Nixon R A
Brain Res. 1980 Oct 27;200(1):69-83. doi: 10.1016/0006-8993(80)91095-1.
The analysis of proteolysis in the nervous system is complicated by the heterogeneity of cell types, extensive reutilization of liberated amino acids, and artifacts that may arise when the integrity of the tissue is disrupted during experimentation. For these reasons, changes in proteolytic activity that are observed during brain development and in neuropathological states may often be difficult to interpret. To minimize these problems, we have developed a technique that permits protein degradation to be investigated specifically within axons of the mouse retinal ganglion cells (RGC). In the present study, the method has been used to examine the degradation of proteins conveyed in the slow phases of axoplasmic transport. When adult C57Bl/6J mice were injected intravitreally with L-[3H]proline, labeled proteins within the primary optic pathway (optic nerve and tract) after 5 days were almost exclusively the slow phase axonal proteins. The rate of degradation of these proteins was then determined within the excised, but otherwise intact, optic pathway by measuring the release of acid soluble radioactivity at 37 degrees C in vitro. At physiological pH, the amino acids released by proteolysis were extensively reutilized. Unless amino acid reutilization was prevented, protein degradative rates were artifactually lowered 3-fold. At least two proteolytic systems within RGC axons actively degraded the slowly transported axonal proteins. A 'neutral' system, stimulated by exogenous calcium ions, was optimally active within the physiological pH range (pH 7.0--7.8). The rate of protein degradation at pH 7.4 was uniform along the RGC axon. An 'acidic' system was optimally active with the incubation was carried out at pH 3.8. This proteolytic activity was calcium-independent and exhibited a proximodistal gradient within the RCG axon with higher activity proximally. Similar proteolytic activities were present in isolated intact retinas but in different proportions. The half-lives of axonal and retinal proteins were comparable to CNS protein half-lives estimated in vivo by methods that take amino acid reutilization into account. These and other recent findings demonstrate the utility of this neuron-specific approach in characterizing proteolytic processes within one cell type that may otherwise be obscured by proteolytic events in other cells when brain tissue is analyzed by conventional methods.
神经系统中蛋白质水解的分析因细胞类型的异质性、释放氨基酸的广泛再利用以及实验过程中组织完整性被破坏时可能出现的假象而变得复杂。由于这些原因,在大脑发育和神经病理状态下观察到的蛋白水解活性变化往往难以解释。为了尽量减少这些问题,我们开发了一种技术,该技术可以专门研究小鼠视网膜神经节细胞(RGC)轴突内的蛋白质降解。在本研究中,该方法已被用于检测轴浆运输慢相中转运的蛋白质的降解情况。当成年C57Bl/6J小鼠经玻璃体注射L-[3H]脯氨酸后,5天后初级视路(视神经和视束)内的标记蛋白几乎全部是慢相轴突蛋白。然后,通过在37℃体外测量酸溶性放射性物质的释放,在切除但其他方面完整的视路内测定这些蛋白质的降解速率。在生理pH值下,蛋白水解释放的氨基酸被广泛再利用。除非防止氨基酸再利用,否则蛋白质降解速率会被人为降低3倍。RGC轴突内至少有两个蛋白水解系统积极地降解缓慢运输的轴突蛋白。一个由外源钙离子刺激的“中性”系统在生理pH范围(pH 7.0 - 7.8)内活性最佳。在pH 7.4时,蛋白质降解速率沿RGC轴突是均匀的。一个“酸性”系统在pH 3.8孵育时活性最佳。这种蛋白水解活性不依赖钙离子,并且在RCG轴突内呈现近端到远端的梯度,近端活性更高。在分离的完整视网膜中也存在类似的蛋白水解活性,但比例不同。轴突蛋白和视网膜蛋白的半衰期与通过考虑氨基酸再利用的体内方法估计的中枢神经系统蛋白半衰期相当。这些以及其他最近的发现证明了这种神经元特异性方法在表征一种细胞类型内的蛋白水解过程中的实用性,否则当通过传统方法分析脑组织时,其他细胞中的蛋白水解事件可能会掩盖这些过程中的蛋白水解过程。
