ATP nucleotidylation of creatine kinase.

Creatine kinase (CK) will autoincorporate radiolabel from [gamma32P]ATP and has thus been reported to be autophosphorylated. Also, in contrast to normal brain enzyme, CK in Alzheimer-diseased brain homogenate shows greatly decreased activity, abolished photolabeling with [32P]8N3ATP, and no detectable autoincorporation of radiolabel by [gamma32P]ATP. Surprisingly, our studies with both human brain and purified CK showed that [alpha32P]ATP, [gamma32P]ATP, [alpha32P]ADP, [2,8H3]ATP, [gamma32P]2',3'-O-(2,4, 6-trinitrophenyl)-ATP, and [gamma32P]benzophenone-gammaATP all autoincorporate radiolabel into CK with good efficiency. This demonstrates that the gamma-phosphate and the 2' and 3' hydroxyls are not involved in the covalent linkage and that all three phosphates, the ribose and base of the ATP molecule are retained upon autoincorporation (nucleotidylation). Treatment with NaIO3 to break the 2'-3' linkage effected total loss of radiolabel indicating that nucleotidylation resulted in opening of the ribose ring at the C1' position. Nucleotidylation with increasing [alpha32P]ATP at 37 degrees C gives an approximate k0.5 of 125 microM and saturates at 340 microM nucleotide. Modification of 8-10% of the copy numbers occurs at saturation, and CK activity is inhibited to approximately the same degree. Low micromolar levels of native substrates such as ADP, ATP, and phosphocreatine substantially reduce [alpha32P]ATP nucleotidylation. In contrast, AMP, GTP, GMP, NADH, and creatine did not effectively reduce nucleotidylation. When [alpha32P]ATP-nucleotidylated or [alpha32P]8N3ATP-photolabeled CK is treated with trypsin a single, identical radiolabeled peptide (V279-R291) is generated that comigrates on reverse phase HPLC and Tris-tricine electrophoresis. Nucleotidylation into this peptide was prevented 86% by the presence of ATP. We conclude that CK is nucleotidylated within the active site by modification at the C1'position and that autophosphorylation of this enzyme does not occur.     

Evidence for myocardial ATP compartmentation from NMR inversion transfer analysis of creatine kinase fluxes

The interpretation of creatine kinase (CK) flux measured by (31)P NMR magnetization transfer in vivo is complex because of the presence of competing reactions, metabolite compartmentation, and CK isozyme localization. In the isovolumic perfused rat heart, we considered the influence of both ATP compartmentation and ATP-P(i) exchange on the forward (F(f): PCr --> ATP) and reverse (F(r)) CK fluxes derived from complete analysis of inversion transfer. Although F(f) should equal F(r) because of the steady state, in both protocols when PCr (inv-PCr) or ATP (inv-ATP) was inverted and the contribution of ATP-P(i) was masked by saturation of P(i) (sat-P(i)), F(f)/F(r) significantly differed from 1 (0.80 +/- 0.06 or 1.32 +/- 0.06, respectively, n = 5). These discrepancies could be explained by a compartment of ATP (f(ATP)) not involved in CK. Consistently, neglecting ATP compartmentation in the analysis of CK in vitro results in an underestimation of F(f)/F(r) for inv-PCr and its overestimation for inv-ATP. Both protocols gave access to f(ATP) if the system was adequately analyzed. The fraction of ATP not involved in CK reaction in a heart performing medium work amounts to 20-33% of cellular ATP. Finally, the data suggest that the effect of sat-P(i) might not result only from the masking of ATP-P(i) exchange.     

Photoaffinity labelling of arginine kinase and creatine kinase with a gamma-P-substituted arylazido analogue of ATP

