Kinetic studies on the regulation of rabbit liver pyruvate kinase

Two kinetically distinct forms of pyruvate kinase (EC 2.7.1.40) were isolated from rabbit liver by using differential ammonium sulphate fractionation. The L or liver form, which is allosterically activated by fructose 1,6-diphosphate, was partially purified by DEAE-cellulose chromatography to give a maximum specific activity of 20 units/mg. The L form was allosterically activated by K(+) and optimum activity was recorded with 30mm-K(+), 4mm-MgADP(-), with a MgADP(-)/ADP(2-) ratio of 50:1, but inhibition occurred with K(+) concentrations in excess of 60mm. No inhibition occurred with either ATP or GTP when excess of Mg(2+) was added to counteract chelation by these ligands. Alanine (2.5mm) caused 50% inhibition at low concentrations of phosphoenolpyruvate (0.15mm). The homotropic effector, phosphoenolpyruvate, exhibited a complex allosteric pattern (n(H)=2.5), and negative co-operative interactions were observed in the presence of low concentrations of this substrate. The degree of this co-operative interaction was pH-dependent, with the Hill coefficient increasing from 1.1 to 3.2 as the pH was raised from 6.5 to 8.0. Fructose 1,6-diphosphate interfered with the activation by univalent ions, markedly decreased the apparent K(m) for phosphoenolpyruvate from 1.2mm to 0.2mm, and transformed the phosphoenolpyruvate saturation curve into a hyperbola. Concentrations of fructose 1,6-diphosphate in excess of 0.5mm inhibited this stimulated reaction. The M or muscle-type form of the enzyme was not activated by fructose 1,6-diphosphate and gave a maximum specific activity of 0.3 unit/mg. A Michaelis-Menten response was obtained when phosphoenolpyruvate was the variable substrate (K(m)=0.125mm), and this form was inhibited by ATP, as well as alanine, even in the presence of excess of Mg(2+).     

Kinetic properties of pyruvate kinase of rabbit brain

Summary The kinetic properties of rabbit brain pyruvate kinase have been studied to determine its role in the regulation of glycolysis. One of the substrates of the enzyme, phosphoenolpyruvate, exhibits homotropic cooperativity (Hill coeff. of 1.45); thus, it is a moderate activator of the enzyme. The other substrate, ADP, shows normal Michaelis-Menton kinetics. Fructose-6-phosphate and glucose-6-phosphate activate the enzyme only slightly at the 1mm level and inhibit slightly at higher levels, and hence have no metabolic influence on the enzyme activity. Fructose-1, 6-diphosphate also has a slight activation up to 0.5 mm but no inhibition at higher level; therefore, it has no influence either. ATP, 2-phosphoglycerate, and phenylalanine are inhibitors of the enzyme. ATP, being the energy reservoir derived from glycolysis as well as a product of the reaction catalyzed by the enzyme, is a significant feedback inhibitor of the enzyme. These kinetic properties suggest a key role for pyruvate kinase in the regulation of glycolysis. Phenylalanine inhibition of the enzyme has been reported to be a possible mechanism of damage to the developing brain in phenylketonuria. The inhibition by phenylalanine at 10 mm in the assay mixture is reversed by alanine, cysteine, or serine at 0.2 mm level. Furthermore, the effect of these amino acids in reversing the phenylalanine inhibition are mutually enhancing. Consequently phenylalanine cannot have a significant inhibition on the activity of pyruvate kinase in brain.A preliminary report has been presented at the American Society of Biological Chemists Meeting at Atlanta, Georgia, June 1978.     

Kinetic studies on the mechanism and regulation of rabbit liver fructose-1,6-bisphosphatase

The interaction of Mg2+, AMP, and fructose 2,6-bisphosphate with respect to rabbit liver fructose-1,6-bisphosphatase was investigated by studying initial-rate kinetics of the system at pH 9.5. A rapid-equilibrium Random Bi Bi mechanism is suggested for the rabbit liver enzyme from the kinetic data. Our kinetic findings indicate that Mg2+ and the inhibitor AMP are mutually exclusive in their binding to fructose-1,6-bisphosphatase. This probably is the mechanism for AMP regulation of fructose-1,6-bisphosphatase and thus, to some extent, gluconeogenesis. A kinetic model for the interaction of these ligands with respect to rabbit liver fructose-1,6-bisphosphatase is presented.     

Kinetic studies on rabbit liver glucocorticoid 5alpha-reductase.

