Increased field resistance to Tilletia caries provided by a specific antifungal virus gene in genetically engineered wheat

The field performance of a viral gene in two Swiss wheat ( Triticum aestivum ) varieties showed 10% increased fungal resistance against Tilletia caries (stinking smut). To the best of our knowledge, this is the first report of improved resistance against any fungus in the field achieved by genetic engineering in wheat. The genetically modified wheat lines previously showed a c . 30% decrease in symptoms of T. caries in the glasshouse (Clausen, M., Kräuter, R., Schachermayr, G., Potrykus, I. and Sautter, C. (2000) Antifungal activity of a virally encoded gene in transgenic wheat. Nat. Biotechnol . 18 , 446–449), depending on the fungal strain inoculated. A glasshouse experiment run in parallel to the field test, and using the same collection of T. caries , gave the same results. In a dose–response experiment with isolated fungal strains, in which the infection pressure was varied via the spore concentration, the transgene behaved as a quantitative resistance gene and shifted the S-shaped dose–response curve towards higher resistance. The transgene was shown to be highly specific for fungi of the order Ustilaginales. Tests of the transgene using cell cultures of eukaryotes, including hamster and human, showed no significant side-effects with respect to biosafety. Endogenous pathogen-related genes were also activated on fungal infection in the presence of the kp4 transgene.     

利用P5CS基因转化白三叶的研究

为了培育抗旱白三叶,构建了植物表达载体pBPC-P5CS,利用基因枪法转化白三叶的愈伤组织,PCR检测和Southern blot鉴定证实白三叶中已导入P5CS基因。对转P5CS基因白三叶植株的不同抗旱指标进行了分析。结果表明,与对照相比,转P5CS基因株系的抗旱能力得到了较大的提高。干旱胁迫下,与对照相比,转P5CS基因植株的脯氨酸含量和相对含水量分别比对照高20.0%-21.2%和5.6%-8.5%。     

Determining the effectiveness of grazing and trampling by livestock in transmitting white clover mosaic and subterranean clover mottle viruses

Glasshouse and mini-sward experiments were done to determine the relative roles of grazing and trampling by livestock in transmitting white clover mosaic (WC1MV) and subterranean clover mottle (SCMoV) viruses between clover plants in pastures. Wounding due to grazing was simulated by repeatedly cutting plants with serrated scissors (glasshouse) or mowing (mini-swards), while wounding due to trampling was simulated by repeatedly bashing plants with the flat end of a wooden hammer handle (glasshouse) or rolling (mini-swards). In glasshouse experiments, cutting was more effective than bashing in transmitting WC1MV to white clover (Trifolium repens) plants but cutting and bashing transmitted it to subterranean clover (T. subterraneum) plants at similar rates. In an experiment with white clover mini-swards, mowing was more effective than rolling in transmitting WC1MV, and when both were combined, initially spread exceeded that obtained when the spread from mowing and rolling alone was added together. In glasshouse experiments, bashing was more effective than cutting in transmitting SCMoV to subterranean clover plants. In one experiment, neither mowing nor rolling spread SCMoV in mini-swards of subterranean clover. When transmission to subterranean clover cultivars which were ‘susceptible’ or ‘moderately susceptible’ to SCMoV was compared in glasshouse experiments, repeated bashing spread the virus more slowly to the ‘moderately susceptible’ cultivars. When mixed with ruminant saliva, infective sap containing WC1MV or SCMoV was still infective to clover plants after 4 wk storage at room temperature. When infective sap was allowed to dry naturally on a metal surface, SCMoV still infected clover plants when the dried sap was taken up in tap water after 4 but not 14 days, while WC1MV was infective after 24 h but not 4 days. These results suggest that grazing and mowing are more effective than trampling at transmitting WC1MV to white clover plants in pastures, while trampling is more effective at spreading SCMoV to subterranean clover. However, both transmitted WC1MV to subterranean clover at similar rates. Possible reasons for these differences are discussed in relation to differences in clover plant morphology and virus-specific factors.     