1. An ATP analogue with a photoactivated azide group attached to the gamma-phosphate via an amide bond, ATP gamma-p-azidoanilide, appeared to have potential use as a photoaffinity label for the nucleotide-binding regions of ATP: guanidine phosphotransferases. Upon photolysis in the presence of lobster muscle arginine kinase and rabbit muscle creatine kinase, the analogue is converted to a potent inhibito of these two kinases. This photo-dependent inhibition is specific as it cannot be induced by azidoaniline, a mixture of azidoaniline and ATP or by ATP gamma-p-aminoanilide. Preirradiated under suitable conditions, the photoanalogue still shows a transitory inhibitory effect which, however, slowly vanishes with time (t0.5 = 3 h). 2. The photoinhibition is significantly decreased by the presence of ATP or ADP but is completely prevented by the addition of a mixture of nucleotide and guanidine substrates. Differential spectroscopy and affinity chromatography on Sepharose-ATP demonstrated the inability of photoinactivated arginine kinase and creatine kinase to recognize their nucleotide substrates. 3. Experiments with [14C]ATP gamma-p-azidoanilide indicated that photolysis is associated with an irreversible and stoichiometric binding of the ATP analogue to the enzymes. Autoradiographs made with the peptide maps corresponding to the tryptic digests of each 14C-labelled photomodified enzyme showed an unexpected highly specific labelling of the proteins. 4. Thiiol titrations of the kinases which have been subjected to various photolysis conditions led to the conclusion that the arylnitrene moiety of the photoanalogue is covalently attached to the single reactive cysteinyl side chain present in the active-site region of the two homologous kinases. This amino acid residue appears, therefore, to be located near the phosphate chain binding subsite occupied by the ATP analogue and probably also by the natural nucleotide substrates.     

The two slow refolding processes of creatine kinase are catalyzed by cyclophilin

A burst phase occurs in the refolding kinetics of guanidine-denatured creatine kinase due to formation of an intermediate within the mixing dead time, with further refolding to the native state after the burst phase along a path following biphasic kinetics. In the presence of cyclophilin, the refolding rates of the two slow processes are accelerated and the values are proportional to the cyclophilin concentration. The activity of cyclophilin in accelerating the slow refolding processes of creatine kinase is totally inhibited by cyclosporin A, indicating that the cis—trans isomerization of the peptidyl—prolyl bonds is involved in the two slow refolding processes.     

Nitric oxide inhibits cardiac energy production via inhibition of mitochondrial creatine kinase

Nitric oxide biosynthesis in cardiac muscle leads to a decreased oxygen consumption and lower ATP synthesis. It is suggested that this effect of nitric oxide is mainly due to the inhibition of the mitochondrial respiratory chain enzyme, cytochrome c oxidase. However, this work demonstrates that nitric oxide is able to inhibit soluble mitochondrial creatine kinase (CK), mitochondrial CK bound in purified mitochondria, CK in situ in skinned fibres as well as the functional activity of mitochondrial CK in situ in skinned fibres. Since mitochondrial isoenzyme is functionally coupled to oxidative phosphorylation, its inhibition also leads to decreased sensitivity of mitochondrial respiration to ADP and thus decreases ATP synthesis and oxygen consumption under physiological ADP concentrations.     

Capillary and venous samples of total creatine kinase are similar after eccentric exercise

Circulating creatine kinase (CK) levels are often monitored as an indirect biomarker of muscle damage after resistive exercise. The purpose of the present investigation was to evaluate whether capillary whole-blood sampling, a simpler and less invasive method for obtaining a venous blood sample, would allow for a reliable measurement of total CK compared to venipuncture. Fifteen untrained subjects performed 50 maximal eccentric elbow extensions to induce muscle damage of the biceps brachii. Capillary (fingerstick) and venous whole-blood samples were collected contemporaneously at baseline and again at 24, 48, 72, and 96 hours post-exercise. Using a commercial CK analysis kit with a protocol modification to account for a reduced sample size, total CK activity of the capillary and venous samples was analyzed concurrently via spectrophotometry. Results indicated a 0.997 correlation between sampling sites for total CK, with disagreement between the venous and capillary samples estimated at <12% across the range of CK values. These findings indicate capillary sampling for total CK activity provides a valid alternative to venipuncture and should be considered by researchers, clinicians, and strength and conditioning specialists as an alternate sampling technique when indirectly evaluating muscle damage after exercise.     

Ins(1,4,5)P3 facilitates ATP accumulation via phosphocreatine/creatine kinase in the endoplasmic reticulum extracted from MDCK cells