The serum concentration of active glucocorticosteroids depends not only on adrenal synthesis but also on enzymatic activation of 11-dehydro-glucocorticoids in the liver by 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1). In order to define the respective involvement of other regulative enzymes in the metabolism of 11-dehydro-glucocorticoids in the liver, the objective of this study was to evaluate the kinetic behavior of NADPH:delta 4-3-ketosteroid-5alpha-reductase (5alpha-reductase, EC 1.3.99.5). The interrelations to liver 11beta-HSD1 will be discussed. The kinetic properties of 5alpha-reductase of the rabbit liver were measured by a radioenzymatic assay and characterized with respect to protein-, substrate-, cosubstrate-, and pH-dependence. Michaelis-Menten enzyme kinetic parameters (Km and Vmax) were obtained for the formation of 5alpha-reduced 11-dehydrocorticosterone and corticosterone metabolites. We found that both 11-dehydrocorticosterone (Km 4.2 x 10(-6) mol/l, Vmax 2,600 pmol x min(-1) x mg(-1)) and corticosterone (Km 0.5 x 10(-6) mol/l, Vmax 38 pmol x min(-1) x mg(-1)) exhibit a high affinity to 5alpha-reductase. With respect to cosubstrate-, pH-dependence and finasteride inhibition, it is likely that 11-dehydrocorticosterone metabolism is primarily controlled by isoenzyme 5alpha-reductase type 1. This study shows that the deactivation of GCS especially of 11-dehydro-glucocorticoids via 5alpha-reductase is an important metabolic pathway in the liver. The metabolic activation of GCS by 11beta-HSD could possibly lead to an excess of GCS in the hepatocytes. Due to 5alpha-reductase activity this excess can be limited - on the level of CORT as well as of 11-DHC.     

25Mg NMR studies of yeast enolase and rabbit muscle pyruvate kinase.

25Mg NMR spectroscopy was used to study the interactions of the activating cations with their respective binding sites in the enzymes yeast enolase and rabbit muscle pyruvate kinase (PK). Titration of Mg2+ with enolase allows for the calculation of 1/T2 for Mg2+ bound at site I of 1510 s-1 and a quadrupolar coupling constant chi = 0.30 MHz. Titration of Mg2+ with enolase in the presence of 2-phosphoglycerate (PGA) and Zn2+, where Zn2+ binds specifically at site I, gives a 1/T2 for Mg2+ bound at site II of 4000 s-1 (chi = 0.49 MHz). The Mg2+ at site II appears to be more anisotropic than Mg2+ at site I. The titration of site I of the enolase-Mg-PGA-Mg complex with Zn2+ or Mn2+ shows a simple displacement of the Mg2+. No paramagnetic effects by Mn2+ on 25Mg relaxation were observed. Temperature studies of the 25Mg resonance show that fast exchange of the Mg2+ occurs under these conditions. From the lack of a paramagnetic effect, the distance between the cations at sites I and II must be more than 6-9 A. This distance limits the location, hence the function, of the cation at site II for catalytic activity. Titration of Mg2+ with PK gives a 1/T2 for bound Mg2+ of 2200 s-1 (chi = 0.24 MHz). A titration of Mg2+ with PK in the presence of the inhibitor oxalate gives a 1/T2 of 400 s-1. The temperature dependence of 25Mg relaxation in the PK-Mg-oxalate complex is consistent with slow exchange (Ea = 6.1 +/- 1.6 kcal/mol). The enzyme-bound cation is more tightly sequestered by the addition of a ligand that binds directly to the cation. An investigation of the 25Mg relaxation in the PK-Mn-oxalate-Mg-ATP complex, where the Mg2+ is bound to the nucleotide and the Mn2+ was enzyme bound, was not successful due to precipitation of PK under experimental conditions and the short T2 relaxation for 25Mg in this complex. The applications of 25Mg NMR have been useful in partially describing the properties of the bound Mg2+ in these two metal-requiring enzymes.     

Kinetic properties of cerebral pyruvate kinase

Partly purified guinea-pig brain pyruvate kinase is not activated by fructose 1,6-diphosphate and gives hyperbolic substrate-saturation curves with phosphoenolpyruvate. It is therefore different from the L-type pyruvate kinase of mammalian liver. Inhibition by MgATP(2-) was competitive for MgADP(-) but not for phosphoenolpyruvate, and the enzyme is therefore different from the M-type pyruvate kinase, which is said to be competitively inhibited by MgATP(2-) with respect to both substrates. The K(i)(MgATP(2-)) value of approx. 8mm for the brain enzyme is higher than the values (about 2mm) reported for the muscle enzyme. Stimulation of enzymic activity was observed at low (1-2mm) concentrations of MgATP(2-). Substrate kinetic constants were K(m) (MgADP(-))=0.47mm, K(m) (phosphoenolpyruvate)=0.08mm. Free Mg(2+) at very high concentrations (over 10mm) was inhibitory (K(i)=20-32mm). Neither ADP(3-) nor 5'-AMP(2-) inhibited the activity. The brain enzyme was concluded to be different from both the M-type and the L-type of other mammalian organs such as muscle and liver.     

