Lost in Translation : Translation Mechanisms in Production of Cocksfoot Mottle Virus Proteins

The present study focuses on the translational strategies of Cocksfoot mottle virus (CfMV, genus Sobemovirus), which infects monocotyledonous plants. CfMV RNA lacks the 5'cap and the 3'poly(A) tail that ensure efficient translation of cellular messenger RNAs (mRNAs). Instead, CfMV RNA is covalently linked to a viral protein VPg (viral protein, genome-linked). This indicates that the viral untranslated regions (UTRs) must functionally compensate for the lack of the cap and poly(A) tail. We examined the efficacy of translation initiation in CfMV by comparing it to well-studied viral translational enhancers. Although insertion of the CfMV 5'UTR (CfMVe) into plant expression vectors improved gene expression in barley more than the other translational enhancers examined, studies at the RNA level showed that CfMVe alone or in combination with the CfMV 3'UTR did not provide the RNAs translational advantage. Mutation analysis revealed that translation initiation from CfMVe involved scanning. Interestingly, CfMVe also promoted translation initiation from an intercistronic position of dicistronic mRNAs in vitro. Furthermore, internal initiation occurred with similar efficacy in translation lysates that had reduced concentrations of eukaryotic initiation factor (eIF) 4E, suggesting that initiation was independent of the eIF4E. In contrast, reduced translation in the eIF4G-depleted lysates indicated that translation from internally positioned CfMVe was eIF4G-dependent. After successful translation initiation, leaky scanning brings the ribosomes to the second open reading frame (ORF). The CfMV polyprotein is produced from this and the following overlapping ORF via programmed -1 ribosomal frameshift (-1 PRF). Two signals in the mRNA at the beginning of the overlap program approximately every fifth ribosome to slip one nucleotide backwards and continue translation in the new -1 frame. This leads to the production of C-terminally extended polyprotein, which encodes the viral RNA-dependent RNA polymerase (RdRp). The -1 PRF event in CfMV was very efficient, even though it was programmed by a simple stem-loop structure instead of a pseudoknot, which is usually required for high -1 PRF frequencies. Interestingly, regions surrounding the -1 PRF signals improved the -1 PRF frequencies. Viral protein P27 inhibited the -1 PRF event in vivo, putatively by binding to the -1 PRF site. This suggested that P27 could regulate the occurrence of -1 PRF. Initiation of viral replication requires that viral proteins are released from the polyprotein. This is catalyzed by viral serine protease, which is also encoded from the polyprotein. N-terminal amino acid sequencing of CfMV VPg revealed that the junction of the protease and VPg was cleaved between glutamate (E) and asparagine (N) residues. This suggested that the processing sites used in CfMV differ from the glutamate and serine (S) or threonine (T) sites utilized in other sobemoviruses. However, further analysis revealed that the E/S and E/T sites may be used to cleave out some of the CfMV proteins.

植物生产生物可降解塑料PHB的研究：真养产碱杆菌H16的phbB和phbC的基因克隆、植物表达载体构建和转基因马铃薯植株的获得

利用聚合酶链式反应(PCR)技术从Alcaligenes eutrophus H16染色体DNA中扩增并克隆了调控聚-3-羟基丁酸(poly-3-hydroxy-butyrate，PHB)生物合成的两个关键酶基因：依赖NADPH的乙酰乙酰CoA还原酶基因(phbB)和PHB合成酶基因(phbC)。限制性内切酶图谱和核苷酸序列分析证实了克隆结果，并表明克隆的基因与国外所报道的有很高的同源性。经过基因拼接，构建了块茎特异性表达的高等植物表达载体pPSAGB（嵌合phbB）、pBIBGC(嵌合phbC)和pPSAGCB（嵌合phbB和phbC）。并以试管薯(microtuber)为外植体经Agrobacterium介导转化了虎头、京丰、Bintje、Favorita、高原4号和88-5共6个马铃薯品种，获得49个株系。经PCR检测导入phbB的株系共有44个，对其中30个株系进行DNA dot blot分析，结果表明phbC导入呈阳性的株系有20个。深入的鉴定工作还在进行中。

