分离的黄化质体膜对叶绿素酸酯形成的重建
Reconstitution of chlorophyllide formation by isolated etioplast membranes.
作者信息
Griffiths W T
出版信息
Biochem J. 1978 Sep 15;174(3):681-92. doi: 10.1042/bj1740681.
Abstract
- The reconstitution of chlorophyllide biosynthesis by barley etioplast membranes is described. 2. The process is dependent on the additon of NADPH and protochlorophyllide and on illumination, which can be either continuous or intermittent. 3. The reconstituted process involves spectroscopically similar intermediates to the native reaction in whole leaves. 4. Steps in the process are an initial enzymic formation in the dark of a photoactive complex, P638/652 (probably a ternary protochlorophyllide-NADPH-enzyme complex), followed by a very rapid light-dependent hydrogen transfer from the NADPH to the protochlorophyllide giving chlorophyllide giving chlorophyllide, finally releasing the enzyme for repeating the process. 5. A continuous assay for the system regenerating complex P638/652 was devised on the basis of monitoring chlorophyllide formation. 6. The pH optimum of the reaction is at 6.9 and Km values for protochlorophyllide and NADPH are 0.46 and 35 micron respectively. 7. The reaction is associated specifically with the etioplast membrane fraction. 8. Activities of the system assayed in vitro are more than adequate to account for rates of chlorophyll formation in vivo.
摘要
- 描述了大麦黄化质体膜对叶绿素酸酯生物合成的重组过程。2. 该过程依赖于添加NADPH和原叶绿素酸酯以及光照,光照可以是连续的或间歇的。3. 重组过程涉及的中间体在光谱上与完整叶片中的天然反应相似。4. 该过程的步骤包括:首先在黑暗中通过酶促形成光活性复合物P638/652(可能是原叶绿素酸酯 - NADPH - 酶三元复合物),然后是非常快速的光依赖型氢从NADPH转移到原叶绿素酸酯生成叶绿素酸酯,最终释放酶以重复该过程。5. 在监测叶绿素酸酯形成的基础上,设计了一种用于系统再生复合物P638/652的连续测定方法。6. 该反应的最适pH为6.9,原叶绿素酸酯和NADPH的Km值分别为0.46和35微摩尔。7. 该反应与黄化质体膜部分特异性相关。8. 体外测定的该系统活性足以解释体内叶绿素形成的速率。
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