Enzyme-substrate and enzyme-inhibitor complexes of triose phosphate isomerase studied by 31P nuclear magnetic resonance.

The complex formed between the enzyme triose phosphate isomerase (EC 5.3.1.1.), from rabbit and chicken muscle, and its substrate dihydroxyacetone phosphate was studied by 31P n.m.r. Two other enzyme-ligant complexes examined were those formed by glycerol 3-phosphate (a substrate analogue) and by 2-phosphoglycollate (potential transition-state analogue). Separate resonances were observed in the 31P n.m.r. spectrum for free and bound 2-phosphoglycollate, and this sets an upper limit to the rate constant for dissociation of the enzyme-inhibitor complex; the linewidth of the resonance assigned to the bound inhibitor provided further kinetic information. The position of this resonance did not vary with pH but remained close to that of the fully ionized form of the free 2-phosphoglycollate. It is the fully ionized form of this ligand that binds to the enzyme. The proton uptake that accompanies binding shows protonation of a group on the enzyme. On the basis of chemical and crystallographic information [Hartman (1971) Biochemistry 10, 146--154; Miller & Waley (1971) Biochem. J. 123, 163--170; De la Mare, Coulson, Knowles, Priddle & Offord )1972) Biochem. J. 129, 321--331; Phillips, Rivers, Sternberg, Thornton & Wilson (1977) Biochem. Soc. Trans. 5, 642--647] this group is believed to be glutamate-165. On the other hand, the position of the resonance of D-glycerol 3 phosphate (sn-glycerol 1-phosphate) in the enzyme-ligand complex changes with pH, and both monoanion and dianon of the ligand bind, although dianion binds better. The substrate, dihydroxyacetone phosphate, behaves essentially like glycerol 3-phosphate. The experiments with dihydroxy-acetone phosphate and triose phosphate isomerase have to be carried out at 1 degree C because at 37 degrees C there is conversion into methyl glyoxal and orthophosphate. The mechanismof the enzymic reaction and the reasons for rate-enhancement are considered, and aspects of the pH-dependence are discussed in an Appendix.     

The kinetics of effector binding to phosphofructokinase. The influence of effectors on the allosteric conformational transition.

1. The extent of the allosteric transition from the R into the T conformation of rabbit skeletal muscle phosphofructokinase induced by Mg2+-1,N6-etheno-ATP was determined by stopped-flow fluorimetry from the amplitude of the slow phase of the Mg2+-1,N6-etheno-ATP fluorescence enhancement [Roberts & Kellet (1979) Biochem. J. 183, 349--360]. 2. The amplitude of the slow phase was decreased by low concentrations of the activators cyclic AMP and fructose 1,6-bisphosphate, but increased in a complex manner by the inhibitor citrate. 3. Mg2+-1,N6-etheno-ATP and Mg2+-ATP are unable to induce the T conformation to a detectable extent in the presence of saturating cyclic AMP, but can do so readily in the presence of saturating fructose 1,6-bisphosphate. 4. The conformational transitions induced in enzyme alone by different ligands were observed by changes in intrinsic protein fluorescence. In general, an R-type conformation has diminished protein fluorescence compared with a T-type conformation. 5. Mg2+-ATP exerts a complex effect on protein fluorescence; both the enhancement at low concentrations and the quenching at high concentrations of Mg2+-ATP result from the binding of Mg2+-ATP to the inhibitory site and the ensuing allosteric transition. Enhancement reflects the extent of the allosteric transition and involves both tyrosine and tryptophan, probably in the region of the active site; quenching reflects occupation of the inhibitory site and involves tyrosine at the inhibitory site. 6. The mechanism of the allosteric transition from the R into the T conformation induced by Mg2+-1,N6-etheno-ATP at low concentrations occurs predominantly by a 'prior-isomerization' pathway; at higher concentrations a limited contribution from a 'substrate-guided' pathway occurs. 7. The allosteric behaviour of phosphofructokinase with respect to Mg2+-ATP and Mg2+-1,N6-ethenol-ATP binding may be accounted for in terms of the simple, concerted model.     

