Expression of active octameric chicken cardiac mitochondrial creatine kinase in Escherichia coli

Over-expression, purification and characterization of the oligomerization dynamics of an invertebrate mitochondrial creatine kinase

Mitochondrial creatine kinase (MtCK) plays a central role in energy homeostasis within cells that display high and variable rates of ATP turnover. Vertebrate MtCKs exist primarily as octamers but readily dissociate into constituent dimers under a variety of circumstances. MtCK is an ancient protein that is also found in invertebrates including sponges, the most primitive of all multi-cellular animals. We have cloned, expressed, and purified one of these invertebrate MtCKs from a marine polychaete worm, Chaetopterus variopedatus (CVMtCK). Size exclusion chromatography and dynamic light scattering (DLS) were used to characterize oligomeric state in comparison with that of octameric chicken sarcomeric isoform (SarMtCK). At protein concentrations >1 mg/ml, CVMtCK was predominantly octameric (>90%). When diluted to 0.1 mg/ml, CVMtCK dissociated into dimers much more rapidly than SarMtCK when observed under identical conditions. The rate of dissociation for both MtCKs increased as temperature rose from 2 to 28 degrees C, and in CVMtCK, fell at higher incubation temperatures. The fraction of octameric CVMtCK at equilibrium increased with temperature and then fell. Temperature transition studies showed that octamers and dimers were rapidly interconvertible on a similar time scale. Importantly, when CVMtCK was converted to the transition state analog complex (TSAC), both size exclusion chromatography and DLS showed that there was minimal dissociation of octamers into dimers while SarMtCK octamers were highly unstable as the TSAC. These results clearly show distinct differences in octamer stability between CVMtCK and SarMtCK, which could impact function under physiological circumstances. Furthermore, the large yield of recombinant protein and high stability of CVMtCK in the TSAC suggest that this protein might be a good target for crystallization efforts.

Cloning and expression of mitochondrial and protoflagellar creatine kinases from a marine sponge: implications for the origin of intracellular energy transport systems

Creatine kinase (CK) plays a central role in energy transactions in cells displaying high and variable rates of ATP turnover. Cytoplasmic and mitochondrial CK genes code for isoforms which are targeted to distinct intracellular compartments often in close physical proximity to sites of ATP hydrolysis or synthesis. In certain lower groups a third CK gene is present which codes for a flagellar CK isoform consisting of three complete, fused CK domains. Recent work has shown that cytoplasmic, mitochondrial, and flagellar CKs are present in protochordates and in deuterostome and protostome invertebrates. We report here that the marine sponge Tethya aurantia, a representative of the oldest of all multi-cellular animal groups, expresses three unique CK transcripts. One of these CK transcripts codes for protein that has a mitochondrial targeting sequence and in a phylogenetic analysis is positioned at the base of the cluster containing mitochondrial CK sequences from invertebrates, protochordates, and vertebrates; it is clearly a mitochondrial CK. When expressed in Escherichia coli the mitochondrial form from T. aurantia was found to be dimeric unlike all other mitochondrial CKs which are typically octameric. The other two T. aurantia transcripts code for proteins that appear to be more closely related to flagellar CKs. These protoflagellar CKs were found to be dimers when expressed in Escherichia coli. Sponges last shared a common ancestor with higher animals as long as one billion years ago. The antiquity of intracellular localization, as evidenced by the presence of a true mitochondrial CK and protoflagellar CKs in the sponge T. aurantia, indicates that physical constraints on cellular energy transport were key, early driving forces in the evolution of this key enzyme system.

Differential effects of peroxynitrite on human mitochondrial creatine kinase isoenzymes. Inactivation, octamer destabilization, and identification of involved residues

Creatine kinase isoenzymes are very susceptible to free radical damage and are inactivated by superoxide radicals and peroxynitrite. In this study, we have analyzed the effects of peroxynitrite on enzymatic activity and octamer stability of the two human mitochondrial isoenzymes (ubiquitous mitochondrial creatine kinase (uMtCK) and sarcomeric mitochondrial creatine kinase (sMtCK)), as well as of chicken sMtCK, and identified the involved residues. Inactivation by peroxynitrite was concentration-dependent and similar for both types of MtCK isoenzymes. Because peroxynitrite did not lower the residual activity of a sMtCK mutant missing the active site cysteine (C278G), oxidation of this residue is sufficient to explain MtCK inactivation. Mass spectrometric analysis confirmed oxidation of Cys-278 and further revealed oxidation of the C-terminal Cys-358, possibly involved in MtCK/membrane interaction. Peroxynitrite also led to concentration-dependent dissociation of MtCK octamers into dimers. In this study, ubiquitous uMtCK was much more stable than sarcomeric sMtCK. Mass spectrometric analysis revealed chemical modifications in peptide Gly-263-Arg-271 located at the dimer/dimer interface, including oxidation of Met-267 and nitration of Trp-268 and/or Trp-264, the latter being a very critical residue for octamer stability. These data demonstrate that peroxynitrite affects the octameric state of MtCK and confirms human sMtCK as the generally more susceptible isoenzyme. The results provide a molecular explanation of how oxidative damage can lead to inactivation and decreased octamer/dimer ratio of MtCK, as seen in neurodegenerative diseases and heart pathology, respectively.

