Field performance of transgenic potato plants compared with controls regenerated from tuber discs and shoot cuttings

Summary The objective of this study was to separate and determine effects on the field performance of transgenic potatoes that originate from the tissue culture process of transformation and from the genes inserted. The constructs introduced contained the reporter gene for betaglucuronidase (GUS) under the control of the patatin promoter (four different constructs) and the neomycin phosphotransferase gene under the control of the nopaline synthase promoter. Both genes might be expected to have a neutral effect on plant phenotype. The field performance of transgenic plants (70 independent transformants) was compared with non-transgenic plants regenerated from tuber discs by adventitious shoot formation and from shoot cultures established from tuber nodal cuttings. Plants from all three treatments were grown in a field trial from previously field-grown tubers, and plant performance was measured in terms of plant height at flowering, weight of tubers, number of tubers, weight of large tubers and number of large tubers. There was evidence of somaclonal variation among the transgenic plants; mean values for all characters were significantly lower and variances generally higher than from plants derived from nodal shoot cultures. A similar change in means and variances was observed for the non-transgenic tuber-disc regenerants when compared with shoot culture plants. Plant height, tuber weight and tuber number were, however, significantly lower in transgenic plants than in tuber-disc regenerants, suggesting an effect on plant performance either of the tissue culture process used for transformation or of the genes inserted. There were significant differences between constructs for all five plant characters. The construct with the smallest segment of patatin promoter and the lowest level of tuber specificity for GUS expression had the lowest values for all five characters. It is proposed that the nature of GUS expression is influencing plant performance. There was no indication that the NPTII gene, used widely in plant transformation, has any substantial effect on plant performance in the field.     

Production of transformed soybean plants by electroporation of protoplasts

Protoplasts obtained from immature seeds of Glycine max (L.) Merr. cv. Clark 63 (soybean) were electroporated with DNA carrying either the kanamycin or hygromycin resistance genes and the reporter genes, β-glucuronidase or opine synthesis. Antibiotic resistance could be selected for at the frequency of about one colony from 2 000 electroporated protoplasts (0.05%) and the reporter genes were expressed in from 75 to 90% of the selected colonies. Antibiotic resistance and reporter gene expression were not found in untreated protoplasts. Shoots formed within about 5 months after a number of transfers of selected portions of the callus on the regeneration medium. The shoots have been rooted to form plants which express the reporter genes and contain the transforming DNA in their leaves as shown by Southern hybridization. The reporter genes are expressed (opine synthesis) in all leaves and roots and NPTII activity was present in all leaves, indicating that the transformed plants are not chimeral. We expect these plants to set seed since untransformed plants regenerated from protoplasts did. We can obtain shoots from several of the soybean genotypes we have used so far. Thus, we should have a method for the efficient production of nonchimeral, transformed plants of the important crop plant soybean.     

Agrobacterium tumefaciens-mediated transformation of Mentha spicata and Mentha arvensis

The stable integration of GUS and NPTII genes in Mentha arvensis and M. spicata has been achieved by Agrobacterium tumefaciens-mediated gene transfer. Transformation assays were performed by cocultivating plant leaf disks with either GV2260/GI or EHA105/MOG Agrobacterium strains. Transgenic plants were selected on medium containing 150 mg l⁻¹ kanamycin. Transgene presence and structure was studied by the use of PCR analysis and Southern blot hybridization. Transgene expression was evaluated by RT-PCR and transgene product activity by a histoenzymatic GUS assay. This revised version was published online in June 2006 with corrections to the Cover Date.     

Transgenic papaya plants from Agrobacterium-mediated transformation of somatic embryos

Summary Transgenic papaya (Carica papaya L.) plants were regenerated from embryogenic cultures that were cocultivated with a disarmed C58 strain of Agrobacterium tumefaciens containing one of the following binary cosmid vectors: pGA482GG or pGA482GG/cpPRV-4. The T-DNA region of both binary vectors includes the chimeric genes for neomycin phosphotransferase II (NPTII) and ß-glucuronidase (GUS). In addition, the plant expressible coat protein (cp) gene of papaya ringspot virus (PRV) is flanked by the NPTII and GUS genes in pGA482GG/cpPRV-4. Putative transformed embryogenic papaya tissues were obtained by selection on 150 g·ml^–1 kanamycin. Four putative transgenic plant lines were obtained from the cp gene^– vector and two from the cp gene⁺ vector. GUS and NPTII expression were detected in leaves of all putative transformed plants tested, while PRV coat protein expression was detected in leaves of the PRV cp gene⁺ plant. The transformed status of these papaya plants was analyzed using both polymerase chain reaction amplification and genomic blot hybridization of the NPTII and PRV cp genes. Integration of these genes into the papaya genome was demonstrated by genomic blot hybridizations. Thus, like numerous other dicotyledonous plant species, papayas can be transformed with A. tumefaciens and regenerated into phenotypically normal-appearing plants that express foreign genes.Journal Series no. 3757 of the Hawaii Institute of Tropical Agriculture and Human Resources     

A simple and efficient gene transfer system of trifoliate orange (Poncirus trifoliata Raf.)

