Long-term T-DNA insert stability and transgene expression consistency in field propagated sugarcane.

KEY MESSAGE: This study addresses T-DNA insert stability and transgene expression consistency in multiple cycles of field propagated sugarcane. T-DNA inserts are stable; no transgene rearrangements were observed. AmCYAN1 and PMI protein accumulation levels were maintained. There was no evidence that production of either protein declined across generations and no transgene silencing was observed in three commercial sugarcane varieties through commercially relevant ratooning, propagation-by-setts, and micro-propagation generation processes over 4 years of field testing. Long term transgene expression consistency and T-DNA insert stability can be achieved in sugarcane, suggesting that it is highly probable that transgenic sugarcane can be successfully commercialized. This study addresses T-DNA insert stability and transgene expression consistency in multiple cycles of field propagated sugarcane. These data are critical supporting information needed for successful commercialization of GM sugarcane. Here seventeen transgenic events, containing the AmCYAN1 gene driven by a CMP promoter and the E. coli PMI gene driven by either a CMP or Ubi promoter, were used to monitor T-DNA insert stability and consistency of transgene encoded protein accumulation through commercially relevant ratooning, propagation-by-setts, and micro-propagation generation processes. The experiments were conducted in three commercial sugarcane varieties over 4 years of field testing. DNA gel blot analysis showed that the T-DNA inserts are stable; no transgene rearrangements were observed. Quantitative ELISA showed no evidence of decreasing AmCYAN1 and PMI protein levels across generations and no transgene silencing was observed. These results indicate that long term transgene expression consistency and T-DNA insert stability can be achieved in sugarcane, suggesting that it is highly probable that transgenic sugarcane can be successfully commercialized.

Eggplant (Solanum melongena L.).

Eggplant is an economically important vegetable crop in Asia and Africa, and although it is grown in Europe and the United States, it does not account for a significant percentage of agricultural production. It is susceptible to a number of pathogens and insects, with bacterial and fungal wilts being the most devastating. Attempts to improve resistance through introgression of traits from wild relatives have had limited success owing to sexual incompatibilities. Therefore, a crop improvement approach that combines both conventional breeding and biotechnological techniques would be beneficial. This chapter describes an Agrobacterium-mediated transformation protocol for eggplant based on inoculation of seedling explants (cotyledons and hypocotyls) and leaves. We have used this protocol to recover transformants from two different types of eggplant, a Solanum melongena L. breeding line, and S. melongena L. var. Black Eggplant. The selectable marker gene used was neomycin phosphotransferase II (nptII) and the selection agent was kanamycin. In vitro grown transformants acclimated readily to greenhouse conditions.