Matsubara Shizue, Morosinotto Tomas, Bassi Roberto, Christian Anna-Luise, Fischer-Schliebs Elke, Lüttge Ulrich, Orthen Birgit, Franco Augusto C, Scarano Fabio R, Förster Britta, Pogson Barry J, Osmond C Barry
Research School of Biological Sciences, and School of Biochemistry and Molecular Biology, Australian National University, GPO Box 475, ACT 2601 Canberra, Australia.
Planta. 2003 Oct;217(6):868-79. doi: 10.1007/s00425-003-1059-7. Epub 2003 Jul 3.
The lutein-epoxide cycle (Lx cycle) is an auxiliary xanthophyll cycle known to operate only in some higher-plant species. It occurs in parallel with the common violaxanthin cycle (V cycle) and involves the same epoxidation and de-epoxidation reactions as in the V cycle. In this study, the occurrence of the Lx cycle was investigated in the two major families of mistletoe, the Loranthaceae and the Viscaceae. In an attempt to find the limiting factor(s) for the occurrence of the Lx cycle, pigment profiles of mistletoes with and without the Lx cycle were compared. The availability of lutein as a substrate for the zeaxanthin epoxidase appeared not to be critical. This was supported by the absence of the Lx cycle in the transgenic Arabidopsis plant lutOE, in which synthesis of lutein was increased at the expense of V by overexpression of epsilon-cyclase, a key enzyme for lutein synthesis. Furthermore, analysis of pigment distribution within the mistletoe thylakoids excluded the possibility of different localizations for the Lx- and V-cycle pigments. From these findings, together with previous reports on the substrate specificity of the two enzymes in the V cycle, we propose that mutation to zeaxanthin epoxidase could have resulted in altered regulation and/or substrate specificity of the enzyme that gave rise to the parallel operation of two xanthophyll cycles in some plants. The distribution pattern of Lx in the mistletoe phylogeny inferred from 18S rRNA gene sequences also suggested that the occurrence of the Lx cycle is determined genetically. Possible molecular evolutionary processes that may have led to the operation of the Lx cycle in some mistletoes are discussed.
叶黄素环氧化循环(Lx循环)是一种已知仅在某些高等植物物种中起作用的辅助叶黄素循环。它与常见的紫黄质循环(V循环)并行发生,并且涉及与V循环相同的环氧化和脱环氧化反应。在本研究中,对槲寄生的两个主要科,即桑寄生科和槲寄生科中Lx循环的发生情况进行了研究。为了找出Lx循环发生的限制因素,比较了具有和不具有Lx循环的槲寄生的色素谱。叶黄素作为玉米黄质环氧化酶底物的可用性似乎并非关键因素。这一点在转基因拟南芥植物lutOE中缺乏Lx循环得到了支持,在该植物中,通过过表达叶黄素合成的关键酶ε-环化酶,叶黄素的合成增加,而以紫黄质为代价。此外,对槲寄生类囊体中色素分布的分析排除了Lx循环和V循环色素不同定位的可能性。基于这些发现,结合先前关于V循环中两种酶底物特异性的报道,我们提出玉米黄质环氧化酶的突变可能导致该酶的调节和/或底物特异性发生改变,从而在某些植物中产生了两个叶黄素循环的并行运行。从18S rRNA基因序列推断的槲寄生系统发育中Lx的分布模式也表明,Lx循环的发生是由基因决定的。本文还讨论了可能导致某些槲寄生中Lx循环运行的分子进化过程。
