基因芯片技术分析转SlNAC10基因拟南芥非生物胁迫相关差异表达基因

NAC(NAM、ATAF1/2和CUC2)转录因子是植物特有的转录调控因子,在植物的器官建成、生长发育以及抵御非生物胁迫等方面发挥着至关重要的作用。该文利用基因芯片技术筛选转Sl NAC10基因拟南芥和野生型拟南芥非生物胁迫抗性相关差异表达基因,并通过实时荧光定量PCR对部分差异表达基因进行验证。芯片结果显示,差异表达2倍以上的基因有4 054个,其中与非生物胁迫相关基因有15个,与非生物胁迫相关的转录因子基因有14个,这些基因参与应答渗透胁迫、响应高盐、冷、热、高光强等胁迫。对差异表达2倍以上的基因进行GO(Gene Ontology)分析和KEGG(Kyoto Encyclopedia of Genes and Genomes)分析,发现这些基因在非生物胁迫相关的13个注释中富集,涉及相关代谢途径96个,其中包括植物激素信号转导、精氨酸和脯氨酸代谢、吲哚生物碱合成、谷胱甘肽代谢等。以上结果表明,SlNAC10可直接或间接调控多种下游基因的表达,提高植物抵御非生物胁迫的能力。     

干旱对水稻生物钟基因和干旱胁迫响应基因每日节律性变化的影响

内源生物钟的节律运动不仅调控植物的生长发育,而且在调控植物响应和适应环境过程中发挥重要的作用。为了解水稻(Oryza sativa L.)干旱胁迫响应基因和生物钟基因在干旱条件下每日表达变化情况,本文利用实时荧光定量PCR方法研究旱稻品种IRAT109在干旱胁迫下相关基因的表达变化。结果表明,干旱胁迫导致早晨生物钟基因OsPRRs、OsLHY和OsZTL1的表达量显著下降,振幅减弱;同时导致夜晚生物钟基因OsTOC1、OsGI和OsELF3整体表达量升高,振幅增强,但对OsFKF1基因影响不大。同样,大部分水稻干旱胁迫响应基因在干旱胁迫后整体表达量显著升高,但OsDST基因表达量下降;同时大部分抗逆基因周期性表达被扰乱,但OsCIPK12、OsCDPK7和OsDREB1A依然保持24 h内震荡。本研究结果表明干旱胁迫能影响生物钟元件的基因表达,这种互相影响改变了部分基因每日的震荡变化。     

水稻受盐抑制基因OsZFP1的转基因分析

OsZFP1(水稻锌指蛋白1)基因编码的蛋白含有3个推测的Cys2/Cys2-型锌指结构域,它的表达受盐胁迫负调控。构建了以35S为启动子的OsZFP1基因的植物表达载体,并将其转入拟南芥(ArabidopsisthalianaL.)植物和水稻(OryzasativaL.)愈伤组织中以过量表达OsZFP1基因。转基因的拟南芥植株和水稻愈伤组织对盐处理的敏感性都比野生型要高。这一结果表明OsZFP1基因可能编码一种负调控蛋白,它可能抑制某些盐诱导基因的表达。在ABA处理下,转基因拟南芥植株比野生型植株抽苔晚,说明OsZFP1基因的作用可能受ABA调节。     

CONSTANS LIKE 7参与调控拟南芥生物钟

植物的生物钟节律可以被环境中的光/黑暗以及冷/热循环所诱导,并使其与环境同步。植物生物钟由输入途径、中央振荡器、输出途径组成。目前对植物生物钟的研究已经揭示生物钟最基本的组成,但是关于生物钟的运作机理及网络还需要进一步研究。CONSTANS LIKE 7(COL7)是CONSTANS(CO)的家族基因。以拟南芥野生型(wild type,WT)、突变体col7以及COL7过量表达转基因株系COL7-OX-10和COL7-OX-11为材料,利用定量PCR、叶片运动等方法,分析COL7是否受生物钟调控以及COL7是否参与调控生物。实验结果显示:COL7不仅受生物钟调控,同时也参与调控生物钟。     