Greenhouse and field testing of transgenic wheat plants stably expressing genes for thaumatin-like protein,chitinase and glucanase against Fusarium graminearum

Genes encoding pathogenesis-related (PR-) proteins isolated from a cDNA library of Fusarium graminearum-infected wheat spikes of scab-resistant cultivar 'Sumai-3' were transformed into susceptible spring wheat, 'Bobwhite' using a biolistic transformation protocol, with the goal of enhancing levels of resistance against scab. Twenty-four putative transgenic lines expressing either a single PR-protein gene or combinations thereof were regenerated. Transgene expression in a majority of these lines (20) was completely silenced in the T(1) or T(2) generations. Four transgenic wheat lines showed stable inheritance and expression of either a single transgene or transgene combinations up to four generations. One line co-expressing a chitinase and beta-1,3-glucanase gene combination, when bioassayed against scab showed a delay in the spread of the infection (type II resistance) under greenhouse conditions. This line and a second transgenic line expressing a rice thaumatin-like protein gene (tlp) which had moderate resistance to scab in previous greenhouse trials, along with susceptible and resistance checks were evaluated for resistance to scab under field conditions. None of the transgenic lines had resistance to scab in the field under conditions of strong pathogen, suggesting these plants lacked effective resistance to initial infection (type I resistance) under these conditions. As far as is known, this is the first report of field evaluation of transgenic wheat expressing genes for PR-proteins against disease resistance.     

T4转基因番木瓜遗传性和果实品质分析

对T 4代转基因番木瓜进行了分子生物学和果实品质分析,结果表明,筛选获得的转基因番木瓜均为转番木瓜环斑病毒(PRV)复制酶突变体基因(RP),且对PRV抗性达到了高抗或免疫,RP基因在转基因植物中能稳定遗传至后代并在RNA水平上表达。在田间种植时,转基因木瓜的生长状况普遍好于普通番木瓜,尤其在生长后期(10月以后),普通番木瓜100%发病(大规模种植时),而大部分(约91.8%)转基因植株生长良好,果实较多且表面光洁、基本上无环斑。与非转基因亲本相比,T 4代转基因番木瓜的果实长度增加2.6%~5%,果实直径变小0.6%~1.5%,果肉厚度增加了12%~15%,因而果实形状与亲本相近或更好,且信用价值更高。转基因番木瓜果实中水分、蛋白质、氮、脂肪、还原性糖、维生素A、维生素C和类胡萝卜素的含量与对照都无显著性差异,即转基因番木瓜与亲本具有实质等同性,这表明转入的外源基因对番木瓜果实品质没有不良影响。     

Transgene × Environment Interactions in Genetically Modified Wheat

Background

The introduction of transgenes into plants may cause unintended phenotypic effects which could have an impact on the plant itself and the environment. Little is published in the scientific literature about the interrelation of environmental factors and possible unintended effects in genetically modified (GM) plants.

Methods and Findings

We studied transgenic bread wheat Triticum aestivum lines expressing the wheat Pm3b gene against the fungus powdery mildew Blumeria graminis f.sp. tritici. Four independent offspring pairs, each consisting of a GM line and its corresponding non-GM control line, were grown under different soil nutrient conditions and with and without fungicide treatment in the glasshouse. Furthermore, we performed a field experiment with a similar design to validate our glasshouse results.The transgene increased the resistance to powdery mildew in all environments. However, GM plants reacted sensitive to fungicide spraying in the glasshouse. Without fungicide treatment, in the glasshouse GM lines had increased vegetative biomass and seed number and a twofold yield compared with control lines. In the field these results were reversed. Fertilization generally increased GM/control differences in the glasshouse but not in the field. Two of four GM lines showed up to 56% yield reduction and a 40-fold increase of infection with ergot disease Claviceps purpurea compared with their control lines in the field experiment; one GM line was very similar to its control.