Kinetic and structural characterization of phosphofructokinase from Lactobacillus bulgaricus

Phosphofructokinase from Lactobacillus delbrueckii subspecies bulgaricus (LbPFK) has been reported to be a nonallosteric analogue of phosphofructokinase from Escherichia coli at pH 8.2 [Le Bras et al. (1991) Eur. J. Biochem. 198, 683-687]. A reexamination of the kinetics of this enzyme shows LbPFK to have limited binding affinity toward the allosteric ligands, MgADP and PEP, with dissociation constants of approximately 20 mM for both. Their allosteric effects are observed only at high concentrations of these ligands, with both exhibiting inhibitory effects on substrate binding. No pH dependence was observed for the binding and the influence of MgADP and PEP on the enzyme. To attempt to explain these results, the crystal structure of LbPFK was solved using molecular replacement to 1.86 A resolution. A comparative study of the LbPFK structure with that of phosphofructokinases from E. coli (EcPFK) and Bacillus stearothermophilus (BsPFK) reveals a structure with conserved fold and substrate binding site. The effector binding site, however, shows many differences that could explain the observed decreases in binding affinity for MgADP and PEP in LbPFK as compared to the other two enzymes.     

Kinetic studies on the major form of aldehyde reductase in ox kidney: a general kinetic mechanism to explain substrate-dependent mechanisms and the inhibition by anticonvulsants

The inhibition of the major form of ox kidney aldehyde reductase (AR 1) by sodium barbitone revealed linear mixed kinetics. This behaviour is distinct from the non-linear intercept effect we reported for valproate [Daly and Mantle (1982) Biochem. J. 205, 381]. 4-Carboxybenzaldehyde exhibits partial uncompetitive substrate inhibition. These results are discussed in terms of a model that involves nucleotide-induced isomerization and an additional flux (with some substrates and inhibitors) through an enzyme.nucleotide.substrate/inhibitor ternary complex.     

Selective thiol group modification renders fructose-1,6-bisphosphatase insensitive to fructose 2,6-bisphosphate inhibition

Limited treatment of native pig kidney fructose-1,6-bisphosphatase (50 microM enzyme subunit) with [14C]N-ethylmaleimide (100 microM) at 30 degrees C, pH 7.5, in the presence of AMP (200 microM) results in the modification of 1 reactive cysteine residue/enzyme subunit. The N-ethylmaleimide-modified fructose-1,6-bisphosphatase has a functional catalytic site but is no longer inhibited by fructose 2,6-bisphosphate. The enzyme derivative also exhibits decreased affinity toward Mg2+. The presence of fructose 2,6-bisphosphate during the modification protects the enzyme against the loss of fructose 2,6-bisphosphate inhibition. Moreover, the modified enzyme is inhibited by monovalent cations, as previously reported (Reyes, A., Hubert, E., and Slebe, J.C. (1985) Biochem. Biophys. Res. Commun. 127, 373-379), and does not show inhibition by high substrate concentrations. A comparison of the kinetic properties of native and N-ethylmaleimide-modified fructose-1,6-bisphosphatase reveals differences in some properties but none is so striking as the complete loss of fructose 2,6-bisphosphate sensitivity. The results demonstrate that fructose 2,6-bisphosphate interacts with a specific allosteric site on fructose-1,6-bisphosphatase, and they also indicate that high levels of fructose 1,6-bisphosphate inhibit the enzyme by binding to this fructose 2,6-bisphosphate allosteric site.     

The exocellular DD-carboxypeptidase-endopeptidase of Streptomyces albus G. Interaction with beta-lactam antibiotics.

Kinetically, the three-step model proposed for the interaction between beta-lactam antibiotics and the exocellular DD-carboxypeptidases-transpeptidases of Streptomyces R61 and Actinomadura R39 [Frère, Ghuysen & Iwatsubo (1975) Eur. J. Biochem. 57, 343--357; Fuad, Frère, Ghuysen, Duez & Iwatsubo (1976) Biochem. J. 155, 623--629] applies to the interaction between the much less penicillin-sensitive exocellular DD-carboxypeptidase-endopeptidase of Streptomyces albus G and at least phenoxymethylpenicillin, cephalothin and cephalosporin C. The penicillin resistance of the albus G enzyme is mainly due to the low efficiency with which the first reversible complex formed with the antibiotic (complex EI) undergoes transformation into a second more stable complex EI*. Analysis of the ternary interaction between enzyme, NalphaNepsilon-diacetyl-L-lysyl-D-alanyl-D-alanine (Ac2-L-Lys-D-Ala-D-Ala) and cephalosporin C indicates a non-competitive mechanism.     