水稻受盐抑制基因OsZFP1的转基因分析

OsZFP1(水稻锌指蛋白1)基因编码的蛋白含有3个推测的Cys2/Cys2-型锌指结构域,它的表达受盐胁迫负调控.构建了以35S为启动子的OsZFP1基因的植物表达载体,并将其转入拟南芥(Arabidopsis thaliana L.)植物和水稻(Oryza sativa L.)愈伤组织中以过量表达OsZFP1基因.转基因的拟南芥植株和水稻愈伤组织对盐处理的敏感性都比野生型要高.这一结果表明OsZFP1基因可能编码一种负调控蛋白,它可能抑制某些盐诱导基因的表达.在ABA处理下,转基因拟南芥植株比野生型植株抽苔晚,说明OsZFP1基因的作用可能受ABA调节.     

应用基因芯片分析植物内生菌醇提取物处理条件下水稻的基因表达图谱

为探索植物内生菌R(人参)与D(越橘)醇提取混合物RD对水稻的促进生长、增强抗病性的作用机制,采用基因芯片技术对RD处理的水稻基因组进行分析,检测RD处理水稻后差异表达基因。结果显示,检测到差异表达基因1 171个,其中上调表达基因671个,下调表达基因500个。根据基因芯片的试验结果,采用Go注释系统对差异表达基因进行功能注释表明,主要为刺激应答、转录调控、生理功能、结合功能、细胞过程、代谢功能等。代谢途径的变化存在明显差异,表达量上调代谢通路39条,表达量下调代谢途径24条。说明植物内生菌R与D醇提取混合物处理影响水稻性状的表达不是某个基因孤立、单一的作用,而是多方面、多层次共同作用的结果。     

水稻生物钟相关基因的表达特征鉴定及其功能预测分析

水稻作为我国重要农作物,其营养生长和生殖发育过程都受到严格的生物钟的控制,因此,生物钟基因的表达变化也是决定水稻产量和种子质量的主要决定因素之一。为了更全面系统的了解生物钟基因在水稻生长和发育过程中的功能,本研究采用生物信息学共表达方法,筛选和鉴定水稻和拟南芥中生物钟基因,并对比分析了这些生物钟基因在单双子叶模式植物中的可能功能。从水稻表达谱公共数据库中筛选与生物钟基因表达密切相关732个基因,并对筛选出的水稻生物钟相关基因进行表达特性、节律性、生物功能预测及其与拟南芥的对比分析,结果表明水稻和拟南芥的生物钟基因可能都具有在生物钟核心振荡器部分功能相对保守的特点。功能预测分析也还表明水稻生物钟基因参与了8类生物学过程,尤其在应激反应和代谢过程的方面具有明显富集性,从而间接佐证了水稻对于外界环境的响应及其代谢过程具有严格时间调控的分子机理。     

小麦E3泛素连接酶基因TaAIRP2-1B克隆及功能分析

干旱等非生物胁迫严重影响农作物生产。本研究克隆了小麦(Triticum aestivum L.)TaAIRP2-1B基因,探讨其对非生物胁迫的响应机制,为促进小麦抗旱性的遗传改良提供基因资源。组织特异性表达模式分析显示,TaAIRP2-1B基因在小麦抽穗期的各个组织中均有表达,在茎组织中的表达水平较高,而根系中的表达水平较低。非生物胁迫表达模式分析显示,Ta AIRP2-1B受ABA、PEG及冷胁迫诱导表达。过表达TaAIRP2-1B拟南芥在0.4μmol/L的ABA处理条件下,种子发芽率显著低于野生型,表明TaAIRP2-1B提高了拟南芥种子萌发期对ABA的敏感性。ABA处理抑制转基因和野生型拟南芥幼苗的根系生长,但转基因拟南芥受抑制程度显著高于野生型,表明TaAIRP2-1B提高了拟南芥幼苗对ABA的敏感性。转基因结果表明超表达TaAIRP2-1B增强了拟南芥的抗旱性,并且转基因株系的保水率显著高于野生型。总之,本研究发现小麦基因Ta AIRP2-1B参与了植物对非生物胁迫的应答,可能是通过ABA途径正向调控植物的抗旱性。     

