TECHNICAL ADVANCE: Transformation of the flax rust fungus,Melampsora lini: selection via silencing of an avirulence gene

Rust fungi cause devastating diseases on many important food crops, with a damaging stem rust epidemic currently affecting wheat production in Africa and the Middle East. These parasitic fungi propagate exclusively on plants, precluding the use of many biotechnological tools available for other culturable fungi. In particular the lack of a stable transformation system has been an impediment to the genetic manipulation required for molecular analysis of rust pathogenicity. We have developed an Agrobacterium‐mediated genetic transformation procedure for the model flax rust fungus Melampsora lini, which infects flax (Linum usitatissimum). Selection of transgenic rust lines is based on silencing of AvrL567, which encodes a rust effector protein that is recognised by the flax L6 immune receptor. The non‐transgenic rust line is unable to infect flax plants expressing L6, while silenced transgenic lines are virulent on these plants, providing an effective selection system. This directly confirms that the cloned AvrL567 gene is responsible for flax rust virulence phenotypes, and demonstrates the utility of this system to probe rust gene function.     

Efficient male germ line transformation for transgenic tobacco production without selection

Microspores at late uninucleate/early binucleate stages were isolated from flower buds of tobacco (Nicotiana tabacum L.) and in vitro culture methods optimised for their maturation to fully functional viable pollen which, after application to the stigma of emasculated plants in situ, led to the generation of large numbers of seed. Efficient protocols were established for the biolistic introduction of a construct containing a reporter gene and selectable marker into these microspores and hence, after in vitro maturation and in situ fertilisation, for the generation of transgenic plants. Stable transformants of low copy number were generated by this procedure. The efficiency of transformation achieved allows the production of large numbers of transgenic plants without selection, dispensing with the requirement for a selectable marker in plant transgenesis.     

农杆菌介导抗储粮害虫转基因小麦(Triticum aestivum L.)的获得及分析

以本实验室选育的小麦优良品系的胚性愈伤组织为材料,采用农杆菌介导将抗虫基因豇豆胰蛋白酶抑制剂基因CpTI转入小麦培养细胞,经筛选获得抗卡那霉素的愈伤组织并再生植株。经PCR和实时PCR检测、PCR-Southern和Southernblot验证,确定了3株独立再生植株为含有CpTI的转基因植株。农杆菌菌浓度、侵染时间及转化处理方式对小麦转化率均有明显影响。3株转基因植株正常可育并结籽,形成转基因株系。外源基因在转基因植株T1代中的分离呈多样性,部分株系(转基因株系T-Ⅰ、T-Ⅲ)表现出孟德尔遗传规律。抗虫试验表明,3株转基因植株T2代籽粒对储粮害虫麦蛾具有一定的抗性,转基因株系T-Ⅰ、T-Ⅱ、T-Ⅲ及非转基因植株的T2代籽粒虫蛀率分别为19·8%、21·9%、32·9%和58·3%。转基因植株T1代群体农艺性状调查显示,3个株系具有良好的农艺性状,为小麦的遗传改良提供了新的种质抗虫材料。     

Transgenic sorghum with improved digestibility of storage proteins obtained by <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation

Development of transgenic plants with modified seed storage protein composition and increased nutritive value is one of the most promising areas of genetic engineering. This task is especially important for sorghum—a unique drought tolerant cereal crop that is characterized, however, by a relatively poor nutritive value in comparison with other cereals. It is considered that one of the reasons of the low nutritive value of the sorghum grain is the resistance of one of its seed storage proteins, γ-kafirin, located in the outer layer of endosperm protein bodies, to protease digestion. Using Agrobacterium-mediated genetic transformation, we obtained transgenic sorghum plants (Sorghum bicolor (L.) Moench) harboring a genetic construct for RNAi silencing of the γ-kafirin gene. In the T₁ generation, the plants with almost floury or modified endosperm texture of kernels were found. In these kernels, the vitreous endosperm layer has been reduced and/or covered by a thin layer of floury endosperm. In vitro protein digestibility (IVPD) analysis showed that the amount of undigested protein in transgenic plants from the T₃ generation was reduced by 2.9–3.2 times, in comparison with the original non-transgenic line, and the digestibility index reached 85–88% (in comparison with 59% in the original line). In T₂ families, the plants combining high IVPD with vitreous endosperm type were found. In the electrophoretic spectra of endosperm proteins of transgenic plants with increased digestibility, the proportion of 20 kD protein that is encoded by the γ-kafirin gene, was significantly reduced, in comparison with the original non-transgenic line. HPLC analysis showed total amino acid content in two out of the three studied transgenic plants from the T₂ generation was reduced in comparison with the original non-transgenic line, while the lysine proportion increased by 1.6–1.7 times. The mechanisms conditioning improved digestibility of storage proteins in transgenic plants are discussed. The results of experiments demonstrate that it is feasible to develop sorghum lines combining high protein digestibility and vitreous endosperm that has a high breeding value.     

