微体功能变化期间向日葵子叶中过氧化氢酶的表观合成:密度标记数据定量评估的数学方法
Apparent Catalase Synthesis in Sunflower Cotyledons during the Change in Microbody Function: A Mathematical Approach for the Quantitative Evaluation of Density-labeling Data.
作者信息
Betsche T, Gerhardt B
机构信息
Botanisches Institut der Universität, D-4400 Münster, Germany.
出版信息
Plant Physiol. 1978 Oct;62(4):590-7. doi: 10.1104/pp.62.4.590.
Abstract
Density-labeling with 10 mm K(15)NO(3)/70% (2)H(2)O has been used to investigate catalase synthesis in different developmental stages of sunflower (Helianthus annuus L.) cotyledons. A mathematical approach is introduced for the quantitative evaluation of the density-labeling data. The method allows, in the presence of preexisting enzyme activity, calculation of this synthesized activity (apparent enzyme synthesis) which results from the balance between actual enzyme synthesis and the degradation of newly synthesized enzyme at a given time. During greening of the cotyledons, when the catalase activity declines and the population of leaf peroxisomes is formed, the apparent catalase synthesis is lower than, or at best equal to, that occurring during a developmental stage when the leaf peroxisome population is established and catalase synthesis and degradation of total catalase are in equilibrium. This result suggests a formation, in fatty cotyledons, of the leaf peroxisomes by transformation of the glyoxysomes rather than by de novo synthesis.
摘要
用10毫米K(15)NO(3)/70% (2)H(2)O进行密度标记,以研究向日葵(Helianthus annuus L.)子叶不同发育阶段的过氧化氢酶合成。引入了一种数学方法来定量评估密度标记数据。该方法在存在预先存在的酶活性的情况下,能够计算出这种合成活性(表观酶合成),它是由给定时间内实际酶合成与新合成酶降解之间的平衡产生的。在子叶绿化过程中,当过氧化氢酶活性下降且叶过氧化物酶体群体形成时,表观过氧化氢酶合成低于或至多等于在叶过氧化物酶体群体建立且总过氧化氢酶合成与降解处于平衡的发育阶段所发生的合成。这一结果表明,在富含脂肪的子叶中,叶过氧化物酶体是由乙醛酸循环体转化形成的,而不是从头合成。
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