Inhibition by substrate of fructose 1,6-bisphosphatase purified from rat kidney cortex. Calculation of the kinetic constants of the enzyme

Fructose 1,6-bisphosphatase is a typical enzyme that is severely inhibited by its own substrate. This makes it difficult to determine all the parameters involved in its kinetics. It has been shown recently that if Vm is satisfactorily estimated the remaining parameters can be determined using the Hill plot (Bounias, M. (1988) Biochem. Int. 17, 147-154). The enzyme has been purified from rat kidney cortex nearly to homogeneity, and its kinetic constants have been calculated using a rigorous algebraic method. The most interesting result is that the substrate is unable to bind to the free enzyme as an inhibitor, which indicates that the enzyme lacks an allosteric site for hexose bisphosphates.     

Substrate- and alkali-metal-ion-induced pK shifts in intestinal brush-border sucrase, according to the three-protons model.

To define adequately enzyme activation/inhibition mechanisms as a function of pH, it is necessary to characterize the effector-induced pK shifts on both the free enzyme and on the enzyme-substrate complex. On the basis of our recent three-protons model for sucrase [Vasseur, van Melle, Frangne & Alvarado (1988) Biochem. J. 251, 667-675], we show how the 'fundamental' pK values, deduced from the classical double-logarithmic transformations, are insufficient to generate the required information. This insufficiency derives from the fact that, for sucrase, the acid ionization constant, K1, is a molecular constant that involves complex, V-type plus K-type, activatory and inhibitory kinetic effects. As a consequence, substrate-induced pK shifts cannot be interpreted correctly only by using the fundamental pK approach, because an unequal number of key protons is involved, depending on whether the free enzyme or the enzyme-substrate complex is considered. We demonstrate how this problem can be solved by using the 'theoretical' pK values, derived from the reciprocals of the Michaelis pH functions, i.e. Cha's fractional concentration factors. The procedure we propose, which is general, has the advantage of yielding all the macroscopic pK values for any given model, as calculated from the microscopic pK values. Furthermore, it permits predicting pK shifts as a function of [S] and/or [A] (where S is the substrate and A is the allosteric modifier), an objective that cannot be attained by using the double-logarithmic plot approach. Finally, we describe the relation existing between the fundamental and the theoretical pK values.     

Purification and properties of alpha-D-mannosidase from the germinated seeds of Medicago sativa (alfalfa).

alpha-Mannosidase of Medicago sativa (alfalfa) was purified 1340-fold. The purification method included dialysis of the crude extract against a citrate/phosphate buffer, pH 3.9, (NH4)SO4 precipitation, hydroxyapatite chromatography, chromatography on Sephadex G-200 and finally a preparatory electrophoresis on polyacrylamide-gel gradient by Doly & Petek's [(1977) J. Chromatogr. 137. 69--81] method. Each step of purification was checked by polyacrylamide-gel disc electrophoresis. The purified enzyme showed a single band, corresponding to alpha-mannosidase activity. alpha-Mannosidase has a mol.wt. 230 000 as estimated by Hedrick & Smith's [(1968) Arch. Biochem. Biophys. 126, 155--164] method and also by polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate by Weber & Osborn [(1969) J. Biol. Chem. 244, 4406--4412]. The enzyme comprises four subunits of different molecular weight. Optimum pH and Km values were determined with p-nitrophenyl alpha-D-mannoside as substrate. When incubated at a temperature between 20 and 62 degrees C before assay, alpha-mannosidase initially shows an increase in activity. alpha-Mannosidase is stable when the pH is about neutrality. It can be inactivated by several metal ions, including Zn2+. At a pH below 5 the enzyme undergoes irreversible inactivation. The presence of EDTA at acid pH considerably enhances the inactivation of the enzyme. This inactivation due to EDTA can be specifically reversed by incubation with Zn2+.     

Kinetics of phosphoenolpyruvate carboxylase from Zea mays leaves at high concentration of substrates

