Consequences of a six residual deletion from the N-terminal of rabbit muscle creatine kinase

Metallothioneins protect cytosolic creatine kinases against stress induced by nitrogen-based oxidants

The formation of intracellular nitrogen-based oxidants has important physiological and pathological consequences. CK (creatine kinase), which plays a key role in intracellular energy metabolism, is a main target of low concentrations of oxidative and nitrative stresses. In the present study, the interaction between cytosolic CKs [MM-CK (muscle-type CK) and BB-CK (brain-type CK)] and MTs [metallothioneins; hMT2A (human MT-IIA) and hMT3 (human MT-III)] were characterized by both in vitro and intact-cell assays. MTs could successfully protect the cytosolic CKs against inactivation induced by low concentrations of PN (peroxynitrite) and NO both in vitro and in hMT2A-overexpressing H9c2 cells and hMT3-knockdown U-87 MG cells. Under high PN concentrations, CK formed granule-like structures, and MTs were well co-localized in these aggregated granules. Further analysis indicated that the number of cells containing the CK aggregates negatively correlated with the expression levels of MTs. In vitro experiments indicated that MTs could effectively protect CKs against aggregation during refolding, suggesting that MT might function as a chaperone to assist CK re-activation. The findings of the present study provide direct evidence of the connection between the two well-characterized intracellular systems: the precisely balanced energy homoeostasis by CKs and the oxidative-stress response system using MTs.

Slow skeletal muscle myosin-binding protein-C (MyBPC1) mediates recruitment of muscle-type creatine kinase (CK) to myosin

Muscle contraction requires high energy fluxes, which are supplied by MM-CK (muscle-type creatine kinase) which couples to the myofibril. However, little is known about the detailed molecular mechanisms of how MM-CK participates in and is regulated during muscle contraction. In the present study, MM-CK is found to physically interact with the slow skeletal muscle-type MyBPC1 (myosin-binding protein C1). The interaction between MyBPC1 and MM-CK depended on the creatine concentration in a dose-dependent manner, but not on ATP, ADP or phosphocreatine. The MyBPC1-CK interaction favoured acidic conditions, and the two molecules dissociated at above pH 7.5. Domain-mapping experiments indicated that MM-CK binds to the C-terminal domains of MyBPC1, which is also the binding site of myosin. The functional coupling of myosin, MyBPC1 and MM-CK is further corroborated using an ATPase activity assay in which ATP expenditure accelerates upon the association of the three proteins, and the apparent K(m) value of myosin is therefore reduced. The results of the present study suggest that MyBPC1 acts as an adaptor to connect the ATP consumer (myosin) and the regenerator (MM-CK) for efficient energy metabolism and homoeostasis.

The generation of the oxidized form of creatine kinase is a negative regulation on muscle creatine kinase

Muscle creatine kinase (CK) is a crucial enzyme in energy metabolism, and it exists in two forms, the reduced form (R-CK) and the oxidized form (O-CK). In contrast with R-CK, O-CK contained an intrachain disulfide bond in each subunit. Here we explored the properties of O-CK and its regulatory role on muscle CK. The intrachain disulfide bond in O-CK was demonstrated to be formed between Cys(74) and Cys(146) by site-directed mutagenesis. Biophysical analysis indicated that O-CK showed decreased catalytic activity and that it might be structurally unstable. Further assays through guanidine hydrochloride denaturation and proteolysis by trypsin and protease K revealed that the tertiary structure of O-CK was more easily disturbed than that of R-CK. Surprisingly, O-CK, unlike R-CK, cannot interact with the M-line protein myomesin through biosensor assay, indicating that O-CK might have no role in muscle contraction. Through in vitro ubiquitination assay, CK was demonstrated to be a specific substrate of muscle ring finger protein 1 (MURF-1). O-CK can be rapidly ubiquitinated by MURF-1, while R-CK can hardly be ubiquitinated, implying that CK might be degraded by the ATP-ubiquitin-proteasome pathway through the generation of O-CK. The results above were further confirmed by molecular modeling of the structure of O-CK. Therefore, it can be concluded that the generation of O-CK was a negative regulation of R-CK and that O-CK might play essential roles in the molecular turnover of MM-CK.

