Octameric mitochondrial and dimeric cytoplasmic creatine kinase. The number of subunits, participating in catalysis

It was found that in the octameric form of mitochondrial creatine kinase (Mr = 340 kD), only 52% of active centers bind Mg-ADP into a E-Mg-ADP-creatine complex with the dissociation constant, K(Cr)ADP, of 0.105 mM, which is close to the Km value for the enzyme (0.072 mM). In the dimeric form of cytoplasmic creatine kinase (Mr = 82 kD), 100% of active centers bind Mg--ADP; the K(Cr)ADP value (0.11 mM) is close to the Km value for the given enzyme preparation (0.083 mM). All active centers of rabbit muscle cytoplasmic creatine kinase were shown to form an analog of the transition state complex (ATSC) - E-Mg-ADP-NO3- -creatine. The constant for Mg-ADP dissociation from ATSC is identical for all centers of cytoplasmic creatine kinase and equals to 6.0 microM. The curves for ATSC saturation with Mg-ADP in the presence of iodacetamide for mitochondrial creatine kinase were constructed and computer analyzed. It was shown that in the octameric form of the enzyme only 54 +/- 13% of subunits can form ATSC. The constant for Mg-ADP dissociation from ATSC, KATSCADP is equal to 1.9 +/- 0.8 microM. It was concluded that 50% of subunits of the octameric form of mitochondrial creatine kinase are not involved in the catalytic act due to masking of their active centres and their inability to form transition state complexes. A model of regulation of cell supply with high energy compounds, e.g., ATP, creatine phosphate, via association-dissociation of mitochondrial creatine kinase oligomers is proposed.     

Inactivation of rabbit muscle creatine kinase by reversible formation of an internal disulfide bond induced by the fungal toxin gliotoxin

The biological activity of gliotoxin is dependent on the presence of a strained disulfide bond that can react with accessible cysteine residues on proteins. Rabbit muscle creatine kinase contains 4 cysteines per 42-kDa subunit and is active in solution as a dimer. Only Cys-282 has been identified as essential for activity. Modification of this residue results in loss of activity of the enzyme. Treatment of creatine kinase with gliotoxin resulted in a time-dependent loss of activity abrogated in the presence of reducing agents. Activity was restored when the inactivated enzyme was treated with reducing agents. Inactivation of creatine kinase by gliotoxin was accompanied by the formation of a 37-kDa form of the enzyme. This oxidized form of creatine kinase was rapidly reconverted to the 42-kDa species by the addition of reducing agents concomitant with restoration of activity. A 1:1 mixture of the oxidized and reduced monomer forms of creatine kinase as shown on polyacrylamide gel electrophoresis was equivalent to the activity of the fully reduced form of the enzyme consistent with only one reduced monomer of the dimer necessary for complete activity. Conversion of the second monomeric species of the dimer to the oxidized form by gliotoxin correlated with loss of activity. Our data are consistent with gliotoxin inducing the formation of an internal disulfide bond in creatine kinase by initially binding and possibly activating a cysteine residue on the protein, followed by reaction with a second neighboring thiol. The recently published crystal structure of creatine kinase suggests the disulfide is formed between Cys-282 and Cys-73.     

Human brain creatine kinase binding to immobilized cibacron blue F3GA: characterization and use in purification of the enzyme.

Creatine kinase (ATP: creatine N-phosphotransferase, EC 2.7.3.2) from adult human brain grey matter was purified by cibacron blue F3GA-Sepharose affinity chromatography. By gel electrophoresis of the purified enzyme under non-denaturing conditions a single protein band was observed. The dye-bound enzyme was eluted using its substrate, ATP. Reversibility of the binding of purified creatine kinase to blue Sepharose by ATP in a concentration-dependent manner indicated that the cibacron blue molecule which structurally mimics nucleotides occupied the substrate binding site of the enzyme. Also the marked dependence of enzyme binding to blue Sepharose on Mg2+ concentration suggested that Mg2+ ion is capable of combining with the dye moiety to form a site-specific binding complex that is similar to the physiological substrate of creatine kinase, namely Mg(2+)-ATP or Mg(2+)-ADP.     

