Ralf Bohnensack

Control of mitochondrial respiration

The control theory of Kacser and Burns [in: Rate Control of Biological Processes (Davies, D.D. ed) pp. 65–104, Cambridge University Press, London, 1973] and Heinrich and Rapoport ([Eur. J. Biochem. (1974) 42, 97‐105] has been used to quantify the amount of control exerted by different steps on mitochondrial oxidative phosphorylation in rat‐liver mitochondria. Inhibitors were used to manipulate the amount of active enzyme. The control strength of the adenine nucleotide translocator was measured by carrying out titrations with carboxyatractyloside. In state 4, the control strength of the translocator was found to be zero. As the rate of respiration was increased by adding hexokinase, the control strength of the translocator increased to a maximum value of ∼30% at ∼80% of state 3 respiration. In state 3, control of respiration is distributed between a number of steps, including the adenine nucleotide translocator, the dicarboxylate carrier and cytochrome c oxidase. The measured values for the distribution of control agree very well with those calculated with the aid of a model for mitochondrial oxidative phosphorylation developed by Bohnensack [Biochim. Biophys. Acta (1982) 680, 271–280].

Inorganic polyphosphate in human osteoblast-like cells

Significant amounts of inorganic polyphosphates and of polyphosphate‐degrading exopolyphosphatase activity were detected in human mandibular‐derived osteoblast‐like cells. The amount of both soluble and insoluble long‐chain polyphosphate in unstimulated osteoblast‐like cells was higher than in human gingival cells, erythrocytes, peripheral blood mononuclear cells, and human blood plasma. The cellular content of polyphosphate in osteoblast‐like cells strongly decreased after a combined treatment of the cells with the stimulators of osteoblast proliferation and differentation, dexamethasone, β‐glycerophosphate, epidermal growth factor, and ascorbic acid. The amount of soluble long‐chain polyphosphate, but not the amount of insoluble long‐chain polyphosphate, further decreased after an additional treatment with 1α,25‐dihydroxyvitamin D3(1,25(OH)2D3). The decrease in polyphosphate content during treatment with dexamethasone, β‐glycerophosphate, epidermal growth factor, and ascorbic acid was accompanied by a decrease in exopolyphosphatase, pyrophosphatase, and alkaline phosphatase activity. However, additional treatment with 1,25(OH)2D3 resulted in an increase in these enzyme activities. Osteoblast‐like cell exopolyphosphatase activity and exopolyphosphatase activity in yeast, rat tissues, and human leukemia cell line HL60 were inhibited by the bisphosphonates etidronate and, to a lesser extent, clodronate and pamidronate. From our results, we assume that inorganic polyphosphate may be involved in modulation of the mineralization process in bone tissue.

Functional characterization of mitochondrial oxidative phosphorylation in saponin-skinned human muscle fibers

The conditions of treatment of human skeletal muscle fibers from M. vastus lateralis with saponin were optimized to achieve complete permeabilization of cell membrane at intact mitochondrial oxidative phosphorylation. After 30 min of incubation with saponin all lactate dehydrogenase, 50% of creatine kinase, 30% of adenylate kinase and less than 20% of citrate synthase was released into the permeabilization medium. These skinned fibers behave similar to isolated mitochondria from human skeletal muscle: (i) the respiration with mitochondrial substrates can be stimulated by ADP, (ii) inhibited by carboxyatractyloside and (iii) it is possible to detect fluorescence changes of mitochondrial NAD(P)H on additions of substrates, uncoupler and cyanide. From a comparison of rates of respiration per cytochrome aa3 content of isolated human skeletal muscle mitochondria and saponin-skinned muscle fibers it was possible to calculate that almost 85% of mitochondria in those fibers are accessible for the investigation of oxidative phosphorylation. As shown by the investigation of biopsy samples of two patients with undefined myopathies these fibers are a suitable object for the replacement of isolated mitochondria in the diagnosis of mitochondrial myopathies and encephalomyopathies.

Control of mitochondrial respiration. The contribution of the adenine nucleotide translocator depends on the ATP- and ADP-consuming enzymes.

