细胞内pH值对完整的小鼠肌肉单纤维收缩功能的影响随温度升高而下降。
The effect of intracellular pH on contractile function of intact, single fibres of mouse muscle declines with increasing temperature.
作者信息
Westerblad H, Bruton J D, Lännergren J
机构信息
Department of Physiology and Pharmacology, Karolinska Institutet, Stockholm, Sweden.
出版信息
J Physiol. 1997 Apr 1;500 ( Pt 1)(Pt 1):193-204. doi: 10.1113/jphysiol.1997.sp022009.
Abstract
- The effect of altered intracellular pH (pHi) on isometric contractions and shortening velocity at 12, 22 and 32 degrees C was studied in intact, single fibres of mouse skeletal muscle. Changes in pHi were obtained by exposing fibres to solutions with different CO2 concentrations. 2. Under control conditions (5% CO2), pHi (measured with carboxy SNARF-1) was about 0.3 pH units more alkaline than neutral water at each temperature. An acidification of about 0.5 pH units was produced by 30% CO2 and an alkalinization of similar size by 0% CO2. 3. In acidified fibres tetanic force was reduced by 28% at 12 degrees C but only by 10% at 32 degrees C. The force increase with alkalinization showed a similar reduction with increasing temperature. Acidification caused a marked slowing of relaxation and this slowing became less with increasing temperature. 4. Acidification reduced the maximum shortening velocity (V0) by almost 20% at 12 degrees C, but had no significant effect at 32 degrees C. Alkalinization had no significant effect on V0 at any temperature. 5. In conclusion, the effect of pHi on contraction of mammalian muscle declines markedly with increasing temperature. Thus, the direct inhibition of force production by acidification is not a major factor in muscle fatigue at physiological temperatures.
摘要
- 研究了细胞内pH值(pHi)改变对小鼠骨骼肌完整单纤维在12、22和32摄氏度下等长收缩和缩短速度的影响。通过将纤维暴露于不同二氧化碳浓度的溶液中来改变pHi。2. 在对照条件下(5%二氧化碳),在每个温度下,用羧基SNARF-1测量的pHi比中性水的pH值约高0.3个单位。30%二氧化碳导致约0.5个pH单位的酸化,0%二氧化碳导致类似程度的碱化。3. 在酸化纤维中,强直收缩力在12摄氏度时降低了28%,但在32摄氏度时仅降低了10%。随着碱化导致的力增加也随着温度升高而有类似程度的降低。酸化导致舒张明显减慢,且这种减慢随着温度升高而减轻。4. 酸化在12摄氏度时使最大缩短速度(V0)降低了近20%,但在32摄氏度时没有显著影响。碱化在任何温度下对V0都没有显著影响。5. 总之,pHi对哺乳动物肌肉收缩的影响随着温度升高而显著下降。因此,在生理温度下,酸化对力产生的直接抑制不是肌肉疲劳的主要因素。
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