水稻NAM基因家族的全基因组鉴定及表达分析（英文）

植物特异性转录因子NAM家族从属于NAC转录因子超家族,在植株生长发育、生理代谢以及应对各种胁迫反应中均发挥重要作用。该研究采用生物信息学方法鉴定水稻基因组中的NAM基因,分析其时空表达模式、亚细胞定位以及蛋白相互作用,并采用实时定量qRT-PCR方法分析不同外源激素(如SA、ABA和MeJA)以及非生物胁迫(包括干旱、盐和冷)处理下各NAM基因的表达特征,为进一步探索NAM基因在非生物胁迫中的功能和应激机制以及激素调控途径奠定基础。结果显示:(1)从水稻基因组中共鉴定出48个NAM基因,进化分析将其分为5个亚家族;NAM基因在水稻基因组中存在9对片段复制事件。(2)组织表达分析显示,NAM基因在水稻不同组织及发育时期表现特异性表达,特别是叶鞘、茎和节的生长过程中高表达,且大多数是核定位,并存在多种蛋白互作。(3)实时定量qRT-PCR表达分析显示,10个NAM基因在不同组织中均特异表达;大部分NAM基因在盐和干旱胁迫下表达上调,而在冷胁迫下表达降低;SA、ABA和MeJA处理均可显著改变各NAM基因的表达水平。研究表明,NAM基因在水稻生长发育、激素应答和非生物胁迫响应中具有重要作用。     

内生菌次生代谢产物提高玉米渗透胁迫抗性的表达谱分析

利用基因芯片技术对10%PEG渗透胁迫下植物内生菌次生代谢产物处理的玉米进行差异基因表达谱分析。结果显示,检测到的差异表达基因共计441个,其中上调表达基因147个,下调表达基因294个,参与21条代谢通路。采用晶芯生物分子功能注释系统V 3.0(MAS)将差异表达基因进行GO功能分类,其中45%基因参与各种生物学过程;18%基因与生成各种细胞组分有关;36%基因编码产物则与执行各种分子功能有关;1%与Gen Bank中功能未知序列相对应。KEGG代谢分析表明差异表达基因广泛涉及基础物质代谢、能量代谢、次生代谢及信号转导途径。表达谱分析结果表明,在渗透胁迫下次生代谢产物对玉米的影响是一个多基因参与、多个生物途径协同调控的过程。     

Conserved expression profiles of circadian clock-related genes in two Lemna species showing long-day and short-day photoperiodic flowering responses

The Lemna genus is a group of monocotyledonous plants with tiny, floating bodies. Lemna gibba G3 and L. paucicostata 6746 were once intensively analyzed for physiological timing systems of photoperiodic flowering and circadian rhythms since they showed obligatory and sensitive photoperiodic responses of a long-day and a short-day plant, respectively. We attempted to approach the divergence of biological timing systems at the molecular level using these plants. We first employed molecular techniques to study their circadian clock systems. We developed a convenient bioluminescent reporter system to monitor the circadian rhythms of Lemna plants. As in Arabidopsis, the Arabidopsis CCA1 promoter produced circadian expression in Lemna plants, though the phases and the sustainability of bioluminescence rhythms were somewhat diverged between them. Lemna homologs of the Arabidopsis clock-related genes LHY/CCA1, GI, ELF3 and PRRs were then isolated as candidates for clock-related genes in these plants. These genes showed rhythmic expression profiles that were basically similar to those of Arabidopsis under light-dark conditions. Results from co-transfection assays using the bioluminescence reporter and overexpression effectors suggested that the LHY and GI homologs of Lemna can function in the circadian clock system like the counterparts of Arabidopsis. All these results suggested that the frame of the circadian clock appeared to be conserved not only between the two Lemna plants but also between monocotyledons and dicotyledons. However, divergence of gene numbers and expression profiles for LHY/CCA1 homologs were found between Lemna, rice and Arabidopsis, suggesting that some modification of clock-related components occurred through their evolution.     

