Faculty of Biology, Institute for Biology II, Botany/Plant Physiology, Albert-Ludwigs-University, Schänzlestr.1, 79104, Freiburg, Germany.
Planta. 2012 Jan;235(1):137-51. doi: 10.1007/s00425-011-1501-1. Epub 2011 Aug 20.
Gibberellins (GA) are involved in bud dormancy release in several species. We show here that GA-treatment released bud dormancy, initiated bud sprouting and promoted sprout growth of excised potato tuber bud discs ('eyes'). Monoterpenes from peppermint oil (PMO) and S-(+)-carvone (CAR) interact with the GA-mediated bud dormancy release in a hormesis-type response: low monoterpene concentrations enhance dormancy release and the initiation of bud sprouting, whereas high concentrations inhibit it. PMO and CAR did, however, not affect sprout growth rate after its onset. We further show that GA-induced dormancy release is associated with tissue-specific regulation of α- and β-amylases. Molecular phylogenetic analysis shows that potato α-amylases cluster into two distinct groups: α-AMY1 and α-AMY2. GA-treatment induced transcript accumulation of members of both α-amylase groups, as well as α- and β-amylase enzyme activity in sprout and 'sub-eye' tissues. In sprouts, CAR interacts with the GA-mediated accumulation of α-amylase transcripts in an α-AMY2-specific and dose-dependent manner. Low CAR concentrations enhance the accumulation of α-AMY2-type α-amylase transcripts, but do not affect the α-AMY1-type transcripts. Low CAR concentrations also enhance the accumulation of α- and β-amylase enzyme activity in sprouts, but not in 'sub-eye' tissues. In contrast, high CAR concentrations have no appreciable effect in sprouts on the enzyme activities and the α-amylase transcript abundances of either group. The dose-dependent effects on the enzyme activities and the α-AMY2-type α-amylase transcripts in sprouts are specific for CAR but not for PMO. Different monoterpenes therefore may have specific targets for their interaction with hormone signalling pathways.
赤霉素(GA)参与了多种物种的芽休眠释放。我们在这里表明,GA 处理释放了芽休眠,启动了芽萌发,并促进了离体马铃薯块茎芽盘(“芽眼”)的芽萌发生长。薄荷油(PMO)和 S-(+)-香芹酮(CAR)中的单萜与 GA 介导的芽休眠释放以一种应激型反应相互作用:低浓度的单萜增强休眠释放和芽萌发的启动,而高浓度则抑制它。然而,PMO 和 CAR 并不影响芽萌发后的生长速率。我们进一步表明,GA 诱导的休眠释放与组织特异性的α-和β-淀粉酶调控有关。分子系统发育分析表明,马铃薯α-淀粉酶分为两个不同的组:α-AMY1 和 α-AMY2。GA 处理诱导两个α-淀粉酶组的成员的转录物积累,以及在芽和“副芽眼”组织中的α-和β-淀粉酶酶活性。在芽中,CAR 以α-AMY2 特异性和剂量依赖的方式与 GA 介导的α-淀粉酶转录物积累相互作用。低浓度的 CAR 增强了 α-AMY2 型α-淀粉酶转录物的积累,但不影响α-AMY1 型转录物。低浓度的 CAR 还增强了芽中α-和β-淀粉酶酶活性的积累,但在“副芽眼”组织中则不然。相比之下,高浓度的 CAR 对芽中酶活性和两组α-淀粉酶转录物的积累没有明显影响。在芽中,酶活性和α-AMY2 型α-淀粉酶转录物对 CAR 的剂量依赖性影响是特异性的,但对 PMO 则不是。因此,不同的单萜可能对其与激素信号通路的相互作用具有特定的靶标。
