Regeneration of transgenic shape Vitis vinifera L. Sultana plants: genotypic and phenotypic analysis

Different approaches to producing transgenic grapevines based on regeneration via embryogenesis were investigated. Embryogenic callus was initiated from anther tissue of Vitis vinifera cv. Sultana and three embryogenic culture types (embryogenic callus, tissue type I; proliferating embryos, tissue type II; and a suspension) were established. The three culture types were incolucaled with Agrobacterium tumefaciens harbouring a binary vector which contained a uidA reporter gene and either a hpt or nptII selectable marker gene or the cultures were bombarded with microprojectiles carrying a uidA/nptII binary vector. Transgenic plants were produced only from Agrobacterium transformation experiments. Transformed embryos were selected with kanamycin or hygromycin antibiotics and recovered with the highest efficiency from inoculated type I cultures. Southern analysis of genomic DNA extracted from ten transgenic plants showed that the number of T-DNA insertions in the genome ranged from 1 to at least 4. Evidence for methylation of the T-DNA at cytosine and adenine residues in transgenic plants was found by Southern analysis of DNA digested with two isoschizomer pairs of restriction endonucleases. No evidence for genotype alterations or somatic meiosis was found when DNA from 80 somatic embryos and seven plants regenerated from embryogenic culture were analysed at six sequence-tagged sites which are heterozygous in cv. Sultana. Expression of the uidA gene in in vitro grown leaves of transgenic plants was most often high and uniform but GUS staining was occasionally observed to be low and/or patchy. Transgenic plants and all plants regenerated from embryogenic culture produced red veined, lobed leaves which are uncharacteristic of the accepted ampelographic phenotype of Sultana. It is suggested that this phenotype may represent a juvenile growth stage.     

Whisker-mediated transformation of embryogenic callus of maize

 The present study was designed to establish embryogenic callus as a target tissue for whisker-mediated transformation of maize (Zea mays L.). Silicon carbide whiskers were used to deliver the bar and uidA (GUS) genes into embryogenic maize callus. Samples of osmotically-treated Type II callus were vigorously agitated in the presence of whiskers and plasmid DNA using a standard laboratory vortex or a modified dental amalgamator. On average, three transgenic callus lines were obtained per 100 samples treated. Plants were regenerated from several GUS-expressing callus lines and DNA analyses confirmed stable integration and inheritance. As with other direct DNA delivery methods involving embryogenic maize callus, integration patterns of the inserted DNA appeared to be complex. Although currently less efficient than microparticle bombardment on a per target basis, whisker-mediated transformation of embryogenic callus represents a viable method for transgenic maize production. Received: 14 May 1999 / Revision received: 11 October 1999 / Accepted: 11 October 1999     

Rapid Production of Multiple Independent Lines of Fertile Transgenic Wheat (Triticum aestivum)

Improvement of wheat (Triticum aestivum) by biotechnological approaches is currently limited by a lack of efficient and reliable transformation methodology. In this report, we detail a protocol for transformation of a highly embryogenic wheat cultivar, Bobwhite. Calli derived from immature embryos, 0.5 to 1 mm long, were bombarded with microprojectiles coated with DNA containing as marker genes the bar gene, encoding phosphinothricin-resistance, and the gene encoding [beta]-glucuronidase (GUS), each under control of a maize ubiquitin promoter. The bombardment was performed 5 d after embryo excision, just after initiation of callus proliferation. The ability of plantlets to root in the presence of 1 or 3 mg/L of bialaphos was the most reliable selection criteria used to identify transformed plants. Stable transformation was confirmed by marker gene expression assays and the presence of the bar sequences in high molecular weight chromosomal DNA of the resultant plants. Nine independent lines of fertile transgenic wheat plants have been obtained thus far, at a frequency of 1 to 2 per 1000 embryos bombarded. On average, 168 d elapsed between embryo excision for bombardment and anthesis of the T0 plants. The transmission of both the resistance phenotype and bar DNA to the T1 generation verified that germline transformation had occurred.     

