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青蛙骨骼肌的细胞外区室。

The extracellular compartments of frog skeletal muscle.

作者信息

Neville M C, Mathias R T

出版信息

J Physiol. 1979 Mar;288:45-70.

PMID:313982
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1281414/
Abstract
  1. Detailed studies of solute efflux from frog sartorius muscle and single muscle fibres were carried out in order to characterize a 'special region' (Harris, 1963) in the extracellular space of muscle and determine whether this 'special region' is the sarcoplasmic reticulum. 2. The efflux of radioactive Na, Cl, glusose, 3-O-methylglucose, xylose, glycine, leucine, cycloleucine, Rb, K, inulin (mol. wt. 5000) and dextran (mol. wt. 17,000) from previously loaded muscles was studied. In all cases except dextran the curve had three components, a rapid (A) component which could be equated with efflux from the extracellular space proper, a slow (C) component representing cellular solute and an intermediate (B) component. The distribution space for the B component was 8% of muscle volume in summer frogs and 12% in winter frogs and appeared to be equal for all compounds studied. We tested the hypothesis that the B component originated from the sarcoplasmic reticulum. 3. The C component was missing from the dextran curves. Both dextran and inulin entered the compartment of origin of the B component (compartment B) to the same extent as small molecules. 4. For all compounds studies, the efflux rate constant for the A component could be predicted from the diffusion coefficient. For the B component the efflux rate constant was 6--10 times slower than that for the A component but was still proportional to the diffusion coefficient for the solute in question. 5. When Na and sucrose efflux from single fibres was followed, a B component was usually observed. The average distribution space for this component was small, averaging 1.5% of fibre volume. There was no difference between the average efflux rate constants for Na and sucrose. 6. In an appendix, the constraints placed on the properties of a hypothetical channel between the sarcoplasmic reticulum and the T-system by the linear electrical parameters of frog skeletal muscle are derived. It is shown that the conductance of such a channel must be less than 0.06 x 10(-3) mohs/cm2 of fibre membrane. 7. The conductance between compartment B and the extracellular space can be calculated from the efflux rate constants for Na, K and Cl. The value obtained was 5 x 10(-3) mhos/cm2 of fibre membrane or 100 times the limiting value for the conductance of the T-SR junction. 8. The finding that there is a B component in the efflux curves for large molecular weight substances like inulin and dextran and the small size of the B component in efflux curves from single muscle fibres indicate that the 'speical region' of the extra-cellular space of frog muscle is not the sarcoplasmic reticulum. This conclusion is confirmed by a calculation of the conductance between the B compartment and the extracellular space. The value obtained is incompatible with predicted electrical properteis of the SR-T-tubule junction...
摘要
  1. 为了对肌肉细胞外空间中的一个“特殊区域”(哈里斯,1963年)进行表征,并确定这个“特殊区域”是否为肌浆网,我们对蛙缝匠肌和单根肌纤维中的溶质外流进行了详细研究。2. 研究了放射性钠、氯、葡萄糖、3 - O - 甲基葡萄糖、木糖、甘氨酸、亮氨酸、环亮氨酸、铷、钾、菊粉(分子量5000)和右旋糖酐(分子量17000)从预先加载的肌肉中的外流情况。除了右旋糖酐外,在所有情况下曲线都有三个成分,一个快速(A)成分,可等同于从细胞外空间本身的外流;一个缓慢(C)成分,代表细胞溶质;以及一个中间(B)成分。B成分的分布空间在夏季青蛙中为肌肉体积的8%,在冬季青蛙中为12%,并且对于所研究的所有化合物似乎是相等的。我们检验了B成分起源于肌浆网的假设。3. 右旋糖酐曲线中没有C成分。右旋糖酐和菊粉进入B成分起源的隔室(B隔室)的程度与小分子相同。4. 对于所有研究的化合物,A成分的外流速率常数可以根据扩散系数预测。对于B成分,外流速率常数比A成分慢6 - 10倍,但仍然与所讨论溶质的扩散系数成比例。5. 当跟踪单根纤维中钠和蔗糖的外流时,通常会观察到一个B成分。该成分的平均分布空间很小,平均为纤维体积的1.5%。钠和蔗糖的平均外流速率常数之间没有差异。6. 在附录中,推导了蛙骨骼肌的线性电学参数对肌浆网和T系统之间假设通道性质的限制。结果表明,这种通道的电导必须小于0.06×10⁻³毫西门子/平方厘米的纤维膜。7. B隔室与细胞外空间之间的电导可以根据钠、钾和氯的外流速率常数计算得出。得到的值为5×10⁻³毫西门子/平方厘米的纤维膜,是T - SR连接电导极限值的100倍。8. 在菊粉和右旋糖酐等大分子物质的外流曲线中存在B成分,以及单根肌纤维外流曲线中B成分较小的发现表明,蛙肌肉细胞外空间的“特殊区域”不是肌浆网。通过计算B隔室与细胞外空间之间的电导,这一结论得到了证实。得到的值与SR - T小管连接的预测电学性质不相符……