Summary A simple and efficient gene transfer system of trifoliate orange (Poncirus trifoliata Raf.) was developed using epicotyl segments. The segments were infected with Agrobacterium harboring the binary vector pBI121 or pBI101-O12-p1. Both vectors contained the neomycin phosphotransferase II (NPTII) and the -glucuronidase (GUS) genes. In the plasmid pBI101-O12-p1, the GUS gene was directed to the promoter region of ORF12 (rolC) of the Ri plasmid. On a selection medium containing 100 or 200 g/ml kanamycin, adventitious shoots were formed from 21.7–44.6% of the segments. Histochemical GUS assay showed that 55.4–87.7% of the shoots expressed the GUS gene. The stable integration of this gene was also confirmed by polymerase chain reaction (PCR) analysis and by Southern blot analysis. When the pBI101-O12-p1 plasmid was used, the GUS activity was found to be located in phloem cells of leaf, stem and root. More than 100 transformed plants were obtained using this method within 2–3 months.     

<Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>-mediated transformation of eggplant (<Emphasis Type="Italic">Solanum melongena</Emphasis> L.) using root explants

An efficient variety-independent method for producing transgenic eggplant (Solanum melongena L.) via Agrobacterium tumefaciens-mediated genetic transformation was developed. Root explants were transformed by co-cultivation with Agrobacterium tumefaciens strain LBA4404 harbouring a binary vector pBAL2 carrying the reporter gene beta-glucuronidase intron (GUS-INT) and the marker gene neomycin phosphotransferase (NPTII). Transgenic calli were induced in media containing 0.1 mg l(-1) thidiazuron (TDZ), 3.0 mg l(-1) N(6)-benzylaminopurine, 100 mg l(-1) kanamycin and 500 mg l(-1) cefotaxime. The putative transgenic shoot buds elongated on basal selection medium and rooted efficiently on Soilrite irrigated with water containing 100 mg l(-1) kanamycin sulphate. Transgenic plants were raised in pots and seeds subsequently collected from mature fruits. Histochemical GUS assay and polymerase chain reaction analysis of field-established transgenic plants and their offsprings confirmed the presence of the GUS and NPTII genes, respectively. Integration of T-DNA into the genome of putative transgenics was further confirmed by Southern blot analysis. Progeny analysis of these plants showed a pattern of classical Mendelian inheritance for both the NPTII and GUS genes.     

选择标记可去除的植物高效表达载体的构建

在常用的植物组成型表达载体pBI121的选择标记基因NPTII两侧插入同向的lox位点并用多克隆位点(MCS)取代了GUS基因序列,构建了NPTII基因可被去除的和可插入目的基因的通用植物表达载体pBI121-lox-MCS。替换pBI121-lox-MCS中驱动目的基因表达的35S启动子,可构建成一系列具有其他表达特性的植物表达载体,如本文描述的韧皮部特异表达载体pBdENP-lox-MCS。为方便地筛选去除选择标记基因的转基因植物,还构建了绿色荧光蛋白(GFP)表达框与NPTII表达框连锁的pBI121-gfp-lox-MCS载体。上述植物表达载体可广泛应用于培育选择标记可去除的转基因植物。     

Variability of organ-specific gene expression in transgenic tobacco plants

Variability of expression of introduced marker genes was analysed in a large number of tobacco regenerants from anAgrobacterium-mediated transformation. In spite of standardization of sampling, considerable variation of GUS and NPTII expression was observed between individual transformants at different times of analysis and in different parts of the same plant. Organ-specificity of root versus leaf expression conferred by the par promoter from the haemoglobin gene ofParasponia andersonii in front of thegus gene showed a continuous spectrum. GUS expression in roots was found in 128 out of 140 plants; expression in leaves was found in 46 plants, and was always lower than in the corresponding roots. NPTII expression regulated by the nos promoter also showed a continuous spectrum. Expression levels were generally higher in roots than in leaves. Plants with high GUS expression in leaves showed high NPTII activity as well. A positive correlation between the level of NPTII expression and the numbers of integrated gene copies was noted. Chromosomal position effects and physiological determination are suggested as triggers for the variations. The transformed regenerated tobacco plants were largely comparable to clonal variants.     