Expression of Torpedo californica creatine kinase in Escherichia coli and purification from inclusion bodies

The pET17 expression vector was used to express creatine kinase from the electric organ of Torpedo californica as inclusion bodies in Escherichia coli BL21(DE3) cells. The insoluble aggregate was dissolved in 8M urea and, following extraction with Triton X-100, the enzyme was refolded by dialysis against Tris buffer (pH 8.0) containing 0.2M NaCl. After two buffer changes, chromatography on Blue Sepharose was used as a final step in the purification procedure. Approximately 54mg active protein was recovered from a 1L culture and the refolded enzyme had a specific activity of 75U/mg. The molecular mass of the purified protein was consistent with that predicted from the amino acid sequence and the CD spectrum of the refolded enzyme was essentially identical to that of creatine kinase from human muscle (HMCK). The K(m) values of ATP and ADP were also similar to those of HMCK, while the K(m) values for both phosphocreatine and creatine were approximately 5-10-fold higher. The purification described here is in marked contrast with earlier attempts at purification of this isozyme where, in a process yielding less than 1mg/L culture, enzyme with a specific activity of ca. 5U/mg was obtained.

Mitochondrial creatine kinase and mitochondrial outer membrane porin show a direct interaction that is modulated by calcium

Mitochondrial creatine kinase (MtCK) co-localizes with mitochondrial porin (voltage-dependent anion channel) and adenine nucleotide translocator in mitochondrial contact sites. A specific, direct protein-protein interaction between MtCK and mitochondrial porin was demonstrated using surface plasmon resonance spectroscopy. This interaction was independent of the immobilized binding partner (porin reconstituted in liposomes or MtCK) or the analyzed isoform (chicken sarcomeric MtCK or human ubiquitous MtCK, human recombinant porin, or purified bovine porin). Increased ionic strength reduced the binding of MtCK to porin, suggesting predominantly ionic interactions. By contrast, micromolar concentrations of Ca(2+) increased the amount of bound MtCK, indicating a physiological regulation of complex formation. No interaction of MtCK with reconstituted adenine nucleotide translocator was detectable in our experimental setup. The relevance of these findings for structure and function of mitochondrial contact sites is discussed.

Divergent enzyme kinetics and structural properties of the two human mitochondrial creatine kinase isoenzymes

The mitochondrial isoenzymes of creatine kinase (MtCK), ubiquitous uMtCK and sarcomeric sMtCK, are key enzymes of oxidative cellular energy metabolism and play an important role in human health and disease. Very little is known about uMtCK in general, or about sMtCK of human origin. Here we have heterologously expressed and purified both human MtCK isoenzymes to perform a biochemical, kinetic and structural characterization. Both isoenzymes occurred as octamers, which can dissociate into dimers. Distinct Stokes' radii of uMtCK and sMtCK in solution were indicative for conformational differences between these equally sized proteins. Both human MtCKs formed 2D-crystals on cardiolipin layers, which revealed further subtle differences in octamer structure and stability. Octameric human sMtCK displayed p4 symmetry with lattice parameters of 145 A, indicating a 'flattening' of the octamer on the phospholipid layer. pH optima and enzyme kinetic constants of the two human isoenzymes were significantly different. A pronounced substrate binding synergism (Kd > Km) was observed for all substrates, but was most pronounced in the forward reaction (PCr production) of uMtCK and led to a significantly lower Km for creatine (1.01 mM) and ATP (0.11 mM) as compared to sMtCK (creatine, 7.31 mM; ATP, 0.68 mM).

Why is creatine kinase a dimer? Evidence for cooperativity between the two subunits

The dimeric chicken brain type isoenzyme of creatine kinase (BB-CK) was mutated by a C283S amino acid exchange in the catalytic site to produce a basically inactive dimer (B*B*-CK). The mutated enzyme showed a residual activity of about 4% compared to the wild-type, whereas substrate binding parameters were not altered. The inactivated dimer was hybridized with native dimeric muscle enzyme (MM-CK) to produce a partially inactivated MB*-CK heterodimeric hybrid and also to a his-tagged BB-CK (hBhB-CK) resulting in a partially inactive hBB*-CK homodimer. The generated hybrids were purified by chromatography. The V(max) and substrate binding parameters K(m) and K(d) were determined for both directions of the CK reaction and compared to the parameters of the wild-type enzymes (MM-, BB-, hBhB-, MB-CK). In the direction of ATP synthesis (reverse reaction), the MB*- and hBB*-CK hybrids showed a decrease of V(max) to 34% and 32%, respectively, compared to the unmodified wild-type isoform. The inactivation of a single subunit in MB*-CK led to an increase in the K(d) value resulting in an significant substrate synergism, not seen with the MB-CK wild-type enzyme. In the direction of phosphocreatine synthesis (forward reaction), the modified hybrids showed a decrease of V(max) to 50% of the wild-type enzymes and no significant alterations of the K(m) and K(d) parameters. These results strongly suggest an enzymatic cooperativity of the two subunits in the reverse reaction but independent catalytic function in the forward reaction.

Isoenzyme-specific interaction of muscle-type creatine kinase with the sarcomeric M-line is mediated by NH(2)-terminal lysine charge-clamps

Creatine kinase (CK) is located in an isoenzyme-specific manner at subcellular sites of energy production and consumption. In muscle cells, the muscle-type CK isoform (MM-CK) specifically interacts with the sarcomeric M-line, while the highly homologous brain-type CK isoform (BB-CK) does not share this property. Sequence comparison revealed two pairs of lysine residues that are highly conserved in M-CK but are not present in B-CK. The role of these lysines in mediating M-line interaction was tested with a set of M-CK and B-CK point mutants and chimeras. We found that all four lysine residues are involved in the isoenzyme-specific M-line interaction, acting pair-wise as strong (K104/K115) and weak interaction sites (K8/K24). An exchange of these lysines in MM-CK led to a loss of M-line binding, whereas the introduction of the very same lysines into BB-CK led to a gain of function by transforming BB-CK into a fully competent M-line-binding protein. The role of the four lysines in MM-CK is discussed within the context of the recently solved x-ray structures of MM-CK and BB-CK.