Generation of large numbers of transgenic Kentucky bluegrass (Poa pratensis L.) plants following biolistic gene transfer

A very efficient transformation system, using biolistic bombardment, has been developed for the production of transgenic plants of Kentucky bluegrass (Poa pratensis L.). Embryogenic calli, initiated from immature embryos, were transformed either with pAct1IHPT-4 containing the hygromycin phosphotransferase (hpt) gene or with pDM803 containing the phosphinothricin acetyltransferase (bar) gene and the β-glucuronidase (uidA) gene. In total 119 independent transgenic plants were recovered from 153 hygromycin-resistant lines. Bialaphos selection yielded a total of 99 bialaphos-resistant lines and from these 34 independent transgenic plants were recovered. Southern blot analysis demonstrated the independent nature of the transgenic plants and also revealed a complex transgene integration pattern with multiple insertions. The first two author contributed equally to this work     

抗逆相关基因GmAREB转基因小麦的获得与鉴定

从大豆中克隆一个抗逆相关的bZIP类转录因子基因GmAREB,功能分析表明:GmAREB基因的过表达可以显著提高转基因拟南芥和烟草的抗旱、耐盐和耐寒性。为了获得抗逆转基因小麦,本研究利用玉米的Ubiqutin启动子控制GmAREB基因表达,构建了用于小麦转化的载体pSK-GmAREB。采用基因枪共转化法转化小麦品种郑147和济麦22。通过PCR检测共获得T0代的阳性植株70株,转化率为1.37%。其中,郑147阳性植株共31株,转化率为2.14%;济麦22阳性植株39株,转化率为1.08%。目前,已经获得T1代转基因株系18个,其中以郑147为受体的株系4个,以济麦22为受体的株系14个。对部分株系进行Southern blotting分析,进一步证实GmAREB基因已经整合到小麦基因组中。在低温胁迫条件下,3个以济麦22为受体的转基因株系体内脯氨酸的积累与受体小麦相比有显著增加,初步证明在小麦中过表达GmAREB基因,可以促进渗透调节物质脯氨酸的积累,可能有助于转基因小麦抗逆性的提高。本研究为进一步筛选抗逆转基因小麦新材料奠定了基础。     

RNA virus accumulation is inhibited by ribonuclease activity of 3D8 scFv in transgenic Nicotiana tabacum

A mannose selection system was adapted for Agrobacterium-mediated transformation of plum (Prunus domestica L.) hypocotyl explants and the recovery of transgenic plants. Adventitious regeneration from non-transformed hypocotyl sections was inhibited when 3 mg/l mannose, combined with 10 mg/l sucrose, was added to the medium. Mature seed hypocotyl slices from the cultivar ‘Claudia Verde’ were infected with A. tumefaciens AGL1, carrying the pNOVgus vector, and placed onto different selective media with mannose. A low mannose selection (1.5 g/l, regeneration below the inhibitory concentration) applied for 16 weeks led to the regeneration of escapes. However, when mannose at 1.5 g/l or at 3 g/l (the regeneration-inhibiting concentration) was applied for 6 weeks from the beginning of the experiments and, after that, was increased to 5 g/l, several independent transgenic lines were obtained. The transformation events were monitored by detection of the GUS enzymatic activity at different stages of the process. Nevertheless, stable integration of transgenes into the genome of the plum plants was confirmed by PCR and Southern blot analysis. The transformed shoots were rooted on a medium supplemented with 10 g/l sucrose and 4 g/l mannose. The transformation procedure described here, using the pmi/mannose system for selection of transgenic plum plants, represents an alternative for the production of transgenic plum plants under conditions that are safe regarding human health and the environment, and would permit the insertion of more transgene/s in a pre-existing transgenic line.     