An improved rice transformation system using the biolistic method

Immature embryos and embryogenic calli of rice, both japonica and indica subspecies, were bombarded with tungsten particles coated with plasmid DNA that contained a gene encoding hygromycin phosphotransferase (HPH, conferring hygromycin resistance) driven by the CaMV 35S promoter or Agrobactenum tumefaciens NOS promoter. Putatively transformed cell clusters were identified from the bombarded tissues 2 weeks after selection on hygromycin B. By separating these cell clusters from each other, and by stringent selection not only at the callus growth stage but also during regeneration and plantlet growth, the overall transformation and selection efficiencies were substantially improved over those previously reported. From the most responsive cultivar used in these studies, an average of one transgenic plant was produced from 1.3 immature embryos or from 5 pieces of embryogenic calli bombarded. Integration of the introduced gene into the plant genome, and inheritance to the offspring were demonstrated. By using this procedure, we have produced several hundred transgenic plants. The procedure described here provides a simple method for improving transformation and selection efficiencies in rice and may be applicable to other monocots.Abbreviations bp base pairs - CaMV cauliflower mosaic virus - GUS -glucuronidase - HPH hygromycin phosphotransferase - hyg B hygromycin B - hyg^r hygromycin resistance - NOS Agrobactenum tumefaciens nopaline synthase - PCR polymerase chain reaction - X-Gluc 5-bromo-4-chloro-3-indolyl--D-glucuronide     

An efficient particle bombardment system for the genetic transformation of asparagus (Asparagus officinalis L.)

The microprojectile bombardment method was used to transfer DNA into embryogenic callus of asparagus (Asparagus officcinalis L.) and to produce stably transformed asparagus plants. Embryogenic callus, derived from UC 157 and UC72 asparagus cultivars, was bombarded with tungsten particles coated with plasmid DNA that contained genes encoding hygromycin phosphotransferase, phosphinothricin acetyl transferase and -glucuronidase. Putatively transformed calli were identified from the bombarded tissue after 4 months selection on 25 mg/L hygromycin B plus 4 mg/L phosphinothricin (PPT). By selecting embryogenic callus on hygromycin plus PPT the overall transformation and selection efficiencies were substantially improved over selection with hygromycin or PPT alone, where no transgenic clones were recovered. The transgenic nature of the selected material was demonstrated by GUS histochemical assays and Southern blot hybridization analysis. Transgenic asparagus plants were found to withstand the prescribed levels of the PPT-based herbicide BASTATM for weed control.Abbreviations GUS -glucuronidase - HPT hygromycin phosphotransferase - bar phosphinothricin acetyl transferase gene - PPT phosphophinothricin - NAA naphthalene acetic acid - 2iP 2-isopentenyl adenine     

Tissue culture specificity of the tobacco ASA2 promoter driving hpt as a selectable marker for soybean transformation selection

This study was carried out to determine if the tobacco anthranilate synthase ASA2 2.3 kb promoter drives tissue culture specific expression and if it is strong enough to drive hpt (hygromycin phosphotransferase) gene expression at a level sufficient to allow selection of transformed soybean embryogenic culture lines. A number of transformed cell lines were selected showing that the promoter was strong enough. Northern blot analysis of plant tissues did not detect hpt mRNA in the untransformed control or in the ASA2-hpt plants except in developing seeds while hpt mRNA was detected in all tissues of the CaMV35S-hpt positive control line plants. However, when the more sensitive RT-PCR assay was used all tissues of the ASA2-hpt plants except roots and mature seeds were found to contain detectable hpt mRNA. Embryogenic tissue cultures initiated from the ASA2-hpt plants contained hpt mRNA detectable by both northern and RT-PCR analysis and the cultures were hygromycin resistant. Friable callus initiated from leaves of ASA2-hpt plants did in some cases contain hpt mRNA that was only barely detectable by northern hybridization even though the callus was very hygromycin resistant. Thus the ASA2 promoter is strong enough to drive sufficient hpt expression in soybean embryogenic cultures for hygromycin selection and only very low levels of expression were found in most plant tissues with none in mature seeds.     

Transgenic maize plants by tissue electroporation.

In this paper, we describe the transformation of regenerable maize tissues by electroporation. In many maize lines, immature zygotic embryos can give rise to embryogenic callus cultures from which plants can be regenerated. Immature zygotic embryos or embryogenic type I calli were wounded either enzymatically or mechanically and subsequently electroporated with a chimeric gene encoding neomycin phosphotransferase (neo). Transformed embryogenic calli were selected from electroporated tissues on kanamycin-containing media and fertile transgenic maize plants were regenerated. The neo gene was transmitted to the progeny of kanamycin-resistant transformants in a Mendelian fashion. This showed that all transformants were nonchimeric, suggesting that transformation and regeneration are a single-cell event. The maize transformation procedure presented here does not require the establishment of genotype-dependent embryogenic type II callus or cell suspension cultures and facilitates the engineering of new traits into agronomically relevant maize inbred lines.     

