海龟视网膜中杆状合胞体的电学特性。
Electrical properties of the rod syncytium in the retina of the turtle.
作者信息
Schwartz E A
出版信息
J Physiol. 1976 May;257(2):379-406. doi: 10.1113/jphysiol.1976.sp011374.
Abstract
- Intracellular responses were recorded from rods in isolated eye-cups of the snapping turtle. Chelydra serpentina. Responses to flashes of small (less than 100 mum diameter) and large (1000 mum diameter) spots of 500 nm light were studied. 2. Responses produced by small and large diameter spots which delivered less than 0-3 photons mum-2 had the same shape. The responses produced by large spots were, however, nearly ten times greater in amplitude. The difference in amplitude is termed enhancement. 3. Perfusing an eye-cup with a Co2+-containing medium blocked synaptic transmission from receptors to horizontal cells but did not affect the responses of rods. 4. The membrane conductance of a single rod, estimated by three independent methods, was approximately 1-2 X 10(-9) MHo. 5. Enhancement can be predicted by a mathematical model which treats rods as an electrical syncytium. The space coefficient describing the spread of current is approximately 65 mum indicating that the coupling conductance between rods was relatively high. 6. When the intensity of a small spot was increased from 0-3 photons mum-2 up to 6 photons mum-2, the shape of the response was unchanged. When the intensity of a large spot was increased to more than 0-3 photons mum-2, the voltage during the recovery phase was decreased. This decrease is termed disenhancement. 7. The voltages produced by bright, large and small diameter spots which delivered the same quantity of light to the impaled rod were compared. The voltage produced by a large diameter spot became for a short period during the recovery phase less than the voltage produced by a small diameter spot. This observation indicates that the response to a large spot included during recovery an active process which is not apparent in the response to a small spot.
摘要
- 在鳄龟(Chelydra serpentina)分离的眼杯中记录视杆细胞的细胞内反应。研究了视杆细胞对直径为500纳米的小光斑(直径小于100微米)和大光斑(直径1000微米)闪光的反应。2. 直径小于0 - 3个光子/微米²的小光斑和大光斑产生的反应具有相同的形状。然而,大光斑产生的反应幅度几乎大十倍。这种幅度差异被称为增强。3. 用含Co²⁺的介质灌注眼杯可阻断从受体到水平细胞的突触传递,但不影响视杆细胞的反应。4. 通过三种独立方法估计,单个视杆细胞的膜电导约为1 - 2×10⁻⁹姆欧。5. 增强可以通过一个将视杆细胞视为电合体的数学模型来预测。描述电流传播的空间系数约为65微米,这表明视杆细胞之间的耦合电导相对较高。6. 当小光斑的强度从0 - 3个光子/微米²增加到6个光子/微米²时,反应形状不变。当大光斑的强度增加到超过0 - 3个光子/微米²时,恢复阶段的电压降低。这种降低被称为去增强。7. 比较了向刺入的视杆细胞传递相同光量的明亮、大直径和小直径光斑产生的电压。在恢复阶段的短时间内,大直径光斑产生的电压变得小于小直径光斑产生的电压。这一观察结果表明,对大光斑的反应在恢复过程中包括一个在对小光斑的反应中不明显的活跃过程。
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