水母雪莲DFR基因的克隆及其正义和反义植物表达载体的构建

水母雪莲（Saussurea medusa Maxim.）为多年生菊科植物，是我国珍稀药用资源。所含的主要生物活性成分是黄酮类物质，具有抗炎、镇痛、免疫抑制及抗氧化等功效。但由于水母雪莲生长环境特殊，生长缓慢，人工引种困难;加上长期掠夺性采挖，造成其野生药用资源短缺，已经不能满足市场的需求。近年来,世界上掀起了植物药开发的热潮,植物药以其天然低毒的特点倍受关注,而黄酮类化合物更是以其广谱的药理作用引人瞩目。 黄酮类化合物的合成代谢途径在植物界进化过程中很保守，黄酮类生物合成途径中的相关酶也已得到确证并进行了系统的研究。二氢黄酮醇-4-还原酶（Dihydroflavonol-4-reductase, DFR）是一个处于花色素或者原花色素合成途径中的关键酶，它与黄酮合成途径中的黄酮醇合成酶（flavonol synthase）竞争底物。本研究以水母雪莲为研究对象，根据近缘物种DFR基因的保守核苷酸序列设计兼并引物，通过PCR技术，从已经建立的水母雪莲红色愈伤组织cDNA文库中筛选到一个编码该酶的cDNA序列，该序列全长1166个碱基对。根据生物信息学分析，此cDNA编码342个氨基酸;Blastp分析结果显示，该氨基酸序列与同科植物翠菊（Callistephus chinensis）的相似性最高，达87%;SWISSMODEL软件预测其蛋白的三级结构与葡萄(Vitis vinifera)的十分相似，活性中心的关键氨基酸残基也完全一致。据此可以断定，我们所得到的cDNA为编码二氢黄酮醇还原酶的基因，并命名为水母雪莲二氢黄酮醇还原酶基因(SmDFR）。为了得到SmDFR的DNA序列，我们又设计特异引物，从水母雪莲的基因组中扩增出了由1871个碱基对组成的DNA序列，该序列包含五个内含子和六个外显子。 为了提高水母雪莲和大苞雪莲中黄酮类物质的含量，我们构建了SmDFR的反义植物表达载体，利用根癌农杆菌介导进行基因转化。通过改变影响农杆菌转化的实验条件包括外植体来源、农杆菌菌株、细菌浓度、外植体预培养时间、侵染时间和乙酰丁香酮的浓度进行转基因试验，目前尚未得到转基因植株。另外，我们构建了SmDFR正义植物表达载体，通过对拟南芥(Arabidopsis thaliana) DFR基因突变体和矮牵牛(Petunia hybrida)进行基因转化，来验证SmDFR的功能;目前，此实验尚在进行之中。