Octamers of mitochondrial creatine kinase isoenzymes differ in stability and membrane binding

Octamer stability and membrane binding of mitochondrial creatine kinase (MtCK) are important for proper functioning of the enzyme and were suggested as targets for regulatory mechanisms. A quantitative analysis of these properties, using fluorescence spectroscopy, gel filtration, and surface plasmon resonance, revealed substantial differences between the two types of MtCK isoenzymes, sarcomeric (sMtCK) and ubiquitous (uMtCK). As compared with human and chicken sMtCK, human uMtCK showed a 23-34 times slower octamer dissociation rate, a reduced reoctamerization rate and a superior octamer stability as deduced from the octamer/dimer ratios at thermodynamic equilibrium. Octamer stability of sMtCK increased with temperature up to 30 degrees C, indicating a substantial contribution of hydrophobic interactions, while it decreased in the case of uMtCK, indicating the presence of additional polar dimer/dimer interactions. These conclusions are consistent with the recently solved x-ray structure of the human uMtCK (Eder, M., Fritz-Wolf, K., Kabsch, W., Wallimann, T., and Schlattner, U. (2000) Proteins 39, 216-225). When binding to 16% cardiolipin membranes, sMtCK showed slightly faster on-rates and higher affinities than uMtCK. However, human uMtCK was able to recruit the highest number of binding sites on the vesicle surface. The observed divergence of ubiquitous and sarcomeric MtCK is discussed with respect to their molecular structures and the possible physiological implications.

Crystal structure of human ubiquitous mitochondrial creatine kinase

Creatine kinase (CK), catalyzing the reversible trans-phosphorylation between ATP and creatine, plays a key role in the energy metabolism of cells with high and fluctuating energy requirements. We have solved the X-ray structure of octameric human ubiquitous mitochondrial CK (uMtCK) at 2.7 A resolution, representing the first human CK structure. The structure is very similar to the previously determined structure of sarcomeric mitochondrial CK (sMtCK). The cuboidal octamer has 422 point group symmetry with four dimers arranged along the fourfold axis and a central channel of approximately 20 A diameter, which extends through the whole octamer. Structural differences with respect to sMtCK are found in isoform-specific regions important for octamer formation and membrane binding. Octameric uMtCK is stabilized by numerous additional polar interactions between the N-termini of neighboring dimers, which extend into the central channel and form clamp-like structures, and by a pair of salt bridges in the hydrophobic interaction patch. The five C-terminal residues of uMtCK, carrying positive charges likely to be involved in phospholipid-binding, are poorly defined by electron density, indicating a more flexible region than the corresponding one in sMtCK. The structural differences between uMtCK and sMtCK are consistent with biochemical studies on octamer stability and membrane binding of the two isoforms.

A quantitative approach to membrane binding of human ubiquitous mitochondrial creatine kinase using surface plasmon resonance

We have evaluated surface plasmon resonance with avidin-biotin immobilized liposomes to characterize membrane binding of ubiquitous mitochondrial creatine kinase (uMtCK). While the sarcomeric sMtCK isoform is well known to bind to negatively charged phospholipids, especially cardiolipin, this report provides the first experimental evidence on the membrane interaction of an uMtCK isoform. Qualitative measurements showed that liposomes containing 16% (w/w) cardiolipin bind octameric as well as dimeric human uMtCK and also cytochrome c, but not bovine serum albumin. Quantitative parameters could be derived only for the membrane interaction of octameric human uMtCK using an improved analytical approach. Association and dissociation kinetics of octameric uMtCK fit well to a model for heterogeneous interaction suggesting two independent binding sites. Rate constants of the two sites differed by one order of magnitude, while their affinity constants were both about 80-100 nM. The data obtained demonstrate that surface plasmon resonance with immobilized liposomes is a suitable approach to characterize the binding of peripheral proteins to a lipid bilayer and that this method yields consistent quantitative binding parameters.

Characterization of two types of mitochondrial creatine kinase isolated from normal human cardiac muscle and brain tissue

Two types of mitochondrial creatine kinase (Mi-CK), sarcomeric (sMi-) and ubiquitous (uMi-)CKs, were isolated from normal human cardiac muscle and brain tissue, respectively, and their heterogeneity was characterized by means of isoelectric focusing (IEF). Octameric sMi-CK and uMi-CK were electrophoresed cathodic to cytoplasmic muscle-type creatine kinase isoenzyme (CK-MM) and dimeric Mi-CKs were found at the position of CK-MM on a cellulose acetate membrane. The electrophoretic mobilities of sMi-CK were similar to those of uMi-CK. Octameric sMi-CK was focused at pI 7.1-8.0 and dimeric forms at pI 6.55, 6.75, 6.85, and 6.95. New bands appearing at pI 6.65 and 6.75 after treatment of sMi-CK with carboxypeptidase B were found to be delysined forms. sMi-CK reacted with anti-sMi-CK antibodies, and the immune complexes were focused at pI 5.8. The Km value of sMi-CK for creatine phosphate (PCr) was 1.19 +/-0.20 mmol/L (mean +/- standard error), the activation energy (Ea) was 108.3+/-1.2 kJ/ mol, and the residual enzyme activity after heating at 45 degrees C for 20 min was 79.6+/-1.9%. On the other hand, octameric uMi-CK was focused at pI 7.1-7.9 and the dimeric forms were focused at pI 6.6, 6.7, 6.8, 6.9, and 7.0. Delysined forms were focused around pI 6.3, 6.4, 6.8, and 6.9. uMi-CK reacted with anti-sMi-CK antibodies, and the immune complexes were focused at pI 5.8. The Km value of uMi-CK for PCr was 1.07+/-0.03 mmol/L, Ea of uMi-CK was 110.0+/-0.9 kJ/mol, and the residual enzyme activity after heating at 45 degrees C for 20 min was 90.3+/-0.4%. The sMi-CK and uMi-CK were hybridized and the hybrid Mi-CK appeared at pI 6.78, 6.98, and 7.1-7.95. The pIs of the hybrid Mi-CK were between those of sMi-CK and uMi-CK. As described above, sMi-CK and uMi-CK were slightly different from each other with respect to the pI and some enzyme characteristics.

