Coat protein mediated resistance to Plum Pox Virus in Nicotiana clevelandii and N. benthamiana

Transgenic Nicotiana benthamiana and N. clevelandii plants expressing the coat protein of Plum Pox Virus under the control of the 35S promoter from Cauliflower Mosaic Virus were engineered by Agrobacterium tumefaciens mediated transformation. The phenomenon of virus resistance was observed at different levels when transgenic plants, expressing the coat protein and control plants were compared after challenge infection with Plum Pox Virus. N. clevelandii coat protein transgenic plants circumvent virus accumulation. After an initial increase in virus titer similar to the control plants, some coat protein expressing plants showed a reduced accumulation of virus and inhibition of the systemic spread, characterized by decrease of the virus titer and formation of new symptomless leaves. In other N. clevelandii coat protein expressing plants virus accumulation was inhibited and disease symptoms never appeared. N. benthamiana coat protein expressing plants were also protected. After a temporary virus accumulation, virus titer decreased without the appearance of symptoms with the exception of a few plants, which showed a delay of thirty days in the development of symptoms post challenge infection.Abbreviations PPV Plum Pox Virus - CP coat protein - CaMV Cauliflower Mosaic Virus - CP+ coat protein expressing plant - CP– control plant = non coat protein expressing plant - TMV Tobacco Mosaic Virus - NPTII neomycin phosphotransferaseII - IBA indole-3-butyric acid - BAP 6-benzylaminopurine; - MS Murashige Skoog - ELISA enzyme linked immunosorbent assay     

Green fluorescent protein as an all-purpose reporter in Petunia

Two critical attributes of a reporter gene are ease of scoring for activity and capacity for expression in all cell types. We have examined a variant of the gene encoding green fluorescent protein,mgfp5, for its ability to meet these criteria in petunia. Under regulation of the Cauliflower Mosaic Virus (CaMV) 35S promoter, GFP was detectable in all vegetative and most floral cell types. Promoters from petuniaadhl andadh2 allowed for production of GFP in those few cell types lacking GFP production from the CaMV 35S promoter, verifying its capacity for expression in all cell types. With the appropriate promoter, GFP fluorescence was thus readily detectable throughout the plant. A potential complication is the green autofluorescence exhibited by some plant tissues. This auto-fluorescence is for the most part distinguishable from that contributed by GFP, but under-scores the need for appropriate controls in GFP-reporter-based experiments. An erratum to this article is available at .     

不同调控序列作用下GUS基因在烟草中瞬时表达活性

以pB1121为出发质粒,利用烟草泛素启动子Ubi．U4、CaMV35S启动子以及Kozak序列构建4种GUS基因表达载体,通过叶盘转化法转化烟草叶片,检测瞬时表达活性,研究不同调控序列对外源基因表达的调控作用。结果表明：CaMV35S启动子附加Kozak序列后使GUS活性比独立使用CaMV35S提高了近2倍：双CaMV35S启动子附加Kozak序列驱动GUS基因的表达活性与单CaMV35S附加Kozak序列相当;烟草泛素启动子附加Kozak序列的表达活性为CaMV35S启动子附加Kozak序列的1．5倍;Ubi．U4-CaMV35S复合启动子附加Kozak序列驱动GUS基因表达水平最高,其表达效率是双CaMV35S启动子附加Kozak序列调控下GUS表达效率的3倍,为CaMV35S独立作用时的10倍。     

不同调控序列作用下GUS基因在烟草中瞬时表达活性的研究

以pBI121为出发质粒, 利用烟草泛素启动子Ubi.U4、CaMV35S启动子以及Kozak序列构建4种GUS基因表达载体,通过叶盘转化法转化烟草叶片, 检测瞬时表达活性, 研究不同调控序列对外源基因表达的调控作用。结果表明: CaMV35S启动子附加Kozak序列后使GUS活性比独立使用CaMV35S提高了近2倍; 双CaMV35S启动子附加Kozak序列驱动GUS基因的表达活性与单CaMV35S附加Kozak序列相当; 烟草泛素启动子附加Kozak序列的表达活性为CaMV35S启动子附加Kozak序列的1.5倍; Ubi.U4-CaMV35S复合启动子附加Kozak序列驱动GUS基因表达水平最高, 其表达效率是双CaMV35S启动子附加Kozak序列调控下GUS表达效率的3倍, 为CaMV35S独立作用时的10倍。     

