Maud A. W. Hinchee

An Improved Green Fluorescent Protein Gene as a Vital Marker in Plants

A synthetic green fluorescent protein (GFP) gene (pgfp) was constructed to improve GFP expression in plants. Corn and tobacco protoplast transient assays showed that pgfp gave about 20-fold brighter fluorescence than the wild-type gene (gfp). Replacement of the serine at position 65 with a threonine (S65Tpgfp) or a cysteine (S65Cpgfp) yielded 100- to 120-fold brighter fluorescence than wild-type gfp upon excitation with 490-nm light. Incorporation of a plant intron into the coding region yielded an additional 1.4-fold improvement, for a cumulative improvement of about 150-fold in fluorescence at 490-nm excitation. Various versions of pgfp were also stably introduced into corn, wheat, tobacco, and Arabidopsis plants. Bright-green fluorescence was observed with a fluorescence microscope in virtually all examined tissues of transgenic monocots and dicots. In the case of Arabidopsis, expression of the pgfp gene under the enhanced 35S promoter of the cauliflower mosaic virus produced green fluorescence that was readily detectable by eye using a hand-held, long-wave ultraviolet lamp and/or a black-light source.

A simplified method for the detection of neomycin phosphotransferase II activity in transformed plant tissues

I n t r o d u c t i o n The development of plant cell transformation systems using the Ti plasmid of A wohactcrium tumefaciem as a vector has depended upon the expression of chimeric genes carrying dominant selectable markers to identify transformants. One of the widely utilized selectable markers is the bacterial Tn5 neomycin phosphotransferase II (NPT II) enzyme that confers resistance to the antibiotics kanamycin, neomycin, and G-418 (reviewed by Fraley et al., 1986). Initial assays of NPT II activity were performed with bacterial extracts to determine if R-f:actors conveying resistance to antibiotics were present.

Plant regeneration by organogenesis in Glycine max.

A procedure for the regeneration of fertile plants by organogenesis from tissue cultures of soybeans, Glycine max is described. Seeds were germinated on reduced inorganic salt MS medium containing 5μM BA. Cotyledonary nodes were excised and cultured on the same medium. Presence of BA in the medium during seed germination and culture of nodal explants was required for multiple shoot and shoot-bud formation. Histological analyses established the de novo nature of shoot regeneration. Separate reduction of the concentration of inorganic salts or substitution of sucrose for fructose during culture had minimal effects on the regeneration response. Conversely, if the BA was reduced, the inhibition response could not be overcome by increased salt concentration or altered carbon source.

Stable transformation via particle bombardment in two different soybean regeneration systems

The Biolistics® particle delivery system for the transformation of soybean (Glycine max L. Merr.) was evaluated in two different regeneration systems. The first system was multiple shoot proliferation from shoot tips obtained from immature zygotic embryos of the cultivar Williams 82, and the second was somatic embryogenesis from a long term proliferative suspension culture of the cultivar Fayette. Bombardment of shoot tips with tungsten particles, coated with precipitated DNA containing the gene for β-glucuronidase (GUS), produced GUS-positive sectors in 30% of the regenerated shoots. However, none of the regenerants which developed into plants continued to produce GUS positive tissue. Bombardment of embryogenic suspension cultures produced GUS positive globular somatic embryos which proliferated into GUS positive somatic embryos and plants. An average of 4 independent transgenic lines were generated per bombarded flask of an embryogenic suspension. Particle bombardment delivered particles into the first two cell layers of either shoot tips or somatic embryos. Histological analysis indicated that shoot organogenesis appeared to involve more than the first two superficial cell layers of a shoot tip, while somatic embryo proliferation occurred from the first cell layer of existing somatic embryos. The different transformation results obtained with these two systems appeared to be directly related to differences in the cell types which were responsible for regeneration and their accessibility to particle penetration.

Production of transgenic maize plants and progeny by bombardment of hi-II immature embryos

SummaryProduction of transgenic maize (Zea mays L.) callus, plants, and progeny from microprojectile bombardment of 2–5-d cultured Hi-II immature embryos is described. Histological evidence indicates that these tissues are amenable to transformation due to surface layer cell division of the scutellum. Two out of every 100 bombarded embryos produced transgenic callus and R0 transgenic plants were both male and female fertile. Expected segregation of transgenes was observed in progeny. The primary advantage of bombarding these tissues is increased male and female fertility of transgenic plants compared with those produced using long-term callus or suspension cultures.

