Lindquist T D, Inogoglia N A
Brain Res. 1979 Apr 20;166(1):95-112. doi: 10.1016/0006-8993(79)90652-8.
Studies in regenerating goldfish optic nerves indicate that RNA may be axonally transported during optic nerve regeneration14,18,19. The present study was performed to determine if the axonal migration of RNA could be demonstrated during regeneration of the rat sciatic nerve. Rats, which had only the left sciatic nerve crushed 10 days earlier, were injected bilaterally with [3H]uridine into the spinal cord at segmental levels L5 and L6, thus labeling ventral horn cells giving rise to the sciatic nerve. Six, 14 and 20 days later rats were sacrificed by cardiac perfusion of saline followed by 10% formaldehyde. Formaldehyde-precipitable radioactivity, identified as [3H]RNA, was 4--5 times greater in the regenerating sciatic nerve compared to the normal nerve and moved without impediment beyond the point of the crush into the regenerating portion of the nerve. The axonal migration of free unincorporated labeled RNA precursors was also demonstrated, raising the possibility that the distribution of [3H]RNA along the sciatic nerve might be entirely extra-axonal; i.e., free [3H]uridine is taken up by Schwann cells from the axon where it is incorporated into [3H]RNA. This interpretation of the data would also result in the appearance of a proximodistal distribution of RNA associated radioactivity. To determine whether any sciatic nerve [3H]RNA was due to axonal transport, rats which had only the left sciatic nerve crushed 10 days earlier were injected bilaterally with [3H]uridine into the spinal cord. Fourteen days after injection, rats were sacrificed and radioactivity present in the nerve was confirmed as RNA by SDS polyacrylamide gel electrophoresis. Radioactivity in the various RNA species 14 days after intraspinal injection showed the following distribution: 28 + 18S RNA--normal 39.3% +/- 2.1; regenerating 45.4% +/- 1.6; 4S RNA--normal 43.0% +/- 1.3; regenerating 46.8% +/- 2.7. Similar characterization of sciatic nerve RNA 1 or 3 days following the intravenous administration of [3H]uridine gave the following distribution: 28 + 18S RNA--normal 72.4% +/- 3.0; regenerating 75.0% +/- 3.6; 4S RNA--normal 7.7% +/- 1.3; regenerating 10.7% +/- 0.8. The intraspinal injection of [3H]uridine would label Schwann cell RNA and, in addition, any species of intra-axonal RNA, while intravenous injections would label Schwann cell RNA and not axonal RNA. If 4S RNA is in the axon, one would predict relatively more labeled 4S RNA following intraspinal injections than following intravenous injections. The data demonstrate an enrichment of 4S RNA in both normal and regenerating rat sciatic nerve following the intraspinal but not following the intravenous injection of labeled precursor. Therefore, we suggest that 4S RNA migrates axonally in both normal and regenerating sciatic nerves of rats.
对再生金鱼视神经的研究表明,在视神经再生过程中RNA可能会进行轴突运输14,18,19。本研究旨在确定在大鼠坐骨神经再生过程中是否能证实RNA的轴突迁移。仅在10天前左侧坐骨神经被挤压的大鼠,在L5和L6节段水平双侧脊髓内注射[3H]尿苷,从而标记发出坐骨神经的腹角细胞。6天、14天和20天后,通过心脏灌注生理盐水然后灌注10%甲醛处死大鼠。被鉴定为[3H]RNA的甲醛沉淀放射性物质,在再生坐骨神经中比正常神经高4 - 5倍,并且不受阻碍地越过挤压点进入神经的再生部分。游离未掺入的标记RNA前体的轴突迁移也得到了证实,这增加了[3H]RNA沿坐骨神经的分布可能完全在轴突外的可能性;即游离的[3H]尿苷被雪旺细胞从轴突摄取,在那里它被掺入[3H]RNA。对数据的这种解释也将导致RNA相关放射性出现近端到远端的分布。为了确定坐骨神经中的任何[3H]RNA是否归因于轴突运输,仅在10天前左侧坐骨神经被挤压的大鼠双侧脊髓内注射[3H]尿苷。注射14天后,处死大鼠,通过SDS聚丙烯酰胺凝胶电泳确认神经中存在的放射性物质为RNA。脊髓内注射后14天,各种RNA种类中的放射性显示出以下分布:28 + 18S RNA——正常为39.3% ± 2.1;再生为45.4% ± 1.6;4S RNA——正常为43.0% ± 1.3;再生为46.8% ± 2.7。静脉注射[3H]尿苷1天或3天后坐骨神经RNA的类似特征显示出以下分布:28 + 18S RNA——正常为72.4% ± 3.0;再生为75.0% ± 3.6;4S RNA——正常为7.7% ± 1.3;再生为10.7% ± 0.8。脊髓内注射[3H]尿苷会标记雪旺细胞RNA,此外还会标记任何种类的轴突内RNA,而静脉注射会标记雪旺细胞RNA而不是轴突RNA。如果4S RNA在轴突中,那么可以预测脊髓内注射后比静脉注射后有相对更多的标记4S RNA。数据表明,在脊髓内注射标记前体后,正常和再生大鼠坐骨神经中4S RNA都有富集,而静脉注射后则没有。因此,我们认为4S RNA在大鼠正常和再生坐骨神经中都进行轴突迁移。