Creatine kinase isoenzymes in Torpedo californica: absence of the major brain isoenzyme from nicotinic acetylcholine receptor membranes

Creatine kinase, actin, and nu 1 are three proteins of Mr 43 000 associated with membranes from electric organ highly enriched in nicotinic acetylcholine receptor. High levels of creatine kinase are required to maintain adequate ATP levels, while actin may play a role in maintaining the synaptic cytoskeleton. Previous investigations have prompted the conclusion that postsynaptic specializations at the receptor-enriched membrane domains in electroplax contain the brain form of creatine kinase rather than the form of creatine kinase predominantly found in muscle. We have examined this conclusion by purifying Torpedo brain creatine kinase to virtual homogeneity in order to examine its immunochemical, molecular, and electrophoretic properties. On the basis of immunological cross-reactivity and isozyme analysis, the receptor-associated creatine kinase is identified to be of the muscle type. When the molecular characteristics of Torpedo brain and muscle creatine kinase are compared, the brain enzyme is positioned at a more basic pH during chromatofocusing and on two-dimensional gel electrophoresis (pI = 7.5-7.9). Furthermore, electrophoretic mobilities of the brain and muscle forms of creatine kinase differ in sodium dodecyl sulfate electrophoresis: the brain isozyme of creatine kinase has lower apparent molecular weight (Mr 41 000) when compared with the muscle enzyme (Mr 43 000). On the basis of the results of our current investigations, the hypothesis that the brain isozyme of creatine kinase is a component of the postsynaptic specializations of the Torpedo californica electroplax must be abandoned. Recent sequence data have established close homology between Torpedo and mammalian muscle creatine kinases. On the basis of electrophoretic criteria, our results indicate that a lower degree of homology exists between the brain isozymes.     

Physiological role of the creatine kinase system and the problem of regulating the activity of mitochondrial creatine kinase

The review contains the analysis of present-day concepts on the physiological role of the creatine kinase system. A hypothesis on the buffering functions of the creatine kinase system which ensures a constant ATP level in cells and a hypothesis according to which phosphocreatine is a macroergic phosphate carrier from mitochondria to the sites of their utilization are considered. In connection with the creatine phosphate carrier hypothesis according to which the transport function of the creatine kinase system is provided for by an effective function of mitochondrial creatine kinase, feasible mechanisms of mitochondrial creatine kinase activity regulation are considered: as a result of creation of local concentration of nucleotide substrates as well as changes in the properties of creatine kinase itself which may result from the enzyme conversion from the membrane-bound to the free form or from the interconversion of oligomeric forms of the enzyme.     

Only one of the two interconvertible forms of mitochondrial creatine kinase binds to heart mitoplasts

When analyzed by cellulose acetate electrophoresis, solubilized pig or rabbit heart mitochondrial creatine kinase is shown to exist under two distinct forms. The less cathodic one (form 1) is a dimer and the other having a higher cathodic mobility (form 2) has a molecular weight of about 350 000. The latter form can be converted into the former by incubation at alkaline pH or when the enzyme forms a reactive or an abortive complex with its substrates. This conversion is a reversible phenomenon and is not due to proteolysis. When rabbit heart mitoplasts are treated with the creatine kinase releasing agents, the enzyme is always solubilized as its form 2 and conversion to form 1, when it occurs, always take place after solubilization. Form 2 is also the only form which can be bound to pig or rabbit mitoplasts. Thus form 2 may be the actual form associated with heart mitochondria in vivo.     

Interaction of various nucleotide-dependent enzymes with bifunctional analogs of ATP, derivatives of polymethylene diamines