Conclusions

Our results demonstrate that, depending on the insertion event, a particular transgene can have large effects on the entire phenotype of a plant and that these effects can sometimes be reversed when plants are moved from the glasshouse to the field. However, it remains unclear which mechanisms underlie these effects and how they may affect concepts in molecular plant breeding and plant evolutionary ecology.     

Analysis on virus resistance and fruit quality for T4 generation of transgenic papaya

Molecular biological characterization,fruit characters,and nutrients were analyzed for T4 generation of transgenic papaya.All transgenic papaya plants with the mutated replicase (RP) gene from papaya ringspot virus (PRSV) showed high resistance or immunity against PRSV in the field.The RP transgene can be steadily inherited to,and expressed at RNA level,the progenies.The growth characteristics of transgenic papaya were much better than nontransgenic papaya in the field.The non-transgenic papaya seedlings began to show typical symptoms caused by PRSV after being inoculated with PRSV.They died quickly and never grew to produce fruit.The adult trees developed yellow leaves and produced smaller fruits and were doomed to a slow death after some time,while most oftransgenic papaya plants (about 91.8%) did not show any symptoms caused by PRSV,and produced more,bigger,and high quality fruits.Compared with non-transgenic plants,the fresh fruit length of T4 generation of transgenic papaya increased 2.6%-5%,and the diameter decreased 0.6%-1.5%.The flesh thickness of fresh fruit increased 12%-15%,which made it fitter for eating.Although the fresh fruit quality changed,there was no significant difference between transgenic and non-transgenic papaya.The quality characteristics of dry fruit including the contents of water,lipid,N,protein,reduced sugar,vitamin A,vitamin C,and carotene in the T4 generation of transgenic papaya were all the same as their non-transgenic parents.This means that transgenic plants and non-transgenic plants are substantially equivalent,and the transgene has no effect on dry fruit quality.In this study,we found that vitamin A and vitamin C in red-fleshed papaya were 1.4-1.8 and 1.78-2.07 times more than the yellow-fleshed ones,respectively,while N and protein were only 84.2%-92.1% and 82.1%-98.9% of the yellow-fleshed ones.     

转不可翻译PVY^N CP基因烟草的抗病性分析

我们曾报道表达不可翻译PVY^N CP基因的转基因烟草抗病性是由RNA介导的,其抗病性类似于转录后的基因沉默(PTGS)。本研究以这类不同抗性的T0代转基因烟草植株为材料,对自交后的T1代转基因植株的遗传和抗病性进行了分析,并选取部分T1代抗病株系自交留种。对T2代RNA介导抗病性转基因植株进行了分子分析和一系列抗病性研究。结果表明,含1—2个转基因拷贝的T0代感病植株,在T1代中的Km抗性分离符合单位点插入的3：1的遗传规律;含3个或3个以上转基因拷贝的T0代中抗或高抗植株,在T1代中的Km抗性分离符合多位点插入的15：1或63：1的遗传规律。大多数T1、T2代转基因植株的抗病性与转基因拷贝数成正相关,转基因在T1、T2代植株中能够转录表达,且转基因植株之间转基因mRNA在细胞质中的积累水平与转基因植株的抗病性成负相关。转基因植株的抗病性能够在T1、T2代中遗传,且T2代转基因植株的抗病性具有以下特征：1)既抗病毒粒体又抗病毒RNA的侵染,且这种抗病性不受接种物剂量的影响;2)抗病谱较窄,只对PVY的某些株系具有高度抗病性;3)与传毒方式无关,既抗摩擦接种又抗带毒蚜虫接种;4)与植株的发育阶段没有关系。     