So far, the content and accumulation of ATP in isolated endoplasmic reticulum (ER) are little understood. First, we confirmed using electron microscopic and Western blotting techniques that the samples extracted from MDCK cells are endoplasmic reticulum (ER). The amounts of ATP in the extracted ER were measured from the filtrate after a spinning down of ultrafiltration spin column packed with ER. When the ER sample (5 μg) after 3 days freezing was suspended in intracellular medium (ICM), 0.1% Triton X and ultrapure water (UPW), ATP amounts from the ER with UPW were the highest and over 10 times compared with that from the control with ICM, indicating that UPW is the most effective tool in destroying the ER membrane. After a 10-min-incubation with ICM containing phosphocreatine (PCr)/creatine kinase (CK) of the fresh ER. ATP amounts in the filtrate obtained by spinning down were not changed from that in the control (no PCr/CK). However, ATP amounts in the filtrate from the second spinning down of the ER (treated with PCr/CK) suspended in UPW became over 10-fold compared with the control. When 1 μM inositol(1,4,5)trisphosphate (Ins(1,4,5)P₃) was added in the incubation medium (ICM with PCr/CK), ATP amounts from the filtrate after the second spinning down were further enhanced around three times. This enhancement was almost canceled by Ca²⁺-removal from ICM and by adding thapsigargin, a Ca²⁺-ATPase inhibitor, but not by 2-APB and heparin, Ins(1,4,5)P₃ receptor antagonists. Administration of 500 μM adenosine to the incubation medium (with PCr/CK) failed to enhance the accumulation of ATP in the ER. These findings suggest that the ER originally contains ATP and ATP accumulation in the ER is promoted by PCr/CK and Ins(1,4,5)P₃.     

Compartmentation of ATP synthesis and utilization in smooth muscle: roles of aerobic glycolysis and creatine kinase

The phosphocreatine content of smooth muscle is of similar magnitude to ATP. Thus the function of the creatine kinase system in this tissue cannot simply be regarded as an energy buffer. Thus an understanding of its role in smooth muscle behavior can point to CK function in other systems. From our perspective CK function in smooth muscle is one example of a more general phenomenon, that of the co-localization of ATP synthesis and utilization. In an interesting and analogous fashion distinct glycolytic cascades are also localized in regions of the cell with specialized energy requirements. Similar to CK, glycolytic enzymes are known to be localized on thin filaments, sarcoplasmic reticulum and plasma membrane. In this chapter we will describe the relations between glycolysis and smooth muscle function and compare and contrast to that of the CK system. Our goal is to more fully understand the significance of the compartmentation of distinct pathways for ATP synthesis with specific functions in smooth muscle. This organization of metabolism and function seen most clearly in smooth muscle is likely representative of many other cell types.     

ATP binding site of mitochondrial creatine kinase. Affinity labelling of Asp-335 with C1RATP

The ATP binding site of mitochondrial creatine kinase from chicken heart has been studied by modifying the purified enzyme with a 14C-labelled ATP analogue, C1RATP, in which the reactive label was covalently bound to the gamma-phosphate group of ATP. The modified enzyme was digested by pepsin, and a single radioactive nonapeptide was isolated by HPLC. Amino acid analysis and direct sequence determination revealed that the isolated peptide corresponds to amino acids 335-343 within the C-terminal region of Mi-CK, this peptide being highly preserved throughout evolution. Asp-335 is very likely the site of modification by C1RATP. The specificity of the ATP analogue for the active site of creatine kinase was demonstrated by the inhibition of the enzymatic activity of Mi-CK by C1RATP and by the prevention of this inhibition bij ADP.     

Kinetics of creatine kinase in an experimental model of low phosphocreatine and ATP in the normoxic heart

To study the dependence of the forward flux of creatine kinase(CK) on its substrates and products we designed an acute normoxic modelof steady-state depletion of phosphocreatine (PCr) and adenylate in theisovolumic acetate-perfused rat heart. Various concentrations of PCrand ATP were induced by prior perfusion with 2 deoxy-D-glucose in the presenceof insulin. The apparent rate constant(k_f) and theforward CK flux were measured under metabolic and contractile steadystate by progressive saturation-transfer³¹P nuclear magnetic resonance(NMR). At high adenylate content CK flux was constant for a twofoldreduction in PCr concentration ([PCr]); CK flux was 6.3 ± 0.6 mM/s (vs. 6.5 ± 0.2 mM/s in control) because of adoubling of k_f.Although, at the lowest ATP concentration and [PCr], CKflux was reduced by 50%, it nevertheless always remained higher thanATP synthesis estimated by parallel oxygen consumption measurement.NMR-measured flux was compared with the flux computed under thehypothesis of CK equilibrium. CK flux could not be fully predicted bythe concentrations of CK metabolites. This is discussed in terms ofmetabolite and CK isozyme compartmentation.

