Development of a non-lethal selection system by using the aadA marker gene for efficient recovery of transgenic rice (Oryza sativa L.).

The application of aminoglycoside-3"-adenyltransferase ( aadA) gene-mediated streptomycin resistance for non-lethal selection of transgenic rice resulted in plant regeneration frequencies under selection pressure as high as those in non-transformed controls without selection. Since streptomycin does not kill non-transgenic cells, and allows plant regeneration from them, a selection procedure was developed that made the visual identification of transgenic calli and regenerants possible. For callus-level selection, a vital pH indicator-Chlorophenol Red-was applied together with streptomycin, making use of the phenomenon that fast-growing cell lines lower the pH in the culture medium. Transgenic plants were selected according to their main distinctive features; their green colour (photomixotrophic assimilation), and more intense growth. At the same time, non-transgenic regenerants were bleached (heterotrophic assimilation), and growth was retarded in the presence of streptomycin and sucrose. The final efficiency of genetic transformation based on streptomycin resistance was found to be double that of transformations where the selective agent was l-phosphinothricin, and nearly three times more compared to transformations resulting in hygromycin-resistant regenerants. To the best of our knowledge, this is the first report on producing nuclear transformed rice plants by using a non-lethal selection strategy based on the chimaeric aadA gene.

Production of phosphinothricin-tolerant rice (Oryza sativa L.) through the application of phosphinothricin as growth regulator.

A novel procedure has been developed to produce rice (Oryza sativa L.) tolerant to the herbicide phosphinothricin (PPT) by means of in vitro selection. First, sublethal and lethal concentrations of PPT on 7-day-old seedlings were determined and morphogenetic events in response to the PPT treatment evaluated. Differentiation of 6-30 microshoots on 5-40% of the treated plant material was observed on a hormone-free culture medium supplemented with a sublethal concentration of PPT. We proved that PPT is morphogenetically active, similar to the action of many other herbicides, showing cytokinin-like effects in rice tissue culture. Fertile plants were grown from those microshoots having PPT tolerance under greenhouse conditions. To the best of our knowledge, this is the first report on the production of rice plants tolerant to this herbicide without genetic transformation. Since PPT is a competitive inhibitor of glutamine synthetase (GS), total GS activity in PPT-tolerant and PPT-sensitive plants was examined comprehensively in order to decide whether this enzyme has any role in PPT tolerance. An elevated GS activity was detected in PPT-tolerant plant material which could result in an elevated PPT tolerance at unchanged concentrations of the herbicide.

Construction of expression vectors based on the rice actin 1 (Act1) 5' region for use in monocot transformation.

It has been previously reported that the 5' region of the rice actin 1 gene (Act1) promoted high-level expression of a beta-glucuronidase reporter gene (Gus) in transformed rice cells. In this paper we describe the construction of Act1-based expression vectors for use in monocot transformation. As part of the development of these vectors, we have evaluated the influence of the Act1 first intron, the Act1-Gus junction-encoded N-terminal amino acids, and the sequence context surrounding the Act1 and Gus translation initiation site on Act1-Gus gene expression in rice and maize cells. We have found that addition of Act1 intron 1 to the transcription unit of a Gus reporter gene under control of the cauliflower mosaic virus (CaMV) 35S promoter stimulated GUS activity more than 10-fold in transformed rice cells. Optimization of the sequence context around the Gus translation initiation site resulted in a 4-fold stimulation of Gus expression in transformed rice cells. By utilizing both the Act1 intron 1 and optimized Gus translation initiation site, a 40-fold stimulation in Gus expression from the CaMV 35S promoter has been achieved in transformed rice cells; very similar results were obtained in transformed maize cells. Taken together these results suggest that the Act1-based expression vectors described here should promote the expression of foreign genes in most, if not all, transformed monocot cells to levels that have not previously been attainable with alternative expression vectors.