Evaluation of the Agronomic Performance of Atrazine-Tolerant Transgenic japonica Rice Parental Lines for Utilization in Hybrid Seed Production

Currently, the purity of hybrid seed is a crucial limiting factor when developing hybrid japonica rice (Oryza sativa L.). To chemically control hybrid seed purity, we transferred an improved atrazine chlorohydrolase gene (atzA) from Pseudomonas ADP into hybrid japonica parental lines (two maintainers, one restorer), and Nipponbare, by using Agrobacterium-mediated transformation. We subsequently selected several transgenic lines from each genotype by using PCR, RT-PCR, and germination analysis. In the presence of the investigated atrazine concentrations, particularly 150 µM atrazine, almost all of the transgenic lines produced significantly larger seedlings, with similar or higher germination percentages, than did the respective controls. Although the seedlings of transgenic lines were taller and gained more root biomass compared to the respective control plants, their growth was nevertheless inhibited by atrazine treatment compared to that without treatment. When grown in soil containing 2 mg/kg or 5 mg/kg atrazine, the transgenic lines were taller, and had higher total chlorophyll contents than did the respective controls; moreover, three of the strongest transgenic lines completely recovered after 45 days of growth. After treatment with 2 mg/kg or 5 mg/kg of atrazine, the atrazine residue remaining in the soil was 2.9–7.0% or 0.8–8.7% respectively, for transgenic lines, and 44.0–59.2% or 28.1–30.8%, respectively, for control plants. Spraying plants at the vegetative growth stage with 0.15% atrazine effectively killed control plants, but not transgenic lines. Our results indicate that transgenic atzA rice plants show tolerance to atrazine, and may be used as parental lines in future hybrid seed production.     

Genetic Transformation and Somatic Embryogenesis in Lathyrus sativus

Direct somatic embryogenesis and genetic transformation has been achieved in Lathyrus sativus. The genetic transformation was achieved by Agrobacterium tumefaciens and biolistic methods of gene transfer. Somatic embryogenesis was obtained from immature leaflets and nodal segments by using 2,4-0 in the induction medium. Somatic embryos formed germinated on growth regulator-free medium. The transgenic nature of the transformants was confirmed by GUS expression assay. The transgenic shoots/plantlets were obtained only from tissue transformed with biolistic method of gene transfer.     

Development of transformation vectors based upon a modified plant alpha-tubulin gene as the selectable marker

A plant transformation and selection system has been developed utilizing a modified tubulin gene as a selectable marker. The vector constructs carrying a mutant alpha-tubulin gene from goosegrass conferring resistance to dinitroaniline herbicides were created for transformation of monocotyledonous and dicotyledonous plants. These constructs contained beta- and/or mutant alpha-tubulin genes driven either by ubiquitin or CaMV 35S promoter. The constructs were used for biolistic transformation of finger millet and soybean or for Agrobacterium-mediated transformation of flax and tobacco. Trifluralin, the main representative of dinitroaniline herbicides, was used as a selective agent in experiments to select transgenic cells, tissues and plantlets. Selective concentrations of trifluralin estimated for each species were as follows: 10 microM for Eleusine coracana, Glycine max, Nicotiana plumbaginifolia and Nicotiana sylvestris; 3 microM for Linum usitatissimum. PCR and Southern blotting analyses of transformed lines with a specific probe to nptII, alpha-tubulin or beta-tubulin genes were performed to confirm the transgenic nature of regenerated plants. Band specific for the mutant alpha-tubulin gene was identified in transformed plant lines. Results confirmed the stable integration of the mutant tubulin gene into the plant genomes. The present study clearly demonstrates the use of a plant mutant tubulin as a selective gene for plant transformation.     

Commercial production of aprotinin in transgenic maize seeds

The development of genetic transformation technology for plants has stimulated an interest in using transgenic plants as a novel manufacturing system for producing different classes of proteins of industrial and pharmaceutical value. In this regard, we report the generation and characterization of transgenic maize lines producing recombinant aprotinin. The transgenic aprotinin lines recovered were transformed with the aprotinin gene using the bar gene as a selectable marker. The bar and aprotinin genes were introduced into immature maize embryos via particle bombardment. Aprotinin gene expression was driven by the maize ubiquitin promoter and protein accumulation was targeted to the extracellular matrix. One line that showed a high level of aprotinin expression was characterized in detail. The protein accumulates primarily in the embryo of the seed. Southern blot analysis showed that the line had at least 20 copies of the bar and aprotinin genes. Further genetic analysis revealed that numerous plants derived from this transgenic line had a large range of levels of expression of the aprotinin gene (0–0.069%) of water-soluble protein in T₂ seeds. One plant lineage that showed stable expression after 4 selfing generations was recovered from the parental transgenic line. This line showed an accumulation of the protein in seeds that was comparable to the best T₂ lines, and the recombinant aprotinin could be effectively recovered and purified from seeds. Biochemical analysis of the purified aprotinin from seeds revealed that the recombinant aprotinin had the same molecular weight, N-terminal amino acid sequence, isoelectric point, and trypsin inhibition activity as native aprotinin. The demonstration that the recombinant aprotinin protein purified from transgenic maize seeds has biochemical and functional properties identical to its native counterpart provides a proof-of-concept example for producing new generation products for the pharmaceutical industry.     