Expression of a fungal cyanamide hydratase in transgenic soybean detoxifies cyanamide in tissue culture and in planta to provide cyanamide resistance

Embryogenic tissue cultures of soybean were transformed by particle bombardment with a vector pCHZ-II that carries the coding sequence for cyanamide hydratase (Cah), an enzyme that converts toxic cyanamide to urea, from the soil fungus Myrothecium verrucaria. The Cah gene was driven by the constitutive Arabidopsis thaliana actin-2 promoter and terminated with its cognate terminator. This vector also carries the hygromycin phosphotransferase gene (hpt) driven by the potato (Solanum tuberosum) ubiquitin-3 promoter. Twelve individual lines of transgenic plants that were obtained under hygromycin selection expressed Cah mRNA and exhibited resistance to hygromycin in leaf tissue culture, while the untransformed tissues were sensitive. Cah enzyme activity was present in extracts of transformed leaves and embryogenic tissue cultures when measured by a colorimetric assay and the presence of the Cah protein was confirmed by enzyme-linked immunosorbent assay (ELISA). Cah expression detoxified cyanamide in leaf callus and embryogenic cultures as well as in whole plants as shown by cyanamide resistance. The Cah-expressing plants grew and set seeds normally indicating that the Cah enzyme activity did not affect soybean plant metabolism. We also describe a test whereby callus was formed on cultured leaf tissue in the presence of hygromycin or cyanamide only if the hpt or Cah gene was expressed, respectively. This test is a convenient and cost-effective way to follow the marker gene in the primary regenerated plants and subsequent generations, which is particularly reliable for the hpt gene expression using hygromycin.     

Transformation of soybean via particle bombardment of embryogenic suspension culture tissue

Summary Embryogenic suspension culture tissue of soybean (Glycine max Merrill.) was bombarded with particles coated with plasmid DNAs encoding hygromycin resistance andβ-glucuronidase (GUS). One to two weeks after bombardment, embryogenic tissue was placed in a liquid proliferation medium containing hygromycin. Four to six weeks after bombardment, lobes of yellow-green, hygromycin-resistant tissue, which began as outgrowths on brown clumps of hygromycin-sensitive tissue, were isolated and cultured to give rise to clones of transgenic embryogenic material. In vivo GUS assays of hygromycin-resistant clones showed that the early outgrowths could be negative, sectored, or positive for GUS activity. Transgenic, fertile plants could be routinely produced from the proliferating transgenic embryogenic clones. Southern hybridization analyses confirmed stable transformation and indicated that both copy number and integration pattern of the introduced DNA varied among independently transformed clones. Hybridization analysis of DNA from progeny plants showed genetic linkage of multiple copies of introduced DNA. An average of three transgenic clones were obtained per bombardment making this procedure very suitable for transformation of soybean.     

Production of transgenic maize from bombarded type II callus: Effect of gold particle size and callus morphology on transformation efficiency

Summary Here we present a routine and efficient protocol for year-round production of fertile transgenic maize plants. Type II callus derived from maize Hi II immature zygotic embryos was transformed using the PDS 1000/He biolistic gun and selected on bialaphos. In an effort to improve the transformation protocol, the effects of gold particle size and callus morphology on transformation efficiency were investigated. Reducing gold particle size from 1.0 μm or 0.6 μm resulted in a significant increase in the rate of recovery of bialaphos-resistant clones from Type II callus. The average transformation efficiency of pre-embryogenic, early embryogenic and late embryogenic callus did not vary significantly. Rates of transformation, regeneration and fertility achieved for Type II callus are summarized and compared to those achieved for greenhouse- and field-derived immature zygotic embryos.     

PIG-mediated cassava transformation using positive and negative selection

 In order to develop new selection systems for production of transgenic cassava (Manihot esculenta Crantz), two different selection regimes were assessed for their efficiency on regeneration of transgenic cassava plants: positive selection using mannose and negative selection using hygromycin. Explants from somatic cotyledons and embryogenic suspensions were used as target tissues in the transformation experiments and bombarded using the particle inflow gun. Different culture and selection strategies were assessed to optimise the selection protocols. For the first time transgenic plants could be obtained using positive, and in the case of embryogenic suspensions, hygromycin-based negative selection. The stably transformed nature of the regenerated cassava plant lines and the expression of the transgenes were verified with PCR, RT-PCR, Southern and northern analyses. A rooting test for transgenic plants on a medium supplemented with mannose was developed to further improve the efficacy of the positive selection system. Our results demonstrate that it is possible to obtain transgenic cassava plants using non-antibiotic positive selection. Received: 21 February 2000 / Revision received: 2 May 2000 / Accepted: 5 May 2000     

Development of transgenic rice pure lines by particle bombardment‐mediated transformation and genetic analysis‐based selection