RNAi沉默烟草GA 20-氧化酶基因研究

赤霉素是一种高效能的广谱植物生长调节剂，为五大植物激素之一，具有重要的生物学功能。目前利用赤霉素突变体研究生物合成途径和信号转导已经成为热点。 GA 20-氧化酶是GA生物合成中的一类关键酶，它位于GA合成途径的中心位置。本研究根据烟草（Nicotiana tabacum）GA 20-氧化酶基因序列，设计2对分别含有特定酶切位点的特异引物，以烟草基因组DNA为模板，扩增目的基因(约250 bp)片段。将正、反向目的片段分别插入中间载体的内含子两侧，再经BamH I和Sac I双酶切回收约700 bp的目的片段，插入到双元载体质粒p2355中，成功构建了含GA 20-氧化酶基因片段反向重复序列的植物表达载体p23700。分别将p2355质粒和p23700质粒导入根癌农杆菌（Agrobacterium tumefaciens）EHA105中并转化烟草叶片细胞，经卡那霉素选择培养，PCR及GUS组织染色鉴定，获得转基因烟草植株。以EHA105-p2355转化的烟草，获得41株转基因植株，均没有矮化表型；而以EHA105-p23700转化的烟草，获得转基因植株14株，其中具有矮化表型的烟草10株，表明反向重复序列转录产物能形成发夹RNA(hpRNA)，产生小分子干扰RNA（small interferring RNA，简称siRNA），干扰目的基因的表达。 赤霉素含量测定表明矮化植株中赤霉素合成途径的最终产物GA3总含量明显低于野生型烟草植株。荧光定量PCR结果表明，矮化转基因烟草的GA 20-氧化酶基因表达量受到明显抑制，表达量明显低于野生型对照。同时对上游内根-贝壳杉合成酶（Ent-kaurene synthase，KS）基因，下游的GA-3β羟化酶基因进行了RT-PCR分析，结果显示上游基因的表达没有规律性变化，而下游基因表达量亦降低。上述结果表明，GA 20-氧化酶基因的表达被有效地干扰了，表达受到抑制，从而影响植株体内GA3的合成，影响植株的生长发育，导致植株矮化。并推测，GA 20-氧化酶基因受到抑制，可能影响下游基因的表达。并且通过干旱胁迫测试，发现矮化植株相对于野生型植株及不含干扰片段的转基因植株，对干旱的耐受力有了很大的提高，具有更强的耐受力。 研究结果为进一步进行相关研究奠定基础。 Gibberellin(GA) is an efficient plant growth regulator. As one of five major plant hormones, it plays an important biological function. Using GA mutant for investigating biosynthetic pathways and signal transduction has become high lights. GA 20-oxidase is a crucial enzyme involved in gibberellin biosynthesis. According to tobacco (Nicotiana tabacum) GA 20-oxidase enzyme gene sequence and based on binary vector p2355, we constructed a plant expression vector p23700, which habors an inverted repeat DNA fragment of GA 20-oxidase gene drivered by Cauliflower mosaic virus promtor (CaMV 35Sp). Binary plasmid p2355 had no inverted repeat DNA fragment of GA 20-oxidase gene. The vector p2355 and p23700 were introduced into Agrobacterium tumefaciens EHA105 and tobacco leaf transformation was conducted. After selected by kanamycin and characterized by PCR and GUS hischemical reaction, transsgenic plants were obtained. Fourtheen transgenic plants, which were transformed by EHA105-p23700, were obtained. Among them, 10 were dwarf mutants. However, 41 transgenic plants with the same normal phenotype as wild type,which were transformed by EHA105-p2355, were obtained. Analysis of Gibberellin contents showed that it was lower in dwarf mutants than in normal phenotype plants. Moreover, comparing to normal phenotype plants including wild type and transgenic plants with no interference fragment, the drought tolerance of dwarf plants have greatly increased. And their proline content increased obviously after drought test. Fluorescence quantitative real time PCR (RT-PCR) showed that GA 20-oxidase gene expression was significantly inhibited in dwarf transgenic tobacco. Meanwhile, the expression of the upstream gene ent-kaurene synthase (KS) gene and downstream gene GA-3β hydroxylase gene was also detected by RT-PCR. The results presented that KS gene expression had no regular change while GA-3β hydroxylase gene expression reduced. It implied that inhibiting GA 20-oxidase gene probably reduce the expression of downstream genes. The results showed that the transcriptional products of the foreign inverted repeat fragment can form hairpin RNA (hpRNA) to induce RNAi. It presented that GA 20-oxidase gene expression was effectively interfered, resulting in reducing GA3 synthesis and inhibiting plant growth and development, then dwarf plants were produced. However, the dwarf plants had higher tolerance of drought.

Etablierung von Expressionsystemen für Gene der Indolalkaloid-Biosynthese unter besonderer Berücksichtigung von Cytochrom P450-Enzymen

