氰化物潜能在发育中的果实中的模式:对积累氰苷单葡糖苷(菜豆)或氰苷双葡糖苷(亚麻、扁桃)的植物的意义。
Pattern of the Cyanide-Potential in Developing Fruits : Implications for Plants Accumulating Cyanogenic Monoglucosides (Phaseolus lunatus) or Cyanogenic Diglucosides in Their Seeds (Linum usitatissimum, Prunus amygdalus).
机构信息
University of California, Department of Biochemistry and Biophysics, Davis, California 95616.
出版信息
Plant Physiol. 1990 Sep;94(1):28-34. doi: 10.1104/pp.94.1.28.
Abstract
The absolute cyanide content of developing fruits was determined in Costa Rican wild lima beans (Phaseolus lunatus), oil flax (Linum usitatissimum), and bitter almonds (Prunus amygdalus). The cyanide potential (HCN-p) of the lima bean and the almond fruit began to increase shortly after anthesis and then stopped before fruit maturity. In contrast, the flax inflorescence had a higher HCN-p in absolute terms than the mature flax fruit. At all times of its development the bean fruit contained the monoglucosides linamarin and lotaustralin. The almond and the flax fruits contained, at anthesis, the monoglucosides prunasin, and linamarin and lotaustralin, respectively, while, at maturity, only the corresponding diglucosides amygdalin, and linustatin and neolinustatin, respectively, were present.
摘要
测定了哥斯达黎加野生利马豆(Phaseolus lunatus)、油亚麻(Linum usitatissimum)和苦杏仁(Prunus amygdalus)中发育果实的游离氰化物含量。利马豆和杏仁果实的氰化物潜力(HCN-p)在开花后不久开始增加,然后在果实成熟前停止。相比之下,亚麻花序在绝对意义上的 HCN-p 高于成熟的亚麻果实。在其发育的所有阶段,豆果均含有亚麻苦苷和卡茄碱。杏仁和亚麻果实的单糖苷分别为李苷、亚麻苦苷和卡茄碱,在开花时含有,而在成熟时仅含有相应的双糖苷苦杏仁苷、亚麻亭和新亚麻亭。
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本文引用的文献
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Mobilization and utilization of cyanogenic glycosides: the linustatin pathway.氰苷的动员和利用:亚麻苦苷途径。
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The Linamarin beta-Glucosidase in Costa Rican Wild Lima Beans (Phaseolus lunatus L.) Is Apoplastic.哥斯达黎加野生利马豆(Phaseolus lunatus L.)中的亚麻苦苷β-葡萄糖苷酶位于质外体。
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