The interaction of bifunctional ATP derivatives, Appp5'[NH-(CH2) n-NH]ppp5'A (n = 0 or 2-8) with tyrosyl-, valyl-, lysyl-, tryptophanyl-tRNA synthetases and creatine kinase was investigated. ATP derivatives don't inhibit the tRNA aminoacylation catalyzed by tyrosyl-tRNA synthetase. These derivatives behave as mixed-type inhibitors with respect to ATP in the case of valyl- and lysyl-tRNA-synthetases. In the case of the other enzymes all analogs of ATP manifest competitive inhibition towards ATP. The affinity of all ATP derivatives to tryptophanyl-tRNA synthetase does not differ significantly (Ki = 0.2 divided by 0.6 mM). The Ki values for these derivatives in the case of creatine kinase are also very similar with the exception of A5'ppp-NH-(CH2)3-NH-ppp5'A. The Ki value for this derivative is one order of magnitude lower than for other ones. The affinity reagents received by periodate oxidation of bifunctional ATP analogs derivatives of di-, tetra- and heptamethylenediamine modify non-identical subunits of creatine kinase with different velocities, but modification of M- and M'-subunits proceeds independently. An analogues derivative of trimethylenediamine interacts simultaneously with two centers of the dimeric form of kinase forming non-equivalent complexes. The covalent attachment of the reagent to one subunit of creatine kinase does not except the complex formation and covalent binding of bifunctional ATP analogs with the other subunit of the dimer, but results in a one order of magnitude decrease in affinity of the ATP derivative to the nonmodified centre of the enzyme. These data permit to evaluate the distance between ATP binding sites of creatine kinase in its dimeric form as 5-6 A approximately. Such a distance between active sites may be the reason for the higher activity of the M- and M'-creatine kinase subunits taken separately as compared to the enzyme dimeric form.     

Characterization of a brain particulate bound form of creatine kinase

A bound form of creatine kinase associated with brain particulate was characterized by isoelectric focusing, antigenicity and chromatography and compared to muscle (MM), brain (BB), and heart mitochondrial isoenzymes. On partial purification and isoelectric focusing, the solubilized enzyme has a pl of 7.3, similar to the pl of muscle creatine kinase MM, pl 6.8, but different from brain creatine kinase BB, which precipitates on isoelectric focusing in sucrose or glycerol stabilized media at its calculated pl of 5.6. Gel filtration chromatography of deoxycholate solubilized particulate creatine kinase on Sephadex Gl50 reveals an estimated molecular weight of approximately 80,000 daltons. The brain particulate enzyme is antigenically distinct from both muscle and rat heart mitochondrial creatine kinase isoenzymes but has antigenic similarity with soluble cytoplasmic brain BB. The situation may be analogous to that found with rat heart mitochondria and rat heart cytoplasmic isoenzymes which we have shown to exhibit antigenic similarity even though differences in electrophoretic and amino acid composition have been demonstrated; however, the confident determination that the particulate enzyme is a separate isoenzyme will have to await amino acid analysis.     

Identification of creatine as a cofactor of thiamin-diphosphate kinase

Thiamin-diphosphate (TDP) kinase which catalyzes thiamin triphosphate formation from TDP requires a low-molecular-mass cofactor in addition to ATP and Mg2+. The cofactor was isolated in a crystalline form from pig skeletal muscle and identified as creatine by proton NMR, mass spectrometry, infrared spectrometry and elemental analysis. The isolated cofactor and authentic creatine supported the same activity of partially purified TDP kinase at identical molar concentrations. Neither creatine phosphate nor creatinine showed activity as a cofactor. This is the first report showing evidence of the existence of a creatine-dependent enzyme.     

Aggregation of creatine kinase during refolding and chaperonin-mediated folding of creatine kinase

The course of refolding and reactivation of urea-denatured creatine kinase (ATP; creatine N-phosphotransferase, EC 2.7.3.2) has been studied in the absence and presence of molecular chaperonin GroEL. The enzyme was denatured in Tris--HCl buffer containing 6 M urea for 1 h. In the refolding studies, the denatured enzyme was diluted 60-fold into the same buffer containing GroEL or not for activity, turbidity, fluorescence measurements and polyacrylamide gel electrophoresis. The results show that the reactivation process is dependent of creatine kinase concentration in the concentration range 2.5--4 microM. The levels of activity recovery decrease with increasing enzyme concentration because of the formation of wrong aggregates. The molecular chaperonin GroEL can bind the refolding intermediate of creatine kinase and thus prevent the formation of wrong aggregates. This intermediate is an inactive dimeric form that is in a conformation resembling the 'molten globule' state.     

