lipid droplets because it extracted the majority of cellular phospholipids and promoted fusion of lipid droplets. Cold acetone fixation is similarly unacceptable because the total cellular lipids are extracted, causing collapse of the shell of lipid droplet-associated proteins. Fixation of cells with paraformaldehyde is the method of choice, because the cells retain their lipid content and lipid droplet structure is unaffected. As more lipid droplet-associated proteins are discovered and studied, it is critical to use appropriate methods to avoid studying artifacts.     

脱水素在植物低温胁迫响应中的作用

脱水素(dehydrin)是一类胚胎发育后期丰富蛋白(LEA.late embryogenesis abundant proteins),含有富含赖氨酸的K片段,属于具有高度热稳定性的亲水性蛋白,在植物脱水条件下能保护细胞内蛋白质和膜结构免受破坏.低温胁迫下,耐低温植物细胞内部会发生一系列的生理生化反应来抵御低温所造成的伤害.很多研究表明植物脱水素的表达和积累与多种双子叶植物(包括草本和木本植物)以及冬季栽培的禾本科植物品种(特别是小麦和大麦)的耐低温能力密切相关.本文对近年来国内外关于脱水素的结构、功能以及内源ABA(abscisie acid)含量、拟南芥CBF(C-repeat binding factor)同源转录激活因子、春化基因、光周期信号等对脱水素基因的表达调控机制进行综述.     

植物冷激蛋白的研究进展

冷激蛋白是存在于细菌、植物与动物中的一类高度保守的核酸结合蛋白,其通过RNA分子伴侣活性参与转录、翻译及生长发育和逆境胁迫应答等细胞生理活动。本文主要从植物冷激蛋白的结构、表达模式、生物学功能以及应用前景等几个方面介绍了植物冷激蛋白的研究进展。     

Cold stress signaling networks in Arabidopsis

Cold is one of the critical environmental conditions that negatively affects plant growth and development and determines the geographic distribution of plants. Cold stress signaling is dynamic and interacts with many other signal transduction pathways to efficiently cope with adverse stress effects in plants. The cold signal is primarily perceived via Ca²⁺ channel proteins, membrane histidine kinases, or unknown sensors, which then activate the sophisticated cold-responsive signaling pathways in concert with phytohormone signaling, the circadian clock, and the developmental transition to flowering, as a part of the stress adaptation response. In this review, we focus on crosstalk between cold signaling and other signal transduction pathways in Arabidopsis.     

All's well that ends well.

A recent Cold Spring Harbour meeting(*) reviewed the latest progress on telomeres (the specialized structures that form the ends of chromosomes) and telomerase (the enzyme primarily responsible for their replication). Among the many aspects of telomere biology covered were strong sessions elaborating telomere replication and length regulation, telomerase structure and function, end-binding and telomere-associated proteins, DNA-damage-response proteins and telomerase-independent telomere maintenance.