Rotov Alexander Yu, Astakhova Luba A, Firsov Michael L, Govardovskii Victor I
Institute for Evolutionary Physiology and Biochemistry, Russian Academy of Sciences, St. Petersburg, Russia.
Peter the Great St. Petersburg Polytechnic University, St. Petersburg, Russia.
Mol Vis. 2017 Jul 7;23:416-430. eCollection 2017.
To identify steps of the phototransduction cascade responsible for the delay of the photoresponse.
Electrical responses of fish () cones and frog rods and cones were recorded with a suction pipette technique and as an aspartate-isolated mass receptor potential from isolated perfused retinas. Special attention was paid to sufficiently high temporal resolution (1-ms flash, 700 Hz amplification bandpass). Stochastic simulation of the activation steps from photon absorption to the formation of catalytically active phosphodiesterase (PDE) was performed. In addition, a deterministic mathematical model was fit to the experimental responses. The model included a detailed description of the activation steps of the cascade that enabled identification of the role of individual transduction stages in shaping the initial part of the response.
We found that the apparent delay of the photoresponse gets shorter with increasing stimulus intensity and reaches an asymptotic value of approximately 3 ms in cones and greater than or equal to 10 ms in rods. The result seems paradoxical since it is suggested that the delay occurs in the chain of steps from photon absorption to the formation of active transducin (T*) which in cones is, on average, slower than in rods. Stochastic simulation shows that actually the steps from photon absorption to T* may not contribute perceptibly to the delay. Instead, the delay occurs at the stage that couples the cycle of repetitive activation of T by rhodopsin (R*) with the activation of PDE. These steps include formation of T* (= T GTP) out of T GTP released from the activation cycle and the subsequent interaction of T* with PDE. This poses a problem. The duration of an average cycle of activation of T in rods is approximately 5 ms and is determined by the frequency of collisions between R* and T in the photoreceptor membrane. The frequency is roughly proportional to the surface packing density of T in the membrane. As the packing density of PDE is approximately 12 times lower than that of T, it could be expected that the rate of the T*-PDE interaction were an order of magnitude slower than that of R* and T. As modeling shows, this is the case in rods. However, the delay in cones is approximately 3 ms which could be achieved only at a T*-PDE interaction time of less than or equal to 5 ms. This means that either the frequency of the collisions of T* and PDE, or the efficiency of collisions, or both in cones are approximately ten times higher than in rods. This may be a challenge to the present model of the molecular organization of the photoreceptor membrane.
The delay of the photoresponse is mainly set by the rate of interaction of T* with PDE. In cones, the delay is shorter than in rods and, moreover, shorter than the duration of the cycle of repetitive activation of T by R*. This poses a problem for the present model of diffusion interaction of phototransduction proteins in the photoreceptor membrane.
确定光转导级联反应中导致光反应延迟的步骤。
采用吸液管技术记录鱼类视锥细胞、青蛙视杆细胞和视锥细胞的电反应,并将其作为从分离灌注视网膜中分离出的天冬氨酸隔离的整体感受器电位。特别关注足够高的时间分辨率(1毫秒闪光,700赫兹放大带通)。对从光子吸收到催化活性磷酸二酯酶(PDE)形成的激活步骤进行了随机模拟。此外,将确定性数学模型拟合到实验反应中。该模型详细描述了级联反应的激活步骤,从而能够确定各个转导阶段在塑造反应初始部分中的作用。
我们发现,随着刺激强度的增加,光反应的明显延迟会缩短,在视锥细胞中达到约3毫秒的渐近值,在视杆细胞中大于或等于10毫秒。这个结果似乎自相矛盾,因为据推测延迟发生在从光子吸收到活性转导蛋白(T*)形成的步骤链中,而视锥细胞中的这一过程平均比视杆细胞慢。随机模拟表明,实际上从光子吸收到T的步骤可能对延迟没有明显贡献。相反,延迟发生在将视紫红质(R)对T的重复激活循环与PDE的激活耦合的阶段。这些步骤包括从激活循环释放的T·GTP形成T*(=T·GTP),以及随后T与PDE的相互作用。这就产生了一个问题。视杆细胞中T平均激活循环的持续时间约为5毫秒,由光感受器膜中R与T之间的碰撞频率决定。该频率大致与膜中T的表面堆积密度成正比。由于PDE的堆积密度比T低约12倍,可以预期T*-PDE相互作用的速率比R与T的相互作用速率慢一个数量级。正如建模所示,视杆细胞中就是这种情况。然而,视锥细胞中的延迟约为3毫秒,这只有在T-PDE相互作用时间小于或等于5毫秒时才能实现。这意味着视锥细胞中T*与PDE的碰撞频率、碰撞效率或两者都比视杆细胞高约十倍。这可能对目前光感受器膜分子组织模型构成挑战。
光反应的延迟主要由T与PDE的相互作用速率决定。在视锥细胞中,延迟比视杆细胞短,而且比R对T的重复激活循环的持续时间短。这给目前光转导蛋白在光感受器膜中扩散相互作用的模型带来了问题。
