绿色荧光蛋白表达载体pXS75－GFP的构建及在嗜热四膜虫中的应用

为获得能够用于构建嗜热四膜虫蛋白定位的载体,该研究将GFP基因与镉（Cd2＋）诱导的四膜虫金属硫蛋白基因（MTTl）启动子序列和终止子序列融合,获得表达载体pXS75-GFP。通过同源重组和抗性筛选,pXS75-GFP载体携带的目的基因整合入四膜虫MTTl位点,在cd2＋诱导下实现GFP融合蛋白的可控表达。将α－tubulin基因ATUl克隆JN－pXS75－GFP中,重组质粒pXS75－GFP－ATUl通过基因枪转化入四膜虫细胞,在巴龙霉素筛选下获得稳定的α-tubulin－GFP过表达细胞株。激光共聚焦显微镜观察α－tubulin．GFP的定位,结果显示,α－tubulin—GFP融合蛋白在四膜虫细胞中表达并分布于皮层上,表明pXS75．GFP载体可用于嗜热四膜虫功能蛋白的定位分析。     

基于农杆菌介导瞬时转化法的AtGLR1.4亚细胞定位分析

将拟南芥基因AtGLR1.4启动子驱动的AtGLR1.4基因与绿色荧光蛋白(GFP)基因融合后,利用根瘤农杆菌介导瞬时转化法(Fast Agro-mediated Seedling Transfomation,FAST)浸染拟南芥幼苗,对其进行亚细胞定位的研究。转基因植株通过激光共聚焦扫描显微镜的观察,发现GFP绿色荧光在叶片表皮细胞的细胞膜上特异表达,表明At-GLR 1.4蛋白定位于细胞质膜上,为其后续的功能研究提供了线索。     

拟南芥谷氨酸受体基因的亚细胞定位

为明确拟南芥谷氨酸受体1.3基因(AtGLR1.3)的亚细胞定位,该实验以拟南芥(Arabidopsis thalianaCo-lumbia ecotype)为材料,运用PCR方法从其基因组中扩增得到了AtGLR1.3的启动子和基因序列,将其连接到载体pBIsGFP上,构建成AtGLR1.3基因与绿色荧光蛋白基因融合的植物表达载体,通过农杆菌介导的花序浸润法将重组载体转化拟南芥野生型,转基因植株通过激光共聚焦扫描显微镜观察显示,GFP荧光信号存在于细胞质膜上,表明AtGLR1.3为细胞膜蛋白.该结果为进一步研究AtGLR1.3的作用机理奠定了基础.     

甘蓝型油菜线粒体功能未知基因 ORF 117的载体构建与转化

本研究克隆了甘蓝型油菜线粒体功能未知基因 ORF 117,构建了带有线粒体转运信号肽序列（TP ）的植物过表达载体35S ∷TP-ORF117、35S ∷TP-EGFP 和35S ∷TP-ORF117-EGFP ,转化野生型拟南芥并进行抗除草剂筛选,共获得纯合的转基因拟南芥株系62个。qPCR 表明,ORF 117在转基因材料中得到高效过表达。用转35S ∷TP-EGFP 、35S ∷TP-ORF117-EGFP 拟南芥制备原生质体,经线粒体特异染料染色,在激光共聚焦显微镜下做线粒体、GFP 共定位检测,GFP 蛋白和 ORF117-EGFP 融合蛋白被准确定位到了线粒体。     

拟南芥未知功能基因At4g22890 编码蛋白的叶绿体定位

蛋白质的亚细胞定位信息对于深入了解该蛋白质的功能具有重要意义。本文对一个预测的拟南芥叶绿体未知功能基因At4g22890 编码蛋白进行了叶绿体定位研究。我们克隆了该基因5′端长208 bp 的DNA 片段, 与绿色荧光蛋白(GFP) 基因构建重组表达载体pMON530-cTP-GFP, 经农杆菌介导转化拟南芥。转基因植株经激光共聚焦显微镜观察, GFP 荧光仅在叶绿体中观察到, 表明所克隆的DNA 序列编码的多肽能够将At4g22890 编码蛋白质引导进入叶绿体, 由此推测该蛋白质为叶绿体蛋白质。     

拟南芥未知功能基因At4g22890编码蛋白的叶绿体定位

蛋白质的亚细胞定位信息对于深入了解该蛋白质的功能具有重要意义。本文对一个预测的拟南芥叶绿体未知功能基因At4g22890编码蛋白进行了叶绿体定位研究。我们克隆了该基因5′端长208bp的DNA片段,与绿色荧光蛋白(GFP)基因构建重组表达载体pMON530-cTP-GFP,经农杆菌介导转化拟南芥。转基因植株经激光共聚焦显微镜观察,GFP荧光仅在叶绿体中观察到,表明所克隆的DNA序列编码的多肽能够将At4g22890编码蛋白质引导进入叶绿体,由此推测该蛋白质为叶绿体蛋白质。     