Mature seed‐derived callus from an elite Chinese japonica rice cv. Eyl 105 was transformed with a plasmid containing the selectable marker hygromycin phosphotransferase (hpt) and the reporter β‐glucuronidase (gusA) genes via particle bombardment. After two rounds of selection on hygromycin (30 mg/l)‐containing medium, resistant callus was transferred to hygromycin (30 mg/l)‐containing regeneration medium for plant regeneration. Twenty‐three independent transgenic rice plants were regenerated from 127 bombarded callus with a transformation frequency of 18.1%. All the transgenic plants contained both gusA and hpt genes, revealed by PCR/Southern blot analysis. GUS assay revealed 18 out of 23 plants (78.3%) proliferated on hygromycin‐containing medium had GUS expression at various levels. Genetic analysis confirmed Mendelian segregation of transgenes in progeny. From R2 generations with their R1 parent plants showing 3:1 Mendelian segregation, we identified three independent homozygous transgenic rice lines. The homozygous lines were phenotypically normal and fertile compared to the control plants. We demonstrate that homozygous transgenic rice lines can be obtained via particle bombardment‐mediated transformation and through genetic analysis‐based selection.     

The effect of parental genotype on initiation of embryogenic callus from elite maize (Zea mays L.) germplasm

Summary Embryogenic callus consisting of both Type 1, firm, compact, translucent, relatively slow growing callus and Type 2, highly friable, rapidly growing callus with well-formed somatic embryos, were observed in elite maize germplasm, notably B73 and hybrids with B73. Parental genotype is very important in the ability to identify and isolate embryogenic callus after 14 and 28 days in culture. A partial diallel analysis revealed that a large proportion of the genotypic variation was of the additive type although heterosis did positively increase culture response in most cases. A significant negative maternal effect for culture response was noted for inbred B73 from Reid-type germplasm while four lines sampled from Lancaster germplasm showed similar response whether used as male or female. Although significant media differences were observed in some genotypes, culture media did not preclude observation of Type 1 or Type 2 embryogenic cultures in this study after 14 and 28 days. Plants could be regenerated from all genotypes in this study after 14-days of culture, but not all genotypes were capable of sustained subculture and plant regeneration. Plant regeneration from Type 2 cultures of B73 and B73 hybrids has been obtained up to a year after initiation.     

Glufosinate as an efficient inhibitor of callus proliferation in coffee tissue

Summary To improve selection of transgenic Coffea spp. tissue after transformation treatments, the effects of the selective agents chlorsulfuron, glufosinate, glyphosate, hygromycin, and kanamycin were studied on callus development from leaf explants (from greenhouse-grown plants and somaplants) and in embryogenic suspension cultures. Studied genotypes were from C. arabica, C. canephora, and the interspecific hybrids Arabusta and Congusta. A culture system based on “direct” somatic embryogenesis from C. canephora leaf explants proved to be more sensitive to selective agents than high frequency somatic embryogenesis from C. arabica or Arabusta leaf explants. With respect to the selective effect, chlorsulfuron and hygromycin provoked strong inhibition and severe necrosis, whereas glyphosate and kanamycin showed variable inhibition. Glufosinate appeared to efficiently inhibit growth of both leaf callus and callus suspensions of all genotypes tested without inducing necrosis. These properties may make the use of glufosinate advantageous in a selective growth system for detection of transformed coffee tissues.     

Expression of green fluorescent protein and its inheritance in transgenic oat plants generated from shoot meristematic cultures

The expression of green fluorescent protein (GFP) and its inheritance were studied in transgenic oat ( Avena sativa L.) plants transformed with a synthetic green fluorescent protein gene [sgfp(S65T)] driven by a rice actin promoter. In vitro shoot meristematic cultures (SMCs) induced from shoot apices of germinating mature seeds of a commercial oat cultivar, Garry, were used as a transformation target. Proliferating SMCs were bombarded with a mixture of plasmids containing the sgfp(S65T) gene and one of three selectable marker genes, phosphinothricin acetyltransferase (bar), hygromycin phosphotransferase (hpt) and neomycin phosphotransferase (nptII). Cultures were selected with bialaphos, hygromycin B and geneticin (G418), respectively, to identify transgenic tissues. From 289 individual explants bombarded with the sgfp(S65T) gene and one of the three selectable marker genes, 23 independent transgenic events were obtained, giving a 8.0% transformation frequency. All 23 transgenic events were regenerable, and 64% produced fertile plants. Strong GFP expression driven by the rice actin promoter was observed in a variety of tissues of the T(0) plants and their progeny in 13 out of 23 independent transgenic lines. Stable GFP expression was observed in T(2) progeny from five independent GFP-expressing lines tested, and homozygous plants from two lines were obtained. Transgene silencing was observed in T(0) plants and their progeny of some transgenic lines.     

