John J. Finer

Development of the particle inflow gun for DNA delivery to plant cells

SummaryA simple and inexpensive particle bombardment device was constructed for delivery of DNA to plant cells. The Particle Inflow Gun (PIG) is based on acceleration of DNA-coated tungsten particles using pressurized helium in combination with a partial vacuum. The particles are accelerated directly in a helium stream rather than being supported by a macrocarrier. Bombardment parameters were partially optimized using transient expression assays of a ß-glucuronidase gene in maize embryogenic suspension culture and cowpea leaf tissues. High levels of transient expression of the ß-glucuronidase gene were obtained following bombardment of embryogenic suspension cultures of corn and soybean, and leaf tissue of cowpea. Stable transformation of embryogenic tissue of soybean has also been obtained using this bombardment apparatus.

Osmotic treatment enhances particle bombardment-mediated transient and stable transformation of maize

SummaryThe effects of osmotic conditioning on both transient expression and stable transformation were evaluated by introducing plasmid DNAs via particle bombardment into embryogenic suspension culture cells of Zea mays (A188 × B73). Placement of cells on an osmoticum-containing medium (0.2 M sorbitol and 0.2 M mannitol) 4 h prior to and 16 h after bombardment resulted in a statistically significant 2.7-fold increase in transient ß-glucuronidase expression. Under these conditions, an average of approximately 9,000 blue foci were obtained from 100 μl packed cell volume of bombarded embryogenic tissue. Osmotic conditioning of the target cells resulted in a 6.8-fold increase in recovery of stably transformed maize clones. Transformed fertile plants and progeny were obtained from several transformed cell lines. We believe the basis of osmotic enhancement of transient expression and stable transformation resulted from plasmolysis of the cells which may have reduced cell damage by preventing extrusion of the protoplasm from bombarded cells.

Transformation of soybean via particle bombardment of embryogenic suspension culture tissue

SummaryEmbryogenic 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.

SAAT : Sonication-assisted Agrobacterium-mediated transformation

Plant transformation via Agrobacterium can be limited by both host specificity and the inability of Agrobacterium to reach the proper cells in the target tissue. Described here is a new and efficient Agrobacterium-based transformation technology that overcomes these barriers and enhances DNA transfer in such diverse plant groups as dicots, monocots, and gymnosperms. This new technology, called sonication-assisted Agrobacterium-mediated transformation (SAAT), involves subjecting the plant tissue to brief periods of ultrasound in the presence of Agrobacterium. Scanning electron and light microscopy reveal that SAAT treatment produces small and uniform fissures and channels throughout the tissue allowing the Agrobacterium easy access to internal plant tissues. Unlike other transformation methods, this system has the potential to transform meristematic tissue buried under several cell layers. SAAT increases transient transformation efficiency in several different plant tissues including leaf tissue, immature cotyledons, somatic and zygotic embryos, roots, stems, shoot apices, embryogenic suspension cells and whole seedlings. A 100- to 1400-fold increase in transient β- glucuronid ase expression has been demonstrated in various tissues of soybean, Ohio buckeye, cowpea, white spruce, wheat and maize. Stable transformation of both soybean and Ohio buckeye has been obtained using SAAT of embryogenic suspension culture tissues. For soybean, SAAT treatment was necessary to obtain stable transformation with this tissue

WRKY transcription factors: key components in abscisic acid signalling

WRKY transcription factors (TFs) are key regulators of many plant processes, including the responses to biotic and abiotic stresses, senescence, seed dormancy and seed germination. For over 15 years, limited evidence has been available suggesting that WRKY TFs may play roles in regulating plant responses to the phytohormone abscisic acid (ABA), notably some WRKY TFs are ABA-inducible repressors of seed germination. However, the roles of WRKY TFs in other aspects of ABA signalling, and the mechanisms involved, have remained unclear. Recent significant progress in ABA research has now placed specific WRKY TFs firmly in ABA-responsive signalling pathways, where they act at multiple levels. In Arabidopsis, WRKY TFs appear to act downstream of at least two ABA receptors: the cytoplasmic PYR/PYL/RCAR-protein phosphatase 2C-ABA complex and the chloroplast envelope-located ABAR-ABA complex. In vivo and in vitro promoter-binding studies show that the target genes for WRKY TFs that are involved in ABA signalling include well-known ABA-responsive genes such as ABF2, ABF4, ABI4, ABI5, MYB2, DREB1a, DREB2a and RAB18. Additional well-characterized stress-inducible genes such as RD29A and COR47 are also found in signalling pathways downstream of WRKY TFs. These new insights also reveal that some WRKY TFs are positive regulators of ABA-mediated stomatal closure and hence drought responses. Conversely, many WRKY TFs are negative regulators of seed germination, and controlling seed germination appears a common function of a subset of WRKY TFs in flowering plants. Taken together, these new data demonstrate that WRKY TFs are key nodes in ABA-responsive signalling networks.

