Fasbender Lukas, Maurer Daniel, Kreuzwieser Jürgen, Kreuzer Ines, Schulze Waltraud X, Kruse Jörg, Becker Dirk, Alfarraj Saleh, Hedrich Rainer, Werner Christiane, Rennenberg Heinz
Institute of Forest Sciences, Chair of Ecosystem Physiology, University of Freiburg, Georges-Köhler-Allee 53/54, Freiburg, 79110, Germany.
Institute of Forest Sciences, Chair of Tree Physiology, University of Freiburg, Georges-Köhler-Allee 53/54, Freiburg, 79110, Germany.
New Phytol. 2017 Apr;214(2):597-606. doi: 10.1111/nph.14404. Epub 2017 Jan 2.
The present study was performed to elucidate the fate of carbon (C) and nitrogen (N) derived from protein of prey caught by carnivorous Dionaea muscipula. For this, traps were fed C/ N-glutamine (Gln). The release of CO was continuously monitored by isotope ratio infrared spectrometry. After 46 h, the allocation of C and N label into different organs was determined and tissues were subjected to metabolome, proteome and transcriptome analyses. Nitrogen of Gln fed was already separated from its C skeleton in the decomposing fluid secreted by the traps. Most of the Gln-C and Gln-N recovered inside plants were localized in fed traps. Among nonfed organs, traps were a stronger sink for Gln-C compared to Gln-N, and roots were a stronger sink for Gln-N compared to Gln-C. A significant amount of the Gln-C was respired as indicated by C-CO emission, enhanced levels of metabolites of respiratory Gln degradation and increased abundance of proteins of respiratory processes. Transcription analyses revealed constitutive expression of enzymes involved in Gln metabolism in traps. It appears that prey not only provides building blocks of cellular constituents of carnivorous Dionaea muscipula, but also is used for energy generation by respiratory amino acid degradation.
本研究旨在阐明食肉植物捕蝇草捕获的猎物蛋白质中碳(C)和氮(N)的去向。为此,给捕虫器喂食C/N-谷氨酰胺(Gln)。通过同位素比率红外光谱法持续监测CO的释放。46小时后,确定C和N标记在不同器官中的分配情况,并对组织进行代谢组、蛋白质组和转录组分析。喂食的Gln中的氮在捕虫器分泌的分解液中已与其C骨架分离。植物体内回收的大部分Gln-C和Gln-N都位于喂食的捕虫器中。在未喂食的器官中,与Gln-N相比,捕虫器对Gln-C的吸收更强,而与Gln-C相比,根对Gln-N的吸收更强。如C-CO排放所示,大量的Gln-C被呼吸消耗,呼吸性Gln降解的代谢物水平升高,呼吸过程的蛋白质丰度增加。转录分析揭示了捕虫器中参与Gln代谢的酶的组成型表达。看来猎物不仅为食肉植物捕蝇草的细胞成分提供构建模块,还通过呼吸性氨基酸降解用于产生能量。
