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部分失神经支配的哺乳动物肌肉中神经肌肉突触的发芽与消退

Sprouting and regression of neuromuscular synapses in partially denervated mammalian muscles.

作者信息

Brown M C, Ironton R

出版信息

J Physiol. 1978 May;278:325-48. doi: 10.1113/jphysiol.1978.sp012307.

DOI:10.1113/jphysiol.1978.sp012307
PMID:671308
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1282352/
Abstract
  1. The capacity of motor units to sprout after partial denervation and the ability of regenerating axons to suppress newly formed sprouts was examined in mouse skeletal muscle. Most experiments were performed on the peroneus tertius muscle which has 300 muscle fibres and eleven motor units ranging in strength from 1 to 35% of the total muscle tension. 2. Individual units, regardless of starting size, were able to sprout by up to 5 times their normal size following interruption of one of the two spinal roots innervating the muscle. In practive this resulted in muscles which had three or more units left intact becoming completely innervated again within 12 days. The majority of the sprouts probably innervated the old denervated end-plate sites. In the absence of re-innervation by the severed motor axons the sprouts persisted. In peroneus tertius about 60% of the sprouts giving rise to end-plates arose terminally and 40% collaterally. In soleus almost all the sprouts were terminal. 3. Re-innervation of the muscle by the severed motor axons occurred, starting from 14 days onwards after a crush injury, 19 days onwards after a cut. Re-innervation occurred even in muscles which presumably had no remaining denervated muscle fibres at the time regenerating axons reached the muscle. The re-innervating fibres grew to the original end-plate sites. 4. Following re-innervation the size of sprouted motor units apparently decreased. Thus, after re-innervation of muscles with three or more sprouted motor units, the sprouted units no longer caused contraction of all the muscle. However, the normal state of the muscle was not restored and the sprouted units continued to innervate more muscle fibres than normal, returning axons less than normal, and a small percentage of muscle fibres (ca. 10%) remained functionally innervated by axons of both sorts. 5. It is concluded that (i) in the mouse, axonal sprouting is a rapid and efficient process for restoring innervation; (ii) re-innervation of already innervated fibres can occur if the regenerating axons can return to existing end-plate sites; (iii) some of the redundant innervation is removed or repressed. 6. Possible mechanisms of competition between axon terminals are considered.
摘要
  1. 在小鼠骨骼肌中研究了运动单位在部分去神经支配后发芽的能力以及再生轴突抑制新形成芽的能力。大多数实验在第三腓骨肌上进行,该肌肉有300条肌纤维和11个运动单位,其强度范围为总肌肉张力的1%至35%。2. 无论起始大小如何,单个运动单位在支配该肌肉的两条脊神经根之一被切断后,能够发芽至其正常大小的5倍。实际上,这导致有三个或更多完整运动单位的肌肉在12天内再次完全被神经支配。大多数芽可能支配了原来去神经支配的终板部位。在切断的运动轴突没有重新支配的情况下,芽持续存在。在第三腓骨肌中,约60%形成终板的芽是末端芽,40%是侧支芽。在比目鱼肌中,几乎所有的芽都是末端芽。3. 切断的运动轴突从挤压伤后14天开始、切割伤后19天开始对肌肉进行重新支配。即使在再生轴突到达肌肉时可能没有剩余去神经支配肌纤维的肌肉中也会发生重新支配。重新支配的纤维生长到原来的终板部位。4. 重新支配后,发芽的运动单位大小明显减小。因此,在用三个或更多发芽运动单位对肌肉进行重新支配后,发芽的运动单位不再引起整块肌肉收缩。然而,肌肉的正常状态并未恢复,发芽的运动单位继续支配比正常更多的肌纤维,返回的轴突比正常少,并且一小部分肌纤维(约10%)仍然由两种类型的轴突进行功能性支配。5. 得出的结论是:(i)在小鼠中,轴突发芽是恢复神经支配的快速且有效的过程;(ii)如果再生轴突能够回到现有的终板部位,已经被神经支配的纤维可以发生重新支配;(iii)一些多余的神经支配被去除或受到抑制。6. 考虑了轴突终末之间竞争的可能机制。
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