Transformation of cotton (Gossypium hirsutum L.) via particle bombardment

Embryogenic suspension cultures of cotton (Gossypium hirsutum L.) were subjected to particle bombardment, where high density particles carrying plasmid DNA were accelerated towards the embryogenic plant cells. The plasmid DNA coating the particles encoded hygromycin resistance. One to two weeks following bombardment, embryogenic cotton cells were placed in proliferation medium containing 100 μg/ml hygromycin. Clumps of tissue which grew in the presence of hygromycin were subcultured at low density into fresh hygromycin-containing proliferation medium. Following sequential transfer of embryogenic tissue to development and then germination media, plants were recovered from transgenic embryogenic tissue. Southern hybridization confirmed the presence of the hygromycin resistance gene in embryogenic suspension culture tissue and regenerated plants.

Transformation of 12 different plasmids into soybean via particle bombardment

Particle bombardment offers a simple method for the introduction of DNA into plant cells. Multiple DNA fragments may be introduced on a single plasmid or on separate plasmids (co-transformation). To investigate some of the properties and limits of co-transformation, 12 different plasmids were introduced into embryogenic suspension culture tissue of soybean [Glycine max (L.) Merrill] via particle bombardment. The DNAs used for co-transformation included 10 plasmids containing KFLP markers for maize and 2 plasmids separately encoding hygromycin-resistance and ß-glucuronidase. Two weeks following bombardment with the 12 different plasmids, suspension culture tissue was placed under hygromycin selection. Hygromycin-resistant clones were isolated after an additional 5 to 6 weeks. Southern hybridization analysis of 26 hygromycin-resistant embryogenic clones verified the presence of introduced plasmid DNAs. All of the co-transforming plasmids were present in most of the transgenic soybean clones and there was no preferential uptake and integration of any of the plasmids. The copy number of individual plasmids was approximately equal within clones but highly variable between clones. While some clones contained as few as zero to three copies of each plasmid, others clones contained as many as 10 to 15 copies of each of the 12 different plasmids.

Sonication-assisted Agrobacterium-mediated transformation of soybean [Glycine max (L.) Merrill] embryogenic suspension culture tissue

Abstract Successful transformation of plant tissue using Agrobacterium relies on several factors including bacterial infection, host recognition, and transformation competency of the target tissue. Although soybean [Glycine max (L.) Merrill] embryogenic suspension cultures have been transformed via particle bombardment, Agrobacterium-mediated transformation of this tissue has not been demonstrated. We report here transformation of embryogenic suspension cultures of soybean using “Sonication-Assisted Agrobacterium-mediated Transformation” (SAAT). For SAAT of suspension culture tissue, 10–20 embryogenic clumps (2–4 mm in diameter) were inoculated with 1 ml of diluted (OD600nm 0.1–0.5) log phase Agrobacterium and sonicated for 0–300 s. After 2 days of co-culture in a maintenance medium containing 100 µM acetosyringone, the medium was removed and replaced with fresh maintenance medium containing 400 mg/l Timentin®. Two weeks after SAAT, the tissue was placed in maintenance medium containing 20 mg/l hygromycin and 400 mg/l Timentin®, and the medium was replenished every week thereafter. Transgenic clones were observed and isolated 6–8 weeks following SAAT. When SAAT was not used, hygromycin-resistant clones were not obtained. Southern hybridization analyses of transformed embryogenic tissue confirmed T-DNA integration.

Sonication-assisted Agrobacterium-mediated transformation of soybean immature cotyledons: optimization of transient expression

Abstract Sonication-assisted Agrobacterium-mediated transformation (SAAT) tremendously improves the efficiency of Agrobacterium infection by introducing large numbers of microwounds into the target plant tissue. Using immature cotyledons of soybean as explants, we evaluated the effects of the following parameters on transient β-glucuronidase (GUS) activity: cultivars, binary vectors, optical density of Agrobacterium during infection, duration of sonication treatment, co-culture conditions, length of explant preculture and addition of acetosyringone during co-culture. The extent of tissue disruption caused by sonication was also determined. The highest GUS expression was obtained when immature cotyledons were sonicated for 2 s in the presence of Agrobacterium (0.11 OD600nm) followed by co-cultivation with the abaxial side of the explant in contact with the culture medium for 3 days at 27°C. The addition of acetosyringone to the co-culture medium enhanced transient expression. No differences were observed when different cultivars or binary vectors were used. Cotyledons sonicated for 2 s had moderate tissue disruption, while the longer treatments resulted in more extensive damage.

Apical proliferation of embryogenic tissue of soybean [Glycine max (L.) Merrill].

Somatic embryos and embryogenic tissues were initiated from immature zygotic embryos of soybean [Glycine max (L.) Merrill cv. ‘Fayette’]. Zygotic embryos were placed on a medium containing 40 mg/l of 2,4-dichlorophenoxyacetic acid and 6% sucrose. Somatic embryos were first seen 4 weeks after cultures were initiated. Following transfer, secondary somatic embryos proliferated directly from the apical or terminal portions of the older primary somatic embryos. Single somatic embryos or clusters of embryos were seen growing directly from the top of older somatic embryos. Light microscopy revealed that these embryos were of surface or subsurface origin. The apical soybean somatic embryo tissue may represent cotyledonary tissue (which has been shown to be most responsive) at a very young and manipulatable state.