Crystal structure of brain-type creatine kinase at 1.41 A resolution

Excitable cells and tissues like muscle or brain show a highly fluctuating consumption of ATP, which is efficiently regenerated from a large pool of phosphocreatine by the enzyme creatine kinase (CK). The enzyme exists in tissue--as well as compartment-specific isoforms. Numerous pathologies are related to the CK system: CK is found to be overexpressed in a wide range of solid tumors, whereas functional impairment of CK leads to a deterioration in energy metabolism, which is phenotypic for many neurodegenerative and age-related diseases. The crystal structure of chicken cytosolic brain-type creatine kinase (BB-CK) has been solved to 1.41 A resolution by molecular replacement. It represents the most accurately determined structure in the family of guanidino kinases. Except for the N-terminal region (2-12), the structures of both monomers in the biological dimer are very similar and closely resemble those of the other known structures in the family. Specific Ca2+-mediated interactions, found between two dimers in the asymmetric unit, result in structurally independent heterodimers differing in their N-terminal conformation and secondary structure. The high-resolution structure of BB-CK presented in this work will assist in designing new experiments to reveal the molecular basis of the multiple isoform-specific properties of CK, especially regarding different subcellular locations and functional interactions with other proteins. The rather similar fold shared by all known guanidino kinase structures suggests a model for the transition state complex of BB-CK analogous to the one of arginine kinase (AK). Accordingly, we have modeled a putative conformation of CK in the transition state that requires a rigid body movement of the entire N-terminal domain by rms 4 A from the structure without substrates.

Cloning, Escherichia coli expression, and phase-transition chromatography-based purification of recombinant rabbit heart mitochondrial creatine kinase

A cDNA clone of the mitochondrial sarcomeric creatine kinase cDNA was obtained by screening a rabbit heart library. This cDNA is characterized by a 1257-nucleotide open reading frame encoding a 419-amino-acid protein with a cleavable 39-amino-acid mitochondrial presequence (Accession No. AJ011334). This new member of the guanidino kinase family shows a high degree of sequence similarity with the other phosphagen kinases sequenced so far. The mature enzyme was efficiently expressed in Escherichia coli BL21(DE3) cells as a soluble octameric protein using the pET21 plasmid and purified by a three-step improved method including a final phase-transition chromatography.

Octamer formation and coupling of cardiac sarcomeric mitochondrial creatine kinase are mediated by charged N-terminal residues

Mitochondrial creatine kinases form octameric structures composed of four active and stable dimers. Octamer formation has been postulated to occur via interaction of the charged amino acids in the N-terminal peptide of the mature enzyme. We altered codons for charged amino acids in the N-terminal region of mature sarcomeric mitochondrial creatine kinase (sMtCK) to those encoding neutral amino acids. Transfection of normal sMtCK cDNA or those with the mutations R42G, E43G/H45G, and K46G into rat neonatal cardiomyocytes resulted in enzymatically active sMtCK expression in all. After hypoosmotic treatment of isolated mitochondria, mitochondrial inner membrane-associated and soluble sMtCK from the intermembranous space were measured. The R42G and E43G/H45G double mutation caused destabilization of the octameric structure of sMtCK and a profound reduction in binding of sMtCK to the inner mitochondrial membrane. The other mutant sMtCK proteins had modest reductions in binding. Creatine-stimulated respiration was markedly reduced in mitochondria isolated from cells transfected with the R42G mutant cDNA as compared with those transfected with normal sMtCK cDNA. We conclude that neutralization of charges in N-terminal peptide resulted in destabilization of octamer structure of sMtCK. Thus, charged amino acids at the N-terminal moiety of mature sMtCK are essential for octamer formation, binding of sMtCK with inner mitochondrial membrane, and coupling of sMtCK to oxidative phosphorylation.

The isoenzyme-diagnostic regions of muscle-type creatine kinase, the M-260 and M-300 box, are not responsible for its binding to the myofibrillar M-band

Muscle-type creatine kinase is known for its unique interaction with the myofibrillar M-band, but the molecular origin for this structural relationship is not well understood. A systematic sequence comparison between the highly homologous cytosolic isoforms, muscle-type and brain-type creatine kinase, yielded two isoenzyme-specific regions in the muscle-type creatine kinases, the M-260 box (residues 258-270) and the M-300 box (residues 300-315). These particular regions were conspicuous for the specific interaction of this CK isoenzyme, but not of brain-type creatine kinase, with the sarcomeric M-band. In situ diffusion assays with fluorescently labeled native, as well as mutated muscle-type creatine kinase variants, were used to study by laser confocal microscopy their association with the M-band of chemically skinned muscle fibers. Neither a set of charge mutants of the M-260 box and/or the M-300 box nor a hybrid construct of both isoforms with the entire C-terminal region derived from the brain-type isoform showed any significant alteration in the in situ M-band-binding properties when compared to the wild-type form of muscle-type creatine kinase. This indicates that in the intact protein of muscle type creatine kinase, these C-terminal isoenzyme-specific regions are not important for M-band interaction and that the actual M-band interaction domain(s) lay mostly within the N-terminal half of the molecule. The highly conserved motives (M-260 box and M-300 box) may serve an isoenzyme-specific purpose yet to be identified.

