Calorimetric studies of the ADP binding to myosin subfragment 1, heavy meromyosin, and to myosin filaments

Energetics of muscle contraction: further trials

Knowledge accumulated in the field of energetics of muscle contraction has been reviewed in this article. Active muscle converts chemical energy into heat and work. Therefore, measurements of heat production and mechanical work provide the framework for understanding the process of energy conversion in contraction. In the 1970s, precise comparison between energy output and the associated chemical reactions was performed. It has been found that the two do not match in several situations, resulting in an energy balance discrepancy. More recently, efforts in resolving these discrepancies in the energy balance have been made involving chemical analysis, phosphorus nuclear magnetic resonance spectroscopy, and microcalorimetry. Through reviewing the evidence from these studies, the energy balance discrepancy developed early during isometric contraction has become well understood on a quantitative basis. In this situation energy balance is established when we take into account the binding of Ca to sarcoplasmic proteins such as troponin and parvalbumin, and also the shift of cross-bridge states. On the other hand, the energy balance discrepancy observed during rapid shortening still remains to be clarified. The problem may be related to the essential mechanism of cross-bridge action.

Anomalous binding of MgADP to myosin of skeletal muscle

Binding of adenosine diphosphate to skeletal muscle myosin was studied using a range of concentrations from 0 to 2 mM. Up to 0.2 mM adenosine diphosphate two equivalent and independent nucleotide binding sites were detected, characterized by the single association constant of 5 x 10(4)M(-1). At greater adenosine diphosphate concentrations a decreasing binding capacity was noticed, bound nucleotide being essentially approximately 0.1 mol/mol at a 1-2mM adenosine diphosphate concentration. We tentatively propose that nucleotides act indirectly on myosin by promoting the perturbation of the solvent, which is supported by the fact that polyphosphates are known powerful kosmotropes.

Post-ischaemic synchronous purine nucleotide oscillations in perfused rat heart

Langendorff perfused rat hearts show synchronous, statistically significant, systematic variations in ATP and ADP. Here we show that AMP and IMP also vary in register with ATP and ADP and we suggest that the synchronizing trigger for these oscillations may be ischaemia. Oscillations in the ATP/ADP ratio were found to be significantly correlated with creatine phosphate content but by contrast these quantities vary quite differently from the GTP/GDP ratio. Cyclic GMP oscillations showed a significant negative correlation with variations in ADP. Epinephrine raised mean cyclic AMP content and stabilized cyclic GMP oscillations, but had little other effect on the purine nucleotide variations.

Interaction of ADP and magnesium with the active site of myosin subfragment-1 observed by reactivity changes of the critical thiols and by direct binding methods at low and high ionic strength

Comprehensive binding studies using direct and indirect methods yield stoichiometry and affinities for the binding of Mg X ADP and uncomplexed ADP to the active site of myosin subfragment-1. Additionally, the binding parameters for Mg2+ in the ternary complex protein X Mg X ADP are presented for the first time. The indirect method makes use of reactivity changes of the critical thiol-1 and thiol-2 groups, which occur upon the binding of the ligand at the active site. The affinity constants derived by this method are corroborated by two independent direct methods, equilibrium dialysis and centrifugation transport. For Mg2+, ADP and Mg X ADP just one mole of ligand binds/mole subfragment-1. The affinity of Mg X ADP at low ionic strength is 2.1 X 10(6) M-1 and only five-times lower in the absence of Mg2+. In the ternary complex Mg2+ has a low affinity of 4.1 X 10(4) M-1. At high ionic strength the uncomplexed ADP binds with a 43-times-lower affinity than Mg X ADP, whose affinity is 6.9 X 10(5) M-1. In this case Mg2+ interacts in the ternary complex with the higher affinity of 3.2 X 10(5) M-1, implying that at high salt concentration it plays a more prominent role in anchoring ADP at the active site.

In perfused rat hearts ischaemia promotes the reversible conversion of appreciable quantities of soluble adenine nucleotides to a stable trichloroacetic acid-precipitable form

Radioactivity from [14C] adenosine was linearly incorporated into tissue nucleotides in perfused rat hearts. All the TCA-extractable 14C was confined to the purine nucleoside phosphates for up to 1 h of perfusion. Radioactivity was also incorporated linearly into the TCA-insoluble fraction, which by 40 min accounted for 24% of the tissue 14 C. Estimates based on precursor specific radioactivity suggest that at least 0.6 micro mol/g of the mononucleotide is in this stable insoluble form. Following 2 min total ischaemia, the tissue nucleotide content and soluble radioactivity decreased while the insoluble radioactivity showed a corresponding increase to account now for 35% of the tissue radiolabel. This redistribution was rapidly reversed by post-ischaemic reperfusion. A possible function for the rapid reversible sequestration of adenine nucleotides in ischaemia is proposed.

Energetics and kinetics of interconversion of two myosin subfragment-1.adenosine 5'-diphosphate complexes as viewed by phosphorus-31 nuclear magnetic resonance

The 31P NMR spectrum of MgADP bound to myosin subfragment-1 (S-1) at 0 degrees C contains two resolved beta-phosphate resonances corresponding to two interconvertible conformations of the S-1 . ADP complex [Shriver, J. W., & Sykes, B. D. (1981) Biochemistry 20, 2004]. The two conformations, MT*ADP and MR*ADP, are in slow exchange on the NMR time scale, and the rates of interconversion are less than 20 s-1. This is consistent with transient kinetic experiments reported in the literature and allows a determination of the rate constants of interconversion: k+ approximately equal to k- approximately equal to 7 s-1 at 0 degrees C. The relative population of the two conformations is highly temperature dependent, and only one form is significantly populated at 25 degrees C. Simulations of the 31P NMR spectra are used to evaluate an equilibrium constant at various temperatures from 0 to 25 degrees C. The standard enthalpy and entropy differences for the R leads to T transition are determined from the variation of the relative free energies of the two states as a function of temperature: delta H degree = 15 (+/- 2) kcal/mol and delta S degree = 55 (+/- 5) cal/(deg mol) (K = 1 at 271 K). This suggests that a significant conformational change occurs in the R leads to T transition with MgADP bound in the active site. However, the entropy and enthalpy differences are nearly compensatory at physiological temperatures. At 25 degrees C the endothermic R leads to T transition is entropy driven, and delta G degree = 1.4 kcal/mol.

Interaction of ADP with skeletal and cardiac myosin and their active fragments observed by proton release

The technique of proton release measurement has been used to explore the binding of ADP to skeletal and cardiac myosins and their active fragments in a variety of conditions. It has proved possible to obtain binding profiles on intact myosin in the filamentous, undissolved form in physiological solvent conditions. Binding constants are given. At higher ionic strength (0.5 M potassium chloride) the binding profile of magnesium-ADP. is compatible with the presence of two types of site, differing from one another both in respect of affinity and the number of protons released per site. Studies with cardiac myosin reveal no such indications of heterogeneity, and are consistent with the presence of a single population of thermodynamically indistinguishable sites. In the absence of divalent cations, in solutions containing potassium ions and EDTA, ADP binds with absorption rather than liberation of protons. The pH profile of proton absorption at saturation can be fitted in terms of an ionising group with an unperturbed pK of 9.4, and at least one of lower pK(5.9). The dissociation constant (pH8 at 5 degrees C) is about 8 microM, and the affinity for uncomplexed ADP is thus only slightly weaker than that for magnesium-ADP