Polyamines stimulate the binding of hexokinase type II to mitochondria

Interaction of hexokinase with the outer mitochondrial membrane and a hydrophobic matrix

The major portion of rat brain hexokinase (HK type 1) is bound to the outer membrane of mitochondria and glucose-6-phosphate (G6P) can release the bound enzyme. In an attempt to look at the 'hydrophobic' component of binding, interaction of the enzyme with a purely hydrophobic matrix, palmityl-substituted Sepharose-4B (Sepharose-lipid) was investigated. Hexokinase readily bound to this matrix with retention of its catalytic activity. Glucose-6-phosphate which has a releasing effect on the mitochondrially bound enzyme, enhanced binding of the enzyme on the hydrophobic matrix. Chymotrypsin treatment of hexokinase which causes loss of binding to mitochondria, also results in loss of adsorption to the hydrophobic matrix, thus demonstrating that the 'hydrophobic tail' present at its N-terminal end is essential for binding in both cases. Data presented provide some new information relevant to understanding how hexokinase interacts with its natural binding matrix, the mitochondrion.

Binding of rat brain hexokinase to recombinant yeast mitochondria: identification of necessary physico-chemical determinants

The association of rat brain hexokinase with heterologous recombinant yeast mitochondria harboring human porin (Yh) is comparable to that with rat liver mitochondria in terms of cation requirements, cooperativity in binding, and the effect of amphipathic compounds. Mg2+, which is required for hexokinase binding to all mitochondria, can be replaced by other cations. The efficiency of hexokinases, however, depends on the valence of hydrophilic cations, or the partition of hydrophobic cations in the membrane, implying that these act by reducing a prohibitive negative surface charge density on the outer membrane rather than fulfilling a specific structural requirement. Macromolecular crowding (using dextran) has dual effects. Dextran added in excess increases hexokinase binding to yeast mitochondria, according to the porin molecule they harbor. This effect, significant with wild-type yeast mitochondria, is only marginal with Yh as well as rat mitochondria. On the other hand, an increase in the number of hexokinase binding sites on mitochondria is also observed. This increase, moderate in wild-type organelles, is more pronounced with Yh. Finally, dextran, which has no effect on the modulation of hexokinase binding by cations, abolishes the inhibitory effect of amphipathic compounds. Thus, while hexokinase binding to mitochondria is predetermined by the porin molecule, the organization of the latter in the membrane plays a critical role as well, indicative that porin must associate with other mitochondrial components to form competent binding sites on the outer membrane.

Binding of rat brain hexokinase to recombinant yeast mitochondria: effect of environmental factors and the source of porin

Heterologous binding of rat brain hexokinase to wild type, porinless, and recombinant yeast mitochondria expressing human porin was assessed, partially characterized, and compared to that in the homologous system (rat liver mitochondria). With porin-containing yeast mitochondria it is shown that (i) a significant, saturable association occurs; (ii) its extent and apparent affinity, correlated with the origin of porin, are enhanced in the presence of dextran; (iii) the binding requires Mg ions and apparently follows a complex cooperative mechanism. This heterologous association does not seem to differ fundamentally from that in the homologous system and represents a good basis for molecular studies in yeast. With porinless yeast mitochondria, binding occurs at much lower affinity, but to many more sites per mitochondrion. The results indicating a major but not exclusive role for porin in the binding are discussed in terms of (i) the mode and mechanism of binding, and (ii) the suitability of the rat hexokinase-yeast mitochondria couple for the study of heterogeneous catalysis in reconstituted cellular model systems.

Spermine binding to liver mitochondria

Non-equilibrium binding of spermine to mitochondrial membranes is studied in rat liver mitochondria by applying a new thermodynamic treatment of ligand-receptor interactions (Di Noto, V., Dalla Via, L., Toninello, A. and Vidali, M. (1996) Macromol. Theory Simul. 5, 165-181). The presence on mitochondrial membranes of two spermine binding sites, both with monocoordination, is demonstrated. The calculated binding energy is characteristic for weak interactions. The treatment allows also to evaluate the variations of the molar fraction ratio of spermine bound to sites 1 and 2 as function of total bound spermine. The possible role of the two sites is discussed.

