Effect of deuterium oxide on contraction characteristics and ATPase activity in glycerinated single rabbit skeletal muscle fibers

IF 2.7 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Biochimica et Biophysica Acta-Bioenergetics Pub Date : 2004-11-04 DOI:10.1016/j.bbabio.2004.07.008

Takakazu Kobayashi , Yasutake Saeki , Shigeru Chaen , Ibuki Shirakawa , Haruo Sugi

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Abstract

We studied the effect of deuterium oxide (D₂O) on contraction characteristics and ATPase activity of single glycerinated muscle fibers of rabbit psoas. D₂O increased the maximum isometric force P₀ by about 20%, while the force versus stiffness relation did not change appreciably. The maximum shortening velocity under zero load V_max did not change appreciably in D₂O, so that the force-velocity (P–V) curve was scaled depending on the value of P₀. The Mg-ATPase activity of the fibers during generation of steady isometric force P₀ was reduced by about 50% in D₂O. Based on the Huxley contraction model, these results can be accounted for in terms of D₂O-induced changes in the rate constants f₁ and g₁ for making and breaking actin–myosin linkages in the isometric condition, in such a way that f₁/(f₁+g₁) increases by about 20%, while (f₁+g₁) remains unchanged. The D₂O effect at the molecular level is discussed in connection with biochemical studies on actomyosin ATPase.

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氧化氘对甘油单根兔骨骼肌纤维收缩特性和atp酶活性的影响

研究了氧化氘（D2O）对兔腰肌单甘油肌纤维收缩特性和atp酶活性的影响。D2O使最大等距力P0提高了约20%，而力与刚度的关系没有明显变化。零载荷下最大缩短速度Vmax在D2O中没有明显变化，因此力-速度（P-V）曲线根据P0的值进行缩放。在D2O中，纤维在产生稳态等距力P0时的mg - atp酶活性降低了约50%。根据赫胥黎收缩模型，这些结果可以用d2o诱导的等长条件下肌动蛋白-肌球蛋白键的形成和破坏速率常数f1和g1的变化来解释，f1/(f1+g1)增加了约20%，而（f1+g1）保持不变。结合肌动球蛋白atp酶的生化研究，讨论了D2O在分子水平上的作用。

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来源期刊

Biochimica et Biophysica Acta-Bioenergetics 生物-生化与分子生物学

CiteScore

9.50

自引率

7.00%

发文量

363

审稿时长

92 days

期刊介绍： BBA Bioenergetics covers the area of biological membranes involved in energy transfer and conversion. In particular, it focuses on the structures obtained by X-ray crystallography and other approaches, and molecular mechanisms of the components of photosynthesis, mitochondrial and bacterial respiration, oxidative phosphorylation, motility and transport. It spans applications of structural biology, molecular modeling, spectroscopy and biophysics in these systems, through bioenergetic aspects of mitochondrial biology including biomedicine aspects of energy metabolism in mitochondrial disorders, neurodegenerative diseases like Parkinson''s and Alzheimer''s, aging, diabetes and even cancer.