Bouges-Bocquet B
Biochim Biophys Acta. 1977 Nov 17;462(2):371-9. doi: 10.1016/0005-2728(77)90135-9.
On dark-adapted Chlorella, after one flash, plastocyanin (PC) undergoes reduction with a half-time of 7 ms. After 4 or 5 flashes, the reduction of PC+ in the 10 ms range is suppressed, and the level of oxidized plastocyanin increases during the next few flashes before reaching a stationary value. Cytochrome f exhibits approximately the same pattern. The reduction of PC+ and cytochrome f+ in the 10 ms range is correlated with an increase of the electrice field named phase b (Joliot, P. and Delosme, R., Biochim. Biophys. Acta 357 (1974) 267-284). Both need the presence of a compound R' in the reduced state. A dark electron transfer involving a carrier of electrons across the membrane, a proton carrier, R' as terminal reducant, PC+ and cytochrome f+ as terminal oxidants, would account for this field generation. Cooperation between the electron transfer chains is implied at the level of plastocyanin oxidation. An equilibrium constant of about 2 is observed between cytochrome f and plastocyanin before 1 ms and after 500 ms after the photochemical reactions. We observe that cytochrome f and plastocyanin are not connected from 1 to 100 ms after a photochemical reaction. The equilibrium constant between plastocyanin and P-700 remains large [20] under these conditions.
在暗适应的小球藻上,一次闪光后,质体蓝素(PC)以7毫秒的半衰期发生还原。4或5次闪光后,10毫秒范围内PC+的还原受到抑制,在达到稳定值之前的接下来几次闪光期间,氧化型质体蓝素的水平会增加。细胞色素f呈现出大致相同的模式。10毫秒范围内PC+和细胞色素f+的还原与名为b相的电场增加相关(乔利奥,P.和德洛姆,R.,《生物化学与生物物理学报》357(1974)267 - 284)。两者都需要还原态的化合物R'的存在。涉及跨膜电子载体、质子载体、作为末端还原剂的R'、作为末端氧化剂的PC+和细胞色素f+的暗电子传递,将解释这种电场的产生。在质体蓝素氧化水平上暗示了电子传递链之间的协同作用。在光化学反应后1毫秒之前和500毫秒之后,观察到细胞色素f和质体蓝素之间的平衡常数约为2。我们观察到,光化学反应后1到100毫秒内,细胞色素f和质体蓝素没有连接。在这些条件下,质体蓝素和P - 700之间的平衡常数仍然很大[20]。
