Alkylation of bovine brain creatine kinase

Alkylation of rabbit muscle creatine kinase surface methionine residues inhibits enzyme activity in vitro

Creatine kinase (CK) catalyzes the formation of phosphocreatine from adenosine triphosphate (ATP) and creatine. The highly reactive free cysteine residue in the active site of the enzyme (Cys²⁸³) is considered essential for the enzymatic activity. In previous studies we demonstrated that Cys²⁸³ is targeted by the alkylating chemical warfare agent sulfur mustard (SM) yielding a thioether with a hydroxyethylthioethyl (HETE)-moiety. In the present study, the effect of SM on rabbit muscle CK (rmCK) activity was investigated with special focus on the alkylation of Cys²⁸³ and of reactive methionine (Met) residues. For investigation of SM-alkylated amino acids in rmCK, micro liquid chromatography-electrospray ionization high-resolution tandem-mass spectrometry measurements were performed using the Orbitrap technology. The treatment of rmCK with SM resulted in a decrease of enzyme activity. However, this decrease did only weakly correlate to the modification of Cys²⁸³ but was conclusive for the formation of Met⁷⁰-HETE and Met¹⁷⁹-HETE. In contrast, the activity of mutants of rmCK produced by side-directed mutagenesis that contained substitutions of the respective Met residues (Met⁷⁰Ala, Met¹⁷⁹Leu, and Met⁷⁰Ala/Met¹⁷⁹Leu) was highly resistant against SM. Our results point to a critical role of the surface exposed Met⁷⁰ and Met¹⁷⁹ residues for CK activity.

Non-identical behaviour of the subunits of rabbit muscule creatine kinase

1. The dimeric enzyme creatine kinase (ATP: creatine N-phospotransferase, EC 2.7.3.2) from rabbit muscle was reacted with three separate reagents, each of which specifically modifies one thiol group per subunit. 2. The reactions of the enzyme with these reagents (4-chloro-7-nitrobenzofurazan, 5,5'-dithiobis-(2-nitrobenzoic acid) and iodoacetate) all behave as normal second-order processes. This indicates that the thiol groups on the two subunits of the enzyme react at the same rate as each other in all three cases. 3. The effects of various ligands (Mg2+, ADP and creatine, and combinations of these) on the kinetics of the reactions were studied. In all cases the reactions behave as normal second-order processes. 4. In the presence of the ligand combination Mg2+ plus ADP plus creatine plus nitrate, which has been postulated to form a "transition state analogue" complex with the enzyme, the reactions of the thiol group show considerable deviation from second-order kinetics. This indicates that the thiol groups on the two subunits react at different rates from each other. A similar effect is also noted in the presence of the combination ADP plus creatine plus nitrate. 5. The binding of ADP to the enzyme (studied by equilibrium dialysis) is hyperbolic in the absence of other ligands or in the presence of Mg2+ or Mg2+ plus creatine. The dissociation constant is similar in all three cases. 6. In the presence of creatine plus nitrate (with or without Mg2+) the bindings of ADP to the enzyme is tightened considerably and the binding plots indicate the presence of either negative interactions between the subunits or two distinct types of binding sites. 7. Possible causes for the observed non-identical behaviour of the two subunits of the enzyme are discussed.

Properties and mechanism of action of creatine kinase from ox smooth muscle. Anion effects compared with pyruvate kinase