Spermine-mediated casein kinase II-uptake by rat liver mitochondria

Spermine, ubiquitous intracellular polyamine, is able to promote the transmembrane translocation of casein kinase CKII through the outer membrane of rat liver mitochondria and its binding to more internal mitochondrial structures. These findings suggest that spermine may play a critical role in regulating the subcellular distribution of casein kinase CKII.

Effect of spermine on membrane-associated and membrane-inserted forms of protein kinase C

Protein kinase C is reported to exist in two membrane-bound states: a reversible one which can be dissociated by calcium chelators (membrane-associated form) and an irreversible one which is chelator stable (membrane-inserted form). In the present work the effects of a naturally occurring polyamine (spermine) on the membrane-associated and membrane-inserted forms of protein kinase C were investigated using a reconstituted system consisting of partially purified protein kinase C from rat brain and phospholipid vesicles of defined composition. The active membrane-bound complex was conveniently determined by its ability to bind radioactive phorbol ester with an exact 1:1 stoichiometry. Our experimental data show that, in the absence of calcium ions, the amount of enzyme bound to phospholipids vesicles was dramatically reduced by the presence of spermine whereas the PDBu binding affinity was not significantly affected. The addition of the divalent cation increased the affinity of phorbol ester for the active complex but had no effect on Nmax; spermine added in this experimental conditions was no longer able to decrease the total number of enzyme molecules bound to liposomes. Moreover gel filtration experiments of the protein kinase C-phospholipids complex formed in the presence of calcium, indicated that polyamine added during the association process was able to reduce the extent of enzyme insertion into liposomes. Since the increase in phospholipid concentration resulted in a higher level of non-dissociable protein kinase C-liposomes complex we propose that spermine, complexing to membrane binding sites both in the absence and in the presence of Ca++, could promote binding conditions that oppose to the formation of the inserted form of the enzyme. As a consequence the distribution between the reversible and the irreversible membrane-bound forms of protein kinase C is affected.

Role of polyamines in the transport in vitro of the precursor of ornithine transcarbamylase

Polyamines induce the transport in vitro of the rat liver precursor of ornithine transcarbamylase (pOTC) into isolated rat liver mitochondria. The accumulation of this precursor at the level of binding to the mitochondrial surface has allowed us to establish that polyamines are involved in the interaction of the precursor with the mitochondrial surface. Transport of a chimeric protein having the signal sequence of pOTC fused to a fragment of the cytosolic protein human arginosuccinate lyase was also induced by polyamines. The sensitivity of the pOTC synthesized in vitro and of the chimeric protein to proteinases decreases in the presence of polyamines. This result suggests that polyamines may play a role in modulating the folding of precursors to favour their binding to mitochondria.

Inhibitory action of polyamines on protein kinase C association to membranes

Physiological activation of protein kinase C requires the interaction of this enzyme with cellular membranes [Nishizuka (1986) Science 233, 305-312]. In the present work a reconstituted system of protein kinase C and human inside-out erythrocyte vesicles was utilized to study the effect in vitro of naturally occurring polyamines on the activation process of protein kinase C. The active membrane-associated complex was conveniently determined by its ability to bind radioactive phorbol ester with an exact 1:1 stoichiometry. The association reaction of the enzyme to membrane was rapid, being complete within 1 min at 25 degrees C. The addition of polyamines, particularly spermine, greatly decreased in a dose-dependent manner the amount of protein kinase C bound to membranes (i.e. in the activated form). The effect observed was quite specific, since it was dependent on the chemical structure of the polyamine and it was manifest at micromolar concentrations of the polycation; the order of potency was spermine greater than spermidine greater than putrescine. A characterization of this effect is presented and possible physiological implications are discussed.

