Korge P
Institute of Exercise Biology, Tartu University, Estonia.
Sports Med. 1995 Oct;20(4):215-25. doi: 10.2165/00007256-199520040-00002.
It is widely accepted that a structural organisation favouring interaction between functionally-related enzymes is required for the economy and efficiency of metabolic reactions. Many functionally-related enzymes have been shown to be reversibly bound to cellular structures and to other enzymes at the sites where they are required. Resulting from this binding, close structural proximity and concentration of enzymes, a microenvironment is generated where the product of one enzyme is the substrate of the other. This reduces the diffusion distance for the substrate, saturates binding sites with maximal speed and, as a final outcome, increases the efficiency and economy of function behind these metabolic reactions. Available data indicate that the above-described association between adenosine triphosphatase (ATPase) and enzymes regenerating ATP has an important role in the regulation of ATPase function. A general consensus exists among published studies that the concentration of ATP ([ATP]) is not significantly decreased in fatigued muscle, even in those with severely diminished power output. However, in studies with isolated perfused hearts it has been possible to significantly reduce [ATP] in muscle cells without compromising mechanical activity. An explanation for this discrepancy is connected with local ATP regeneration in the vicinity of ATPase. Furthermore, when ATP regeneration is unable to balance ATP consumption a critical drop in the free energy of ATP hydrolysis is avoided by down-regulation of ATP consumption. The main function of local ATP regeneration is to maintain a low concentration of adenosine diphosphate ([ADP]), and the ADP/ATP ratio in the vicinity of the ATP-binding site of ATPase that is a prerequisite for high thermodynamic efficiency of ATP hydrolysis. Close proximity of creatine kinase and glycolytic enzymes to ATPase and high-affinity binding of substrates generate an ATPase microenvironment, where ADP and ATP are not in free equilibrium with those adenine nucleotides in the surrounding medium. In the physiological range of operation for important cellular ATPases (free energy change of 55 to 60 kJ/mol ATP) only a small fraction of energy, available in ATP, can be utilised, provided that no ATP regeneration takes place. However, ATP regeneration allows utilisation of most of the regenerating capacity, before ATP hydrolysis drops below the critical 55 kJ/mol. The importance of local ATP regeneration increases in parallel with an increase in the rate of ATPase turnover.(ABSTRACT TRUNCATED AT 400 WORDS)
人们普遍认为,为了使代谢反应经济高效,需要一种有利于功能相关酶之间相互作用的结构组织。许多功能相关的酶已被证明在需要它们的部位与细胞结构和其他酶可逆结合。这种结合导致酶的紧密结构接近和浓度增加,从而产生一个微环境,其中一种酶的产物是另一种酶的底物。这减少了底物的扩散距离,以最大速度饱和结合位点,最终提高了这些代谢反应背后功能的效率和经济性。现有数据表明,上述三磷酸腺苷酶(ATPase)与再生ATP的酶之间的关联在ATPase功能调节中起重要作用。已发表的研究普遍达成共识,即疲劳肌肉中的ATP浓度([ATP])不会显著降低,即使是那些功率输出严重下降的肌肉。然而,在离体灌注心脏的研究中,已能够在不影响机械活动的情况下显著降低肌肉细胞中的[ATP]。这种差异的一个解释与ATPase附近的局部ATP再生有关。此外,当ATP再生无法平衡ATP消耗时,通过下调ATP消耗可避免ATP水解自由能的临界下降。局部ATP再生的主要功能是维持二磷酸腺苷([ADP])的低浓度以及ATPase的ATP结合位点附近的ADP/ATP比值,这是ATP水解具有高热力学效率的先决条件。肌酸激酶和糖酵解酶与ATPase的紧密接近以及底物的高亲和力结合产生了一个ATPase微环境,其中ADP和ATP与周围介质中的那些腺嘌呤核苷酸并非处于自由平衡状态。在重要细胞ATPase的生理操作范围内(ATP的自由能变化为55至60 kJ/mol),如果不发生ATP再生,只有一小部分ATP中可用的能量能够被利用。然而,ATP再生允许在ATP水解降至临界的55 kJ/mol以下之前利用大部分再生能力。局部ATP再生的重要性随着ATPase周转速率的增加而平行增加。(摘要截断于400字)
