Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Molar enthalpy change for hydrolysis of phosphorylcreatine under conditions in muscle cells.

Literature DB >> 3416035

Molar enthalpy change for hydrolysis of phosphorylcreatine under conditions in muscle cells.

Abstract

The enthalpy change for the hydrolysis of phosphorylcreatine (PCr) by hydrochloric acid or by alkaline phosphatase was observed at 0, 25, and 37 degrees C. The value for delta H is -44 kJ mol-1 under alkaline, Mg2+-free conditions and is almost independent of temperature, ionic strength, and concentration of reactants. In muscle the reaction is accompanied by a transfer of protons from the buffers (largely histidine) to orthophosphate, release of Mg2+ from PCr, and binding of Mg2+ to orthophosphate. Measurements are reported of the heats of these processes. The calculated value of the overall heat of hydrolysis of PCr (including these processes) at pH 7, pMg 3 is -35 kJ mol-1.

Entities: Chemical Gene

Mesh：

Substances：
Phosphocreatine

Year: 1988 PMID： 3416035 PMCID： PMC1330319 DOI： 10.1016/S0006-3495(88)82934-5

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

16 in total

1. THE STABILITY CONSTANTS OF METAL-ADENINE NUCLEOTIDE COMPLEXES.

Authors: W J O'SULLIVAN; D D PERRIN
Journal: Biochemistry Date: 1964-01 Impact factor: 3.162

Review 2. Energy changes and muscular contraction.

Authors: N A Curtin; R C Woledge
Journal: Physiol Rev Date: 1978-07 Impact factor: 37.312

3. Chemical change and energy production during contraction of frog muscle: how are their time courses related?

Authors: N A Curtin; R C Woledge
Journal: J Physiol Date: 1979-03 Impact factor: 5.182

4. Standard Gibbs free energy, enthalpy, and entropy changes as a function of pH and pMg for several reactions involving adenosine phosphates.

Authors: R A Alberty
Journal: J Biol Chem Date: 1969-06-25 Impact factor: 5.157

5. A reaction calorimeter. Some modifications of a previous system.

Authors: H Ots
Journal: Acta Chem Scand Date: 1972

6. [Micro-determination of creatinine].

Authors: H Bartels; M Böhmer
Journal: Clin Chim Acta Date: 1971-03 Impact factor: 3.786

7. Calcium transients in isolated amphibian skeletal muscle fibres: detection with aequorin.

Authors: J R Blinks; R Rüdel; S R Taylor
Journal: J Physiol Date: 1978-04 Impact factor: 5.182

8. High-energy phosphate metabolism and energy liberation associated with rapid shortening in frog skeletal muscle.

Authors: E Homsher; M Irving; A Wallner
Journal: J Physiol Date: 1981-12 Impact factor: 5.182

9. Free magnesium in sheep, ferret and frog striated muscle at rest measured with ion-selective micro-electrodes.

Authors: P Hess; P Metzger; R Weingart
Journal: J Physiol Date: 1982-12 Impact factor: 5.182

10. Heat production and fluorescence changes of toad sartorius muscle during aerobic recovery after a short tetanus.

Authors: A Godfraind-de Becker
Journal: J Physiol Date: 1972-06 Impact factor: 5.182

23 in total

1. A weakly coupled version of the Huxley crossbridge model can simulate energetics of amphibian and mammalian skeletal muscle.

Authors: C J Barclay
Journal: J Muscle Res Cell Motil Date: 1999-02 Impact factor: 2.698

10. The time course of phosphate metabolites and intracellular pH using 31P NMR compared to recovery heat in rat soleus muscle.

Authors: S K Phillips; M Takei; K Yamada
Journal: J Physiol Date: 1993-01 Impact factor: 5.182

Molar enthalpy change for hydrolysis of phosphorylcreatine under conditions in muscle cells.

1. THE STABILITY CONSTANTS OF METAL-ADENINE NUCLEOTIDE COMPLEXES.

Review 2. Energy changes and muscular contraction.

3. Chemical change and energy production during contraction of frog muscle: how are their time courses related?

4. Standard Gibbs free energy, enthalpy, and entropy changes as a function of pH and pMg for several reactions involving adenosine phosphates.

5. A reaction calorimeter. Some modifications of a previous system.

6. [Micro-determination of creatinine].

7. Calcium transients in isolated amphibian skeletal muscle fibres: detection with aequorin.

8. High-energy phosphate metabolism and energy liberation associated with rapid shortening in frog skeletal muscle.

9. Free magnesium in sheep, ferret and frog striated muscle at rest measured with ion-selective micro-electrodes.

10. Heat production and fluorescence changes of toad sartorius muscle during aerobic recovery after a short tetanus.

1. A weakly coupled version of the Huxley crossbridge model can simulate energetics of amphibian and mammalian skeletal muscle.

2. Heat production in human skeletal muscle at the onset of intense dynamic exercise.

3. Slow skeletal muscles of the mouse have greater initial efficiency than fast muscles but the same net efficiency.

4. Estimation of cross-bridge stiffness from maximum thermodynamic efficiency.

Review 5. Kinetics and energetics of the crossbridge cycle.

6. Components of activation heat in skeletal muscle.

7. Experimental and modelling evidence of shortening heat in cardiac muscle.

8. Altered cross-bridge characteristics following haemodynamic overload in rabbit hearts expressing V3 myosin.

9. The stiffness of rabbit skeletal actomyosin cross-bridges determined with an optical tweezers transducer.

10. The time course of phosphate metabolites and intracellular pH using 31P NMR compared to recovery heat in rat soleus muscle.