甜瓜ACC氧化酶反义基因植物表达载体的构建及转化烟草的研究

用限制性内切酶从目的基因供体质粒pBI-aACO1上切下大小约2．3kb的目的基因,将其定向连接在受体质粒pCAMBIA2301载体上,构建成含有GUS基因的甜瓜ACC钣化酶反义基因植物表达载体pCB-aACO1。采用直接转化法将pCB-aACO1导入根癌农杆菌菌株EHA105,并用新构建的工程菌对普通烟草进行了遗传转化研究。在Kanamycin选择压力下获得的烟草转化不定芽和完整植株,经过GUS基因组织化学法检测以及PCR方法鉴定,证实了该反义基因已导入烟草基因组中,此项研究为下一阶段用该反义基因转化甜瓜品种以改良甜瓜果实耐贮运性打下基础。     

Transgenic papaya plants from Agrobacterium-mediated transformation of petioles of in vitro propagated multishoots

Summary In order to establish a model system for introduction of foreign genes into papaya (Carica papaya L.) plants by Agrobacterium-mediated transformation, petioles from multishoots were used as explant source and bacterial neomycin phosphotransferase II (NPT II) gene and -glucuronidase (GUS) gene were used as a selection marker and a reporter, respectively. Cross sections of papaya petioles obtained from multishoots micropropagated in vitro were infected with A. tumefaciens LBA4404 containing NPTII and GUS genes and co-cultured for 2 d. The putative transformed calluses were identified by growth on the selective medium containing kanamycin and carbenicillin, and consequently regenerated to plants via somatic embryogenesis. Thirteen putative transgenic lines were obtained from a total of 415 petiole fragments treated. Strong GUS activity was detected in the selected putative transgenic calli or plants by fluorogenic assay. Western blot analysis using GUS antiserum confirmed that the GUS protein was expressed in putative transformed papaya cells and transgenic plants. The presence of the GUS gene in the papaya tissues was detected by PCR amplification coupled with Southern blot.     

High-frequency homologous recombination in plants mediated by zinc-finger nucleases

Homologous recombination offers great promise for plant genome engineering. This promise has not been realized, however, because when DNA enters plant cells homologous recombination occurs infrequently and random integration predominates. Using a tobacco test system, we demonstrate that chromosome breaks created by zinc-finger nucleases greatly enhance the frequency of localized recombination. Homologous recombination was measured by restoring function to a defective GUS:NPTII reporter gene integrated at various chromosomal sites in 10 different transgenic tobacco lines. The reporter gene carried a recognition site for a zinc-finger nuclease, and protoplasts from each tobacco line were electroporated with both DNA encoding the nuclease and donor DNA to effect repair of the reporter. Homologous recombination occurred in more than 10% of the transformed protoplasts regardless of the reporter's chromosomal position. Approximately 20% of the GUS:NPTII reporter genes were repaired solely by homologous recombination, whereas the remainder had associated DNA insertions or deletions consistent with repair by both homologous recombination and non-homologous end joining. The DNA-binding domain encoded by zinc-finger nucleases can be engineered to recognize a variety of chromosomal target sequences. This flexibility, coupled with the enhancement in homologous recombination conferred by double-strand breaks, suggests that plant genome engineering through homologous recombination can now be reliably accomplished using zinc-finger nucleases.     

Histology and chimeral segregation reveal cell-specific differences in the competence for shoot regeneration and Agrobacterium-mediated transformation in Kohleria internode explants

Summary Internode explants of Kohleria sp. (Gesneriaceae) are capable of regenerating large numbers of adventitious shoots. Regeneration of green shoots from explants of an albino periclinal chimera with genetically green L1, as well as microsurgical removal of the epidermis revealed that shoots originate only from the epidermis. Histological studies further showed that shoots arise from a particular epidermal cell type, viz the basal cell of young glandular trichomes. On the other hand, cells competent for Agrobacterium-mediated transformation are mainly located in vascular tissues, as could be shown by histochemical localization of ß-glucuronidase (GUS) expression in explants that had been inoculated with A. tumefaciens strains carrying binary plasmids with GUS and kanamycin resistance (NPTII) genes. Only 3% of GUS expression events took place in the epidermis. Consequently, shoot regeneration in the presence of kanamycin was very poor. Moreover, most of those shoots proved GUS-negative and did not survive subcultivation on kanamycin-containing medium. Six regenerants, however, were most probably transgenic, as suggested by the ability to produce adventitious shoots in the presence of kanamycin and by polymerase chain reaction (PCR) analysis. To our knowledge, this is the first positive result towards genetic transformation in a taxon of the Gesneriaceae.Abbreviations BA N⁶-benzyladenine - ct cefotaxime - GUS ß-glucuronidase - IAA indole-3-acetic acid - km kanamycin - NPTII neomycin phosphotransferase II - PCR polymerase chain reaction     

Genetic transformation ofRhododendron byAgrobacterium tumefaciens

Summary TransgenicRhododendron plants were obtained byAgrobacterium tumefaciens-mediated gene transfer.A. tumefaciens harboring a binary vector that contained the chimeric neomycin phosphotransferase II (NPTII) and (3-glucuronidase (GUS) genes was co-cultivated with stem and leaf segments fromRhododendron tissues culturedin vitro. Adventitious buds were fonned and shoots were regenerated on kanamycin selection medium 3-4 months after inoculation. Integration of the NPTII and the GUS genes was confirmed by polymerase chain reaction (PCR) and by Southern hybridization analyses. Histochemical GUS assay showed that the inserted gene was expressed in all tissues with the cauliflower mosaic virus (CaMV) 35S promoter. This transformation procedure has the potential to expand the range of genetic variation inRhododendron.     

