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辐照增强的光敏色素可沉淀性：体内需要磷酸化能量。

Irradiation-enhanced Phytochrome Pelletability: Requirement for Phosphorylative Energy in Vivo.

机构信息

Carnegie Institution of Washington, 290 Panama Street, Stanford, California 94305.

出版信息

Plant Physiol. 1978 Nov;62(5):773-8. doi: 10.1104/pp.62.5.773.

DOI:10.1104/pp.62.5.773

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1092218/

Abstract

Short, high intensity pulses of red and far red light are used to study, at room temperature, the kinetics of the in vivo dark reaction responsible for irradiation-enhanced phytochrome pelletability. The t((1/2)) for this reaction is 2 seconds at 25 C in both Avena shoots and Zea mays coleoptiles. This is the most rapid phytochrome-far red-absorbing form (Pfr)-mediated cellular response thus far reported. Anoxia, KCN, NaN(3) and carbonyl cyanide p-trifluoromethoxyphenylhydrazone reduce the rate (but not the final extent) of the reaction by more than an order of magnitude. The rate of the reaction under these conditions is strongly correlated with the inhibitor-induced reductions in cellular ATP levels. Likewise, recovery in ATP levels upon withdrawal of the inhibitors is accompanied by a parallel recovery in the rate of the reaction. Cytochalasin B blocks cytoplasmic streaming without diminishing the pelletability response. Colchicine is likewise without effect. These data suggest a requirement for phosphorylative energy in one or more of the Pfr-dependent intracellular events leading to enhanced phytochrome pelletability. The possibility that this event might represent an ATP-dependent modification of the pigment protein itself in the Pfr form is discussed.

摘要

采用短时间、高强度的红光和远红光脉冲，在室温下研究活体暗反应动力学，该反应负责光照增强的光敏色素颗粒形成。在 25°C 时，玉米黄化苗和玉米胚芽鞘的该反应 t((1/2))为 2 秒。这是迄今为止报道的最快的光敏色素-远红光吸收形式（Pfr）介导的细胞反应。缺氧、KCN、NaN(3)和羰基氰化物 p-三氟甲氧基苯腙使反应速率（但不是最终程度）降低了一个数量级以上。在这些条件下，反应速率与抑制剂诱导的细胞内 ATP 水平降低密切相关。同样，在除去抑制剂后 ATP 水平的恢复伴随着反应速率的平行恢复。细胞松弛素 B 阻断细胞质流而不减少颗粒形成反应。秋水仙素也没有效果。这些数据表明，在导致增强的光敏色素颗粒形成的 Pfr 依赖性细胞内事件中，需要磷酸化能量。该事件可能代表 Pfr 形式的色素蛋白本身的 ATP 依赖性修饰，这一可能性值得讨论。