The consequence of the complexity of the metabolic network on the amount of control strength of adenine nucleotide translocator was investigated with isolated rat liver mitochondria. Two experimental systems were compared: (i) mitochondria in the presence of yeast hexokinase (hexokinase system) and (ii) the same system plus additional pyruvate kinase (pyruvate kinase system). In both systems the control strength was analysed for the adenine nucleotide translocator by inhibitor titration studies with carboxyatractyloside and for the hexokinase or pyruvate kinase by changing their relative activities. Experimental results were compared with computer simulation of these systems and that of a third one, where the extramitochondrial ATP/ADP ratio was held constant by perifusion (perifusion system). The results demonstrate quite different flux-dependent control strength of the translocator in the three systems. In the hexokinase system the control strength of the translocator on mitochondrial respiration was zero up to respiration rates of about 60 nmol O2/mg protein per min. For higher rates, the control strength increased until the maximum value (0.45) was reached in the fully active state. Here, the same value was also found in the pyruvate kinase system. In all other states of respiration the translocator exerts a higher control strength in the pyruvate kinase system than in the hexokinase system. This different behaviour was attributed to the various changes in the adenine nucleotide pattern caused by partial inhibition of the translocator in the hexokinase and pyruvate kinase system. The data clearly show that the sharing of control strength depends not only on the respiration rate but also on the complexity of the metabolic system.

Dynamic compartmentation of adenine nucleotides in the mitochondrial intermembrane space of rat-heart mitochondria

To investigate whether or not the mitochondrial intermembrane space together with the extramitochondrial space form a homogeneous pool for adenine nucleotides, rat-heart mitochondria were studied in reconstituted systems with pyruvate kinase and ADP-producing enzymes with varied localization. In the hexokinase system, ADP is produced extramitochondrially by added yeast hexokinase, whereas in the creatine kinase system mitochondrial creatine kinase is responsible for ADP regeneration in the intermembrane space. The dependence of mitochondrial respiration on the extramitochondrial [ATP]/[ADP] ratio in both systems was investigated experimentally and by means of computer simulation. Near the resting state, higher [ATP]/[ADP] ratios were found in the creatine kinase system than in the hexokinase system at the same rate of respiration. This and the maintaining of a substantial creatine kinase-stimulated respiration in the presence of pyruvate kinase in excess is explained by a two-compartment model considering diffusion limitations of adenine nucleotides. A diffusion rate constant of (8.7 +/- 4.7) 10(4) microliters X mg-1 X min-1 for ADP and ATP was estimated, resulting in rate-dependent concentration differences up to 13.7 microM AdN between the extramitochondrial space and the AdN-translocator at the maximum rate of oxidative phosphorylation of rat-heart mitochondria. The results support the assumption that ADP diffusion towards the AdN-translocator is limited if its extramitochondrial concentration is low, resulting in a dynamic compartmentation of adenine nucleotides in the mitochondrial intermembrane space.

Control of oxidative phosphorylation by the extramitochondrial ATP/ADP ratio

The control of mitochondrial ATP synthesis by the extramitochondrial adenine nucleotide pattern was investigated with rat liver mitochondria. It is demonstrated that any stationary state between the two limit states of maximum activity (state 3) and of resting activity (state 4) can be obtained by a hexokinase-glucose trap as an ADP-regenerating system. These intermediate states are characterized by stationary respiratory rates, stationary redox levels of the cytochromes b and c and stationary levels of extramitochondrial ATP and ADP between the rates and levels of the limit states. At a constant concentration of inorganic phosphate the activity of mitochondria between the limit states is controlled by the extramitochondrial ATP/ADP ratio independent of the total concentration of adenine nucleotides present. The control range was found to be between ratios of about 5 and 100 at 10 mM phosphate. At lower ratios the mitochondria are in their maximum phosphorylating state. With succinate+rotenone and glutamate+malate the same control range was observed, indicating that it is independent of the nature of substrate oxidized. The results suggest that in the control range the mitochondrial activity is limited by the competition of ADP and ATP for the adenine nucleotide translocator.