Etablierung von Expressionsystemen für Gene der Indolalkaloid-Biosynthese unter besonderer Berücksichtigung von Cytochrom P450-Enzymen In der vorliegenden Arbeit wurden Enzyme aus der Arzneipflanze Rauvolfia serpentina bearbeitet. Es wurde versucht, das an der Biosynthese des Alkaloids Ajmalin beteiligte Cytochrom P450-Enzym Vinorin-Hydroxylase heterolog und funktionell zu exprimieren. Ein zunächst unvollständiger, unbekannter Cytochrom P450-Klon konnte komplettiert und eindeutig mittels heterologer Expression in sf9-Insektenzellen als Cinnamoyl-Hydroxylase identifiziert werden. Die Tauglichkeit des Insektenzellsystems für die Untersuchung der Vinorin-Hydroxylase ist auf Grund der deacetylierenden Wirkung der Insektenzellen auf das Substrat Vinorin nicht gegeben. Im Rahmen des Homology Cloning Projektes konnten mehrere Volllängenklone und diverse Teilsequenzen von neuen Cytochrom P450-Klonen ermittelt werden. Ausserdem wurde durch das unspezifische Binden eines degenerierten Primers ein zusätzlicher Klon gefunden, der der Gruppe der löslichen Reduktasen zugeordnet werden konnte. Diese putative Reduktase wurde auf die Aktivität von mehreren Schlüsselenzymen der Ajmalin-Biosynthese durch heterologe Expression in E.coli und anschliessende HPLC-gestützte Aktivitätstests ohne Erfolg geprüft. Bedingt durch die Untauglichkeit des Insektenzellsystems für die Identifizierung der Vinorin-Hydroxylase, wurde ein neuartiges Modul-gestütztes, pflanzliches Expressionsystem etabliert, um vorhandene P450-Volllängenklone auf Vinorin- Hydroxylaseaktivität testen zu können. Die Funktionalität des Systems konnte durch die heterologe Expression der Polyneuridinaldehyd Esterase bestätigt werden. Trotzdem war es bis jetzt nicht möglich, die Cinnamoyl-Hydroxylase als Kontrollenzym für das pflanzliche System oder aber die gesuchte Vinorin- Hydroxylase in aktiver Form zu exprimieren.

Ribozyme-mediated high resistance against potato spindle tuber viroid in transgenic potatoes

A hammerhead ribozyme [R(-)] targeting the minus strand RNA of potato spindle tuber viroid (PSTVd) and a mutated nonfunctional ribozyme [mR(-)] were designed, cloned, and transcribed. As predicted, both monomer and dimer transcripts of the active R(-) ribozyme gene could cleave the PSTVd minus strand dimer RNA into three fragments of 77, 338, and 359 bases in vitro at 25 and 50°C. The tandem dimer genes of R(-) and mR(-) were subcloned separately into the plant expression vector pROK2. Transgenic potato plants (cultivar Desirée) were generated by Agrobacterium tumefaciens-mediated transformation. Twenty-three of 34 independent transgenic plant lines expressing the active ribozyme R(-) resulted in having high levels of resistance to PSTVd, being free of PSTVd accumulation after challenge inoculation with PSTVd, but the remaining lines showed weaker levels of resistance to PSTVd with low levels of PSTVd accumulation. In contrast, 59 of 60 independent transgenic lines expressing the mutated ribozyme mR(-) were susceptible to PSTVd inoculation and had levels of PSTVd accumulation similar to that of the control plants transformed with the empty vector. The resistance against PSTVd replication was stably inherited to the vegetative progenies.

Nucleotide sequence of coat protein gene for GPV isolate of barley yellow dwarf virus and construction of expression plasmid for plant

GPV is a Chinese serotype isolate of barley yellow dwarf virus (BYDV) that has no reaction with antiserum of MAV, PAV, SGV, RPV and RMV The sequence of the coat protein (CP) of GPV isolate of BYDV was identified and its amino acid sequence was deduced. The coding region for the putative GPV CP is 603 bases nucleotides and encodes a Mr 22 218 (22 ku) protein. The same as MAV, PAV and RPV, GPV contained a second ORF within the coat protein coding region. This protein of 17 024 Mr (17 ku) is thought to correspond to the Virion protein genome linked (Vpg). Sequence comparisons of the CP coding region between the GPV isolate of BYDV and other isolates of BYDV have been done. The nucleotide and amino acid sequence homology of GPV has a greater identity to the sequence of RPV than those of PAV and MAV. The GPV CP sequence stored 83.7% of nucleotide similarity and 77.5% of deduced amino acid similarity, whereas that of the PAV and MAV shared 56.9%, 53.2% and 44.1%, 43.8% respectively. According to BYDV-GPV CP sequence, two primers were designed. The cDNA of CP was produced by RT-PCR. Full-length cDNA of CP was inserted into plasmid to construct expression plasmids named pPPI1, pPPI2 and pPPI5 based on different promoters. The recombinant plasmids were identified by using α-32P-dATP labelled CP probe, α-32P-ATP labelled GPV RNA probe and sequencing to confirm real GPV CP gene cDNA in plasmids.