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本文引用的文献

1
Volume of interfibre spaces in frog muscle and the calculation of concentrations in the fibre water.青蛙肌肉中肌纤维间隙的体积以及纤维内水分浓度的计算
J Physiol. 1941 Jun 30;99(4):401-14. doi: 10.1113/jphysiol.1941.sp003911.
2
Kinetics of release of radioactive sodium, sulfate and sucrose from the frog sartorius muscle.青蛙缝匠肌中放射性钠、硫酸盐和蔗糖的释放动力学。
Am J Physiol. 1955 May;181(2):263-8. doi: 10.1152/ajplegacy.1955.181.2.263.
3
INFLUENCE OF OSMOTIC STRENGTH ON CROSS-SECTION AND VOLUME OF ISOLATED SINGLE MUSCLE FIBRES.渗透压对离体单根肌纤维横截面积和体积的影响
J Physiol. 1965 Mar;177(1):42-57. doi: 10.1113/jphysiol.1965.sp007574.
4
THE SPACE ACCESSIBLE TO ALBUMIN WITHIN THE STRIATED MUSCLE FIBRE OF THE TOAD.蟾蜍横纹肌纤维内白蛋白可及的空间。
J Physiol. 1964 Dec;175(2):275-94. doi: 10.1113/jphysiol.1964.sp007517.
5
THE OSMOTIC PROPERTIES OF STRIATED MUSCLE FIBERS IN HYPERTONIC SOLUTIONS.高渗溶液中横纹肌纤维的渗透特性
J Physiol. 1963 Nov;169(2):312-29. doi: 10.1113/jphysiol.1963.sp007258.
6
Distribution and movement of muscle chloride.肌肉中氯离子的分布与移动
J Physiol. 1963 Apr;166(1):87-109. doi: 10.1113/jphysiol.1963.sp007092.
7
Studies of tissue permeability. IX. The effect of insulin on the penetration of 3-methylglucose-H3 in frog muscle.组织通透性研究。IX. 胰岛素对3-甲基葡萄糖-H3在蛙肌中渗透的影响。
J Biol Chem. 1963 Jan;238:40-9.
8
The dimensions of the extracellular space in sartorius muscle.缝匠肌细胞外空间的维度。
J Gen Physiol. 1959 Sep;43(1):39-53. doi: 10.1085/jgp.43.1.39.
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Internal chloride concentration and chloride efflux of frog muscle.青蛙肌肉的细胞内氯离子浓度及氯离子外流
J Physiol. 1961 May;156(3):623-32. doi: 10.1113/jphysiol.1961.sp006698.
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J Physiol. 1959 Mar 3;145(2):405-32. doi: 10.1113/jphysiol.1959.sp006150.