Hexose metabolism in pancreatic islets: compartmentation of hexokinase in islet cells

Hexokinase activity was found in both soluble (cytosolic) and particulate subcellular fractions prepared from rat pancreatic islet homogenates. The bound enzyme was associated with mitochondria rather than secretory granules. Relative to the total hexokinase activity, the amount of bound enzyme was higher in islet homogenates prepared at pH 6.0 (72 +/- 7%) than in islets homogenized at pH 7.4 (38 +/- 1%). The affinity of hexokinase for equilibrated D-glucose was not different in the cytosolic and mitochondrial fractions. In both fractions, hexokinase displayed a greater affinity for alpha- than beta-D-glucose, but a higher maximal velocity with the beta- than alpha-anomer. Glucose 6-phosphate inhibited to a greater extent cytosolic than mitochondrial hexokinase. A high Km glucokinase-like enzymic activity was also present in both subcellular fractions. It is proposed that the ambiguity of hexokinase plays a propitious role in the glucose-sensing function of pancreatic islet cells.

An examination of the in vivo distribution of brain hexokinase between the cytosol and the outer mitochondrial membrane

These studies addressed the question of the in vivo distribution of rat brain hexokinase (HK), and whether physiologically relevant changes in the glycolytic rate are accompanied by changes in the distribution of HK. Homogenates of fresh tissue showed only 11-15% of the overt (assayable without added detergent) HK to be soluble (found in high-speed centrifugation supernatant fractions) when homogenization was begun within 15-20 s of sacrifice. Freeze-blown rat brain tissue also was used, coupled with a new technique wherein it was homogenized as it thawed in a buffered sucrose solution containing 1 mM EDTA. In tissue sampled 15 min (anesthetized) or 60 min (waking) after ip Nembutal injection (40 mg/kg), 23% of the overt HK and 79% of the total lactate dehydrogenase were soluble. The average phosphocreatine content of these and similar homogenates had decreased only 23% from in vivo levels, while ATP had decreased by 65%, due to the combined effects of a high level of endogenous ATPase, chelation of Mg2+ by EDTA, and the greater stability of Mg-ATP2- relative to Mg-ADP1-. These data indicated that the tissue experienced, at most, the equivalent of 6 s of complete ischemia prior to the completion of homogenization. Synaptosomes derived from rat and chicken cerebra were incubated at 37 degrees C in a physiological salt solution containing 10 mM glucose. Addition of veratridine has been shown to stimulate glycolysis and oxidative phosphorylation two- to threefold (H. T. Kyriazi and R. E. Basford (1986) J. Neurochem., in press), but did not alter the HK distribution, as 21% was found in the supernatant fractions of both control and veratridine-stimulated synaptosomes treated with digitonin. These results indicate that in brain tissue, large net movements of HK on and off the outer mitochondrial membrane do not occur, and thus play no role in the regulation of glycolysis.

Some observations on mitochondrial-bound hexokinase and creatine kinase of the heart

A large part of the hexokinase activity of the rat brain 20,000g supernatant became mitochondrial bound when incubated with rat heart mitochondria which had been pretreated with glucose-6-phosphate. This binding was dependent on small-molecular compounds (as yet unidentified) of the brain supernatant. Divalent cations, spermine, and pentalysine strongly stimulated the binding of brain supernatant hexokinase to heart mitochondria. Inorganic phosphate, alpha-glycerophosphate, and fructose-1,6-diphosphate showed some stimulatory effect. No effect was observed with insulin or glucose. Mitochondria isolated from hearts of fasted rats had less specific hexokinase activity than mitochondria from fasted and then carbohydrate refed rats. This dietary treatment had no significant effect on the total heart hexokinase activity. Oligomycin did not inhibit the formation of creatine phosphate or glucose-6-phosphate by isolated rabbit heart mitochondria incubated in the presence of phosphoenolpyruvate and pyruvate kinase. However, the presence of creatine inhibited the formation of glucose-6-phosphate when the ATP/ADP ratio was low, indicating that creatine kinase has a greater access to ATP/ADP translocation than has hexokinase.