Use of green fluorescent protein as A non-destructive marker for peanut genetic transformation

Summary The ability to non-destructively visualize transient and stable gene expression has made green fluorescent protein (GFP) a most efficient reporter gene for routine plant transformation studies. We have assessed two fluorescent protein mutants, enhanced GFP (EGFP) and enhanced yellow fluorescent protein (EYFP), under the control of the CaMV35S promoter, for their transient expression efficiencies after particle bombardment of embryogenic cultures of the peanut cultivar, Georgia Green. A third construct (p524EGFP.1) that expressed EGFP from a double 35S promoter with an AMV enhancer sequence also was compared. The brightest and most dense fluorescent signals observed during transient expression were from p524EGFP. 1 and EYFP. Optimized bombardment conditions consisted of 0.6 μm diameter gold particles, 12410 kPa bombardment pressure, 95 kPa vacuum pressure, and pretreatment with 0.4 M mannitol. Bombardments with p524EGFP.1 produced tissue sectors expressing GFP that could be visually selected under the fluorescence microscope over multiple subcultures. Embryogenic lines selected for GFP expression initially may have been chimeric since quantitative analysis of expression sometimes showed an increase when GFP-expressing lines, that also contained a hygromycin-resistance gene, subsequently were cultured on hygromycin. Transformed peanut plants expressing GFP were obtained from lines selected either visually or on hygromycin. Integration of the gfp gene in the genomic DNA of regenerated plants was confirmed by Southern blot hybridization and transmission to progeny.     

Removal of the Selectable Marker Gene from Transgenic Tobacco Plants by Expression of Cre Recombinase from a Tobacco Mosaic Virus Vector through Agroinfection

Selection markers are often indispensable during the process of plant transformation, but dispensable once transgenic plants have been established. The Cre/lox site-specific recombination system has been employed to eliminate selectable marker genes from transgenic plants. Here we describe the use of a movement function-improved Tobacco Mosaic Virus (TMV) vector, m30B, to express Cre recombinase for elimination of the selectable marker gene nptII from transgenic tobacco plants. The transgenic tobacco plants were produced by Agrobacterium-mediated transformation with a specially designed binary vector pGNG which contained in its T-DNA region a sequence complex of 35S promoter-lox-the gfp coding sequence-rbcS terminator-Nos promoter-nptII-Nos terminator-lox-the gus coding region-Nos terminator. The expression of the recombinant viral vector m30B:Cre in plant cells was achieved by placing the viral vector under the control of the 35S promoter and through agroinoculation. After co-cultivating the pGNG-leaf discs with agro35S-m30B:Cre followed by shoot regeneration without any selection, plants devoid of the lox-flanked sequences including nptII were obtained with an efficiency of about 34% as revealed by histochemical GUS assay of the regenerants. Three of 11 GUS expressing regenerants, derived from two independent transgenic lines containing single copy of the pGNG T-DNA, proved to be free of the lox-flanked sequences by Southern blot analysis. Excision of the lox-flanked sequences in the three plants could be attributed to transient expression of Cre from the viral vector at the early stage of co-cultivation, since the cre sequence could not be detected in the viral RNA molecules accumulated in the plants, nor in their genomic DNA. The parental marker-free genotype was inherited in their selfed progeny, and all of the progeny were virus-free, apparently because TMV is not seed-transmissible. Therefore, expression of Cre from a TMV-based vector could be used to eliminate selectable marker genes from transgenic tobacco plants without sexual crossing and segregation, and this strategy could be extended to other TMV-infected plant species and applicable to other compatible virus–host plant systems.     

