棒状光导中时空信号的数学和计算模型。

G Caruso, H Khanal, V Alexiades, F Rieke, H E Hamm, E DiBenedetto
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引用次数: 25

摘要

杆状光感受器通过激活级联反应被光激活,该级联反应包括G蛋白偶联受体视紫红质、G蛋白转导蛋白、其效应物环鸟苷单磷酸(cGMP)磷酸二酯酶和第二信使cGMP和Ca2+。信号被定位到特定的棒外段盘,它被单个光子的吸收激活。这种级联的建模以前主要是通过假设一个充分搅拌的细胞质来进行的。我们最近发表了第一个完全空间分辨的模型,它捕捉到了光激活的局部性质。该模型利用均质化和浓缩容量的数学理论,将细胞复杂的几何结构简化为简单的几何结构。该模型表明,在激活单个视紫红质后,第二信使cGMP和Ca2+的变化是特定激活盘的局部变化。在目前的工作中,计算比较了均匀化模型与完整的非均匀化模型,设置在杆外段的原始几何形状中。在计算积分响应时,与全模型相比,该模型的精度为0.03%,计算时间减少了5200倍。该模型可以重建cGMP和Ca2+在激活椎间盘附近的椎间盘间隙的径向时间分布。细胞电反应被定位在激活位点附近,而距离足够远的多个光子产生本质上独立的反应。这导致了对“传播”的概念和估计的计算分析,以及使响应最大化的活化位点的最佳分布。从时空模型中产生的生物学见解包括对昏暗光线响应的可变性如何受到捕获光子的外段圆盘之间距离的影响的量化。因此,该模型是生物学家预测影响G蛋白偶联受体介导级联的时间、扩散和控制机制的各种因素的模拟工具。它允许在一系列条件下轻松进行模拟实验,例如,夹紧钙的浓度,其结果与模拟实验结果相匹配。此外,该模型适应不同脊椎动物的杆外段的不同几何形状。因此,它代表了视觉转导预测模型的一个组成部分。
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Mathematical and computational modelling of spatio-temporal signalling in rod phototransduction.

Rod photoreceptors are activated by light through activation of a cascade that includes the G protein-coupled receptor rhodopsin, the G protein transducin, its effector cyclic guanosine monophosphate (cGMP) phosphodiesterase and the second messengers cGMP and Ca2+. Signalling is localised to the particular rod outer segment disc, which is activated by absorption of a single photon. Modelling of this cascade has previously been performed mostly by assumption of a well-stirred cytoplasm. We recently published the first fully spatially resolved model that captures the local nature of light activation. The model reduces the complex geometry of the cell to a simpler one using the mathematical theories of homogenisation and concentrated capacity. The model shows that, upon activation of a single rhodopsin, changes of the second messengers cGMP and Ca2+ are local about the particular activated disc. In the current work, the homogenised model is computationally compared with the full, non-homogenised one, set in the original geometry of the rod outer segment. It is found to have an accuracy of 0.03% compared with the full model in computing the integral response and a 5200-fold reduction in computation time. The model can reconstruct the radial time-profiles of cGMP and Ca2+ in the interdiscal spaces adjacent to the activated discs. Cellular electrical responses are localised near the activation sites, and multiple photons sufficiently far apart produce essentially independent responses. This leads to a computational analysis of the notion and estimate of 'spread' and the optimum distribution of activated sites that maximises the response. Biological insights arising from the spatio-temporal model include a quantification of how variability in the response to dim light is affected by the distance between the outer segment discs capturing photons. The model is thus a simulation tool for biologists to predict the effect of various factors influencing the timing, spread and control mechanisms of this G protein-coupled, receptor-mediated cascade. It permits ease of simulation experiments across a range of conditions, for example, clamping the concentration of calcium, with results matching analogous experimental results. In addition, the model accommodates differing geometries of rod outer segments from different vertebrate species. Thus it represents a building block towards a predictive model of visual transduction.

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