Transgenic Agrostis mongolica Roshev. with enhanced tolerance to drought and heat stresses obtained from Agrobacterium-mediated transformation

Efficient procedures for regeneration and Agrobacterium-mediated transformation were established for Agrostis mongolica Roshev. and generated transgenic plants tolerant to drought and heat stresses using a regulatory gene from Arabidopsis, ABF3, which controls the ABA-dependent adaptive responses. The identification and selection of regenerable and reproducible callus type was a key factor for successful transformation. The transformation efficiency was 49.2% and gfp expression was detected in hygromycin-resistant calli and stem of putative transgenic plants. The result of Southern blot analysis showed that the ABF3 transgene was stably integrated into the genome of transgenic plants. Of the five transgenic lines analyzed, single transgene integration was observed in two lines and two copy integration was observed in three transgenic lines. Northern blot analysis confirmed that ubi::ABF3 was expressed in all transgenic lines. Transgenic plants exhibited neither growth inhibition nor visible vegetative phenotypic alternations. However, both transgenic and wild-type plants were highly sterile and did not flower during 3 years of growth period in the open field under subtropical Jeju Island climate. The stomata of the transgenic plants opened less than did stomata of the wild-type plants, and water content of the transgenic leaves remained about 3–4 fold higher than observed for wild-type leaves under drought stress. The transgenic plants showed about 2 fold higher survival rates under drought stress and about 3 fold higher survival rates under heat stress when compared to wild-type plants. Thus, overexpression of the Arabidopsis ABF3 gene results in enhancement of both drought and heat stress tolerance in Agrostis mongolica Roshev.     

Enhancement of tolerance to soft rot disease in the transgenic Chinese cabbage (<Emphasis Type="Italic">Brassica rapa</Emphasis> L. ssp. <Emphasis Type="Italic">pekinensis</Emphasis>) inbred line,Kenshin

We developed a transgenic Chinese cabbage (Brassica rapa L. ssp. pekinensis) inbred line, Kenshin, with high tolerance to soft rot disease. Tolerance was conferred by expression of N-acyl-homoserine lactonase (AHL-lactonase) in Chinese cabbage through an efficient Agrobacterium-mediated transformation method. To synthesize and express the AHL-lactonase in Chinese cabbage, the plant was transformed with the aii gene (AHL-lactonase gene from Bacillus sp. GH02) fused to the PinII signal peptide (protease inhibitor II from potato). Five transgenic lines were selected by growth on hygromycin-containing medium (3.7% transformation efficiency). Southern blot analysis showed that the transgene was stably integrated into the genome. Among these five transgenic lines, single copy number integrations were observed in four lines and a double copy number integration was observed in one transgenic line. Northern blot analysis confirmed that pinIISP-aii fusion gene was expressed in all the transgenic lines. Soft rot disease tolerance was evaluated at tissue and seedling stage. Transgenic plants showed a significantly enhanced tolerance (2–3-fold) to soft rot disease compared to wild-type plants. Thus, expression of the fusion gene pinIISP-aii reduces susceptibility to soft rot disease in Chinese cabbage. We conclude that the recombinant AHL-lactonase, encoded by aii, can effectively quench bacterial quorum-sensing and prevent bacterial population density-dependent infections. To the best of our knowledge, the present study is the first to demonstrate the transformation of Chinese cabbage inbred line Kenshin, and the first to describe the effect of the fusion gene pinIISP-aii on enhancement of soft rot disease tolerance.