在雪貂心室肌长度改变后,其去表皮肌浆中的钙浓度。
Calcium concentration in the myoplasm of skinned ferret ventricular muscle following changes in muscle length.
作者信息
Allen D G, Kentish J C
机构信息
Department of Physiology, University College London.
出版信息
J Physiol. 1988 Dec;407:489-503. doi: 10.1113/jphysiol.1988.sp017427.
Abstract
- Ferret ventricular muscles were skinned by prolonged application of Triton X-100. Aequorin was allowed to diffuse into the myoplasmic space and the resulting light emission was used to monitor the myoplasmic [Ca2+]. The muscle was then activated with a lightly buffered Ca2+ solution and the changes in myoplasmic [Ca2+] and tension in response to length changes were investigated. 2. A sudden reduction in muscle length led to a rapid increase in myoplasmic [Ca2+] to a new level which was maintained as long as muscle length was reduced and which was reversed when the muscle was stretched back to the control length. The rate of increase of [Ca2+] when the muscle length was reduced was greater than the rate of decrease in [Ca2+] when the muscle was stretched. 3. Increasing the concentration of EGTA in the activating solution, so as to increase its Ca2+-buffering capacity, eliminated the changes in myoplasmic [Ca2+] in response to a length change but had little effect on developed tension. 4. On stretching the muscle there was a slow component of recovery of tension with a time course broadly similar to the rate of decrease of myoplasmic [Ca2+]. The time course of tension redevelopment and of the accompanying reduction in myoplasmic [Ca2+] both decreased to a similar extent when the [Ca2+] used to activate the muscle was increased. 5. Step reductions of length of increasing amplitude caused increases in myoplasmic [Ca2+] which were larger in proportion to the size of the step. 6. Step reductions of length of equal size but from different starting lengths caused changes in myoplasmic [Ca2+] the amplitude of which correlated with the change in tension rather than the change in length. 7. The increase in myoplasmic [Ca2+] when muscle length is reduced suggests that Ca2+ is released from a site in the muscle, probably troponin C. The time course and magnitude of the changes in myoplasmic [Ca2+] correlate more closely with the changes in developed tension than muscle length.
摘要
- 通过长时间应用 Triton X - 100 对雪貂心室肌进行去膜处理。使水母发光蛋白扩散到肌浆空间,并利用产生的光发射来监测肌浆[Ca2+]。然后用轻度缓冲的 Ca2+溶液激活肌肉,并研究肌浆[Ca2+]和张力随长度变化的响应。2. 肌肉长度突然缩短导致肌浆[Ca2+]迅速增加到一个新水平,只要肌肉长度保持缩短状态,该水平就会维持,而当肌肉拉伸回到对照长度时,[Ca2+]会恢复。肌肉长度缩短时[Ca2+]的增加速率大于肌肉拉伸时[Ca2+]的降低速率。3. 增加激活溶液中乙二醇双四乙酸(EGTA)的浓度以提高其 Ca2+缓冲能力,消除了肌浆[Ca2+]随长度变化的改变,但对产生的张力影响很小。4. 拉伸肌肉时,张力恢复存在一个缓慢成分,其时程与肌浆[Ca2+]的降低速率大致相似。当用于激活肌肉的[Ca2+]增加时,张力重新发展的时程以及伴随的肌浆[Ca2+]降低均以相似程度减小。5. 幅度逐渐增大的长度阶跃性缩短导致肌浆[Ca2+]增加,且增加幅度与阶跃大小成比例。6. 大小相等但起始长度不同的长度阶跃性缩短导致肌浆[Ca2+]发生变化,其幅度与张力变化相关而非与长度变化相关。7. 肌肉长度缩短时肌浆[Ca2+]的增加表明 Ca2+从肌肉中的一个位点释放,可能是肌钙蛋白 C。肌浆[Ca2+]变化的时程和幅度与产生的张力变化比与肌肉长度变化更密切相关。
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