pH studies on the chemical mechanism of rabbit muscle pyruvate kinase. 2. Physiological substrates and phosphoenol-alpha-ketobutyrate

pH profiles have been determined for the reactions catalyzed by pyruvate kinase between pyruvate and MgATP and between phosphoenolpyruvate and MgADP. V, V/KMgATP, and V/Kpyruvate all decrease below a pK of 8.3 and above one of 9.2. The group with pK = 8.3 is probably a lysine that removes the proton from pyruvate during enolization, while the pK of 9.2 is that of water coordinated to enzyme-bound Mg2+. The fact that this pK shows in all three pH profiles shows that pyruvate forms a predominantly second sphere complex and cannot replace hydroxide to form the inner sphere complex that results in enolization and subsequent phosphorylation. On the basis of the displacement of the pK of the acid-base catalytic group in its V/K profile, phosphoenolpyruvate is a sticky substrate, reacting to give pyruvate approximately 5 times faster than it dissociates. The V/K profile for the slow substrate phosphoenol-alpha-ketobutyrate shows the pK of 8.3 for the acid-base catalytic group in its correct position, but this group must be protonated so that it can donate a proton to the intermediate enolate following phosphoryl transfer. The secondary phosphate pK of the substrate is seen in this V/K profile as well as in the pKi profile for phosphoglycolate (but not in those for glycolate O-sulfate or oxalate), showing a preference for the trianion for binding. The chemical mechanism with the natural substrates thus appears to involve phosphoryl transfer between MgADP and a Mg2+-bound enolate with metal coordination of the enolate serving to make it a good leaving group.     

Kinetic properties of liver pyruvate kinase from the flounder (Platichthys flesus L.)

Pyruvate kinase, purified from flounder liver, in two forms, i.e. PK I and PK II, is characterized by sigmoid kinetics with phosphoenolpyruvate as substrate at pH 6.3, 6.7 and 7.7. K0.5 for PEP increases with increasing pH. PK I and PK II show hyperbolic kinetics with ADP, but are inhibited by ADP concentrations above 1-2 mM. K0.5 for ADP decreases with increasing pH. PK I and PK II differ in their K0.5 values for PEP with a factor of at least 2, showing the highest figures for the latter. K0.5 for ADP is about the same for the two enzyme forms. Other nucleotide diphosphates can replace ADP as the substrate. When the nucleoside diphosphates are arranged in a rank order showing decreasing effectiveness as substrate, different rank orders are obtained for PK I and PK II.     

Nuclear magnetic relaxation studies of the conformation of adenosine 5'-triphosphate on pyruvate kinase from rabbit muscle.

The conformation of adenosine 5'-triphosphate in the manganese complex of pyruvate kinase from rabbit muscle was determined from six metal to nucleus distances derived by nuclear magnetic relaxation techniques. On the enzyme, no direct metal-ATP coordination exists. The phosphorous atoms of ATP are 4.9 to 5.1 A away from manganese, a distance which indicates either a predominantly (greater than or equal to 94%) second sphere complex or, less likely, a highly distorted inner sphere complex. Thus, water ligands or ligands from the protein might intervene between the ATP molecule and the divalent metal ion and facilitate their interaction. The metal-gammaP distance of 5 A for pyruvate kinase-bound ATP is equal to that found for the phosphorous atom of phosphoenolpyruvate and cobalt(II) on pyruvate kinase (Melamud, E., and Mildvan, A. S. (1975) J. Biol. Chem. 250, 8193-8201), which is consistent with the overlap in space of the P-enolpyruvate-phosphorus and the gammaP of ATP at the active site. This observation explains the competitive binding of these two substrates to the enzyme, as detected by NMR and by early kinetic studies. From the phosphorus data and from measurements of the relaxation rates of 3 protons of ATP in the pyruvate kinase-metal-ATP complex, the conformation of ATP was characterized as extended with distances of 6.0, 9.1, and 7.5 A from manganese to the H8, H2, and H'1 protons, respectively. The torsion angle about the glycosidic bond (chi) which defines the conformation of the enzyme-bound riboside and adenine rings was determined to be 30 degrees. In contrast, the conformation of the binary Mn(II)-ATP complex in solution is folded around the metal with direct manganese coordination of the alpha-, beta-, and gamma-phosphorus atoms, and with metal to proton distances of 4.5, 6.4, and 6.2 A for the H8, H2, and H'1 protons, suggesting a second sphere manganese-adenine interaction. The chi angle equals 90 degrees for the binary complex primarily because of the metal-base interaction. Thus, a profound change in the conformation and structure of Mn(II)-ATP from a folded chelate to an extended second sphere complex results when the nucleotide binds to pyruvate kinase.     