At low concentrations of phosphoenolpyruvate and magnesium, the substrate of phosphoenolpyruvate carboxylase (PEPC) from Zea mays leaves is the MgPEP complex and free phosphoenolpyruvate (fPEP) is an allosteric activator [A. Tovar-Méndez, R. Rodríguez-Sotres, D.M. López-Valentín, R.A. Mu?oz-Clares, Biochem. J. 332 (1998) 633-642]. To further the understanding of this photosynthetic enzyme, we have re-investigated its kinetics covering a 500-fold range in fPEP and free Mg(2+) (fMg(2+)) concentrations. Apparent V(max) values were dependent on the concentration of the fixed free species, suggesting that these species are substrates of the PEPC-catalyzed reaction. However, when substrate inhibition was taken into account, similar V(max) values were obtained in all saturation curves for a given varied free species, indicating that MgPEP is indeed the reaction substrate. As substrate inhibition may be the result of the rise in ionic strength of the assay medium, we studied its effects on the kinetics of the enzyme. Mixed inhibition against MgPEP was found, with apparent K(ic) and K(iu) values of 36 and 1370 mM, respectively. Initial velocity patterns determined at constant ionic strength, 600 mM, were consistent with MgPEP being the true PEPC substrate, fPEP an allosteric activator, and fMg(2+) a weak, non-competitive inhibitor, thus confirming the kinetic mechanism determined previously at low concentrations of PEP and Mg(2+), and indicating that apparent substrate inhibition by MgPEP in maize leaf PEPC is caused by inhibition by high magnesium and ionic strength.     

Generalized microscopic reversibility, kinetic co-operativity of enzymes and evolution.

Generalized microscopic reversibility implies that the apparent rate of any catalytic process in a complex mechanism is paralleled by substrate desorption in such a way that this ratio is held constant within the reaction mechanism [Whitehead (1976) Biochem. J. 159, 449--456]. The physical and evolutionary significances of this concept, for both polymeric and monomeric enzymes, are discussed. For polymeric enzymes, generalized microscopic reversibility of necessity occurs if, within the same reaction sequence, the substrate stabilizes one type of conformation of the active site only. Generalized microscopic reversibility suppresses the kinetic co-operativity of the slow transition model [Ainslie, Shill & Neet (1972) J. Biol. Chem. 247, 7088--7096]. This situation is obtained if the free-energy difference between the corresponding transition states of the two enzyme forms is held constant along the reaction co-ordinate. This situation implies that the 'extra costs' of energy (required to pass each energy barrier) that are not covered by the corresponding binding energies of the transition states vary in a similar way along the two reaction co-ordinates. The regulatory behaviour of monomeric enzymes is discussed in the light of the concept of 'catalytic perfection' proposed by Albery & Knowles [(1976) Biochemistry 15, 5631--5640]. These authors claim that an enzyme will be catalytically 'perfect' when its catalytic efficiency is maximum. If this situation occurs for a monomeric enzyme obeying either the slow transition or the mnemonical model, it can be shown that the kinetic co-operativity disappears. In other words, kinetic co-operativity of a monomeric enzyme is 'paid for' at the expense of catalytic efficiency, and the monomeric enzyme cannot be simultaneously co-operative and catalytically very efficient. This is precisely what has been found experimentally in a number of cases.     

Ox glutamate dehydrogenase. Comparison of the kinetic properties of native and proteolysed preparations.

Kinetic constants were determined for commercially available samples of ox liver glutamate dehydrogenase, which had previously been shown to have suffered limited proteolysis during preparation, with a range of substrates and effectors. These were compared with the values obtained with enzyme preparations purified in such a way as to prevent this proteolysis from occurring [McCarthy, Walker & Tipton (1980) Biochem. J. 191, 605-611]. The Km values and maximum velocities determined with different substrates revealed little difference between the two preparations although the proteolysed enzyme had lower Km values for NH4+ and glutamate when the activities were determined with NADPH and NADP+ respectively. This preparation was more sensitive to inhibition by Cl- ions but less sensitive to inhibition by high concentrations of the substrate NADH. The two preparations also differed in their sensitivities to allosteric effectors, with the proteolysed enzyme being the less sensitive to inhibition by GTP. At high concentrations of NADH, this preparation was also more sensitive to activation by ADP and ATP.     

Monamine oxidase in outer membrane of skeletal muscle mitochondria.

(1) Monoamine oxidase (EC 1.4.3.4) is present in rat skeletal muscle mitochondria. (2) A radioassay procedure for the assay of monoamine oxidase in muscle mitochondria is described. It is based on teh procedure using side-chain [2-14C]-tryptamine as substate described by Wurtman, R.J. and Axelrod, J. (1963) Biochem. Pharmacol. 12, 1439--1441 and employs a pH of 8.0 and a substrate concentration of 0.25 mM. (3) The Km of the muscle mitochondrial enzyme at pH 8.0 is 1.34 - 10(-5) M and that of the liver enzyme under the same conditions is 2.5 - 10(-5) M. Muscle mitochondria contain only one quarter of the activity of enzyme present in liver mitochondria. (4) Monoamine oxidase is shown to be in the outer membrane of skeletal muscle mitochondria and thus to be a suitable marker enzyme for use in the fractionation of these mitochondria.     

