We have analyzed the temporal and spatial expression of genes encoding the glycoxylate cycle enzymes isocitrate lyase and malate synthase in Brassica napus L. to determine whether they are coordinately expressed. Both enzymes participate in reactions associated with lipid mobilization in oilseed plant seedlings and are sequestered in a specialized organelle, the glyoxysome. We have identified an isocitrate lyase cDNA clone containing the complete protein coding region. RNA blot and in situ hybridization studies with isocitrate lyase and malate synthase cDNA clones from B. napus showed that the genes exhibit similar expression patterns. The mRNAs begin to accumulate during late embryogeny, reach maximal levels in seedling cotyledons, are not detected at significant amounts in leaves, and are distributed similarly in cotyledons and axes of seedlings. Furthermore, transcription studies with isolated nuclei indicate that the genes are controlled primarily although not exclusively at the transcriptional level. We conclude that glyoxysome biogenesis is regulated in part through the coordinate expression of isocitrate lyase and malate synthase genes.
We have analyzed the nucleotide sequence and accumulation of an mRNA which is prevalent in seeds of Brassica napus L. During normal development, the mRNA begins to accumulate during late embryogeny, is stored in dry seeds, and becomes undetectable in seedlings within 24 hours after imbibition. Moreover, abscisic acid treatment of embryos precociously induces or enhances accumulation of the mRNA. Nucleotide sequencing studies show that the deduced 30 kDa polypeptide has an unusual primary structure; the polypeptide possesses direct amino acid sequence repeats and is virtually entirely hydrophilic with the exception of a hydrophobic carboxyl-terminal region. Based upon the expression pattern and predicted polypeptide sequence, we conclude that the mRNA is encoded by a late embryogenesis-abundant (Lea) gene in B. napus.
We used in vitro growth inhibition assays to demonstrate that synthetic cecropin protein has potent activity against a range of plant pathogenic bacteria. We then prepared transgenic tobacco plants which express cecropin mRNA and protein. We have used Pseudomonas syringae pv tabaci infection of these transgenic tobacco as a model system to evaluate whether the plants which express cecropin protein also have increased tolerance to infection. We found no dramatic difference in disease response between plants which are expressing cecropin protein and control plants which were derived from the transformation with a binary vector which did not carry the gene encoding cecropin protein.
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