Design and construction of an in-plant activation cassette for transgene expression and recombinant protein production in plants

Virus-based transgene expression systems have become particularly valuable for recombinant protein production in plants. The dual-module in-plant activation (INPACT) expression platform consists of a uniquely designed split-gene cassette incorporating the cis replication elements of Tobacco yellow dwarf geminivirus (TYDV) and an ethanol-inducible activation cassette encoding the TYDV Rep and RepA replication-associated proteins. The INPACT system is essentially tailored for recombinant protein production in stably transformed plants and provides both inducible and high-level transient transgene expression with the potential to be adapted to diverse crop species. The construction of a novel split-gene cassette, the inducible nature of the system and the ability to amplify transgene expression via rolling-circle replication differentiates this system from other DNA- and RNA-based virus vector systems used for stable or transient recombinant protein production in plants. Here we provide a detailed protocol describing the design and construction of a split-gene INPACT cassette, and we highlight factors that may influence optimal activation and amplification of gene expression in transgenic plants. By using Nicotiana tabacum, the protocol takes 6-9 months to complete, and recombinant proteins expressed using INPACT can accumulate to up to 10% of the leaf total soluble protein.

Modelling the effect of plant water use traits on yield and stay-green expression in sorghum

Post-rainy sorghum (Sorghum bicolor (L.) Moench) production underpins the livelihood of millions in the semiarid tropics, where the crop is affected by drought. Drought scenarios have been classified and quantified using crop simulation. In this report, variation in traits that hypothetically contribute to drought adaptation (plant growth dynamics, canopy and root water conducting capacity, drought stress responses) were virtually introgressed into the most common post-rainy sorghum genotype, and the influence of these traits on plant growth, development, and grain and stover yield were simulated across different scenarios. Limited transpiration rates under high vapour pressure deficit had the highest positive effect on production, especially combined with enhanced water extraction capacity at the root level. Variability in leaf development (smaller canopy size, later plant vigour or increased leaf appearance rate) also increased grain yield under severe drought, although it caused a stover yield trade-off under milder stress. Although the leaf development response to soil drying varied, this trait had only a modest benefit on crop production across all stress scenarios. Closer dissection of the model outputs showed that under water limitation, grain yield was largely determined by the amount of water availability after anthesis, and this relationship became closer with stress severity. All traits investigated increased water availability after anthesis and caused a delay in leaf senescence and led to a ‘stay-green’ phenotype. In conclusion, we showed that breeding success remained highly probabilistic; maximum resilience and economic benefits depended on drought frequency. Maximum potential could be explored by specific combinations of traits.

Regulation of gene expression by SnRK1 kinases and miRNAs during the plant stress response

Dissertation presented to obtain the Ph.D degree in Plant Physiology

Starvation Induces Expression of the Plant-Adhesin Gene, Mad2, of the Entomopathogenic Fungus Metarhizium robertsii.

Metarhizium robertsii is an entomopathogenic fungus that is additionally plant rhizosphere competent. Two adhesin-encoding gens, Mad1 and Mad2, are involved in insect pathogenesis or plant root colonization, respectively. This study examined differential expression of the Mad genes for M robertsii grown on a variety of insectand plant-related substrates. Mad1 was up regulated in response to insect cuticles and up regulation of Mad2 resulted from root exudates, tomato stems and non-preferred carbohydrates. A time course analysis that compared water, minimal media, and nutrient rich broth revealed Mad2 gene expression increased as nutrient availability decreased. The regulation of Mad2 compared to known stress-related genes (Hsp30, Hsp70 and ssgA) under various stresses (nutrient, pH, osmotic, oxidative, temperature) revealed Mad2 to be generally up regulated by nutrient starvation only. Examination of the Mad2 promoter region revealed two copies of a stress-response element (S TRE) known to be regulated under the general stress response pathway.