     

An essential tryptophan residue for rabbit muscle creatine kinase

The tryptophan residues in rabbit muscle creatine kinase (ATP:creatine N-phosphotransferase, EC 2.7.3.2) have been modified by dimethyl(2-hydroxy-5-nitrobenzyl) sulfonium bromide after reversible protection of the reactive SH groups. The modification of two tryptophan residues as measured by spectrophotometric titration leads to complete loss of enzymatic activity. Control experiments show that reversible protection of the reactive SH groups as S-sulfonates followed by reduction results in nearly quantitative recovery of enzyme activity. The presence of a 410 nm absorption maximum and the decrease in fluorescence of the modified enzyme indicate the modification of tryptophan residues. At the same time, SH determinations after reduction of the modified enzyme show that the reagent has not affected the protected SH groups. Quantitative treatment of the data (Tsou, C.-L. (1962) Sci. Sin. 11, 1535 1558) shows that among the tryptophan residues modified, one is essential for its catalytic activity. The presence of substrates partially protects the modification of tryptophan residues as well as the inactivation, suggesting that the essential tryptophan residue is situated at the active site of this enzyme.     

Radiochemical assays for creatine kinase and arginine kinase using rapid ion exchange separations

Simple and specific radiochemical assays for the determination of creatine and arginine kinase activities in crude tissue extracts are described. Creatine kinase is assayed by incubation with radioactive creatine and subsequent determination of the radioactivity in creatine phosphate. Creatine and creatine phosphate are separated on DEAE-cellulose ion exchange papers. Arginine kinase is assayed simllarly by using radioactive arginine and separating it from arginine phosphate on short ion exchange columns. An assay for creatine kinase in the direction of creatine formation is also described.     

The alpha beta-methylene analogues of ADP and ATP act as substrates for creatine kinase. delta G0 for this reaction and for the hydrolysis of the alpha beta-methylene analogue of ATP

The alpha beta-methylene analogues of ATP and ADP, [alpha beta CH2]ATP and [alpha beta CH2]ADP, are substrates for creatine kinase. However, the rate of the phosphoryl transfer reaction catalysed is about 10(-5)-times lower than that with normal ATP. The affinities of the analogues (especially [alpha beta CH2]ADP) for the enzyme are lower than those of the normal substrates. The equilibrium constant at 25 degrees C, measured using 31P NMR, for the reaction Mg[alpha beta CH2]ATP + creatine in equilibrium Mg[alpha beta CH2]ADP + phosphocreatine + H+ is 2.2 X 10(-12) M compared with a value of 2.5 X 10(-10) M for the same reaction with the normal substrates, corresponding to a difference in delta G0 values of 11.7 kJ X mol-1. It follows that delta G0 for the hydrolysis of the terminal phosphate group of Mg[alpha beta CH2]ATP is less favourable by 11.7 kJ X mol-1 than that for MgATP.     

ATP produced by myocardial sarcolemmal-bound creatine kinase is not preferentially used by the Na+ pump

It has been proposed (Grosse et al. (1980) Biochim. Biophys. Acta 603, 142–156) that membrane-bound creatine kinase and the ATP-dependent Na⁺ pump form a functional complex in cardiac sarcolemmal vesicles. In this model ADP produced at Na⁺ pump sites would be rephosphorylated by the creatine kinase for preferential delivery back to the Na⁺ pump. We have reexamined this hypothesis and find that under some conditions active Na⁺ transport can be stimulated by ATP produced by sarcolemmal creatine kinase. However, the characteristics of this stimulation are no different than stimulation produced by an added soluble ATP-regenerating system (phosphoenolpyruvate/pyruvate kinase). Thus, we are unable to detect coupling between the Na⁺ pump and sarcolemmal creatine kinase.     

Immobilized bacterial luciferase for microscale analysis of creatine kinase activity

The commercially available bacterial luciferase: oxidoreductase system obtained from Vibrio fischerii has been immobilized in a bovine serum albumin (BSA) gel. The gel was cut in the shape of a disc and held to the bottom of a reaction cell, gel upwards. The immobilized enzyme gels are stable, reusable and easily cleaned of spent reagents. NADH and NADPH have been assayed down to nanomolar concentrations, although with an error of ± 15%. The system has been coupled to an NADPH-producing commercial assay for creatine kinase (ATP: creatine N-phosphotransferase, EC 2.7.3.2) activity. The kinetic assay gives a linear reaction rate vs. creatine kinase activity plot in the clinically important range.