Binding and function of mitochondrial glycerol kinase in comparison with those of mitochondrial hexokinase

Mitochondrial-bound glycerol kinase in rat brain was examined with reference to factors involved in the binding and significance of the binding in relation to ATP metabolism inside the mitochondria. The mitochondrial-bound glycerol kinase was solubilized with glycerol 3-phosphate or ADP, and the solubilized enzyme was rebound to mitochondria by addition of divalent cations. The rebinding was decreased by the presence of glycerol 3-phosphate, while was increased by glucose 6-phosphate. Positive correlation was found between the formation of glycerol 3-phosphate by mitochondrial-bound glycerol kinase and ATP content in mitochondria in experiments using various concentrations of succinate and ADP. On the other hand, glycerol 3-phosphate formation was inhibited by addition of inhibitors for mitochondria functions, such as oligomycin, dinitrophenol, cyanide, and atractyloside. Furthermore, formation of dihydroxyacetone phosphate from glycerol was proved, indicating the involvement of glycerol kinase in glycerol phosphate shuttle in combination with glycerol phosphate dehydrogenase. These findings are discussed in comparison with those of mitochondrial-bound hexokinase.

Lactate dehydrogenase binding to the mitochondrial fraction and to a mitochondrial inhibitor as a function of the isoenzymatic composition

Purified rabbit skeletal muscle LDH M4 isoenzyme, but not H4 isoenzyme, was observed to bind to either the crude mitochondrial fraction or a mitochondrial inhibitor. Several sources of LDH isoenzymes in which M-type subunits with an alkaline pI are predominant bind to this crude mitochondrial fraction and are inhibited by the mitochondrial inhibitor. Binding and inhibition have also been observed with H-type isoenzymes with a pI near 7. The binding and the inhibition processes did not occur with H-type isoenzymes with an acid pI or with M-type isoenzymes with pI near 6. The binding capacity of LDH to the mitochondrial fraction and to the mitochondrial inhibitor is very similar and depends on the net protein charge and not on whether the subunits are H- or M-type.

Rabbit heart mitochondrial hexokinase: solubilization and general properties

In rabbit heart, results show that two isoenzymes of hexokinase (HK) are present. The enzymatic activity associated with mitochondria consists of only one isoenzyme; according to its electrophoretic mobility and its apparent Km for glucose (0.065 mM), it has been identified as type I isoenzyme. The bound HK I exhibits a lower apparent Km for ATPMg than the solubilized enzyme, whereas the apparent Km for glucose is the same for bound and solubilized HK. Detailed studies have been performed to investigate the interactions which take place between the enzyme and the mitochondrial membrane. Neutral salts efficiently solubilize the bound enzyme. Digitonin induces only a partial release of the enzyme bound to mitochondria; this result could be explained by the existence of contacts between the outer and the inner mitochondrial membranes [C. R. Hackenbrock (1968) Proc. Natl. Acad. Sci. USA 61, 598-605]. Furthermore, low concentrations (0.1 mM) of glucose 6-phosphate (G6P) or ATP4- specifically solubilize hexokinase. The solubilizing effect of G6P and ATP4-, which are potent inhibitors of the enzyme, can be prevented by incubation of mitochondria with Pi or Mg2+. In addition, enzyme solubilization by G6P can be reversed by Mg2+ only when the proteolytic treatment of the heart homogenate is omitted during the course of the isolation of mitochondria. These results concerning the interaction of rabbit heart hexokinase with the outer mitochondrial membrane agree with the schematic model proposed by Wilson [(1982) Biophys. J. 37, 18-19] for the brain enzyme. This model involves the existence of two kinds of interactions between HK and mitochondria; a very specific one with the hexokinase-binding protein of the outer mitochondrial membrane, which is suppressed by glucose 6-phosphate, and a less specific, cation-mediated one.