RNAi-mediated <Emphasis Type="Italic">Soybean mosaic virus</Emphasis> (SMV) resistance of a Korean Soybean cultivar

Soybean [Glycine max (L.) Merr.] is an important crop for vegetable oil production, and is a major protein source worldwide. Because of its importance as a crop, genetic transformation has been used extensively to improve its valuable traits. Soybean mosaic virus (SMV) is one of the most well-known viral diseases affecting soybean. Transgenic soybean plants with improved resistance to SMV were produced by introducing HC-Pro coding sequences within RNA interference (RNAi) inducing hairpin construct via Agrobacterium-mediated transformation. During an experiment to confirm the response of transgenic plants (T₂) to SMV infection, no T₂ plants from lines #2 (31/31), #5 (35/35) or #6 (37/37) exhibited any SMV symptoms, indicating strong viral resistance (R), whereas NT (non-transgenic wild type) plants and those from lines #1, #3 and #4 exhibited mild mosaic (mM) or mosaic (M) symptoms. The northern blot analysis showed that three resistant lines (#2, #5 and #6) did not show the detection of viral RNA accumulation while NT, EV (transformed with empty vector carrying only Bar) and lines #1, #3 and #4 plants were detected. T₃ seeds from SMV-inoculated T₂ plants were harvested and checked for changes in seed morphology due to viral infection. T₃ seeds of lines #2, #5 and #6 were clear and seed coat mottling was not present, which is indicative of SMV resistance. RT-PCR and quantitative real-time PCR showed that T₃ seeds from the SMV-resistant lines #2, #5 and #6 did not exhibit any detection of viral RNA accumulation (HC-Pro, CP and CI), while the viral RNA accumulation was detected in SMV-susceptible lines #1, #3 and #4 plants. During the greenhouse test for viral resistance and yield components, T₃ plants from the SMV-inoculated transgenic lines #2, #5 and #6 showed viral resistance (R) and exhibited a more favorable average plant height, number of nodes per plant, number of branches per plant, number of pods per plant and total seed weight with statistical significance during strong artificial SMV infection than did other plant lines. In particular, the SMV-resistant line #2 exhibited superior average plant height, pod number and total seed weight with highly significance. According to our results, RNAi induced by the hairpin construct of the SMV HC-Pro sequence effectively confers much stronger viral resistance than did the methods used during previous trials, and has the potential to increase yields significantly. Because of its efficiency, the induction of RNAi-mediated resistance will likely be used more frequently as part of the genetic engineering of plants for crop improvement.     

Constitutive overexpression of small HSP24.4 gene in transgenic tomato conferring tolerance to high-temperature stress

Acquired thermotolerance in plants refers to the ability to cope with lethal high temperatures and it reflects an actual tolerance mechanism that occurs naturally in plants. Tomato (Solanum lycopersicum syn. Lycopersicon esculentum L.) is sensitive to high temperature at all stages of its growth and development. Considering the important role of the heat shock protein gene (sHSP24.4 gene) in imparting tolerance to high temperature stress in the cells and tissues, we isolated small HSP24.4 (MasHSP24.4) cDNA from wild banana (Musa accuminata) and introduced it into the cultivated tomato cv. PKM1 by using Agrobacterium tumefaciens-mediated genetic transformation. Stable integration and expression of the transgene in the tomato genome was demonstrated by Southern, Northern and Western blot analyses. There was no adverse effect of transgene expression on overall growth and development of the transgenic plants. The genetic analysis of the transgenic T2 lines showed that the transgene segregated in a Mendelian ratio. We compared the survival of T2 transgenic lines compared to the control plants after exposure to different levels of high temperature. The gene MasHSP24.4 was expressed in root, shoot and stem tissues under 45 °C treatment and conferred tolerance to high-temperature stress as shown by increased seed germination, healthy vegetative growth and normal fruit and seed setting. The transgenic tomato plants showed significantly better growth performance in the recovery phase following the stress. This thermotolerance appeared to be solely due to overexpression of the sHSP24.4 gene. Thus, the transgenic tomato plants developed during the present investigations can be grown at high temperatures.     

