原位发育的小鼠骨骼肌中对地理毒素敏感和不敏感的钠电流。

Geographutoxin-sensitive and insensitive sodium currents in mouse skeletal muscle developing in situ.

作者信息

Gonoi T, Hagihara Y, Kobayashi J, Nakamura H, Ohizumi Y

机构信息

Division of Developmental Biology, School of Medicine, Chiba University, Japan.

出版信息

J Physiol. 1989 Jul;414:159-77. doi: 10.1113/jphysiol.1989.sp017682.

DOI:10.1113/jphysiol.1989.sp017682

PMID:2607429

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1189136/

Abstract

The whole-cell voltage-clamp technique was used to examine developmental changes of Na+ current properties in single fibres of mouse flexor digitorum brevis muscles developing in situ from birth to 20 days post-natal. 2. Geographutoxin II (GTX II), a novel polypeptide toxin from the marine snail Conus geographus, distinguished two different types of voltage-sensitive Na+ currents: GTX II-sensitive and GTX II-insensitive currents, which corresponded respectively to currents with high or low TTX sensitivity. 3. Voltage-dependent activation and inactivation of the GTX II-insensitive currents occurred at membrane potentials 10-20 mV more negative than those for the GTX II-sensitive currents. 4. The GTX II-insensitive current in fibres from mice older than 8 days inactivated more slowly than the GTX II-sensitive current. However, in fibres from younger mice, the two currents decayed with similar speed. 5. The mean specific Na+ conductance (gNa) for the total (GTX II-sensitive plus GTX II-insensitive) Na+ channels was 0.22 mS/muF at a Na+ concentration of 5 mM at birth. The total gNa increased 6-fold to 1.32 mS/muF during the first 20 days after birth. 6. The mean specific gNa for the GTX II-insensitive channels was 0.15 mS/muF at birth, remained at approximately the same level for the first 8 days, and then decreased progressively to become undetectable by day 16. 7. In muscle fibres denervated 12 days after birth, the GTX II-insensitive gNa increased over the next 8 days, whereas the total gNa increased less than normal. 8. By contrast, in fibres denervated on day 4, the total gNa increased more than normal in the following 8 days, and the GTX II-insensitive specific gNa increased above the level seen at birth. 9. Half-maximal activation and inactivation potentials of the total and the GTX II-insensitive currents shifted in the negative direction by 9-17 mV in the first 8 days after birth. 10. We conclude that the regulatory effects of innervation on the total gNa are either suppressive or enhancing depending on the stage of development. On the other hand, denervation elicits an increase in GTX II-insensitive Na+ currents at all ages studied.

摘要

采用全细胞电压钳技术，研究了出生至出生后20天在原位发育的小鼠趾短屈肌单纤维中Na⁺电流特性的发育变化。2. 地理蛤毒素II（GTX II）是一种来自海蜗牛地纹芋螺的新型多肽毒素，可区分两种不同类型的电压敏感性Na⁺电流：GTX II敏感电流和GTX II不敏感电流，它们分别对应于对TTX高敏感性或低敏感性的电流。3. GTX II不敏感电流的电压依赖性激活和失活发生在比GTX II敏感电流负10 - 20 mV的膜电位。4. 出生8天以上小鼠纤维中的GTX II不敏感电流比GTX II敏感电流失活更慢。然而，在幼龄小鼠的纤维中，两种电流以相似的速度衰减。5. 在出生时Na⁺浓度为5 mM时，总（GTX II敏感加GTX II不敏感）Na⁺通道的平均比Na⁺电导（gNa）为0.22 mS/μF。出生后的前20天内，总gNa增加了6倍，达到1.32 mS/μF。6. GTX II不敏感通道的平均比gNa在出生时为0.15 mS/μF，在出生后的前8天保持在大致相同水平，然后逐渐下降，到第16天时变得无法检测到。7. 在出生后12天去神经支配的肌纤维中，GTX II不敏感gNa在接下来的8天内增加，而总gNa的增加少于正常情况。8. 相比之下，在出生第4天去神经支配的纤维中，总gNa在接下来的8天内增加超过正常水平，且GTX II不敏感比gNa增加到高于出生时的水平。9. 总电流和GTX II不敏感电流的半数最大激活和失活电位在出生后的前8天内向负方向移动了9 - 17 mV。10. 我们得出结论，神经支配对总gNa的调节作用根据发育阶段要么是抑制性的要么是增强性的。另一方面，去神经支配在所有研究的年龄段都会引起GTX II不敏感Na⁺电流增加。