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Molecular Signal Processing
Bioorganic Chemistry
Biochemistry of Plant Interactions
Cell and Metabolic Biology
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Publications - Cell and Metabolic Biology
Publications
Precise annotation of time and spatial distribution of enzymes involved in plant secondary metabolism by gel electrophoresis are usually difficult due to their low abundance. Therefore, effective methods to enrich these enzymes are required to correlate available transcript and metabolite data with the actual presence of active enzymes in wild-type and mutant plants or to monitor variations of these enzymes under various types of biotic and abiotic stress conditions. S-Adenosyl-L-methionine-dependent O-methyltransferases play important roles in the modification of natural products such as phenylpropanoids or alkaloids. In plants they occur as small superfamilies with defined roles for each of its members in different organs and tissues. We explored the use of S-adenosyl-L-homocysteine as a selectivity function in affinity-based protein profiling supported by capture compound mass spectrometry. Due to their high affinity to this ligand it was possible to identify developmental changes of flower-specific patterns of plant natural product O-methyltransferases and corroborate the absence of individual O-methyltransferases in the corresponding Arabidopsis knockout lines. Developmental changes in the OMT pattern were correlated with transcript data obtained by qPCR.
Publications
Seeds of oilseed rape (Brassica napus) accumulate high amounts of antinutritive sinapate esters (SE) with sinapoylcholine (sinapine) as major component, accompanied by sinapoylglucose. These phenolic compounds compromise the use of the protein-rich valuable seed meal. Hence, a substantial reduction of the SE content is considered essential for establishing rape as a protein crop. The present work focuses on the suppression of sinapine synthesis in rape. Therefore, rape (spring cultivar Drakkar) was transformed with a dsRNAi construct designed to silence seed-specifically the BnSGT1 gene encoding UDP-glucose:sinapate glucosyltransferase (SGT1). This resulted in a substantial decrease of SE content in T2 seeds with a reduction reaching 61%. In T2 seeds a high and significant correlation between the contents of sinapoylglucose and all other sinapate esters has been observed. Among transgenic plants, no significant difference in other important agronomic traits, such as oil, protein, fatty acid and glucosinolate content in comparison to the control plants was observed. Maximal reduction of total SE content by 76% was observed in seeds of one homozygous T2 plant (T3 seeds) carrying the BnSGT1 suppression cassette as a single copy insert. In conclusion, this study is an initial proof of principle that suppression of sinapoylglucose formation leads to a strong reduction of SE in rape seeds and is thus a promising approach in establishing rape, currently an important oil crop, as a protein crop as well.
Publications
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Publications
In our studies on tyrosinase-catalyzed tyrosine hydroxylation, possibly involved in betalain biosynthesis, we have evaluated different assays for the detection and quantification of the enzymatic product Dopa with respect to sensitivity, simplicity, and suitability for automatization. A tyrosinase assay including reversed-phase high-performance liquid chromatography with isocratic elution and fluorescence detection has been developed (native fluorescence of Dopa; excitation at 281 nm, emission at 314 nm). This improved assay was sensitive (detection limit: 2 pmol Dopa) and showed a wide linear range of Dopa detection (10 pmol–20 nmol Dopa). The method proved to be suitable for high-performance liquid chromatography with an autosampler and has been applied for measuring tyrosinase activity of cell cultures and different tissues ofPortulaca grandiflora.
This page was last modified on 27 Jan 2025 .