Development of insect resistant transgenic cotton lines expressing cry1EC gene from an insect bite and wound inducible promoter

Transgenic cotton lines were developed for high-level expression of a synthetic cry1EC gene from a wound inducible promoter. The tobacco pathogenesis related promoter PR-1a was modified by placing CaMV35S promoter on its upstream in reverse orientation. The resultant chimeric promoter CaMV35S(r)PR-1a expressed constitutively and was further up-regulated at the site of feeding by insects. It was induced more rapidly by treatment with salicylic acid (SA). The CaMV35S(r)PR-1a cry1EC expressing transgenic lines of cotton showed 100% mortality of Spodoptera litura larvae. The tightly regulated low-level expression of PR-1a was modified to a highly expressing constitutive expression by CaMV35S placed in reverse orientation. Salicylic acid treatment and wounding enhanced the expression further by the chimeric promoter. The leaves expressed more δ-endotoxin around the sites of insect bites. The levels of expression and induction varied among different transgenic lines, suggesting position effect. Some of the transgenic lines that expressed Cry1EC from the chimeric promoter at a low level also showed 100% mortality when induced with salicylic acid. A highly expressing insect bite and wound inducible promoter is desirable for developing insect resistant transgenic plants.     

麻疯树逆境蛋白(curcin 2)基因在烟草中的表达

麻疯树（Jatropha curcas）幼苗在干旱、高低温胁迫和真菌浸染下,其叶片中诱导产生了一种新的毒蛋白curcin 2。这意味着curcin 2在其它植物中的异源表达可能会增强植物对外界胁迫的抵抗。curcin 2 cDNA的两个片断：cur2p片断（编码前成熟蛋白）和cur2m片断（编码成熟蛋白）,通过农杆菌的介导分别转化烟草并获得转基因植株。但是,只有在插入了cur2p片断的烟草中检测到了curcin 2蛋白的表达。同时,curcin 2在烟草中的表达增强了植株对烟草花叶病毒（TMV）的抗性。     

Viral and chloroplastic signals essential for initiation and efficiency of translation in Agrobacterium tumefaciens

The construction of high-level protein expression vectors using the CaMV 35S promoter in concert with highly efficient translation initiation signals for Agrobacterium tumefaciens is a relatively less explored field compared to that of Escherichia coli. In the current study, we experimentally investigated the capacity of the CaMV 35S promoter to direct GFP gene expression in A. tumefaciens in the context of different viral and chloroplastic translation initiation signals. GFP expression and concomitant translational efficiency was monitored by confocal microscopy and Western blot analysis. Among all of the constructs, the highest level of translation was observed for the construct containing the phage T7 translation initiation region followed by the chloroplastic Rubisco Large Subunit (rbcL) 58-nucleotide 5′ leader region including its SD-like sequence (GGGAGGG). Replacing the SD-like (GGGAGGG) with non SD-like (TTTATTT) or replacing the remaining 52 nucleotides of rbcL with nonspecific sequence completely abolished translation. In addition, this 58 nucleotide region of rbcL serves as a translational enhancer in plants when located within the 5′ UTR of mRNA corresponding to GFP. Other constructs, including those containing sequences upstream of the coat proteins of Alfalfa Mosaic Virus, or the GAGG sequence of T4 phage or the chloroplastic atpI and/or PsbA 5′ UTR sequence, supported low levels of GFP expression or none at all. From these studies, we propose that we have created high expression vectors in A. tumefaciens and/or plants which contain the CaMV 35S promoter, followed by the translationally strong T7 SD plus RBS translation initiation region or the rbcL 58-nucleotide 5′ leader region upstream of the gene of interest.     