Purification and characterization of human mitochondrial creatine kinase. A single enzyme form

Purification of human mitochondrial creatine kinase has been difficult and procedures that were highly successful in purifying canine enzyme failed for human mitochondrial creatine kinase. In the present study, we employed ultracentrifugation to remove the lipid, urea to prevent aggregation, followed by a final step of chromatofocusing which yielded a preparation of human mitochondrial creatine kinase with a specific enzyme activity of greater than 400 IU/mg. Biochemical and immunological characterization showed the preparation to be highly pure and free of even trace amounts of other creatine kinase isoenzymes. Antiserum specific for mitochondrial creatine kinase was developed which exhibited no cross-reactivity to cytosolic creatine kinase and mitochondrial creatine kinase did not cross-react with antiserum to the cytosolic forms. Marked differences were noted, both biochemically and immunologically, between mitochondrial creatine kinase and the cytosolic forms. Human mitochondrial creatine kinase was shown to have a molecular weight of around 82,000 and to be composed of two subunits of equal molecular weights around 41,000. Aggregates of mitochondrial creatine kinase were observed with molecular weights of around 200,000 in the absence of urea or if isolated from material after having undergone proteolysis. Isolation from fresh material or in the presence of urea inhibited aggregate formation for both canine and human mitochondrial creatine kinase. Despite claims of several investigators that mitochondrial creatine kinase exhibits two to three forms with varying molecular weights, our data indicate a single enzyme form made up of a subunit with a molecular weight of 41,000 and the high molecular weight aggregates appear to be induced artifacts. A radioimmunoassay was developed for human mitochondrial creatine kinase which, with appropriate modifications, should detect mitochondrial creatine kinase in human plasma.     

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.     

Rate equation for creatine kinase predicts the in vivo reaction velocity: 31P NMR surface coil studies in brain, heart, and skeletal muscle of the living rat

Brain, heart, and skeletal muscle contain four different creatine kinase isozymes and various concentrations of substrates for the creatine kinase reaction. To identify if the velocity of the creatine kinase reaction under cellular conditions is regulated by enzyme activity and substrate concentrations as predicted by the rate equation, we used 31P NMR and spectrophotometric techniques to measure reaction velocity, enzyme content, isozyme distribution, and concentrations of substrates in brain, heart, and skeletal muscle of living rat under basal or resting conditions. The total tissue activity of creatine kinase in the direction of MgATP synthesis provided an estimate for Vmax (23.4 +/- 2.8, 62.4 +/- 4.5, and 224 +/- 16 mM/s) and exceeded the NMR-determined in vivo reaction velocities by an order of magnitude (4.1 +/- 1.2, 5.1 +/- 1.6, and 18.4 +/- 2.4 mM/s for brain, heart, and skeletal muscle, respectively). The isozyme composition varied among the three tissues: greater than 99% BB for brain; 14% MB, 61% MM, and 25% mitochondrial for heart; and 98% MM and 2% mitochondrial for skeletal muscle. The NMR-determined reaction velocities agreed with predicted values from the creatine kinase rate equation (r2 = 0.98; p less than 0.001). The concentrations of free creatine and cytosolic MgADP, being less than or equal to the dissociation constants for each isozyme, were dominant terms in the creatine kinase rate equation for predicting the in vivo reaction velocity. Thus, we observed that the velocity of the creatine kinase reaction is regulated by total tissue enzyme activity and by the concentrations of creatine and MgADP in a manner that is independent of isozyme distribution.     

Relating structure to mechanism in creatine kinase

Found in all vertebrates, creatine kinase catalyzes the reversible reaction of creatine and ATP forming phosphocreatine and ADP. Phosphocreatine may be viewed as a reservoir of "high-energy phosphate" which is able to supply ATP, the primary energy source in bioenergetics, on demand. Consequently, creatine kinase plays a significant role in energy homeostasis of cells with intermittently high energy requirements. The enzyme is of clinical importance and its levels are routinely used as an indicator of myocardial and skeletal muscle disorders and for the diagnosis of acute myocardial infarction. First identified in 1928, the enzyme has undergone intensive investigation for over 75 years. There are four major isozymes, two cytosolic and two mitochondrial, which form dimers and octamers, respectively. Depending on the pH, the enzyme operates by a random or an ordered bimolecular mechanism, with the equilibrium lying towards phosphocreatine production. Evidence suggests that conversion of creatine to phosphocreatine occurs via the in-line transfer of a phosphoryl group from ATP. A recent X-ray structure of creatine kinase bound to a transition state analog complex confirmed many of the predictions based on kinetic, spectroscopic, and mutagenesis studies. This review summarizes and correlates the more significant mechanistic and structural studies on creatine kinase.     