Transformation and regeneration of transgenic aspen plants via shoot formation from stem explants

An Agrobacterium -mediated transformation procedure for aspen ( Populus tremula L.), involving the direct regeneration of shoot-buds from stem explants, is described. Disarmed Agrobacterium tumefaciens strain EHA101 harboring the binary plasmid pKIW1105 (which carries the uidA and nptII genes, coding for β-glucuronidase [GUS] and neomycin phosphotransferase II, respectively) was used for the transformation of stem explants. An incubation period of 48 to 72 h was found to be most effective in terms of transient GUS expression on the cut surface of the stem explants. Adventitious shoots regenerated after 2–3 weeks of culture in a woody plant medium (WPM) supplemented with TDZ (1-phenyl-3-[1,2,3-thiadiazol-5-yl]-urea, Thidiazuron) and carbenicillin. Three different kanamycin-based selection schemes were evaluated for optimization of transformation efficiency: (1) Kanamycin was added only to the rooting medium (5 to 6 weeks post-inoculation), or (2) to the regeneration medium 10–14 days after inoculation, or (3) after 2 days of co-cultivation. The third selection scheme was found to be optimal for adventitious shoots with regard to both the time required and the transformation efficiency, the latter being much higher than with the other schemes. Leaf samples from kanamycin-resistant shoots and plantlets were tested for GUS expression, and subjected to polymerase chain reaction (PCR) analysis of uidA and nptII genes. A Southern blot of the corresponding PCR-amplified fragments confirmed their authenticity and Southern blots of total plant DNA confirmed integration of the nptII gene into the plant genome.     

Agrobacterium rhizogenes-mediated DNA transfer inPinus halepensis Mill.

Agrobacterium rhizogenes strain LBA9402 was used to transformPinus halepensis embryos, seedlings and shoots. Mature embryos exhibited susceptibility to the agrobacterium as monitored by -glucurortidase (GUS) expression, with more than 85% showing considerable transient GUS expression in the radicle. GUS expression was also observed in cotyledons, but at a lower rate of about 24% of the embryos (1–5 spots/embryo). Stable transformation was evidenced by the regeneration of GUS-expressing roots and calli from infectedP. halepensis seedlings. Inoculum injections into intact seedling hypocotyls induced callus and root formation at the wound sites in 64% of the seedlings. Dipping seedling cuttings in a bacterial suspension resulted in adventitious root formation in 7I% of the seedling cuttings, all of which expressed GUS activity. Adventitious shoots, that were induced on 2.5-year-old seedlings by pruning and spraying with 6-benzylaminopurine, were infected by injecting of bacterial suspension into their basal side. Two months later, adventitious roots and root primordia regenerated in 74% and 40% of 2- and 5-month-old shoots, respectively. Non-transformed shoots, either without or with auxin application, failed to form roots. Polymerase chain reaction and Southern blot analyses confirmed theuidA-transgenic nature of the root and callus, as well as the presence ofrolC androlB genes in roots from infectedP. halepensis seedlings.Abbreviations BA 6-benzylaminopurine - NOS nopaline synthase - PCR polymerise chain reaction - EtOH ethanol - GUS -glucuronidase - NPTII neomycin phosphotransferase II - CaMV cauliflower mosaic virus - X-gluc 5-bromo-4-chloro-3-indolyl -D-glucuronic acid     

Meristem transformation of sunflower via Agrobacterium

Summary For transformation of sunflower (Helianthus annuus L. cv. Zebulon), shoot apical meristems were dissected from seeds and cocultivated with a disarmed Agrobacterium tumefaciens strain harboring a binary vector carrying genes encoding GUS- and NPTII-activity. The influence of the media conditions, the time of cocultivation and the stage of the developing seed on shoot development and meristem transformation was analysed. Transformants were selected by their ability to grow on kanamycin. Transformation was confirmed by assays for GUS and NPTII. GUS-positive shoots were rooted on rockwool and transferred to soil. Transformation of shoot meristem cells occurred at low frequencies. Chimaeric expression of the two genes was observed in transformed plants. Integration of the foreign DNA in the sunflower genome was confirmed with the polymerase chain reaction.Abbreviations GUS ß-Glucuronidase - NPTII Neomycin phosphotransferase II