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L-抗坏血酸在植物的源叶韧皮部中积累，并运输到库组织。

L-Ascorbic acid is accumulated in source leaf phloem and transported to sink tissues in plants.

作者信息

Franceschi Vincent R, Tarlyn Nathan M

机构信息

School of Biological Sciences, Washington State University, Pullman, WA 99164-4236, USA.

出版信息

Plant Physiol. 2002 Oct;130(2):649-56. doi: 10.1104/pp.007062.

DOI:10.1104/pp.007062

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC166594/

Abstract

L-Ascorbic acid (AsA) was found to be loaded into phloem of source leaves and transported to sink tissues. When L-[(14)C]AsA was applied to leaves of intact plants of three different species, autoradiographs and HPLC analysis demonstrated that AsA was accumulated into phloem and transported to root tips, shoots, and floral organs, but not to mature leaves. AsA was also directly detected in Arabidopsis sieve tube sap collected from an English green aphid (Sitobion avenae) stylet. Feeding a single leaf of intact Arabidopsis or Medicago sativa with 10 or 20 mM L-galactono-1,4-lactone (GAL-L), the immediate precursor of AsA, lead to a 7- to 8-fold increase in AsA in the treated leaf and a 2- to 3-fold increase of AsA in untreated sink tissues of the same plant. The amount of AsA produced in treated leaves and accumulated in sink tissues was proportional to the amount of GAL-L applied. Studies of the ability of organs to produce AsA from GAL-L showed mature leaves have a 3- to 10-fold higher biosynthetic capacity and much lower AsA turnover rate than sink tissues. The results indicate AsA transporters reside in the phloem, and that AsA translocation is likely required to meet AsA demands of rapidly growing non-photosynthetic tissues. This study also demonstrates that source leaf AsA biosynthesis is limited by substrate availability rather than biosynthetic capacity, and sink AsA levels may be limited to some extent by source production. Phloem translocation of AsA may be one factor regulating sink development because AsA is critical to cell division/growth.

摘要

研究发现，L-抗坏血酸（AsA）被装载到源叶的韧皮部并运输到库组织。当将L-[（14）C]AsA施用于三种不同物种的完整植株叶片时，放射自显影片和高效液相色谱分析表明，AsA积累在韧皮部并运输到根尖、茎尖和花器官，但未运输到成熟叶片。在从英国绿色蚜虫（麦长管蚜）口针收集的拟南芥筛管汁液中也直接检测到了AsA。用10或20 mM L-半乳糖-1,4-内酯（GAL-L），即AsA的直接前体，饲喂完整拟南芥或紫花苜蓿的一片叶子，导致处理叶片中的AsA增加7至8倍，同一植株未处理的库组织中的AsA增加2至3倍。处理叶片中产生并积累在库组织中的AsA量与施用的GAL-L量成正比。对器官从GAL-L产生AsA能力的研究表明，成熟叶片的生物合成能力比库组织高3至10倍，且AsA周转速率低得多。结果表明，AsA转运体存在于韧皮部，AsA的转运可能是为了满足快速生长的非光合组织对AsA的需求。本研究还表明，源叶AsA生物合成受底物可用性而非生物合成能力的限制，库中AsA水平可能在一定程度上受源叶产量的限制。AsA的韧皮部转运可能是调节库发育的一个因素，因为AsA对细胞分裂/生长至关重要。