Kimberly A. Torbert

Use of paromomycin as a selective agent for oat transformation

SummaryFriable, embryogenic oat (Avena sativa L.) tissue cultures were stably transformed with two different plasmids containing the E. coli tn5 neomycin phosphotransferase II gene (npt II). Selection was accomplished using the antibiotic paromomycin sulfate following microprojectile bombardment. From two independent experiments, 88 paromomycin-resistant tissue cultures were shown to be transgenic based on Southern blot analysis and detection of the neomycin phosphotransferase (NPT II) protein using ELISA. Copy numbers of the npt II gene ranged from one to eight copies per haploid oat genome integrated into high molecular weight DNA of the paromomycin-resistant cultures. Plants were regenerated from 32 of the 88 transgenic tissue cultures. Plants from 17 of the 32 regenerable cultures exhibited fertility. Stable transformation was shown by segregation patterns of the NPT II protein in R1 seedlings produced from 16 fertile culture lines that were tested. The overall results demonstrate that the combination of the npt II gene and paromomycin provides efficient selection of transgenic oat tissue cultures. Oat plants transformed with the npt II gene present reduced ecological risk compared to the previously used herbicide-resistance selection system.

Irregular patterns of transgene silencing in allohexaploid oat.

An irregular pattern of transgene silencing was revealed in expression and inheritance studies conducted over multiple generations following transgene introduction by microprojectile bombardment of allohexaploid cultivated oat (Avena sativa L.). Expression of two transgenes, bar and uidA, delivered on the same plasmid was investigated in 23 transgenic oat lines. Twenty-one transgenic lines, each derived from an independently selected transformed tissue culture, showed expression of both bar and uidA while two lines expressed only bar. The relationship of the transgenic phenotypes to the presence of the transgenes in the study was determined using (1) phenotypic scoring combined with Southern blot analyses of progeny, (2) coexpression of the two transgenic phenotypes since the two transgenes always cosegregated, and (3) reactivation of a transgenic phenotype in self-pollinated progenies of transgenic plants that did not exhibit a transgenic phenotype. Transgene silencing was observed in 19 of the 23 transgenic lines and resulted in distorted segregation of transgenic phenotypes in 10 lines. Silencing and inheritance distortions were irregular and unpredictable. They were often reversible in a subsequent generation of self-pollinated progeny and abnormally segregating progenies were as likely to trace back to parents that exhibited normal segregation in a previous generation as to parents showing segregation distortions. Possible causes of the irregular patterns of transgene silencing are discussed.

Coat protein-mediated resistance to isolates of barley yellow dwarf in oats and barley

Tissue cultures of GAF30/Park oats were biolistically co-transformed with constructs containing the coat protein (CP) genes of the P-PAV, MAV-PS1 or NY-RPV isolates of barley yellow dwarf virus (BYDV), together with a construct containing the bar gene for herbicide resistance and the uidA reporter gene. Transformed, herbicide-resistant tissue cultures were screened by PCR for the presence of the CP genes. Fertile regenerated plants were recovered from some CP-transformed tissue cultures. T1 progeny of these plants were screened for resistance to the BYDV isolate corresponding to the introduced gene by inoculation with viruliferous aphids followed by ELISA tests. Variation in ELISA values for GAF30/Park control plants made interpretation of the data difficult, but oat plants resistant to each of the three isolates of BYDV (ELISA values less than 0.3; virus titers equivalent to less than 25% of infected controls) were identified in T1 generations. Further testing of MAV-PS1 CP-transformed lines to the T2 generation, NY-RPV CP-transformed lines to the T3 generation and P-PAV CP-transformed lines to the T4 generation identified further resistant plants. Similarly, immature embryos and calli of the barley cultivar Golden Promise were biolistically bombarded with constructs containing the CP gene of the P-PAV isolate of BYDV and the bar and uidA reporter genes, lines of self-fertile P-PAV CP-transformed barley plants were developed, and T1plants were screened for resistance to P-PAV. Eight plants from six lines showed moderate to high levels of resistance to P-PAV that correlated with the presence of the CP gene. Plants giving low ELISA values were also found in other lines, even though the CP gene was not detected in these plants. Some T2 plants derived from resistant parents that contained the CP gene were themselves highly resistant.