拟南芥未知功能基因At3g61870编码蛋白的叶绿体定位研究

利用反向遗传学研究方法对1个预测的拟南芥叶绿体未知功能基因At3g61870编码蛋白进行了亚细胞定位研究.通过克隆At3g61870基因5′端长229 bp的DNA片段,与绿色荧光蛋白(GFP)基因构建重组表达载体pMON530-CP-TP-GFP,经农杆菌介导转化拟南芥.转基因植株的叶肉细胞经激光共聚焦显微镜观察,叶绿素自发荧光与GFP荧光共定位于叶绿体中.结果表明,未知功能基因At3g61870编码的蛋白质为叶绿体蛋白质.     

两种瞬时表达体系研究拟南芥Profilin-1的亚细胞定位

使用两种瞬时表达方法研究Profilin-1(PRF1)的亚细胞定位,并比较了2种瞬时表达体系在亚细胞定位研究中的优缺点。利用拟南芥幼叶作为材料,提取叶片的RNA,采用特异性引物RT-PCR的方法克隆PRF1基因,连接到p CAMBIA1300-GFP的改造载体上,成功的构建p CAMBIA1300-GFP-PRF1的表达载体。然后分别利用PEG转化拟南芥原生质体、农杆菌浸染烟草叶片两种技术进行了瞬时表达,并在激光共聚焦显微镜下观察绿色荧光蛋白(GFP)融合蛋白的表达。研究结果表明,将PRF1基因导入拟南芥的原生质体和烟草表皮细胞后,融合蛋白绿色荧光均能被观察到,PRF1基因与GFP融合蛋白的产物在烟草表皮细胞中主要定位在细胞质和外周细胞器中,在拟南芥的原生质体中的细胞核和细胞质中都有定位。两种不同的瞬时表达体系中PRF1蛋白的定位出现了不同,这可能与同源或异源表达的植物的特性相关。     

GFP基因在新疆小拟南芥和拟南芥中的表达分析

以质粒pMCB30为模板,扩增GFP基因,连接到载体pCMBIA2300-35S-OCS上,构建过量表达载体p35S:GFP,将其转入农杆菌GV3101.通过农杆菌介导法将p35S:GFP载体分别转入新疆特色植物小拟南芥和拟南芥中.T0代经含有卡那霉素的1/2MS培养基筛选,获得了T1代转基因小拟南芥2株,T1代转基因拟南芥9株.通过激光共聚焦显微镜观察,在转基因小拟南芥和拟南芥的根尖细胞中均可检测到GFP绿色荧光蛋白;对转基因植株进行PCR扩增,均可检测到GFP基因,表明GFP基因已成功转入小拟南芥和拟南芥中.该研究建立了小拟南芥的遗传转化体系,为进一步利用GFP基因和进一步研究小拟南芥的功能基因奠定基础.     

拟南芥AtPUB18的亚细胞定位和酶活性及AtPUB18的表达

通过RT-PCR技术从拟南芥中克隆到AtPUB18全长ORF。利用VectorNTI和MEGA 5.0对蛋白序列进行生物信息学分析结果显示,AtPUB18和AtPUB19蛋白序列相似性为74.9%,一致性为63.5%;构建AtPUB18启动子(1 974bp)融合GUS报告基因载体并转化拟南芥,组织化学染色分析显示,低温和干旱诱导后转基因植株中AtPUB18表达水平显著提高;构建AtPUB18与绿色荧光蛋白基因(GFP)融合的瞬时表达载体并转化原生质体,激光共聚焦显微镜观察发现,AtPUB18-GFP融合蛋白分布在细胞核和细胞质中;构建AtPUB18与麦芽糖结合蛋白基因(MBP)融合表达载体并转化大肠杆菌表达融合蛋白,纯化后的蛋白进行泛素连接酶活性检测结果显示,在小麦泛素激活酶E1和人泛素结合酶E2存在时,AtPUB18具有泛素连接酶活性。研究表明,AtPUB18是一个有功能的泛素连接酶,定位在细胞膜和细胞质中,可能参与拟南芥对非生物胁迫的响应。     

Structural and functional analyses of Arabidopsis thaliana chlorophyll a/b-binding protein (cab) promoters