转不可翻译PVYN CP基因烟草的抗病性分析

我们曾报道表达不可翻译PVY~N CP基因的转基因烟草抗病性是由RNA介导的,其抗病性类似于转录后的基因沉默(PTGS)。本研究以这类不同抗性的Tn代转基因烟草植株为材料,对自交后的T1代转基因植株的遗传和抗病性进行了分析,并选取部分T_1代抗病株系自交留种。对T_2代RNA介导抗病性转基因植株进行了分子分析和一系列抗病性研究。结果表明,含1-2个转基因拷贝的T_0代感病植株,在T_1代中的Km抗性分离符合单位点插入的3∶1的遗传规律;含3个或3个以上转基因拷贝的T_0代中抗或高抗植株,在T_1代中的Km抗性分离符合多位点插入的15∶1或63∶1的遗传规律。大多数T_1、T_2代转基因植株的抗病性与转基因拷贝数成正相关,转基因在T_1、T_2代植株中能够转录表达,且转基因植株之间转基因mRNA在细胞质中的积累水平与转基因植株的抗病性成负相关。转基因植株的抗病性能够在T_1、T_2代中遗传,且T_2代转基因植株的抗病性具有以下特征:1)既抗病毒粒体又抗病毒RNA的侵染,且这种抗病性不受接种物剂量的影响;2)抗病谱较窄,只对PVY的某些株系具有高度抗病性;3)与传毒方式无关,既抗摩擦接种又抗带毒蚜虫接种;4)与植株的发育阶段没有关系。     

Performance of transgenic spring wheat plants and effects on non-target organisms under glasshouse and semi-field conditions

Abstract:  A convertible glasshouse was established to study annual transgenic plants under near-field environmental conditions while simultaneously ensuring a high level of biological containment. This system can provide a useful step in the assessment of transgenic plants prior to open-field experiments. Two transgenic wheat lines (cv. Bobwhite) were investigated and compared with their corresponding non-transformed wildtypes with respect to plant performance, expression of the transgenic trait and interactions with antagonists. The first line expressed snowdrop lectin [ Galanthus nivalis agglutinin (GNA)] for enhanced resistance to aphids, and the second one overexpressed the endogenous Lr10 gene to enhance resistance to leaf rust. Interestingly, 1000-kernel weight of Lr10 -transgenic plants was significantly reduced, indicating that the overexpression of the Lr10 gene caused a significant fitness cost for the plant. GNA-transgenic plants expressed the lectin at levels too low to affect the target aphids. A detached leaf bioassay with Lr10 -transgenic plants revealed an increased resistance to leaf rust. No differences in the performance of aphids or cereal leaf beetles on transgenic and non-transformed plants were recorded in the convertible glasshouse and in complementary glasshouse studies. Similarly, infection levels with powdery mildew did not differ between transgenic and non-transformed plants but Bobwhite plants were significantly more infected when compared with conventional Swiss spring wheat cultivars. Overall, the assessment revealed that for the plants investigated here, their genetic background had a stronger impact on the performance of a plant and its interactions with insect herbivores and pathogens than the expression of the transgene.     

Analysis on virus resistance and fruit quality for T4 generation of transgenic papaya

Molecular biological characterization, fruit characters, and nutrients were analyzed for T4 generation of transgenic papaya. All transgenic papaya plants with the mutated replicase (RP) gene from papaya ringspot virus (PRSV) showed high resistance or immunity against PRSV in the field. The RP transgene can be steadily inherited to, and expressed at RNA level, the progenies. The growth characteristics of transgenic papaya were much better than non-transgenic papaya in the field. The non-transgenic papaya seedlings began to show typical symptoms caused by PRSV after being inoculated with PRSV. They died quickly and never grew to produce fruit. The adult trees developed yellow leaves and produced smaller fruits and were doomed to a slow death after some time, while most of transgenic papaya plants (about 91.8%) did not show any symptoms caused by PRSV, and produced more, bigger, and high quality fruits. Compared with non-transgenic plants, the fresh fruit length of T4 generation of transgenic papaya increased 2.6%–5%, and the diameter decreased 0.6%–1.5%. The flesh thickness of fresh fruit increased 12%–15%, which made it fitter for eating. Although the fresh fruit quality changed, there was no significant difference between transgenic and non-transgenic papaya. The quality characteristics of dry fruit including the contents of water, lipid, N, protein, reduced sugar, vitamin A, vitamin C, and carotene in the T4 generation of transgenic papaya were all the same as their non-transgenic parents. This means that transgenic plants and non-transgenic plants are substantially equivalent, and the transgene has no effect on dry fruit quality. In this study, we found that vitamin A and vitamin C in red-fleshed papaya were 1.4–1.8 and 1.78–2.07 times more than the yellow-fleshed ones, respectively, while N and protein were only 84.2%–92.1% and 82.1%–98.9% of the yellow-fleshed ones. Translated from Acta Ecologica Sinica, 2005, 25(12): 3301–3306 [译自: 生态学报]     

