Karl T, Fall R, Rosenstiel T N, Prazeller P, Larsen B, Seufert G, Lindinger W
Institut für Ionenphysik, Universität Innsbruck, Technikerstrasse 25, 6020 Innsbruck Austria.
Planta. 2002 Oct;215(6):894-905. doi: 10.1007/s00425-002-0825-2. Epub 2002 Jul 17.
Isoprene (2-methyl-1,3-butadiene) is the most abundant biogenic hydrocarbon released from vegetation, and there is continuing interest in understanding its biosynthesis from photosynthetic precursors in leaf chloroplasts. We used on-line proton-transfer-reaction mass spectrometry (PTR-MS) to observe the kinetics of (13)C-labeling of isoprene following exposure to (13)CO(2) and then the loss of (13)C after a return to normal (12)CO(2) in oak ( Quercus agrifolia Nee) and cottonwood (Populus deltoides Barr.) leaves. Assignments of labeled isoprene species were verified by gas chromatography-mass spectrometry. For the first time, it was possible to observe the half-lives of individually (13)C-labeled isoprene species during these transitions, and to trace some of the label to a C3 fragment that contained the two isoprene carbons derived from pyruvate via the deoxyxylulose-5-phosphate (DOXP) pathway. At steady state (under (13)CO(2)), approximately 80% of isoprene carbon was labeled, with fully labeled isoprene as the major species (approx. 60%). The source of the unlabeled C is suggested to be extrachloroplastic, but not from photorespiratory carbon. After a transfer to (12)CO(2), (13)C-labeling persisted in one isoprene carbon for several hours; this persistence was much more pronounced in (i) leaves inhibited by fosmidomycin, a specific inhibitor of the DOXP pathway, and (ii) in sun leaves which have higher ratios of soluble sugars to starch. From the mass 41-44 fragment data, and labeling predicted from the DOXP pathway in chloroplasts, precursors may arise from cytosolic pyruvate/phospho enolpyruvate equivalents transported into the chloroplast; this idea was supported by an indirect measure of pyruvate labeling. Other sources of cytosolic isoprene precursors (i.e. dimethylallyl diphosphate or pentose phosphate) could not be excluded. The data obtained shed light on the half-lives of photosynthetic metabolites, exchanges of carbon between cellular pools, and suggest multiple origins of isoprene precursors in leaves.
异戊二烯(2-甲基-1,3-丁二烯)是植物释放的最丰富的生物源碳氢化合物,人们一直对了解其在叶片叶绿体中由光合前体合成的过程很感兴趣。我们使用在线质子转移反应质谱法(PTR-MS)来观察橡树(Quercus agrifolia Nee)和三角叶杨(Populus deltoides Barr.)叶片在暴露于(^{13}CO_2)后异戊二烯的(^{13}C)标记动力学,以及恢复到正常的(^{12}CO_2)后(^{13}C)的损失情况。通过气相色谱-质谱法验证了标记异戊二烯物种的归属。首次有可能观察到在这些转变过程中各个(^{13}C)标记的异戊二烯物种的半衰期,并追踪部分标记到一个C3片段,该片段包含通过脱氧木酮糖-5-磷酸(DOXP)途径源自丙酮酸的两个异戊二烯碳。在稳态(在(^{13}CO_2)下)时,约80%的异戊二烯碳被标记,完全标记的异戊二烯是主要物种(约60%)。未标记的C的来源被认为是叶绿体外部的,但不是来自光呼吸碳源。转移到(^{12}CO_2)后,(^{13}C)标记在一个异戊二烯碳上持续了几个小时;这种持续性在(i)被福斯米霉素(DOXP途径的特异性抑制剂)抑制的叶片中,以及(ii)可溶性糖与淀粉比例较高的阳生叶中更为明显。从质量数41 - 44的片段数据以及叶绿体中DOXP途径预测的标记情况来看,前体可能来自转运到叶绿体中的胞质丙酮酸/磷酸烯醇丙酮酸等价物;丙酮酸标记的间接测量支持了这一观点。不能排除胞质异戊二烯前体的其他来源(即二甲基烯丙基二磷酸或磷酸戊糖)。所获得的数据揭示了光合代谢物的半衰期、细胞池之间的碳交换,并表明叶片中异戊二烯前体有多种来源。
