). † These authors contributed equally to the work. SummaryThe properties and expression patterns of the six isoforms of sucrose synthase in Arabidopsis are described, and their functions are explored through analysis of T-DNA insertion mutants. The isoforms have generally similar kinetic properties. Although there is variation in sensitivity to substrate inhibition by fructose this is unlikely to be of major physiological significance. No two isoforms have the same spatial and temporal expression patterns. Some are highly expressed in specific locations, whereas others are more generally expressed. More than one isoform is expressed in all organs examined. Mutant plants lacking individual isoforms have no obvious growth phenotypes, and are not significantly different from wild-type plants in starch, sugar and cellulose content, seed weight or seed composition under the growth conditions employed. Double mutants lacking the pairs of similar isoforms sus2 and sus3, and sus5 and sus6, are also not significantly different in these respects from wild-type plants. These results are surprising in the light of the marked phenotypes observed when individual isoforms are eliminated in crop plants including pea, maize, potato and cotton. A sus1/sus4 double mutant grows normally in well-aerated conditions, but shows marked growth retardation and accumulation of sugars when roots are subjected to hypoxia. The sucrose synthase activity in roots of this mutant is 3% or less of wild-type activity. Thus under well-aerated conditions sucrose mobilization in the root can proceed almost entirely via invertases without obvious detriment to the plant, but under hypoxia there is a specific requirement for sucrose synthase activity.
Brachypodium distachyon is a novel model system for structural and functional genomics studies of temperate grasses because of its biological and genetic attributes. Recently, the genome sequence of the community standard line Bd21 has been released and the availability of an efficient transformation system is critical for the discovery and validation of the function of Brachypodium genes. Here, we provide an improved procedure for the facile and efficient Agrobacterium-mediated transformation of line Bd21. The protocol relies on the transformation of compact embryogenic calli derived from immature embryos using visual and chemical screening of transformed tissues and plants. The combination of green fluorescent protein expression and hygromycin resistance enables early identification of transformation events and drastically reduces the quantity of tissue to be handled throughout the selection process. Approximately eight independent fully developed transgenic Bd21 plants can be produced from each immature embryo, enabling the generation of thousands of T-DNA lines. The process--from wild-type seeds to transgenic T(1) seeds--takes approximately 8 months to complete.
SummaryBrachypodium distachyon is a promising model system for the structural and functional genomics of temperate grasses because of its physical, genetic and genome attributes.The sequencing of the inbred line Bd21 (www.brachypodium.org) started in 2007.However, a transformation method remains to be developed for the community standard line Bd21. In this article, a facile, efficient and rapid transformation system for Bd21 is described using Agrobacterium -mediated transformation of compact embryogenic calli
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