Use of the wound-inducible NtQPT2 promoter from Nicotiana tabacum for production of a plant-made vaccine

The wound-inducible quinolinate phosphoribosyl transferase promoter from Nicotiana tabacum (NtQPT2) was assessed for its capacity to produce B-subunit of the heat-labile toxin (LTB) from enterotoxigenic Escherichia coli in transgenic plant tissues. Comparisons were made with the widely used and constitutive Cauliflower Mosaic Virus 35S (CaMV35S) promoter. The NtQPT2 promoter produced somewhat lower average concentrations of LTB protein per unit weight of hairy root tissue but allowed better growth thereby producing similar or higher overall average yields of LTB per culture batch. Transgenic tobacco plants containing the NtQPT2-LTB construct contained LTB protein in roots but not leaves. Moreover, wounding NtQPT2-LTB transgenic plants, by removal of apices, resulted in an approximate 500% increase in LTB levels in roots when analysed several days later. CaMV35S-LTB transgenic plants contained LTB protein in leaves and roots but wounding made no difference to their LTB content.     

Effects of pollen-synthesized green fluorescent protein on pollen grain fitness

Genetically engineered pollen with a visible marker gene could be useful to monitor the movement of transgenic pollen provided there are no negative physiological or fitness effects of expressing such a gene. In this study, we measured the fitness of Nicotiana tabacum cv. Xanthi pollen expressing the marker gene green fluorescent protein (GFP). Average pollen tube germination frequencies and pollen tube growth rates in vitro were measured in three different types of plants: (1) plants producing GFP in pollen cells only (LAT59-GFP), (2) plants synthesizing GFP under the control of a constitutive promoter (CaMV 35S) in which no GFP was produced in pollen, and (3) non-transgenic plants. Pollen synthesizing the GFP protein did not differ significantly in average pollen germination frequencies from pollen without GFP (P=0.65). Average pollen tube growth rates over a 5-h period did not differ significantly between transgenic and non-transgenic types (R²=0.89, 0.98, and 0.95, respectively, for GFP-tagged, 35S-GFP, and wild type). Overall, GFP expression in pollen grains of tobacco was not found to have an effect on pollen fitness under the controlled experimental conditions of this study.     

Evaluation of transformation in peach Prunus persica explants using green fluorescent protein (GFP) and beta-glucuronidase (GUS) reporter genes

To determine the optimum conditions for Agrobacterium-mediated gene transfer, peach explants including cotyledons, embryonic axes and hypocotyl slices from non-germinated seeds and epicotyl internode slices from germinating seeds were exposed to Agrobacterium-mediated transformation treatments. The GUS (uidA) marker gene was tested using two different A. tumefaciens strains, three plasmids and four promoters [CaMV35s, (Aocs)3AmasPmas (“super-promoter”), mas-CaMV35s, and CAB]. GFP was tested with six A.␣tumefaciens strains, one plasmid (pLC101) and the doubleCaMV35s (dCaMV35s) promoter. The CaMV35s promoter produced more GUS expression than the CAB promoter. A. tumefaciens strains EHA105 and LBA4404 harboring the same plasmid (pBIN19) differed in their effects on GUS expression suggesting an interaction between A. tumefaciens strain and plasmid. A combination of A. tumefaciens EHA105, plasmid pBIN19 and the CaMV35s promoter produced the highest rates of transformation in peach epicotyl internodes (56.8%), cotyledons (52.7%), leaves (20%), and embryonic axes (46.7%) as evaluated by the percentage of explants expressing GUS 14 days after co-cultivation. GFP expression under the control of the dCaMV35s promoter was highest for internode explants but only reached levels of 18–19%. When GFP-containing plasmid pCL101 was combined with each of five A. tumefaciens strains the highest levels of transformation were 20–21% (internode and cotyledons, respectively). When nine peach genotypes were co-cultivated with A. tumefaciens strain EHA105 and GFP-containing plasmid pCL101 the highest levels of transformation were 26–28% (cotyledons and internodes, respectively). While GFP represents a potentially useful transformation marker that allows the non-destructive evaluation of transformation, rates of GFP transformation under the conditions of this study were low. It will be necessary to optimize expression of this marker gene in peach.     

