互叶白千层萜烯化学型的生化解释。

A biochemical interpretation of terpene chemotypes in Melaleuca alternifolia.

机构信息

Research School of Biology, Australian National University, Canberra 0200, Australia.

出版信息

J Chem Ecol. 2010 Jun;36(6):652-61. doi: 10.1007/s10886-010-9798-y. Epub 2010 May 29.

PMID:20509043

Abstract

The variation of foliar monoterpenes in the Australian Tea Tree (Melaleuca alternifolia) has been of significant interest both to the essential oil industry as well as to ecologists. The majority of studies on leaf chemistry have been aimed directly towards obtaining oil of higher quality or quantity. In the current study, we aimed to understand how molecular mechanisms contribute to the chemical variability of this species, based on chemical analysis of the leaf oils from a biochemical perspective. Correlations between monoterpenes across the species as well as within chemotypes show strong, persistent patterns, which enable us to establish groups based on possible common biosynthetic origins. We found that three distinct enzymes corresponding to these groups: a sabinene-hydrate synthase, a 1,8-cineole synthase, and a terpinolene synthase may be sufficient to explain all six chemotypes in M. alternifolia.

摘要

叶面单萜在澳大利亚茶树（互叶白千层）中的变化不仅引起了精油行业的关注，也引起了生态学家的关注。大多数关于叶片化学的研究都直接旨在获得更高质量或数量的油。在本研究中，我们旨在从生化角度通过对叶油的化学分析来了解分子机制如何促成该物种的化学变异性。种间和同种内单萜之间的相关性显示出强烈而持久的模式，使我们能够根据可能的共同生物合成起源建立组。我们发现，与这些组相对应的三种不同的酶：柠檬烯水合酶、1,8-桉叶油醇合酶和松油烯合酶可能足以解释互叶白千层中的所有六种化学型。

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互叶白千层萜烯化学型的生化解释。

A biochemical interpretation of terpene chemotypes in Melaleuca alternifolia.

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