Department of Ophthalmology, Northwestern University, Chicago, Illinois 60611, USA.
J Neurosci. 2011 Jul 27;31(30):11003-15. doi: 10.1523/JNEUROSCI.2631-11.2011.
The gain of signaling in primary sensory circuits is matched to the stimulus intensity by the process of adaptation. Retinal neural circuits adapt to visual scene statistics, including the mean (background adaptation) and the temporal variance (contrast adaptation) of the light stimulus. The intrinsic properties of retinal bipolar cells and synapses contribute to background and contrast adaptation, but it is unclear whether both forms of adaptation depend on the same cellular mechanisms. Studies of bipolar cell synapses identified synaptic mechanisms of gain control, but the relevance of these mechanisms to visual processing is uncertain because of the historical focus on fast, phasic transmission rather than the tonic transmission evoked by ambient light. Here, we studied use-dependent regulation of bipolar cell synaptic transmission evoked by small, ongoing modulations of membrane potential (V(M)) in the physiological range. We made paired whole-cell recordings from rod bipolar (RB) and AII amacrine cells in a mouse retinal slice preparation. Quasi-white noise voltage commands modulated RB V(M) and evoked EPSCs in the AII. We mimicked changes in background luminance or contrast, respectively, by depolarizing the V(M) or increasing its variance. A linear systems analysis of synaptic transmission showed that increasing either the mean or the variance of the presynaptic V(M) reduced gain. Further electrophysiological and computational analyses demonstrated that adaptation to mean potential resulted from both Ca channel inactivation and vesicle depletion, whereas adaptation to variance resulted from vesicle depletion alone. Thus, background and contrast adaptation apparently depend in part on a common synaptic mechanism.
信号在初级感觉回路中的增益通过适应过程与刺激强度相匹配。视网膜神经回路适应视觉场景统计信息,包括光刺激的平均值(背景适应)和时间方差(对比适应)。视网膜双极细胞和突触的固有特性有助于背景和对比适应,但尚不清楚这两种形式的适应是否依赖于相同的细胞机制。双极细胞突触的研究确定了增益控制的突触机制,但由于历史上侧重于快速、相位传递而不是环境光诱发的紧张性传递,这些机制与视觉处理的相关性尚不确定。在这里,我们研究了在生理范围内对膜电位 (V(M)) 进行小的持续调制时,双极细胞突触传递的依赖使用的调节。我们在小鼠视网膜切片制备中从杆状双极 (RB) 和 AII 无长突细胞进行了配对全细胞记录。准白噪声电压命令调制 RB V(M) 并在 AII 中诱发 EPSC。我们通过去极化 V(M) 或增加其方差分别模拟背景亮度或对比度的变化。对突触传递的线性系统分析表明,增加 V(M) 的平均值或方差都会降低增益。进一步的电生理和计算分析表明,对平均势的适应既来自钙通道失活,也来自囊泡耗竭,而对方差的适应仅来自囊泡耗竭。因此,背景和对比适应显然部分依赖于共同的突触机制。