Transgenic sugarcane plants via microprojectile bombardment

Transgenic sugarcane plants were produced by bombardment of embryogenic callus with high-velocity DNA-coated microprojectiles, followed by a selection and regeneration procedure designed for this target tissue. Optimal bombardment conditions for embryogenic callus required microprojectile velocities higher than those previously found effective for sugarcane suspension culture cells. Bombardment of target tissues twice increased the number of transiently expressing cells in regenerable callus regions, to more than 300 per treated plate. Stable transformants were obtained following bombardment with the neomycin phosphotransferase (npt-II) gene under the control of the Emu strong monocot promoter. Stepped increases in antibiotic concentration during selection and regeneration allowed recovery of actively growing callus and plants on media containing geneticin concentrations completely inhibitory to untransformed controls. NPT-II levels in transformed plants were 20–50 times the background levels in control plants in ELISA assays, and Southern analysis revealed integration of one to three copies of the introduced gene in the sugarcane genome. The procedures described yield one to three transgenic plants per treated plate within 16 weeks of bombardment and provide a simple, efficient and broadly applicable system for genetic transformation of sugarcane. A similar approach should be applicable to other members of the Poaceae able to form embryogenic callus.     

A protocol for consistent, large-scale production of fertile transgenic rice plants

A protocol for consistent production of fertile transgenic rice plants was established utilizing microparticle bombardment of embryogenic tissues (Oryza sativa L. japonica cv. Taipei 309). This system has been employed to produce several thousand independently transformed plant lines carrying the hygromycin phosphotransferase (hph) gene and various genes of interest. The most efficient target tissue was highly embryogenic callus or suspension cell aggregates, when they were given an osmotic pre- and post-transformation treatment of 0.6 m carbohydrate. By optimizing the age of the tissue at the time of gene transfer and applying an improved selection procedure, transgenic plants were recovered in 8 weeks from the time of gene transfer, at an average of 22.3±9.7 per 100 calli and 22.4±8.0 plant lines per dish of suspension cell aggregates. This system has facilitated a number of studies using rice as a model for genetic transformation and will enable the large-scale production of transgenic rice plants for genomic studies. Received: 12 March 1998 / Revision received: 5 May 1998 / Accepted: 15 May 1998     

Genetic transformation of maize cells by particle bombardment

Intact maize cells were bombarded with microprojectiles bearing plasmid DNA coding for selectable (neomycin phosphotransferase [NPT II]) and screenable (β-glucuronidase [GUS]) marker genes. Kanamycin-resistant calli were selected from bombarded cells, and these calli carried copies of the NPT II and GUS genes as determined by Southern blot analysis. All such calli expressed GUS although the level of expression varied greatly between transformed cell lines. These results show that intact cells of important monocot species can be stably transformed by microprojectiles.     

An improved system to establish highly embryogenic haploid cell and protoplast cultures from pollen calluses of maize (Zea mays L.)

Regenerable, embryogenic haploid cell suspensions were initiated and established from type II pollen calluses of two selected Chinese maize genotypes (No 592 Y and 592.A2 LY). The induction frequency of friable, embryogenic callus (type II) was highly dependent on three factors: genotype, medium, cold pretreatment, and on their interactions. Repeated callus and cell selection during the culture procedure led to stable haploid suspensions consisting of fine clusters each containing 20–50 cells. The selected cell lines were able to maintain their morphogenic ability during long-term subculture (2 years). Protoplasts were successfully isolated from subcultured, friable, embryogenic pollen calluses and cultured on N₆BM and N₆K media using a feeder layer, obtained from 2-day-old suspension culture. Healthy plants were regenerated from protoplast-derived calluses.     

Regeneration of transgenic cassava plants (Manihot esculenta Crantz) through Agrobacterium-mediated transformation of embryogenic suspension cultures

A protocol was developed for Agrobacterium-mediated transformation of embryogenic suspension cultures of cassava. The bacterial strain ABI containing the binary vector pMON977 with the nptII gene as selectable marker and an intron-interrupted uidA gene (encoding β-glucuronidase) as visible marker was used for the experiments. Selection of transformed tissue with paromomycin resulted in the establishment of antibiotic-resistant, β-glucuronidase-expressing lines of friable embryogenic callus, from which embryos and subsequently plants were regenerated. Southern blot analysis demonstrated stable integration of the uidA gene into the cassava genome in five lines of transformed embryogenic suspension cultures and in two plant lines.