Functional conservation of clock-related genes in flowering plants: overexpression and RNA interference analyses of the circadian rhythm in the monocotyledon Lemna gibba

Circadian rhythms are found in organisms from cyanobacteria to plants and animals. In flowering plants, the circadian clock is involved in the regulation of various physiological phenomena, including growth, leaf movement, stomata opening, and floral transitions. Molecular mechanisms underlying the circadian clock have been identified using Arabidopsis (Arabidopsis thaliana); the functions and genetic networks of a number of clock-related genes, including CIRCADIAN CLOCK ASSOCIATED1, LATE ELONGATED HYPOCOTYL (LHY), TIMING OF CAB EXPRESSION1, GIGANTEA (GI), and EARLY FLOWERING3 (ELF3), have been analyzed. The degree to which clock systems are conserved among flowering plants, however, is still unclear. We previously isolated homologs for Arabidopsis clock-related genes from monocotyledon Lemna plants. Here, we report the physiological roles of these Lemna gibba genes (LgLHYH1, LgLHYH2, LgGIH1, and LgELF3H1) in the circadian system. We studied the effects of overexpression and RNA interference (RNAi) of these genes on the rhythmic expression of morning- and evening-specific reporters. Overexpression of each gene disrupted the rhythmicity of either or both reporters, suggesting that these four homologs can be involved in the circadian system. RNAi of each of the genes except LgLHYH2 affected the bioluminescence rhythms of both reporters. These results indicated that these homologs are involved in the circadian system of Lemna plants and that the structure of the circadian clock is likely to be conserved between monocotyledons and dicotyledons. Interestingly, RNAi of LgGIH1 almost completely abolished the circadian rhythm; because this effect appeared to be much stronger than the phenotype observed in an Arabidopsis gi loss-of-function mutant, the precise role of each clock gene may have diverged in the clock systems of Lemna and Arabidopsis.     

脂代谢相关三基因突变小鼠肝脏差异表达蛋白组研究

应用双向电泳及质谱技术对5周龄三基因(apoE^-1- / LDLR^-1-/Lepr^db/db)联合突变小鼠和野生型小鼠肝组织的差异蛋白质进行比较研究,借此分析脂代谢相关三基因联合突变小鼠肝脏蛋白质表达特点,研究差异表达蛋白与血脂代谢紊乱和动脉粥样硬化的关系.在实验中检测到三基因联合突变小鼠和野生型小鼠肝脏中分别平均有（841±57）个和（1 017±50）个蛋白点（n=3）,两者的平均匹配率分别为71.9%,83.2%.三基因联合突变小鼠有140个蛋白点未能与野生型小鼠匹配,其中相差5倍以上的上调点和下调点分别为7个和39个.选取其中的6个点做质谱分析,鉴定为endoplasmin precursor(Grp-94)、酸性富亮氨酸核磷蛋白32家族成员A(acidic leucin-rich nuclear phosphoprotein 32 family member A)、转铁蛋白前体、果糖二磷酸酶1、纤维连接蛋白前体、补体C3前体,纤维蛋白原B β多肽7种蛋白. 该结果提示,差异表达的蛋白对三基因联合突变小鼠的血脂代谢紊乱和动脉粥样硬化发生发展过程起一定作用.     