The sugarcane bacilliform badnavirus promoter is active in both monocots and dicots

Regions of the sugarcane bacilliform badnavirus genome were tested for promoter activity. The genomic region spanning nucleotides 5999–7420 was shown to possess promoter activity as exemplified by its ability to drive the expression of the coding region of the uidA gene of Escherichia coli, in both Avena sativa and Arabidopsis thaliana. In A. sativa, the promoter was active in all organs examined and, with the exception of the anthers where the expression was localized, this activity was constitutive. In A. thaliana, the promoter activity was constitutive in the rosette leaf, stem, stamen, and root and limited primarily to vascular tissue in the sepal and the silique. The transgene was inherited and active in progeny plants of both A. sativa and A. thaliana.

Expression of the Commelina yellow mottle virus promoter in transgenic oat

Abstract The Commelina yellow mottle virus (CoYMV) infects the monocot weed Commelina diffusa. The objective of this study was to investigate the transgene expression conferred by the CoYMV promoter in a monocot species. Friable, embryogenic oat (Avena sativa L.) tissue cultures were stably transformed with the CoYMV promoter fused to the coding region of E. coli β-glucuronidase (uidA, GUS). Developmental and tissue-specific expression of the CoYMV-GUS construct was investigated in regenerated plants and their progeny. Histochemical GUS staining was primarily localized in the vascular tissues of shoots, leaves, floral bracts and in roots. While ovaries stained intensely, no staining was detected in anthers or the endosperm in mature seed. The scutellum of mature and germinating seed exhibited GUS activity.

Genetic Engineering of Oat

Fertile, transgenic oat (Avena sauva L.) plants were regenerated from approximately 35% of phosphinothricin (PPT)-resistant callus cultures selected following microprojectile bombardment to deliver the plasmid pBARGUS. The plasmid pBARGUS contains the bar gene, which confers plant cell resistance to PPT and related herbicides, and the uidA gene for β-glucuronidase (GUS) under the control of the maize alcohol dehydrogenase I promoter. This promoter conferred high levels of GUS activity in the endosperm of mature oat kernels, thus enabling ready determination of transmission genetics of the GUS transgene. Segregation ratios of GUS activity in mature R1 seed and, in some cases, the R2 and R3 generations were determined in 15 transgenic families. Seven families fit a 3: 1 GUS+:GUS- segregation ratio whereas two families segregated 15: 1 for GUS activity. The remaining six families exhibited aberrant segregation ratios. These initial studies used friable, embryogenic callus initiated from immature embryos of a specific genotype selected for high frequency callus initiation. Although this system was useful in establishing and characterizing oat transformation, its limitation to a specific genotype and the undesirability of herbicide tolerance in oat dictated further development of transformation systems for use in oat improvement. Transformation of current oat cultivars and the use of an antibiotic-based selection system to obviate the herbicide resistance marker are described.

Tissue specificity of the sugarcane bacilliform virus promoter in oat, barley and wheat

The tissue-specificity of the sugarcane bacilliform virus (SCBV) promoter was investigated in oat, barley, and wheat to determine whether its expression pattern in one species was predictive of promoter specificity in the other closely related Gramineae species. Progeny of transgenic plants produced using constructs containing the SCBV promoter driving gusA were sampled at different stages of plant development and stained for GUS activity using a histochemical assay. Overall, the GUS staining patterns were most similar between oat and barley. In all three species, similar GUS staining patterns were observed in mature endosperms, leaves, and floral bracts of developing infloresences. No GUS staining was detected in oat embryos whereas the entire barley embryo was stained, and GUS staining was confined to the scutellum of wheat embryos. Oat and barley stems exhibited GUS staining whereas no GUS staining was observed in stems of the transgenic wheat plants. The SCBV promoter conferred strong GUS staining intensity in most tissues of oat and barley but was generally weaker in wheat. These differences in SCBV promoter specificity indicate that promoter evaluation should be conducted in the target species of interest rather than by extrapolation from expression patterns in other species.

Genetic Transformation in Avena sativa L. (Oat)

Genetic transformation of cultivated hexaploid oat (Avena sativa L.) was first reported in 1992 (Somers et al. 1992). Since that time, the oat transformation system has been significantly improved. Current applications of transformation to oat improvement are focused on investigating mechanisms of resistance to barley yellow dwarf virus and fungal pathogens. This chapter reviews the key factors leading to the development of a routine transformation system for oat. The current status of oat transformation will be presented with consideration of selection systems and transgene inheritance in regard to eventual practical applications of transformation to oat improvement.