Structural changes of creatine kinase upon substrate binding

Small-angle x-ray scattering was used to investigate structural changes upon binding of individual substrates or a transition state analog complex (TSAC; Mg-ADP, creatine, and KNO3) to creatine kinase (CK) isoenzymes (dimeric muscle-type (M)-CK and octameric mitochondrial (Mi)-CK) and monomeric arginine kinase (AK). Considerable changes in the shape and the size of the molecules occurred upon binding of Mg-nucleotide or TSAC. The radius of gyration of Mi-CK was reduced from 55.6 A (free enzyme) to 48.9 A (enzyme plus Mg-ATP) and to 48.2 A (enzyme plus TSAC). M-CK showed similar changes from 28.0 A (free enzyme) to 25.6 A (enzyme plus Mg-ATP) and to 25.5 A (enzyme plus TSAC). Creatine alone did not lead to significant changes in the radii of gyration, nor did free ATP or ADP. AK also showed a change of the radius of gyration from 21.5 A (free enzyme) to 19.7 A (enzyme plus Mg-ATP), whereas with arginine alone only a minor change could be observed. The primary change in structure as seen with monomeric AK seems to be a Mg-nucleotide-induced domain movement relative to each other, whereas the effect of substrate may be of local order only. In CK, however, additional movements have to be involved.

Mitochondrial creatine kinase is a prime target of peroxynitrite-induced modification and inactivation

The reaction of peroxynitrite (PN) with sarcomeric mitochondrial creatine kinase (Mib-CK; EC 2.7.3.2) was observed at different stages of complexity (i) with purified Mi-CK, (ii) with enzyme bound on isolated mitoplasts, and (iii) within intact respiring mitochondria. Creatine-stimulated respiration was abolished by PN concentrations likely to be physiological and far before the respiratory chain itself was affected, thus demonstrating that Mi-CK is a prime target for inactivation by PN in intact mitochondria. The inactivation by PN of Mi-CK was reversed by 22% with 2-mercaptoethanol. More remarkable protective effects were noticed with the full set of CK substrates, e.g. 30 and 50% protection with MgATP plus creatine and MgADP plus phosphocreatine, respectively, but not with each substrate alone. These data indicate an involvement of the active-site Cys-278 residue of Mi-CK in this process. Furthermore, changes in endogenous tryptophan fluorescence intensity and spectral changes after reaction of Mi-CK with PN suggest additional modifications of Trp and Tyr residues. PN-inactivated Mi-CK can no longer be efficiently converted into dimers by incubation with reagents inducing a transition state analog complex at the active site. Thus, obviously, upon reaction of octameric Mi-CK with PN, the octamer-dimer equilibrium of Mi-CK is also affected. The consequences for cellular energy homeostasis and calcium handling are discussed.

Functional aspects of the X-ray structure of mitochondrial creatine kinase: a molecular physiology approach

Mitochondrial creatine kinase (Mi-CK) is a central enzyme in energy metabolism of tissues with high and fluctuating energy requirements. In this review, recent progress in the functional and structural characterization of Mi-CK is summarized with special emphasis on the solved X-ray structure of chicken Mib-CK octamer (Fritz-Wolf et al., Nature 381, 341-345, 1996). The new results are discussed in a historical context and related to the characteristics of CK isoforms as known from a large number of biophysical and biochemical studies. Finally, two hypothetical functional aspects of the Mi-CK structure are proposed: (i) putative membrane binding motifs at the top and bottom faces of the octamer and (ii) a possible functional role of the central 20 A channel.

Origin of octameric creatine kinases

Mitochondrial creatine kinase (MiCK) occurs primarily as an octameric form localized in the mitochondrial intermembrane compartment in vertebrate tissues and echinoderm spermatozoa (both deuterostome groups). The octameric quaternary structure is thought to play important functional and enzyme targeting roles. We have found that the spermatozoa of the protostome polychaete Chaetopterus variopedatus contain three distinct isoenzymes of creatine kinase (CK) termed CK1, CK2 and CK3. CK3 appears to be present only in the sperm head/midpiece complex where mitochondria are restricted and has a subunit relative molecular mass (Mr) of 43.4 kDa. Gel permeation chromatography using Superdex 200HR showed that CK3 has a native Mr of 344.9 kDa indicating that this enzyme exists as an octamer. Electron micrographs of negatively stained CK3 preparations show structures which are virtually identical to those that have been seen for octameric vertebrate MiCK. The above observations show that CK3 from C. variopedatus displays great similarities to MiCKs from vertebrates and echinoderms. Octamerization of CK is not an advanced feature. The evolution of octameric subunit association is ancient and occurred prior to the divergence of protostomes and deuterostomes.