Relations between extramitochondrial and intramitochondrial adenine nucleotide systems

Abstract The control of oxidative phosphorylation by the extramitochondrial [ ATP ] [ ADP ] ratio and [Pi] was investigated by incubations of isolated mitochondria with an ADP regenerating system and by a new perifusion technique using glass filters for immobilization of mitochondria. With mitochondria from different sources oxidizing different substrates and with both techniques, similar results were obtained. Changes of the extramitochondrial [ ATP ] [ ADP ] ratio from about 100 to 5 transfer mitochondria from the resting state (state 4) to the fully active state (state 3). The importance of the adenine nucleotide translocator in this transition was demonstrated by the influence of its specific inhibitor carboxyatractyloside. The sensitivity to the inhibitor was more pronounced in states with high [ ATP ] [ ADP ] ratios than in the fully active state. In the hexokinase-glucose system the action of the inhibitor caused a transition to a new steady state, where a decreased [ ATP ] [ ADP ] ratio overcomes the inhibition. Thus, a partial inhibition of the translocator shifted the control characteristics to lower [ ATP ] [ ADP ] ratios. When the concentration of inorganic phosphate was decreased, the main effect was a reduction of the maximum rate of oxidative phosphorylation (i.e., in state 3), whereas the [ ATP ] [ ADP ] sensitive range was not altered. This effect is caused by changes in the intramitochondrial phosphorylation potential. Furthermore, this indicates that the kinetic properties of the adenine nucleotide translocator prevent a simple equilibration of the phosphorylation potential across the inner membrane. This is also demonstrated by the fact that the extramitochondrial formation of glucose-6-phosphate and the intramitochondrial synthesis of citrulline compete for ATP.

Control of energy transformation in mitochondria. Analysis by a quantitative model

A mathematical model of control of energy transformation in mitochondria is presented. The considered processes are: the proton translocation by the respiratory chain, the production of ATP by ATPase, the translocation of adenine nucleotides and of phosphate by their translocators, and a passive backflow of protons through the mitochondrial membrane. The mathematical equations expressing the steady-state kinetics of these processes and the relations between them were derived on the basis of current experimental data. The model predicts fairly well the values of the proton electrochemical gradient, of the ATP/ADP ratios within and outside mitochondria and of the distribution of phosphate between both compartments in different metabolic states of mitochondria. From the general agreement of model computations with experimental data, it is suggested that the electron flux through the respiratory chain is immediately controlled by the energy back-pressure of the proton electrochemical gradient, that the ATPase reaction is near equilibrium in phosphorylating mitochondria but that the adenine nucleotide exchange across the mitochondrial membrane requires some loss of energy. The latter is caused by an inhibition of the translocator by ATP from the outer side or by ADP from the inner side depending on the actual ATP/ADP in both compartments. It explains that no fixed relation exists between the rate of respiration and the phosphorylation state of extramitochondrial adenine nucleotides. The relation is modified by the concentration of phosphate and by intramitochondrial energy utilization.

Estimation of flux control coefficients from inhibitor titrations by non-linear regression

A mathematical model was developed to estimate flux control coefficients (Co) from titration studies with specific non‐competitive inhibitors. In contrast to the normally used graphical determination the model pays regard to the dissociation equilibrium (k D) that exists between inhibitor and its binding sites (E o) as well as to an objective estimation of the initial slope. The model was used for the analysis of titration experiments where the respiration of rat liver mitochondria was inhibited with carboxyatractyloside and antimycin A. It is shown that the graphical estimation of E o and C o lead to significant overestimation if the ratio K d/E o is larger than 10−4 which can be avoided by using our model.

Rate-controlling steps of oxidative phosphorylation in rat liver mitochondria. A synoptic approach of model and experiment

The contribution of different steps to the control of oxidative phosphorylation in isolated rat liver mitochondria was investigated by a combination of experiments and computer simulations. The parameters of the mathematical model of phosphorylating mitochondria were derived from experimental data. The model correctly described the competition between ATP utilization inside and outside mitochondria for the ATP generated in mitochondria. On the basis of the good agreement between experiments and simulations, the contribution of different steps to the control of respiration was estimated by computing their control strengths, i.e., the influence of their activities on the rate of respiration. The rate-controlling influences vary depending on the load of oxidative phosphorylation. The predominant steps are: in the fully active state (State 3)--the hydrogen supply to the respiratory chain; in the resting state (State 4)--the proton leak of the mitochondrial inner membrane; in states of non-maximum ATP export--the adenine nucleotide translocator. Titrations of respiration with phenylsuccinate, antimycin, oligomycin and carboxyatractyloside completely support these conclusions.