蓝光和脱落酸独立诱导四叶苹的异形叶转换。
Blue light and abscisic acid independently induce heterophyllous switch in marsilea quadrifolia.
作者信息
Lin BL, Yang WJ
机构信息
Institute of Molecular Biology, Academia Sinica, Nankang, Taipei 115, Taiwan, Republic of China (B.-L.L., W.-J.Y.).
出版信息
Plant Physiol. 1999 Feb;119(2):429-34. doi: 10.1104/pp.119.2.429.
Abstract
In natural habitats Marsilea quadrifolia L. produces different types of leaves above and below the water level. In aseptic cultures growth conditions can be manipulated so that leaves of the submerged type are produced continuously. Under such conditions the application of either blue light or an optimal concentration of abscisic acid (ABA) induced the development of aerial-type leaves. When fluridone, an inhibitor of ABA biosynthesis, was added to the culture medium it did not prevent blue light induction of aerial leaf development. During blue light treatment the endogenous ABA level in M. quadrifolia leaves remained unchanged. However, after the plants were transferred to an enriched medium, the ABA level gradually increased, corresponding to a transition in development from the submerged type of leaves to aerial leaves. These results indicate that the blue light signal is not mediated by ABA. Therefore, in the regulation of heterophyllous determination, discrete pathways exist in response to environmental signals.
摘要
在自然生境中,四叶苹在水面上下产生不同类型的叶子。在无菌培养中,可以控制生长条件,使水下型叶子持续产生。在这种条件下,施加蓝光或最佳浓度的脱落酸(ABA)可诱导气生型叶子的发育。当将ABA生物合成抑制剂氟啶酮添加到培养基中时,它并不能阻止蓝光诱导气生叶的发育。在蓝光处理期间,四叶苹叶片中的内源ABA水平保持不变。然而,在将植株转移到富集培养基后,ABA水平逐渐升高,这与叶子从水下型向气生叶的发育转变相对应。这些结果表明,蓝光信号不是由ABA介导的。因此,在异形叶决定的调控中,存在响应环境信号的不同途径。
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