Conditions for reciprocal conversion of oligomeric forms of heart mitochondrial creatine kinase

A procedure for purifying creatine kinase from bovine heart mitochondria, including enzyme extraction from mitochondria with salt solutions, concentration on cellulose phosphate gel and gel filtration on Sephacryl S-300 has been developed. Using ultracentrifugation in a sucrose density gradient and gel filtration, it was demonstrated that mitochondrial creatine kinase is present in solution as a mixture of two main forms, i. e., an octamer and a dimer. The distribution of the oligomeric forms is not influenced by changes in the ionic strength from 0.02 to 0.25, temperature (5-20 degrees C), freezing-thawing and the nature of monovalent anions (Cl-, NO3-, CH3COO-) and cations (Na+, K+) present in the medium. At pH 6.0, the predominant form is the octamer; an increase in pH induces its dissociation. An equilibrious mixture of the creatine kinase reaction substrates in the presence of Mg2+ also causes octamer dissociation; no dissociation is observed in the absence of Mg2+ or in the presence of one of the substrates. The non-working couple of substrates, Mg-ADP and creatine, causes dissociation of the octamer in the presence of Cl-, but not of CH3COO-. It is assumed that the dissociating effect of the substrates is due to conformational changes in the subunits concomitant with the formation of the creatine kinase active center in the course of catalysis. At physiological concentrations of nucleotide substrates, the degree of octamer dissociation depends on pH, creatine phosphate/creatine ratio and Pi. It is assumed that the above factors may regulate the reversible conversion of the octamer into the dimer in vivo.     

Purification and Characterization of Sperm Creatine Kinase and Guanylate Cyclase of the Sea Urchin Hemicentrotus pulcherrimus

Creatine kinase and guanylate cyclase were purified from Hemicentrotus pulcherrimus spermatozoa. The molecular weight of the purified sperm tail creatine kinase was estimated to be 137,000 by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Sperm tail guanylate cyclase was purified by chromatography on a WGA-Sepharose column connected to a Concanavalin A-Sepharose column, and a Superose 12 HR column. The molecular weight of the tail guanylate cyclase was estimated to be 128,000 by SDS-PAGE. The specific activity of the purified enzyme was 8.25 μmol of cGMP formed/min/mg protein. Sperm-activating peptide I (SAP-I) causes an electrophoretic mobility shift of H. pulcherrimus sperm guanylate cyclase from 131 kDa to 128 kDa. The 131 kDa form of guanylate cyclase was co-purified with a 76 kDa protein, whose molecular mass is similar to that of a SAP-I receptor. The purified 131 kDa form of guanylate cyclase had higher activity than the 128 kDa form. The 131 kDa and 128 kDa forms of guanylate cyclase contained 23.83 ± 0.65 and 4.16 ± 0.45 moles of phosphate per mol protein (mean ± S.D.; n = 3), respectively. The activities of guanylate cyclase and creatine kinase increased during the testis development. During spermatogenesis, sperm tail creatine kinase was detected immunohistochemically only in mature spermatozoa.     

Analysis of creatine kinase variation in some members of the family Acipenseridae

Creatine kinase (E.C. 2.7.3.2) was examined in stellate sturgeon Acipenser stellatus Pallas, Russian sturgeon A. gueldenstaedtii Brandt, European sterlet A. ruthenus L., Siberian sterlet A. ruthenus marsiglii Brandt, and great sturgeon (beluga) Huso huso L., using polyacrylamide gel electrophoresis. Two loci for creatine kinase were identified: CK-A* in white skeletal muscle and CK-C* in stomach wall muscle. Most species proved to be monomorphic at the CK-A* locus, showing the same phenotype represented by a single band. Heterogeneity and polymorphism in creatine kinase, determined by the CK-A* locus, were found only in Russian sturgeon. Based on the results of densitometric analysis of band staining intensity, we have advanced a hypothesis that synthesis of subunits of the CK-A* product in this species was controlled by eight genes. However, the genotype frequencies in the sample were significantly different from those theoretically expected upon free and independent gene recombination. The results of this study support the hypothesis on the absence of heterodimeric creatine kinase molecules in the skeletal muscle of Russian sturgeon. Locus CK-C* in sterlet was revealed as a single, intensely stained, rapidly migrating fraction, whereas in Russian sturgeon, the enzyme activity in this zone was very weak. No creatine kinase was found in liver, kidneys, spleen, heart, and intestine mucous tunic.     

