Publications - Cell and Metabolic Biology

In oilseed rape (Brassica napus), the glucosyltransferase UGT84A9 catalyzes the formation of 1-O-sinapoyl-β-glucose, which feeds as acyl donor into a broad range of accumulating sinapate esters, including the major antinutritive seed component sinapoylcholine (sinapine). Since down-regulation of UGT84A9 was highly efficient in decreasing the sinapate ester content, the genes encoding this enzyme were considered as potential targets for molecular breeding of low sinapine oilseed rape. B. napus harbors two distinguishable sequence types of the UGT84A9 gene designated as UGT84A9-1 and UGT84A9-2. UGT84A9-1 is the predominantly expressed variant, which is significantly up-regulated during the seed filling phase, when sinapate ester biosynthesis exhibits strongest activity. In the allotetraploid genome of B. napus, UGT84A9-1 is represented by two loci, one derived from the Brassica C-genome (UGT84A9a) and one from the Brassica A-genome (UGT84A9b). Likewise, for UGT84A9-2 two loci were identified in B. napus originating from both diploid ancestor genomes (UGT84A9c, Brassica C-genome; UGT84A9d, Brassica A-genome). The distinct UGT84A9 loci were genetically mapped to linkage groups N15 (UGT84A9a), N05 (UGT84A9b), N11 (UGT84A9c) and N01 (UGT84A9d). All four UGT84A9 genomic loci from B. napus display a remarkably low micro-collinearity with the homologous genomic region of Arabidopsis thaliana chromosome III, but exhibit a high density of transposon-derived sequence elements. Expression patterns indicate that the orthologous genes UGT84A9a and UGT84A9b should be considered for mutagenesis inactivation to introduce the low sinapine trait into oilseed rape.

Resveratrol is a phytoalexin produced in various plants like wine, peanut or pine in response to fungal infection or UV irradiation, but it is absent in members of the Brassicaceae. Moreover, resveratrol and its glucoside (piceid) are considered to have beneficial effects on human health, known to reduce heart disease, arteriosclerosis and cancer mortality. Therefore, the introduction of the gene encoding stilbene synthase for resveratrol production in rapeseed is a tempting approach to improve the quality of rapeseed products. The stilbene synthase gene isolated from grapevine (Vitis vinifera L.) was cloned under control of the seed-specific napin promotor and introduced into rapeseed (Brassica napus L.) by Agrobacterium-mediated co-transformation together with a ds-RNA-interference construct deduced from the sequence of the key enzyme for sinapate ester biosynthesis, UDP-glucose:sinapate glucosyltransferase (BnSGT1), assuming that the suppression of the sinapate ester biosynthesis may increase the resveratrol production in seeds through the increased availability of the precursor 4-coumarate. Resveratrol glucoside (piceid) was produced at levels up to 361 μg/g in the seeds of the primary transformants. This value exceeded by far piceid amounts reported from B. napus expressing VST1 in the wild type sinapine background. There was no significant difference in other important agronomic traits, like oil, protein, fatty acid and glucosinolate content in comparison to the control plants. In the third seed generation, up to 616 μg/g piceid was found in the seeds of a homozygous T3-plant with a single transgene copy integrated. The sinapate ester content in this homozygous T3-plant was reduced from 7.43 to 2.40 mg/g. These results demonstrate how the creation of a novel metabolic sink could divert the synthesis towards the production of piceid rather than sinapate ester, thereby increasing the value of oilseed products.

Mycorrhizas are the most important mutualistic symbioses on earth. The most prevalent type are the arbuscular mycorrhizas (AMs) that develop between roots of most terrestrial plants and fungal species of the Zygomycota. The AM fungi are able to grow into the root cortex forming intercellular hyphae from which highly branched structures, arbuscules, originate within cortex cells. The arbuscules are responsible for nutrient exchange between the host and the symbiont, transporting carbohydrates from the plant to the fungus and mineral nutrients, especially phosphate, and water from the fungus to the plant. Plants adapt their phosphate uptake to the interaction with the AM fungus by synthesis of specific phosphate transporters. Colonization of root cells induces dramatic changes in the cytoplasmic organization: vacuole fragmentation, transformation of the plasma membrane to a periarbuscular membrane covering the arbuscule, increase of the cytoplasm volume and numbers of cell organelles, as well as movement of the nucleus into a central position. The plastids form a dense network covering the symbiotic interface. In some of these changes, microtubules are most likely involved. With regard to the molecular crosstalk between the two organisms, a number of phytohormones (cytokinins, abscisic acid, jasmonate) as well as various secondary metabolites have been examined: (i) Jasmonates occur at elevated level, which is accompanied by cell-specific expression of genes involved in jasmonate biosynthesis that might be linked to strong carbohydrate sink function of AM roots and induced defense reactions; (ii) apocarotenoids (derivatives of mycorradicin and glycosylated cyclohexenones) accumulate in most mycorrhizal roots examined so far. Their biosynthesis via the nonmevalonate methylerythritol phosphate (MEP) pathway has been studied resulting in new insights into AM-specific gene expression and biosynthesis of secondary isoprenoids.