Fraser J A, Skepper J N, Hockaday A R, Huang C L
Physiological Laboratory, University of Cambridge, UK.
J Muscle Res Cell Motil. 1998 Aug;19(6):613-29. doi: 10.1023/a:1005325013355.
The exposure of amphibian muscle to osmotic shock through the introduction and subsequent withdrawal of extracellular glycerol causes 'vacuolation' in the transverse tubules. Such manoeuvres can also electrically isolate the transverse tubules from the surface ('detubulation'), particular if followed by exposures to high extracellular [Ca2+] and/or gradual cooling. This study explored factors influencing vacuolation in Rana temporaria sartorius muscle. Vacuole formation was detected using phase contrast microscopy and through the trapping or otherwise of lissamine rhodamine dye fluorescence within such vacuoles. The preparations were also examined using electron microscopy, for penetration into the transverse tubules and tubular vacuoles of extracellular horseradish peroxidase introduced following the osmotic procedures. These comparisons distinguished for he first time two types of vacuole, 'open' and 'closed', whose lumina were respectively continuous with or detached from the remaining extracellular space. The vacuoles formed closed to and between the Z-lines, but subsequently elongated along the longitudinal axis of the muscle fibres. This suggested an involvement of tubular membrane material; the latter appeared particularly concentrated around such Z-lines in the electron-micrograph stereopairs of thick longitudinal sections. 'Open' vacuoles formed following osmotic shock produced by extracellular glycerol withdrawal from a glycerol-loaded fibre at a stage when one would expect a net water entry to the intracellular space. This suggests that vacuole formation requires active fluid transport into the tubular lumina in response to fibre swelling. 'Closed' vacuoles only formed when the muscle was subsequently exposed to high extracellular [Ca/+] and/or gradual cooling following the initial osmotic shock. Their densities were similar to those shown by 'open' vacuoles in preparations not so treated, suggesting that both vacuole types resulted from a single process initiated by glycerol withdrawal. However, vacuole 'closure' took place well after formation of 'open' vacuoles, over 25 min after glycerol withdrawal. Its time course closely paralleled the development of detubulation reported recently. It was irreversible, in contrast to the reversibility of 'open' vacuole formation. These findings identify electrophysiological 'detubulation' of striated muscle with 'closure' of initially 'open' vacuoles. The reversible formation of open vacuoles is compatible with some normal membrane responses to some physiological stresses such as fatigue, whereas irreversible formation of closed vacuoles might only be expected in pathological situations as in dystrophic muscle.
通过引入并随后去除细胞外甘油,使两栖动物肌肉遭受渗透压休克,会导致横管出现“空泡化”。这样的操作还能使横管与表面发生电隔离(“脱管化”),特别是在随后暴露于高细胞外[Ca2+]和/或逐渐冷却的情况下。本研究探讨了影响林蛙缝匠肌空泡化的因素。使用相差显微镜并通过利萨明罗丹明染料荧光在这些空泡内的捕获情况等来检测空泡形成。还使用电子显微镜检查标本,以观察在渗透压操作后引入的细胞外辣根过氧化物酶渗透到横管和管状空泡中的情况。这些比较首次区分了两种类型的空泡,即“开放型”和“封闭型”,它们的腔分别与其余细胞外空间连续或分离。空泡在Z线附近和之间形成,但随后沿肌纤维的纵轴伸长。这表明管状膜材料参与其中;在厚纵切片的电子显微镜立体对中,后者似乎特别集中在这些Z线周围。由从加载甘油的纤维中去除细胞外甘油所产生的渗透压休克后形成的“开放型”空泡,是在预期有净水流进入细胞内空间的阶段形成的。这表明空泡形成需要响应纤维肿胀而进行主动的液体运输进入管状腔。“封闭型”空泡仅在肌肉在初始渗透压休克后随后暴露于高细胞外[Ca2+]和/或逐渐冷却时形成。它们的密度与未进行此类处理的标本中“开放型”空泡的密度相似,这表明两种空泡类型均由甘油去除引发的单一过程导致。然而,空泡“封闭”发生在“开放型”空泡形成之后很久,在甘油去除后超过25分钟。其时间进程与最近报道的脱管化发展密切平行。与“开放型”空泡形成的可逆性相反,它是不可逆的。这些发现确定了横纹肌的电生理“脱管化”与最初“开放型”空泡的“封闭”相关。开放型空泡的可逆形成与一些正常膜对诸如疲劳等生理应激的反应相符,而封闭型空泡的不可逆形成可能仅在诸如营养不良性肌肉等病理情况下出现。