Properties of creatine kinase from skeletal muscle mitochondria

Creatine kinase from pigeon breast muscle was obtained in a homogeneous (as evidenced from polyacrylamide gel SDS electrophoresis) state. The molecular mass of the enzyme monomer is 43,000. Ultracentrifugation in a sucrose density gradient and gel filtration revealed that the enzyme is present in solution as a mixture of two major forms, i.e., octamer and dimer, which differ in their activity. The decrease of ionic strength from 0.25 to 0.02 results in reversible dissociation of the octameric form. A temperature rise from 5 degrees to 20 degrees C or the nature of monovalent anions (e.g., Cl-, CH3COO-, NO3-) and cations (K+, Na+) present in the medium do not influence the distribution of oligomeric forms. At pH 6.0 the major form is represented by the octamer; its dissociation is caused by an increase of pH. The octamer dissociation occurs in a mixture of substrates of the creatine kinase reaction in the presence of Mg2+; no such dissociation is observed in the absence of Mg2+ and in the presence of each of the reaction substrates. The non-interacting pair of substrates--ADP and creatine--causes the dissociation of the octamer in the presence of nitrate ions but not acetate. It is concluded that the dissociating effect of substrates is due to the conformational changes of subunits during catalysis. At physiological concentrations of nucleotide substrates the degree of octamer dissociation depends on the ratio of creatine phosphate and creatine concentrations, as well as on the presence of chlorine and phosphate ions. A qualitative estimation of the rate of pH- and substrate-dependent dissociation of creatine kinase octamer revealed that under the given experimental conditions the pH-dependent dissociation is completed within hours, whereas the substrate-dependent one--within seconds or minutes. According to its properties, mitochondrial creatine kinase from pigeon breast muscle is close to its bovine heart counterpart; the observed differences were found to be quantitative.     

Cytosolic adenylate kinase catalyzes the synthesis of thiamin triphosphate from thiamin diphosphate

An attempt was made to purify a porcine skeletal muscle enzyme catalyzing the formation of thiamin triphosphate (TTP) from thiamin diphosphate (TDP), requiring ATP, Mg2+ and a cofactor (creatine). As the purification proceeded, the reaction requirements for ATP and creatine were lost and then a requirement for ADP was manifested. The activity responsible for TTP synthesis from TDP, ADP, and Mg2+ was found to be copurified with adenylate kinase [EC 2.7.4.3] activity, and was finally purified to a single band on SDS-PAGE. Antiserum obtained against the purified enzyme preparation inhibited both adenylate kinase activity and the TTP-synthesizing activity to exactly the same extent. These results indicate that adenylate kinase catalyzes TTP formation from TDP in vitro.     

Affinity modification of creatine kinase and ATP-ADP translocase in heart mitochondria: determination of their stoichiometric ratio

The interaction of mitochondrial creatine kinase and ATP-ADP translocase with 2.3-dialdehyde derivatives of ADP and ATP (oADP and oATP) has been studied. It was shown that these compounds are irreversible and specific inhibitors of creatine kinase (KioADP = 0.6mM, KioATP = 1.12 mM) and ATP-ADP translocase (KioADP = 0.065mM, KioATP = 0.14 mM). The substrates protect both enzymes from inactivation by these compounds. The maximal pseudo-first order rate constants for the 2,3-dialdehyde nucleotide derivative interaction with creatine kinase are 0.2 min-1 for oADP (pH 6.5) and 0.11 min-1 for oATP (pH 7.0). A decrease in the creatine kinase activity correlates with the incorporation of the reagent into the protein. The completely inactivated, isolated and purified enzyme contains 1 mol of oADP per mole of active sites. A procedure for simultaneous determination of the creatine kinase and translocase content in mitochondria and mitoplasts has been developed, which is based on the application of [3H]oADP in combination with specific treatment of mitochondria (or mitoplasts) with carboxyatractyloside 2,4-dinitrofluorobenzene and a mixture of creatine kinase substrates (MgADP + phosphocreatine). It has been found that for heart mitochondria from different animals the content of creatine kinase and translocase is 2.1-2.6 and 2.4-2.9 mol per mol of cytochrome c oxidase, respectively. Thus, the stoiochiometric ratio of creatine kinase and ATP-ADP translocase is close to 1.0 for all mitochondrial preparations under study (i.e. rat, dog, rabbit and chicken).