Characterization of SMV resistance of soybean produced by genetic transformation of SMV-CP gene in RNAi

Soybean mosaic virus (SMV), a species of the Potyvirus genus in the Potyviridae family, is one of the most typical viral diseases and results in yield and quality loss of cultivated soybean. Due to the depletion of genetic resources for resistance breeding, a trial of genetic transformation to improve disease resistance has been performed by introducing the SMV-CP gene by the RNA interference (RNAi) method via Agrobacterium-mediated transformation. Among 30 transgenic plants produced, 7 lines with enough seeds were infected with SMV and two lines (3 and 4) showed viral resistance to SMV infection. In genomic Southern blot analysis, all the lines tested contained at least one T-DNA insertion. Subsequent investigation confirmed that no viral CP gene expression was detected in two SMV-resistant lines after artificial inoculation of SMV, while non-transgenic control and other transgenic lines expressed substantial amounts of the viral gene. Viral symptoms affected seed morphology, and clean seeds were harvested from the resistant lines. Also, strong viral gene expression was detected from the seeds of susceptible lines. In further generations, the same phenotypic appearance was maintained among non-transgenic and transgenic plants. Finally, the presence of helper component-proteinase (HC-Pro), known as a suppressor of gene silencing apparatus, was checked among transgenic lines. No expression of HC-Pro in resistant lines indicated that the viral CP-RNAi transformation into soybean somehow created a functional gene silencing system and resulted in a viral-resistant phenotype.     

Efficient genetic transformation of okra (Abelmoschus esculentus (L.) Moench) and generation of insect-resistant transgenic plants expressing the cry1Ac gene

Key message

Agrobacterium -mediated transformation system for okra using embryos was devised and the transgenic Bt plants showed resistance to the target pest, okra shoot, and fruit borer ( Earias vittella ).

Abstract

Okra is an important vegetable crop and progress in genetic improvement via genetic transformation has been impeded by its recalcitrant nature. In this paper, we describe a procedure using embryo explants for Agrobacterium-mediated transformation and tissue culture-based plant regeneration for efficient genetic transformation of okra. Twenty-one transgenic okra lines expressing the Bacillus thuringiensis gene cry1Ac were generated from five transformation experiments. Molecular analysis (PCR and Southern) confirmed the presence of the transgene and double-antibody sandwich ELISA analysis revealed Cry1Ac protein expression in the transgenic plants. All 21 transgenic plants were phenotypically normal and fertile. T₁ generation plants from these lines were used in segregation analysis of the transgene. Ten transgenic lines were selected randomly for Southern hybridization and the results confirmed the presence of transgene integration into the genome. Normal Mendelian inheritance (3:1) of cry1Ac gene was observed in 12 lines out of the 21 T₀ lines. We selected 11 transgenic lines segregating in a 3:1 ratio for the presence of one transgene for insect bioassays using larvae of fruit and shoot borer (Earias vittella). Fruit from seven transgenic lines caused 100 % larval mortality. We demonstrate an efficient transformation system for okra which will accelerate the development of transgenic okra with novel agronomically useful traits.     

Genetic transformation of wheat using mature seed tissues

A protocol for biolistic transformation of bread wheat based on using mature seed tissues as explants has been developed. Embryogenic callus obtained from mature seed tissues was transformed with a psGFP-BAR plasmid containing gfp reporter gene and bar selectable marker gene. The influence of hormone composition of the medium on the efficiency of transformation of mature wheat seed tissues has been demonstrated. The use of auxin 2,4-D resulted in the formation of transgenic plants with a frequency of 0.75%, while the use of Dicamba auxin for the regeneration of plants did not result in transformant development. The transgenic status of the plants obtained in the experiments has been confirmed by PCR and RT-PCR. Stable inheritance of transgenic features in the following generations of wheat (T₁, T₂) has been demonstrated and transgenic plants exhibiting high resistance to herbicides have been obtained. The protocol developed allows for a simplified transformation of wheat in order to obtain transgenic plants with novel features.