Arabidopsis thaliana carries three functional copies of the chlorophyll a/b-binding protein (cab) gene which code for an identical mature protein. DNA sequence comparison of all three cab promoters indicated that cab2 and cab3 are more closely related compared to cab1. Although the highest degree of homology was found between the TATA box and -256 of cab3 promoter, suggesting that this region plays a major role in promoter function, this promoter regions are only 47% homologous. To study whether these promoters are regulated by identical cis-acting regulatory elements, the promoters were mutated by progressive deletions and the effects on the promoter activity were measured in either transformed plants or cultured cells. It was found that the minimum sequence necessary for the light-dependent tissue-specific promoter activity of the cab3 is the 89 bp DNA fragment (between -74 and -164) at the region of the TATA and the CCAAT boxes. However, an additional 45 bp DNA fragment (between -164 and -209) upstream of the CCAAT box was necessary for the full promoter activity in the leaves. The regulatory element in the 45 bp region appears to be a positive regulator or enhancer which is specific to photosynthetic cells, since the region did not enhance the promoter activity in cultured cells. This region contains an octamer, TGCCACGT (cab2) or TGCCACAT (cab3), which is similar to the previously identified element, TGACACGT from Arabidopsis cab1 promoter. The upstream regions of the cab promoters appear to contain additional elements which are functionally distinct in each promoter since the upstream region of cab1 activated a non-functional nos promoter whereas that of cab3 did not.     

Sequence-specific interaction between S1F, a spinach nuclear factor, and a negative cis-element conserved in plastid-related genes.

The nuclear gene rps1 coding for the spinach plastid ribosomal protein CS1 exhibits both a constitutive and leaf-specific expression pattern. In contrast to other chloroplast-related genes like rbcS and cab, the leaf induction of rps1 expression is light-independent. These unique features of rps1 expression provide good models to study the mechanisms regulating plastid development and differentiation in higher plants. We report on the identification of a spinach leaf nuclear factor, designated S1F, interacting with the rps1 promoter. The S1F binding site is conserved in the promoter region of many plastid-related genes, including rbcS, cab, and rpl21. A binding activity similar to S1F was detected in nuclear extract from dark-grown de-differentiated soybean suspension cells. Through site-specific mutagenesis and transient expression in soybean cell protoplasts, we show that the S1F binding site is a negative element down-regulating the promoter activity of rps1. A ligated tetramer of S1F site was able to repress activity of the cauliflower mosaic virus 35 S promoter extending the negative function of the S1F binding site on promoter activity.     

A New Class of Arabidopsis Constitutive Photomorphogenic Genes Involved in Regulating Cotyledon Development

Light signals have profound effects on morphogenesis of hypocotyls and cotyledons of Arabidopsis seedlings, but the mechanisms by which light signals are transduced and integrated to control these processes are poorly understood. We report here the identification of a new class of constitutive photomorphogenic (cop) mutants, cop2, cop3, and cop4, in which dark-grown seedlings have open and enlarged cotyledons resembling those of light-grown wild-type seedlings. The epistatic relationships of these three mutations to previously characterized phytochrome-deficient mutations suggest that COP2, COP3, and COP4 may act downstream of phytochrome in the light regulatory pathway. Mutations in each of the three loci alleviate the normal inhibition of cell-type differentiation, cell enlargement, and lateral cell division observed in cotyledons of dark-grown wild-type seedlings, but do not affect plastid differentiation. The cop4 mutation also leads to high-level dark expression of nuclear, but not plastid-encoded, light-inducible genes. We further show that for the nuclear cab1 gene encoding a chlorophyll a/b binding protein of the photosynthetic light-harvesting complex, activation in dark-grown cop4 mutants is achieved by modulation of promoter activity. Interestingly, COP4 modulates cab1 promoter activity through a pathway distinct from that of COP1 and COP9. Furthermore, cop4 mutants are defective in both root and shoot gravitropic responses, indicating that the COP4 locus may be involved in both light-signaling and gravity-sensing processes.     

Expression of bacterial chitinase protein in tobacco leaves using two photosynthetic gene promoters

Summary A bacterial chitinase gene from Serratia marcescens (chiA) was fused to (i) a promoter of the ribulose bisphosphate carboxylase small subunit (rbcS) gene and (ii) two different chlorophyll a/b binding protein (cab) gene promoters from petunia. The resulting constructions were introduced into Agrobacterium Ti plasmid-based plant cell transformation vectors and used to generate multiple independent transgenic tobacco plants. ChiA mRNA and protein levels were measured in these plants. On average, the rbcS/chiA fusion gave rise to threefold more chiA mRNA than either cab/chiA fusion. We investigated the influence of sequences around the translational initiation ATG codon on the level of ChiA protein. The rbcS/chiA and cab/chiA fusions in which the sequence in the vicinity of the translational initiation codon is ACC ATGGC gave rise to transformants with higher levels of ChiA protein than those carrying a cab/chiA fusion with the sequence CAT ATGCG in the same region. This difference in translational efficiency is consistent with previous findings on preferred sequences in this region of the mRNA. In those transformants showing the highest level of ChiA expression, ChiA protein accumulated to about 0.25% of total soluble leaf protein. These plants contained significantly higher chitinase enzymatic activity than control plants.