An In Vitro ES Cell-Based Clock Recapitulation Assay Model Identifies CK2α as an Endogenous Clock Regulator

We previously reported emergence and disappearance of circadian molecular oscillations during differentiation of mouse embryonic stem (ES) cells and reprogramming of differentiated cells, respectively. Here we present a robust and stringent in vitro circadian clock formation assay that recapitulates in vivo circadian phenotypes. This assay system first confirmed that a mutant ES cell line lacking Casein Kinase I delta (CKIδ) induced ∼3 hours longer period-length of circadian rhythm than the wild type, which was compatible with recently reported results using CKIδ null mice. In addition, this assay system also revealed that a Casein Kinase 2 alpha subunit (CK2α) homozygous mutant ES cell line developed significantly longer (about 2.5 hours) periods of circadian clock oscillations after in vitro or in vivo differentiation. Moreover, revertant ES cell lines in which mutagenic vector sequences were deleted showed nearly wild type periods after differentiation, indicating that the abnormal circadian period of the mutant ES cell line originated from the mutation in the CK2α gene. Since CK2α deficient mice are embryonic lethal, this in vitro assay system represents the genetic evidence showing an essential role of CK2α in the mammalian circadian clock. This assay was successfully applied for the phenotype analysis of homozygous mutant ES cells, demonstrating that an ES cell-based in vitro assay is available for circadian genetic screening.     

Differential effects of two period genes on the physiology and proteomic profiles of mouse anterior tibialis muscles

The molecular components that generate and maintain circadian rhythms of physiology and behavior in mammals are present both in the brain (suprachiasmatic nucleus; SCN) and in peripheral tissues. Examination of mice with targeted disruptions of either mPer1 or mPer2 has shown that these two genes have key roles in the SCN circadian clock. Here we show that loss of the clock gene mPer2 affects forced locomotor performance in mice without altering muscle contractility. A proteomic analysis revealed that the anterior tibialis muscles of the mPer2 knockout mice had higher levels of glycolytic enzymes such as triose phosphate isomerase and enolase than those of either the wild type or mPer1 knockout mice. In addition, the level of expression of HSP90 in the mPer2 mutant mice was also significantly higher than in wildtype mice. These results suggest that the reduced locomotor endurance of the mPer2 knockout mice reflects a greater dependence on anaerobic metabolism under stress conditions, and that the two canonical clock genes, mPer1 and mPer2, play distinct roles in the physiology of skeletal muscle.     

Feeding cues and injected nutrients induce acute expression of multiple clock genes in the mouse liver

The circadian clock is closely associated with energy metabolism. The liver clock can rapidly adapt to a new feeding cycle within a few days, whereas the lung clock is gradually entrained over one week. However, the mechanism underlying tissue-specific clock resetting is not fully understood. To characterize the rapid response to feeding cues in the liver clock, we examined the effects of a single time-delayed feeding on circadian rhythms in the liver and lungs of Per2::Luc reporter knockin mice. After adapting to a night-time restricted feeding schedule, the mice were fed according to a 4, 8, or 13 h delayed schedule on the last day. The phase of the liver clock was delayed in all groups with delayed feeding, whereas the lung clock remained unaffected. We then examined the acute response of clock and metabolism-related genes in the liver using focused DNA-microarrays. Clock mutant mice were bred under constant light to attenuate the endogenous circadian rhythm, and gene expression profiles were determined during 24 h of fasting followed by 8 h of feeding. Per2 and Dec1 were significantly increased within 1 h of feeding. Real-time RT-PCR analysis revealed a similarly acute response in hepatic clock gene expression caused by feeding wild type mice after an overnight fast. In addition to Per2 and Dec1, the expression of Per1 increased, and that of Rev-erbα decreased in the liver within 1 h of feeding after fasting, whereas none of these clock genes were affected in the lung. Moreover, an intraperitoneal injection of glucose combined with amino acids, but not either alone, reproduced a similar hepatic response. Our findings show that multiple clock genes respond to nutritional cues within 1 h in the liver but not in the lung.