Allelic composition and genetic background effects on transgene expression and inheritance in white clover

Allelic composition and genetic background effects on GUS expression and inheritance using a chimeric (cauliflower mosaic virus 35Sp:uidA) transgene were investigated in white clover as a prelude to transgenic cultivar development. Stable expression and Mendelian inheritance of the uidA transgene was observed over two generations when the uidA transgene was maintained in a heterozygous state. Transgenic backcross progeny (BC1) were intercrossed to produce segregating F2 populations. GUS-positive F2 plants were test-crossed with a non-transgenic control plant to determine whether individuals were heterozygous or homozygous for the transgene. Both expected and distorted segregation ratios were observed. Distortion of the segregation ratio was not caused by transgene inactivation or rearrangement, but was influenced by genetic background. BC1, BC2 and F2 populations were found to have similar levels of uidA gene expression. Quantification of GUS expression from progeny of high and low GUS expressing plants indicate that it is possible to alter transgene expression through selection. No difference was found between the level of expression for F2 plants homozygous or heterozygous for the transgene. These results indicate that F2 plants, homozygous for a transgene, might be used to develop a transgenic cultivar. However, progeny testing to determine the influence of genetic background is a prerequisite to such a development.     

Edible vaccine development: stability of Mannheimia haemolytica A1 leukotoxin 50 during post-harvest processing and storage of field-grown transgenic white clover

Mannheimia haemolytica is the principal microorganism responsible for bovine pneumonic pasteurellosis, or shipping fever. We have previously expressed a fragment of leukotoxin, a major virulent factor of M. haemolytica A1, as a fusion protein with green fluorescent protein (GFP) in transgenic white clover and demonstrated that this antigen was immunogenic and elicited toxin neutralizing antibodies in rabbits. These previous results showed that using plants to produce M. haemolytica antigen for use as a vaccine against this disease is a viable strategy. In this present study, we examined the stability of the truncated leukotoxin GFP-fusion protein (Lkt50-GFP) in field-grown transgenic white clover. Transgenic clover expressing Lkt50-GFP was clonally propagated and a confined field trial was established. Western immunoblotting showed that the level of Lkt50-GFP expression in field plants was the same as in transgenic plants maintained under optimal conditions in the greenhouse. We also observed that after harvesting and oven drying at 50 °C, the antigen was still present in the dried clover after 1 year of storage at ambient temperature. As special post-harvest conditions (e.g., refrigeration) are not required, the use of transgenic plants to deliver an oral vaccine against shipping fever appears to be economically feasible.     

Production of Bean yellow mosaic virus resistant subterranean clover (Trifolium subterraneum) plants by transformation with the virus coat protein gene

Transgenic lines of subterranean clover were constructed that contained three different Bean yellow mosaic virus (BYMV) coat protein (CP) gene constructs; full-length CP, the core region of the CP, and full-length CP plus the 3′ untranslated region of the viral genome. Transgenic plants containing the full-length and core CP gene constructs showed high and moderate levels of BYMV resistance. Resistance was measured as a lack or amelioration of viral disease symptoms, which was correlated with a reduction in virus levels and yield loss. A range of different resistance phenotypes was observed. They included reduced infection rates, delay and reduction in local lesion development, and delay and reduction in severity of systemic symptom development. Resistance levels were not correlated with transgene mRNA levels and no transgene-encoded protein was detected in any of the transgenic lines. This is the first example of genetically engineered virus resistance in a clover.