单萜类化合物的代谢：负责樟脑、3-侧柏酮和3-异侧柏酮生物合成的脱氢酶的特异性

Metabolism of monoterpenes: specificity of the dehydrogenases responsible for the biosynthesis of camphor, 3-thujone, and 3-isothujone.

作者信息

Dehal S S, Croteau R

机构信息

Institute of Biological Chemistry, Washington State University, Pullman 99164-6340.

出版信息

Arch Biochem Biophys. 1987 Oct;258(1):287-91. doi: 10.1016/0003-9861(87)90346-8.

DOI:10.1016/0003-9861(87)90346-8

Abstract

Sage (Salvia officinalis) is shown to contain two electrophoretically distinct dehydrogenases for the respective oxidations of (+)-borneol to (+)-camphor, and of (+)-cis-sabinol to (+)-sabinone en route to (-)-3-isothujone. Similarly, tansy (Tanacetum vulgare) is shown to contain two electrophoretically distinct dehydrogenases for the respective oxidations of (-)-borneol to (-)-camphor and of (+)-cis-sabinol to (+)-sabinone en route to (+)-3-thujone. These results demonstrate that separate dehydrogenases are responsible for the biosynthesis of camphor from borneol and of the thujyl ketones via cis-sabinol, and they also indicate that the previously reported oxidations of various thujanols by the borneol dehydrogenases are only coincidental activities not relevant to the formation of 3-thujone and 3-isothujone.

摘要

鼠尾草（药用鼠尾草）被证明含有两种电泳性质不同的脱氢酶，分别用于将（+）-龙脑醇氧化为（+）-樟脑，以及将（+）-顺式桧醇氧化为（+）-桧酮，进而生成（-）-3-异侧柏酮。同样，艾菊（普通菊蒿）被证明含有两种电泳性质不同的脱氢酶，分别用于将（-）-龙脑醇氧化为（-）-樟脑，以及将（+）-顺式桧醇氧化为（+）-桧酮，进而生成（+）-3-侧柏酮。这些结果表明，不同的脱氢酶分别负责从龙脑醇生物合成樟脑以及通过顺式桧醇生物合成侧柏基酮，并且它们还表明，先前报道的龙脑醇脱氢酶对各种侧柏醇的氧化作用只是偶然的活性，与3-侧柏酮和3-异侧柏酮的形成无关。

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