Regeneration of soybean (Glycine max L. Merr.) from cultured primary leaf tissue

A reproducible method for regeneration of plants from primary leaf tissue of 27 varieties of soybean (Glycine max), encompassing maturity groups 00 to VIII, has been developed. Progeny from seeds recovered from regenerated plants appear normal. Best regeneration was from leaf explants (2.1–4.0 mm) obtained from 5 day old seedlings. While 2,4,5-trichlorophenoxyacetic acid (2,4,5-T) was demonstrated to be essential for regeneration, addition of benzyladenine (BA) was found to enhance regeneration. Of the 6 other auxins tested, only picloram induced any regenerative response. Using identical volumes of medium and other conditions, regeneration could be obtained in 95 × 25 mm glass culture tubes but not in 60 × 15 mm Petri dishes.The regeneration of soybeans from primary leaf tissue was shown to be greatly enhanced by pyroglutamic acid (5-oxoproline). Stimulatory effects were attained if pyroglutamic acid was added directly to the medium or if it was formed in situ as a result of chemical transformation of glutamine during autoclaving. The “active” component produced by autoclaving glutamine was not a conjugate of glutamine with inorganic salts or another organic component of the medium. Filter-sterilized glutamine was shown to be inhibitory to regeneration.Murashige and Skoog (MS) and Schenk and Hildebrandt (SH) basal media were compared to Gamborg B5 medium. All contained 0.1 mg/l 2,4,5-T, 40 mg/l adenine sulfate and 10 mM pyroglutamic acid. No regeneration occurred when MS medium was used. Growth and appearance of callus growing on SH and B5 media with the additives were similar. The incidence of regeneration among cultures growing on SH medium was only one third compared to cultures grown on B5 medium.

Transient expression of GUS and anthocyanin constructs in intact maize immature embryos following electroporation

Electroporation was used for the delivery and subsequent expression of GUS and anthocyanin reporter genes into intact maize immature embryos. The optimal conditions consisted of culturing immature embryos for 4 days on N6 1-100-25-Ag medium prior to electroporation (375 V/cm; 960 µF capacitance) in EPR buffer containing DNA and 0.07 M sodium glutamate at room temperature (22°C) after a 10 min heat shock at 37°C. Under these conditions, over 40 spots of GUS transient activity were observed per immature embryo. Transient gene expression after electroporation was further demonstrated using an anthocyanin construct, which is specific for expression in plant cells.

Agrobacterium-mediated transformation of Solanum tuberosum L. cv. 'Russet Burbank'.

Stem sections from shoot cultures maintained in vitro were used to produce transgenic plants of the potato, Solanum tuberosum L. cv. ‘Russet Burbank’. Stem internode pieces inoculated with Agrobacterium tumefaciens containing coat protein genes from potato virus X and potato virus Y, produced shoots with a frequency of 60% in the absence of selection and 10% on medium containing 100 mg/l kanamycin monosulfate. Regenerated shoots were assayed for kanamycin resistance by placing stem segments on callus induction medium containing an increased level of kanamycin. Of a total 255 regenerated shoots, 47 (18%) were kanamycin resistant. Of the kanamycin resistant shoots, 25 (53%) expressed the PVX or PVY coat protein genes as assayed by enzyme-linked immunosorbent assay or Western immunoblot analysis.

Cell and tissue specific expression localized byin situ RNA hybridization in floral tissues

The differentiation of the reproductive organs of plants involves the coordinated expression of many genes. A subset of these genes will have tissue or cell specific expression in different stages of development. The isolation and characterization of these genes is a first step in increasing our understanding of the mechanisms involved in plant differentiation and development. Flower development in Lycopersicon esculentum was selected as a model for these studies, because Lycopersicon esculentum produces abundant moderate sized flowers, is genetically well characterized, and can be transformed (McCormick et al., 1986). Floral c D N A libraries were produced from tomato pistils or anthers at various stages of development. Clones representing floral-specific genes were selected by a series of differential screenings (Charles S. Gasser et al., in preparation). Plaque lifts or Southern blots of cDNA inserts were hybridized with m R N A labeled as c D N A from either entire seedlings or m R N A labeled from the homologous floral tissues. Clones which hybridized to the homolo-

Control of Pollen-Mediated Gene Flow in Transgenic Trees

Pollen elimination provides an effective containment method to reduce direct gene flow from transgenic trees to their wild relatives. Until now, only limited success has been achieved in controlling pollen production in trees. A pine (Pinus radiata) male cone-specific promoter, PrMC2, was used to drive modified barnase coding sequences (barnaseH102E, barnaseK27A, and barnaseE73G) in order to determine their effectiveness in pollen ablation. The expression cassette PrMC2-barnaseH102E was found to efficiently ablate pollen in tobacco (Nicotiana tabacum), pine, and Eucalyptus (spp.). Large-scale and multiple-year field tests demonstrated that complete prevention of pollen production was achieved in greater than 95% of independently transformed lines of pine and Eucalyptus (spp.) that contained the PrMC2-barnaseH102E expression cassette. A complete pollen control phenotype was achieved in transgenic lines and expressed stably over multiple years, multiple test locations, and when the PrMC2-barnaseH102E cassette was flanked by different genes. The PrMC2-barnaseH102E transgenic pine and Eucalyptus (spp.) trees grew similarly to control trees in all observed attributes except the pollenless phenotype. The ability to achieve the complete control of pollen production in field-grown trees is likely the result of a unique combination of three factors: the male cone/anther specificity of the PrMC2 promoter, the reduced RNase activity of barnaseH102E, and unique features associated with a polyploid tapetum. The field performance of the PrMC2-barnaseH102E in representative angiosperm and gymnosperm trees indicates that this gene can be used to mitigate pollen-mediated gene flow associated with large-scale deployment of transgenic trees.