Fluxes through cytosolic and mitochondrial creatine kinase, measured by P-31 NMR

The kinetic properties of the cytoplasmic and the mitochondrial iso-enzymes of creatine kinase from striated muscle were studied in vitro and in vivo. The creatine kinase (CK) iso-enzyme family has a multi-faceted role in cellular energy metabolism and is characterized by a complex pattern of tissue-specific expression and subcellular distribution. In mammalian tissues, there is always co-expression of at least two different CK isoforms. As a result, previous studies into the role of CK in energy metabolism have not been able to directly differentiate between the individual CK species. Here, we describe experiments which were directed at achieving this goal. First, we studied the kinetic properties of the muscle-specific cytoplasmic and mitochondrial CK isoforms in purified form under in vitro conditions, using a combination of P-31 NMR and spectrophotometry. Secondly, P-31 NMR measurements of the flux through the CK reaction were carried out on intact skeletal and heart muscle from wild-type mice and from transgenic mice, homozygous for a complete deficiency of the muscle-type cytoplasmic CK isoform. Skeletal muscle and heart were compared because they differ strongly in the relative abundance of the CK isoforms. The present data indicate that the kinetic properties of cytoplasmic and mitochondrial CK are substantially different, both in vitro and in vivo. This finding particularly has implications for the interpretation of in vivo studies with P-31 NMR.

The active site histidines of creatine kinase. A critical role of His 61 situated on a flexible loop

A histidine residue with a pKa of 7 has been inferred to act as a general acid-base catalyst for the reaction of creatine kinase (CK), catalyzing the reversible phosphorylation of creatine by ATP. The chicken sarcomeric muscle mitochondrial isoenzyme Mib-CK contains several histidine residues that are conserved throughout the family of creatine kinases. By X-ray crystal structure analysis, three of them (His 61, His 92, and His 186) were recently shown to be located close to the active site of the enzyme. These residues were exchanged against alanine or aspartate by in vitro mutagenesis, and the six mutant proteins were expressed in E. coli and purified. Structural integrity of the mutant proteins was checked by small-angle X-ray scattering. Kinetic analysis showed the mutant His 61 Asp to be completely inactive in the direction of ATP consumption while exhibiting a residual activity of 1.7% of the wild-type (wt) activity in the reverse direction. The respective His to Ala mutant of residue 61 showed approximately 1% wt activity in the forward and 10% wt activity in the reverse reaction. All other mutants showed near wt activities. Changes in the kinetic parameters K(m) or Vmax, as well as a significant loss of synergism in substrate binding, could be observed with all active mutants. These effects were most pronounced for the binding of creatine and phosphocreatine, whereas ATP or ADP binding were less severely affected. Based on our results, we assume that His 92 and His 186 are involved in the binding of creatine and ATP in the active site, whereas His 61 is of importance for the catalytic reaction but does not serve as an acid-base catalyst in the transphosphorylation of creatine and ATP. In addition, our data support the idea that the flexible loop bearing His 61 is able to move towards the active site and to participate in catalysis.

The in vitro kinetics of mitochondrial and cytosolic creatine kinase determined by saturation transfer 31P-NMR

Michaelis- and dissociation constants of sarcomeric mitochondrial creatine kinase (Mi(b)-CK) in solution were determined by enzyme assay and compared to those of cytosolic MM-CK under identical conditions at pH 7.4 and 25 degrees C. Saturation transfer 31P-NMR was used to determine the steady state fluxes mediated by Mi-CK and MM-CK in solution. The NMR detected fluxes of both Mi-CK and MM-CK exhibited, as expected, a linear dependence on Vmax (Vmax range 0-9 mM.s-1). Interestingly, the oligomeric state of Mi-CK, with the Mi-CK octamer/dimer ratio ranging from 2 to 9, did not have a significant effect on the flux/Vmax ratio. Furthermore, the flux/Vmax ratio of Mi-CK was twice as high as that of MM-CK under similar conditions (flux/Vmax for Mi-CK was 0.31 and for MM-CK was 0.15). This difference was primarily due to a 4-fold higher apparent affinity for MgADP of Mi-CK compared to MM-CK (K(m)(MgADP) = 22 +/- 9 microM and 80 +/- 17 microM, resp.). The NMR observed fluxes were in agreement with the fluxes as calculated from the rate equation, using the appropriate metabolite concentrations and the kinetic constants from the spectrophotometric assays. Thus we conclude, that Mi-CK and MM-CK, when in solution, catalyse an exchange-reaction, the flux of which is fully observable by saturation transfer 31P-NMR.

Expression of horseshoe crab arginine kinase in Escherichia coli and site-directed mutations of the reactive cysteine peptide

Arginine kinase (AK) from the horseshoe crab Limulus polyphemus was expressed in Escherichia coli. The bulk of expressed protein resided in insoluble inclusion bodies. However, approximately 3 mg enzyme protein/l culture was present as active soluble AK. The AK-containing expression vector construct was subjected to site-directed mutagenesis via a polymerase chain reaction-based megaprimer protocol. The AK reactive cysteine peptide was engineered so that it was identical to the corresponding peptide sequence of creatine kinase, another member of the guanidino kinase enzyme family. The resulting expressed protein had a considerably reduced specific activity but was still specific for arginine/arginine phosphate. No catalytic activity was observed with other guanidine substrates (creatine, glycocyamine, taurocyamine, lombricine). The reactive cysteine peptide, characteristic of all guanidino kinases, very likely plays a minimal role in determining guanidine specificity.