1. An improved purification procedure for the brain-type creatine kinase from ox smooth muscle is described. 2. Michaelis constants show the characteristic dependence on the concentration of the second substrate: the derived constants are compared with those for the enzyme from ox brain. 3. Inhibition by iodoacetamide gives a biphasic curve and the total extent of the reaction depends on the enzyme concentration. The rate of inhibition at pH8.6 is not affected by creatine plus MgADP or by a range of simple anions. Addition of creatine plus MgADP plus either NO(3) (-) or Cl(-) ions affords 71.5 and 44% protection respectively. ADP could be replaced by 2-deoxy-ADP but not by alphabeta-methylene ADP, XDP, IDP, GDP or CDP. Nucleotides that did not protect would not act as substrates. 4. Difference-spectra measurements support the interpretation that addition of NO(3) (-) ions to the enzyme-creatine-MgADP complex causes further conformational changes in the enzyme accompanying the formation of a stable quaternary enzyme-creatine-NO(3) (-)-MgADP complex that simulates an intermediate stage in the transphosphorylation reaction. However, the enzyme structure is partially destabilized by quaternary-complex formation. IDP apparently fails to act as a substrate because it cannot induce the necessary conformational change. This behaviour is compared with that of rabbit skeletal muscle creatine kinase. 5. With pyruvate kinase from rabbit muscle, anions activate in the absence of an activating cation and either inhibit or have no effect in its presence. 6. Both activation and inhibition were competitive with respect to the substrate, phosphoenolpyruvate, and curved double-reciprocal plots were obtained. The results may be interpreted in terms of co-operatively induced conformational changes, and this is supported by difference-spectra measurements. However, the Hill coefficient of 1 was not significantly altered. 7. Inhibition by lactate plus pyruvate is less than additive, indicating that both bind to the same site on the enzyme, whereas that by lactate plus NO(3) (-) is additive, indicating binding at separate sites. It is inferred that a quaternary enzyme-pyruvate-NO(3) (-)-MgADP complex could form, but no evidence was obtained to suggest that it possessed special properties comparable with those found with creatine kinase. The implications of these findings for the unidirectional nature of the mechanism of pyruvate kinase is discussed. 8. Lactate or alpha-hydroxybutyrate could not act instead of pyruvate to form a stable quaternary complex, although both activate the K(+)-free enzyme. Only the former inhibits the K(+)-activated enzyme. The activating cation both lowers the Michaelis constant for phosphoenolpyruvate and tightens up the specificity of its binding site.

Purification and properties of adenosine triphosphate-creatine phosphotransferase from muscle of the dogfish Scylliorhinus canicula

1. Creatine kinase occurs in high concentration in the soluble proteins of dogfish muscle. A fourfold purification gives essentially pure enzyme but with a low specific activity. This appears to be a property of the native enzyme and not a result of the isolation procedures used. 2. The amino acid composition is similar to that of other phosphagen kinases, but the enzyme differs from mammalian creatine kinases in having four thiol groups readily reactive towards 5,5'-dithiobis-(2-nitrobenzoic acid). Titration of two thiol groups is accompanied by almost complete loss of activity. The remaining two thiol groups react at different rates, suggesting that modifying the third thiol group affects the reactivity of the fourth thiol group. 3. The enzyme is markedly protected against inactivation by iodoacetamide by MgATP or MgADP. Addition of creatine to MgADP decreases protection, but the further addition of Cl(-) restores protection to the original value. The quaternary MgADP-creatine-enzyme-nitrate complex protects very strongly as is found for the rabbit enzyme. The involvement of the conformational state of the enzyme in such effects is discussed. 4. Creatine kinase from both dogfish and rabbit is equally sensitive to urea denaturation. Urea protects the dogfish enzyme by about 9% against inhibition by iodoacetamide. 5. The formation of a hybrid between the dogfish and rabbit enzymes in vitro has been demonstrated. 6. At high substrate concentrations the dogfish enzyme shows apparent ordered kinetics. The effect of temperature on V(max.) and the Michaelis constants for MgATP and creatine were determined. These and changes in the apparent activation energy suggest that limited adaptation has occurred commensurate with physiological need.

Brain adenosine 5'-triphosphate-creatine phosphotransferase

1. The purification of creatine kinase (ATP-creatine phosphotransferase, EC 2.7.3.2) from ox brain by a method that is quicker, simpler and gives much higher yields than other published procedures is described. 2. Stoicheiometric inhibition studies with iodoacetate showed that the enzyme, like that from muscle, has two reactive thiol groups that are essential for enzyme activity. 3. The amino acid sequence around the essential thiol groups was determined and found to be virtually identical with that in creatine kinases from rabbit and ox muscle, and very similar to that found in arginine kinase; the evolutionary significance of this is discussed. 4. The identification of DNS-amino acids on thin layers of silica gel was found to have, in many cases, distinct advantages over that on polyamide layers.