Relationship between oxygen uptake of perifused rat-liver cells and the cytosolic phosphorylation state calculated from indicator metabolites and a redetermined equilibrium constant

Linear relation between rate and thermodynamic force in enzyme-catalyzed reactions

Starting from enzyme kinetics, it is shown that generally a linear rather than a proportional relationship exists between rate and free energy changes in biochemical processes. In the derivation the boundary condition of constant substrate plus product is used, which is appropriate for many cellular systems. An example is the ADP plus ATP concentration is mitochondrial oxidative phosphorylation, as is illustrated experimentally.

Bacteriorhodopsin in liposomes. II. Experimental evidence in support of a theoretical model

In the preceding article equations describing relevant ion flows in illuminated suspensions of bacteriorhodopsin liposomes have been derived. Here these equations are subjected to experimental tests. Changes in permeability characteristics of the liposomal membrane are brought about by addition of specific ionophores and change of medium composition. Using light-driven proton uptake and electrochemical potential differences for protons across the membrane as observation parameters, ridig attempts to falsify the derived equations are unsuccessful. Agreement between equations and experimental results is established on the point of: (i) the antagonistic effect of valinomycin and nigericin on the two components of the proton-motive force, (ii) the time dependence of the changes in transmembrane electrical and chemical potential differences after the onset of illumination. In three independent experimental systems evidence was obtained for the correctness of the postulated dependence of the turnover rate of the photochemical cycle on back pressure by the transmembrane electrochemical potential difference for protons.

Bacteriorhodopsin in liposomes. I. A description using irreversible thermodynamics

A comprehensive description of light-induced ion transport in bacteriorhodopsin liposomes is presented. Linear irreversible thermodynamics and the chemiosmotic theory serve as theoretical bases for the formulation of a limited number of fundamental equations. In these equations mechanistic parameters characterize the dependence of ion movement and flux through the photochemical cycle of bacteriorhodopsin on electrochemical potential differences and a so-called light affinity. By making appropriate steady-state assummptions and carrying out mathematical reduction experimentally testable expressions, still containing the mechanistic parameters, are obtained. In the accompanying article rigid trials to falsify these expressions are shown to be unsuccessful.

Computer simulation of the fructose bisphosphatase/phosphofructokinase couple in rat liver

Recycling of fructose 6-phosphate and fructose 1,6-bisphosphate in the rat liver under gluconeogenic and glycolytic conditions was investigated with a computer model containing representations of the kinetic properties of phosphofructokinase and fructose 1,6-bisphosphatase under realistic physiological conditions. The two enzyme submodels were constructed from data for the isolated enzymes in vitro by formal optimization. Tissue metabolite concentrations were corrected for cytosolic/mitochondrial compartmentation and effects of chelation and protonation equilibria. This model, which mostly considers the behavior of livers from starved rats, predicts negligible recycling under physiologically realistic conditions. Metabolic regulation of fructose 6-phosphate, the magnesium ion concentration and the distribution of adenine nucleotides appear to prevent operation of a 'futile cycle' in vivo. Rate-limiting chemical species were identified by sensitivity analysis.