Reconstitution of active octameric mitochondrial creatine kinase from two genetically engineered fragments

Creatine kinase (CK) has been postulated to consist of two flexibly hinged domains. A previously demonstrated protease-sensitive site in M-CK (Morris & Jackson, 1991) has directed our attempts to dissect mitochondrial CK (Mi-CK) into two protein fragments encompassing amino acids [1-167] and [168-380]. When expressed separately in Escherichia coli, the two fragments yielded large amounts of insoluble inclusion bodies, from which the respective polypeptides could be purified by a simple two-step procedure. In contrast, co-expression of the two fragments yielded a soluble, active, and correctly oligomerizing enzyme. This discontinuous CK showed nearly full specific activity and was virtually indistinguishable from native Mi-CK by far- and near-UV CD. However, the positive cooperativity of substrate binding was abolished, suggesting a role of the covalent domain linkage in the crosstalk between the substrate binding sites for ATP and creatine. The isolated C-terminal fragment refolded into a native-like conformation in vitro, whereas the N-terminal fragment was largely unfolded. Prefolded [168-380] interacted in vitro with [1-167] to form an active enzyme. Kinetic analysis indicated that the fragments associate rapidly and with high affinity (1/K1 = 17 microM) and then isomerize slowly to an active enzyme (k2 = 0.12 min-1; k-2 = 0.03 min-1). Our data suggest that the C-terminal fragment of Mi-CK represents an autonomous folding unit, and that the folding of the C-terminal part might precede the conformational stabilization of the N-terminal moiety in vivo.

Autophosphorylation of creatine kinase: characterization and identification of a specifically phosphorylated peptide

We report that several different chicken and rabbit creatine kinase (CK)1 isoenzymes showed an incorporation of 32P when incubated with [gamma-32P]ATP in an autophosphorylation assay. This modification was was shown to be of covalent nature and resulted from an intramolecular phosphorylation reaction that was not dependent on the CK enzymatic activity. By limited proteolysis and sequence analysis of the resulting peptides, the autophosphorylation sites of chicken brain-type CK could be localized within the primary sequence of the enzyme to a 4.5 kDa peptide, spanning a region that is very likely an essential part of the active site of creatine kinase. Homologous peptides were found to be autophosphorylated in chicken muscle-type CK and a mitochondrial CK isoform. Phosphopeptide as well as mutant enzyme analysis provided evidence that threonine-282(2), threonine-289 and serine-285 are involved in the autophosphorylation of CK. Thr-282 and Ser-285 are located close to the reactive cysteine-283. Thr-289 is located within a conserved glycine-rich region highly homologous to the glycine-rich loop of protein kinases, which is known to be important for ATP binding. Thus, it seems likely that the described region constitutes an essential part of the active site of CK.

Multiple-state equilibrium unfolding of guanidino kinases

The denaturant-induced equilibrium unfolding of octameric mitochondrial creatine kinase, dimeric cytosolic muscle-type creatine kinase, and monomeric arginine kinase was investigated. Stable unfolding intermediates for all three enzymes were manifested by a strongly biphasic red shift of intrinsic protein fluorescence upon increasing denaturant concentrations. In the intermediate state, all proteins were monomeric and enzymatically inactive, but still retained a globular shape. Native tertiary structure interactions were largely disrupted, while at least 50% of the secondary structures were conserved, as suggested by near- and far-UV circular dichroism, respectively. A significantly increased surface hydrophobicity of the intermediate conformation, compared to both the native and the fully unfolded states, was observed by the binding of the hydrophobic fluorescent dye ANS. The observed properties agree formally with the definition of the molten globule state, but can be alternatively explained by a sequential unfolding of individual domains, involving a transient exposure of domain interfaces. Very similar unfolding profiles for all three proteins suggest that the formation of stable unfolding intermediates is not a consequence of the specific oligomeric structures of the CKs but rather due to a common, probably two-domain architecture of the guanidino kinase protomers.

Creatine kinase isoenzyme profiles in the plasma of the domestic fowl (Gallus domesticus): effects of acute heat stress

Creatine kinase isoenzyme activities in extracts of plasma, skeletal muscle, heart and brain tissue of domestic fowls were separated by anion exchange chromatography and tissue specific distributions of the isoenzyme designated MM-CK, BB-CK1 and BB-CK2 were demonstrated. The muscle isoenzyme (MM-CK) was the predominant form in plasma (99 per cent) and its activity increased in response to an episode of acute heat stress.

Functional differences between dimeric and octameric mitochondrial creatine kinase

Mitochondrial creatine kinase (Mi-CK) consists of octameric and dimeric molecules that are interconvertible. In the present study, the kinetic properties of purified chicken heart Mi-CK (Mib-CK) dimers and octamers were investigated separately under highly controlled conditions. Gel-permeation chromatography was performed before and after kinetic measurements in order to clearly define the proportions of octamers and dimers. 'Dimeric' Mi-CK solutions consisted of > or = 90% dimers throughout the experiment whereas 'octameric' Mi-CK solutions consisted in the beginning of 90% octamers, but upon measuring with the highest concentrations of creatine (Cr) and ATP approximately one-third of the octamers dissociated into dimers. These proper controls enabled us to pinpoint the observed kinetic differences between dimers and octamers solely to the oligomeric state of Mib-CK. Both dimeric and octameric Mi-CK displayed synergism in substrate binding (Kd values are higher than Km values), meaning that binding of the first substrate facilities subsequent binding of the second substrate. Most interestingly, Km(Cr) and Kd(Cr) values are both 2-3 times higher for octameric than for dimeric Mi-CK. Thus, at low Cr concentrations, the dimer is kinetically favoured for the forward direction of the reaction (phosphorylcreatine synthesis) compared with the octamer. The possible physiological significance of the lower Kd(Cr) value of dimeric versus octameric Mib-CK, as well as the apparent negative cooperativity of ATP binding at higher [Cr], are discussed within the context of a possible functional role for dimeric Mib-CK in vivo.