Induction of protective immunity in swine by recombinant bamboo mosaic virus expressing foot-and-mouth disease virus epitopes

Background

Plants are increasingly being examined as alternative recombinant protein expression systems. Recombinant protein expression levels in plants from Tobacco mosaic virus (TMV)-based vectors are much higher than those possible from plant promoters. However the common TMV expression vectors are costly, and at times technically challenging, to work with. Therefore it was a goal to develop TMV expression vectors that express high levels of recombinant protein and are easier, more reliable, and more cost-effective to use.

Results

We have constructed a Cauliflower mosaic virus (CaMV) 35S promoter-driven TMV expression vector that can be delivered as a T-DNA to plant cells by Agrobacterium tumefaciens. Co-introduction (by agroinfiltration) of this T-DNA along with a 35S promoter driven gene for the RNA silencing suppressor P19, from Tomato bushy stunt virus (TBSV) resulted in essentially complete infection of the infiltrated plant tissue with the TMV vector by 4 days post infiltration (DPI). The TMV vector produced between 600 and 1200 micrograms of recombinant protein per gram of infiltrated tissue by 6 DPI. Similar levels of recombinant protein were detected in systemically infected plant tissue 10–14 DPI. These expression levels were 10 to 25 times higher than the most efficient 35S promoter driven transient expression systems described to date.

Conclusion

These modifications to the TMV-based expression vector system have made TMV vectors an easier, more reliable and more cost-effective way to produce recombinant proteins in plants. These improvements should facilitate the production of recombinant proteins in plants for both research and product development purposes. The vector should be especially useful in high-throughput experiments.     

Assessment of Transient Gene Expression in Plant Tissues Using the Green Fluorescent Protein as a Reference

Four different promoters (35S and enhanced 35S of the cauliflower mosaic virus, polyubiquitin of maize and actin1 of rice) were compared in a transient assay using maize leaves and particle bombardment. A gene encoding the jellyfish green fluorescent protein (GFP) driven by the 35S promoter was used as an internal standard to monitor the effectiveness of each bombardment. Normalisation of the transient expression assay using the GFP reference significantly reduced the variability between separate bombardments and allowed for a rapid and accurate evaluation of different promoters in microprojectile-bombarded leaves.     

A Comparison of Constitutive Promoters for Expression of Transgenes in Alfalfa (Medicago Sativa)

The activity of constitutive promoters was compared in transgenic alfalfa plants using two marker genes. Three promoters, the 35S promoter from cauliflower mosaic virus (CaMV), the cassava vein mosaic virus (CsVMV) promoter, and the sugarcane bacilliform badnavirus (ScBV) promoter were each fused to the beta-glucuronidase (gusA) gene. The highest GUS enzyme activity was obtained using the CsVMV promoter and all alfalfa cells assayed by in situ staining had high levels of enzyme activity. The 35S promoter was expressed in leaves, roots, and stems at moderate levels, but the promoter was not active in stem pith cells, root cortical cells, or in the symbiotic zones of nodules. The ScBV promoter was active primarily in vascular tissues throughout the plant. In leaves, GUS activity driven by the CsVMV promoter was approximately 24-fold greater than the activity from the 35S promoter and 38-fold greater than the activity from the ScBV promoter. Five promoters, the double 35S promoter, figwort mosaic virus (FMV) promoter, CsVMV promoter, ScBV promoter, and alfalfa small subunit Rubisco (RbcS) promoter were used to control expression of a cDNA from Trichoderma atroviride encoding an endochitinase (ech42). Highest chitinase activity in leaves, roots, and root nodules was obtained in plants containing the CsVMV:ech42 transgene. Plants expressing the endochitinase were challenged with Phoma medicaginis var. medicaginis, the causal agent of spring black stem and leaf spot of alfalfa. Although endochitinase activity in leaves of transgenic plants was 50- to 2650-fold greater than activity in control plants, none of the transgenic plants showed a consistent increase in disease resistance compared to controls. The high constitutive levels of both GUS and endochitinase activity obtained demonstrate that the CsVMV promoter is useful for high-level transgene expression in alfalfa.