Human high-Km 5'-nucleotidase effects of overexpression of the cloned cDNA in cultured human cells.

5'-Nucleotidases participate, together with nucleoside kinases, in substrate cycles involved in the regulation of deoxyribonucleotide metabolism. Three major classes of nucleotidases are known, one on the plasma membrane and two in the cytosol. The two cytosolic classes have been named high-Km nucleotidases and 5'(3')-nucleotidases. Starting from two plasmids with partial sequences (Oka, J., Matsumoto, A., Hosokawa, Y. & Inoue, S. (1994) Biochem. Biophys. Res. Commun. 205, 917-922) we cloned the complete cDNA of the human high-Km nucleotidase into vectors suitable for transfection of Escherichia coli or mammalian cells. After transfection, E. coli overproduced large amounts of the enzyme. Most of the enzyme was present in inclusion bodies that also contained many partially degraded products of the protein. Part of the enzyme, corresponding to approximately 2% of the soluble proteins, was in a soluble active form. Stably transfected human 293 cells were obtained with a vector where the 3'-end of the nucleotidase coding sequence is linked to the 5'-end of the green fluorescent protein coding sequence. Several green clones overproduced both mRNA and fusion protein. Two clones with 10-fold higher enzyme activity were analyzed further. The nucleotidase activity of cell extracts showed the same substrate specificity and allosteric regulation as the high-Km enzyme. The growth rate of the two clones did not differ from the controls. The cells were not resistant to deoxyguanosine or deoxyadenosine, and did not show an increased ability to phosphorylate dideoxyinosine. Both ribonucleoside and deoxyribonucleoside triphosphate pools were decreased slightly, suggesting participation of the enzyme in their regulation.     

Simplifications of the derivations and forms of steady-state equations for non-equilibrium random substrate-modifier and allosteric enzyme mechanisms.

The steady-state equations for "random" enzymic mechanisms (ones with alternative routes for substrate and enzyme to form enzyme-substrate complexes) are non-Michaelian and very complicated when a quasi-equilibrium approximation cannot be used. General methods for simplifying their forms and derivations are given and applied to several single-substrate mechanisms of general or topical interest. The special simplifications resulting from partial ordering of reaction mechanism, from gross inequalities of rate constants, and from special relationships between catalytic and dissociation rate constants, are considered with reference to allosteric mechanisms. Some equations mentioned, but not given here, and more detailed working out of some of those given, have been deposited as Supplementary Publication SUP 50069 (18 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms given in Biochem. J. (1976) 153, 5.     

Molecular cloning and characterization of (R)-3-hydroxybutyrate dehydrogenase from human heart.

The complete amino acid sequence of human heart (R)-3-hydroxybutyrate dehydrogenase (EC 1.1.1.30) has been deduced from the nucleotide sequence of cDNA clones. This mitochondrial enzyme has an absolute and specific requirement of phosphatidylcholine for enzymic activity (allosteric activator) and is an important prototype of lipid-requiring enzymes. Despite extensive studies, the primary sequence has not been available and is now reported. The mature form of the enzyme consists of 297 amino acids (predicted M(r) of 33,117), does not appear to contain any transmembrane helices, and is homologous with the family of short-chain alcohol dehydrogenases (SC-ADH) (Persson, B., Krook, M., and J?rnvall, H. (1991) Eur. J. Biochem. 200, 537-543) (30% residue identity with human 17 beta-hydroxysteroid dehydrogenase). The first two-thirds of the enzyme includes both putative coenzyme binding and active site conserved residues and exhibits a predicted secondary structure motif (alternating alpha-helices and beta-sheet) characteristic of SC-ADH. Bovine heart peptide sequences (174 residues in nine sequences determined by microsequencing) have extensive homology (89% identical residues) with the deduced human heart sequence. The C-terminal third (Asn-194 to Arg-297) shows little sequence homology with the SC-ADH and likely contains elements that determine the substrate specificity for the enzyme including the phospholipid (phosphatidylcholine) binding site(s). Northern blot analysis identifies a 1.3-kilobase mRNA encoding the enzyme in heart tissue.     