Dimer-dimer interactions in octameric mitochondrial creatine kinase

Mitochondrial creatine kinase (Mi-CK) forms octamers and dimers, which are readily interconvertible in vitro. The kinetic and thermodynamic octamer stability of wild-type and two mutant, octamer-destabilized forms of chicken sarcomeric Mi-CK was investigated at varying temperatures, pHs, and salt and substrate concentrations, in order to identify parameters which might regulate the octamer/dimer ratio in vivo and to assess the nature of octamer-stabilizing interactions. For wild-type Mi-CK, the rate of the transition state analogue complex (TSAC)-induced octamer decay increased with increasing temperature up to 28 degrees C; increasing pH markedly accelerated the decay in a biphasic manner. The substrate-dependent decay data suggest that also the productive enzymatic transition state of Mi-CK induces an octamer-destabilizing conformation. Thermodynamically, the octamers are stabilized by a combination of hydrophobic and polar contributions. Van't Hoff analysis showed that hydrophobic interactions dominate both in the absence of substrates and in the TSAC conformation, since the equilibrium octamer fractions increased with increasing temperatures, in spite of the accelerated decay kinetics. For the Mi-CK mutant E4Q, a similar temperature dependence was found; in contrast, mutant W264C exhibited an inverted temperature dependence, suggesting that hydrophobic interactions might be largely abolished in this mutant. Both the kinetic and the thermodynamic data seem to suggest that the octamer-dimer transitions of Mi-CK might not play a major role in a fast regulation of mitochondrial energy metabolism, but could rather be involved in slow long-term modulations.

The tryptophan residues of mitochondrial creatine kinase: roles of Trp-223, Trp-206, and Trp-264 in active-site and quaternary structure formation

The 5 tryptophan residues of chicken sarcomeric mitochondrial creatine kinase (Mib-CK) were individually replaced by phenylalanine or cysteine using site-directed mutagenesis. The mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, circular dichroism, and conformational stability studies. In the present work, Trp-223 is identified as an active-site residue whose replacement even by phenylalanine resulted in > or = 96% inactivation of the enzyme. Trp-223 is responsible for a strong (18-21%) fluorescence quenching effect occurring upon formation of a transition state-analogue complex (TSAC;Mib-CK.creatine.MgADP.NO3-), and Trp-223 is probably required for the conformational change leading to the TSAC-induced octamer dissociation of Mib-CK. Replacement of Trp-206 by cysteine led to a destabilization of the active-site structure, solvent exposure of Trp-223, and to the dissociation of the Mib-CK dimers into monomers. However, this dimer dissociation was counteracted by TSAC formation or the presence of ADP alone. Trp-264 is shown to be located at the dimer-dimer interfaces within the Mib-CK octamer, being the origin of another strong (25%) fluorescence quenching effect, which was observed upon the TSAC-induced octamer dissociation. Substitution of Trp-264 by cysteine drastically accelerated the TSAC-induced dissociation and destabilized the octameric structure by one-fourth of the total free interaction energy, probably by weakening hydrophobic contacts. The roles of the other 2 tryptophan residues, Trp-213 and Trp-268, could be less well assigned.

The structure of mitochondrial creatine kinase and its membrane binding properties

The biochemical and biophysical characterization of the mitochondrial creatine kinase (Mi-CK) from chicken cardiac muscle is reviewed with emphasis on the structure of the octameric oligomer by electron microscopy and on its membrane binding properties. Information about shape, molecular symmetry and dimensions of the Mi-CK octamer, as obtained by different sample preparation techniques in combination with image processing methods, are compared. The organization of the four dimeric subunits into the Mi-CK complex as apparent as apparent in the end-on projections is discussed and the consistently observed high binding affinity of the four-fold symmetric end-on faces towards many support films and towards each other is outlined. A study on the oligomeric state of the enzyme in solution and in intact mitochondria, using chemical crosslinking reagents, is presented together with the results of a search for a possible linkage of Mi-CK with the adenine nucleotide translocator (ANT). The nature of Mi-CK binding to model membranes, demonstrating that rather the octameric than the dimeric subspecies is involved in lipid interaction and membrane contact formation, is resumed and put into relation to our structural observations. The findings are discussed in light of a possible in vivo function of the Mi-CK octamer bridging the gap between outer and inner mitochondrial membranes at the contact sites.

Kinetics of assembly and dissociation of the mitochondrial creatine kinase octamer. A fluorescence study

The dissociation of octameric mitochondrial creatine kinase (Mi-CK) into dimers induced by the transition-state analogue complex (TSAC) mixture (creatine+Mg(2+)+ADP+NO3-) is accompanied by a large (25.2%) decrease in Trp fluorescence. This effect is caused by a Trp residue situated at the dimer-dimer interface within the octamer, which becomes susceptible to solvent quenching upon octamer dissociation. Octamer formation, induced by adding excess EDTA to TSAC-dissociated Mi-CK, involves a transient tetrameric species, whereas the dissociation reaction proceeds in a one-step, all-or-none fashion. From fluorescence spectroscopic investigations of the octamer formation and dissociation reactions, a first-order dissociation rate constant of 0.19 min-1 and a bimolecular association rate constant of 318 M-1 s-1 at 30 degrees C were obtained. The octamers formed after EDTA addition can be dissociated again by lowering the temperature to 4 degrees C, indicating a substantial hydrophobic contribution to the interactions stabilizing the octamer.