Phosphoenolpyruvate hydrolase activity of rabbit muscle pyruvate kinase.

Rabbit muscle pyruvate kinase catalyzes the hydrolysis of P-enolpyruvate at the same active site which catalyzes the physiologically important kinase reaction. The hydrolase activity is lower than the kinase activity by a factor of at least 10(3). There are specific monovalent cation and divalent cation requirements. No other cofactors are required. The relative activation of the pyruvate kinase for the hydrolase reaction is: Ni(II) greater than Co(II) greater than Mg(II) greater than Mn(II). This parallels the rates of nonenzymatic hydrolysis of P-enolpyruvate (Benkovic, S.J., and Schray, K.J. (1968) Biochemistry 7, 4097-4102). The pH rate profiles of the hydrolase and kinase reactions activated by Ni(II) and Co(II) are similar, suggesting common features in their mechanisms. In contrast to the kinase reaction, the reaction velocity of the hydrolase increases at high Co(II) concentrations indicating a second mode for hydrolysis.     

Kinetic properties of human muscle pyruvate kinase

Summary The steady-state kinetics of human skeletal muscle pyruvate kinase (M_A) and its RNA-complex (M_B) has been examined and compared. Kinetic studies revealed significant differences in kinetic properties with respect to free and complex form of pyruvate kinase.The M_A form follows a simple Michaelis-Menten kinetics in contrast with the M_B form, which displays a negative cooperativity with respect to ADP. V_max for the complex is 40–60% that for free enzyme. Heterologous RNA is a noncompetitive inhibitor of free enzyme but the kinetics of the complex (M_B) is not affected.In presence of 1.0 mM ATP in an assay mixture the kinetic constants of the complex were unchanged except for V_max, which increased by nearly 60%. Aged preparations of free enzyme (M_A) were activated by 100% and more, but the native enzyme was inhibited by 22%.Inorganic phosphate is a potent activator of both forms of pyruvate kinase. In presence of 50 mM K-phosphate the apparent Michaelis constant and interaction coefficient are unchanged, but V_max for free enzyme increases by 35% and for the complex by 70%, respectively. The specific activity of aged M_A form can be restored to the original value after incubation of the enzyme in 50 mM K-phosphate, pH 7.6, or by addition of ATP (1.0 mM) to the assay mixture.     

Dexamethasone effects on liver pyruvate kinase

Dexamethasone in the medium perfusin isolated rabbit livers caused a fast-acting and reversible effect on liver pyruvate kinase. The effect was to lower th assayable V activity (units/g tissue) without changing the concentration (nmol/g enzyme protein). In effect, glucocorticoid lowered the specific activity (units/nmol of enzyme) by direct action on liver. The effect on liver pyruvate kinase is mediated by a relatively stable alteration; 30 min after perfusate (with steroid) was replaced by perfusate (without steroid), the effect remained strongly evident.     

The refolding of denatured rabbit muscle pyruvate kinase.

The refolding of rabbit muscle pyruvate kinase after denaturation by guanidine hydrochloride was studied. On dilution of the denaturing agent, enzyme activity is only partially regained. The extent of regain of activity is dependent on protein concentration, showing a marked decrease at higher concentrations. The failure to regain complete activity appears to be related to the formation of inactive aggregates, which can be separated from active enzyme by gel filtration. Insoluble aggregates can be partially re-activated after solubilization in guanidine hydrochloride. Changes in the circular-dichroism and fluorescence spectra during refolding suggest that a partially folded, inactive species is formed rapidly; this differs from native enzyme in being more susceptible to proteolysis by trypsin.     

Turnover of liver pyruvate kinase

The relative rates of synthesis and degradation for liver pyruvate kinase have been determined in rats fed standard lab chow, fasted, and refed a high-carbohydrate-low-protein diet. Relative rates of synthesis and apparent rates of degradation were determined by pulse-labeling the enzyme in vivo with l-[4,5-³H]leucine and by measuring the incorporation of radioactivity into liver pyruvate kinase after quantitative precipitation of the enzyme with anti-liver pyruvate kinase immunoglobulin. The relative rate of synthesis decreased approximately 75% upon fasting and then increased 20- to 30-fold upon refeeding the high-carbohydrate diet. The apparent half-lives for liver pyruvate kinase in fasted, control, and refed animals are very similar (55, 59, and 47 h, respectively). Thus, the nutritional alterations in the levels of liver pyruvate kinase seem to result primarily from alterations in the rate of enzyme synthesis.