Spectral and kinetic studies on Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating)

Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating) contains two FAD molecules in one molecule of the enzyme (Koyama, H. (1983) J. Biochem. 93, 1313-1319). When the enzyme was mixed anaerobically with L-phenylalanine, beta-2-thienylalanine, L-tyrosine, or L-methionine, a spectral species (purple intermediate) with a broad absorption band around 540 nm was observed with each substrate, and decayed slowly. From the data on the overall reaction kinetics, the rate of the L-phenylalanine oxidase reaction was expressed as follows. e/v = e/Vm + A/[S] + B/[O2] where e represents the concentration of enzyme unit, v the rate of the overall reaction, Vm the maximum velocity, and A and B are constants. Furthermore, the reactions of the enzyme with beta-2-thienylalanine (mostly an oxygenase substrate) and L-methionine (an oxidase substrate) were analyzed by the "stopped flow" method. The following scheme for the mechanism of L-phenylalanine oxidase reaction with both substrates is proposed, based on the data obtained. (formula; see text) Where Eox represents the oxidized form of the enzyme unit, EoxS the enzyme unit (oxidized form)-substrate compound, X the purple intermediate with a characteristic broad absorption band around 540 nm, S the substrate and P the product.     

Effects of primary sequence differences on the global structure and function of an enzyme: a study of pyruvate kinase isozymes

Pyruvate kinase is an important glycolytic enzyme which is expressed differentially as four distinct isozymes whose catalytic activity is regulated in a tissue-specific manner. The kidney isozyme is known to exhibit sigmoidal kinetics, whereas the muscle isozyme exhibits hyperbolic kinetic properties. By integration of the crystallographic [Stuart, D. I., Levine, M., Muirhead, H., & Stammers, D.K. (1979) J. Mol. Biol. 134, 109-142] and primary sequence data [Noguchi, T., Inoue, H., & Tanaka, T. (1986) J. Biol. Chem. 261, 13807], it was shown that the primary sequence for the C alpha 1 and C alpha 2 regions may constitute the allosteric switching site. To provide insights into the effects of the localized sequence change on the global structural and functional behavior of the enzyme, kinetic studies under a wide spectrum of conditions were conducted for both the muscle and kidney isozymes. These conditions include measurements of enzyme activity as a function of substrate concentrations with different concentrations of allosteric inhibitors or activators. These results showed that both isozymes exhibit the same regulatory properties although quantitatively the distribution of active and inactive forms and the various dissociation constants which govern the binding of substrate and allosteric effectors with the enzyme are different. For such a majority of equilibrium constants to be altered, the localized primary sequence change must confer global perturbations which are manifested as differences in the various equilibrium constants. Structural information about these two isozymes was provided by phase-modulation measurement of the fluorescence lifetime of tryptophan residues under a variety of experimental conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Importance of experimental conditions in evaluating the malonyl-CoA sensitivity of liver carnitine acyltransferase. Studies with fed and starved rats.

The experiments reconfirm the powerful inhibitory effect of malonyl-CoA on carnitine acyltransferase I and fatty acid oxidation in rat liver mitochondria (Ki 1.5 microM). Sensitivity decreased with starvation (Ki after 18 h starvation 3.0 microM, and after 42 h 5.0 microM). Observations by Cook, Otto & Cornell [Biochem. J. (1980) 192, 955--958] and Ontko & Johns [Biochem. J. (1980) 192, 959--962] have cast doubt on the physiological role of malonyl-CoA in the regulation of hepatic fatty acid oxidation and ketogenesis. The high Ki values obtained in the cited studies are shown to be due to incubation conditions that cause substrate depletion, destruction of malonyl-CoA or generation of excessively high concentrations of unbound acyl-CoA (which offsets the competitive inhibition of malonyl-CoA towards carnitine acyltransferase I). The present results are entirely consistent with the postulated role of malonyl-CoA as the primary regulatory of fatty acid synthesis and oxidation in rat liver.     

Is rat skeletal muscle hexokinase an allosteric enzyme?

A recent report by M. Gregoriou, I. P. Trayer, and A. Cornish-Bowden (1986, Eur. J. Biochem. 161, 171-176) showed that the mechanism for rat skeletal muscle hexokinase contains two allosteric sites: one for ATP and one for glucose 6-phosphate. In this report, we show that the allosteric mechanism is at variance with a large amount of kinetic data for the skeletal muscle hexokinase reaction in the literature. In addition, the allosteric mechanism conflicts with isotope exchange at chemical equilibrium data reported by M. Gregoriou, I. P. Trayer, and A. Cornish-Bowden (1983, Eur. J. Biochem. 134, 283-288).