Impact of intra-subunit domain-domain interactions on creatine kinase activity and stability

Creatine kinase (CK) is a key enzyme in vertebrate excitable tissues. In this research, five conserved residues located on the intra-subunit domain-domain interface were mutated to explore their role in the activity and structural stability of CK. The mutations of Val72 and Gly73 decreased both the activity and stability of CK. The mutations of Cys74 and Val75, which had no significant effect on CK activity and structure, gradually decreased the stability and reactivation of CK. Our results suggested that the mutations might modify the correct positioning of the loop contributing to domain-domain interactions, and result in decreased stability against denaturation.

The evolution from asparagine or threonine to cysteine in position 146 contributes to generation of a more efficient and stable form of muscle creatine kinase in higher vertebrates

Creatine kinase, a key enzyme in vertebrate excitable tissues that require large energy fluxes, catalyzes the reversible transfer of phosphate between adenosine triphosphate and creatine. Sequence alignment indicated that the 146th amino acid is cysteine in the muscle creatine kinase of higher vertebrates including Amphibia, Reptilia, Aves and Mammalia. In fishes, it is cysteine in Agnatha and Chondrichthyes, and asparagine or threonine in Osteichthyes, which is the ancestor of Amphibia, Reptilia, Aves and Mammalia. To explore the structural and functional role of this special residue, a series of site-directed mutants of rabbit muscle creatine kinase were constructed, including C146S, C146N, C146T, C146G, C146A, C146D and C146R. A detailed comparison was made between wild-type creatine kinase and the mutants in catalytic activity, physico-chemical properties and structural stability against thermal inactivation and guanidine hydrochloride denaturation. It was found that except for C146S, the mutants had relatively lower catalytic activity and structural stability than Wt-CK. Wt-CK and C146S were the most stable ones, followed by C146N and C146T, and then C146G and C146A, and C146D and C146R were the least stable mutants. These results suggested that the 146th residue plays a crucial role in maintaining the structural stability of creatine kinase, and that the evolution in this amino acid from asparagine or threonine to cysteine contributes to the generation of a more efficient and more stable form of creatine kinase in higher vertebrates.

Isolation, characterization, and cDNA-derived amino acid sequence of glycocyamine kinase from the tropical marine worm Namalycastis sp

We isolated cytoplasmic glycocyamine kinase (GK) and creatine kinase (CK) from the tropical marine worm Namalycastis sp. by ammonium sulfate fractionation, gel filtration on Sephacryl S-200, and DEAE-5PW chromatography. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) showed that the isolated GK is highly purified and appears to be a heterodimer of two distinct subunits, alpha and beta, with molecular masses of approximately 40 kDa. The complete nucleotide sequences of the cDNAs for Namalycastis GKalpha and GKbeta were 1527 (encoding 374 amino acids) and 1579 bp (encoding 390 amino acids), respectively. The predicted amino acid sequences differ only in the N-terminal 50 residues. This is consistent with the characteristics of Neanthes GKalpha and GKbeta chains, which we have previously shown to be generated by alternative splicing. The recombinant enzymes GKalpha, GKbeta, and CK from Namalycastis were successfully expressed in Escherichia coli as maltose-binding protein fusion proteins. In contrast to the stable GKbeta enzyme, GKalpha was quite unstable, and its activity decreased remarkably with time. Thus, the N-terminal 50 residues appear to play a key role in enzyme stability. The kinetic parameters for the native GK heterodimer were similar to GKbeta, suggesting that GKalpha would have an activity similar to GKbeta if part of a heterodimer. This is the first report of precise kinetic parameters for GK. Finally, based on our results, we present a model for pluriphosphagen function in Namalycastis wherein cytoplasmic GK and CK and mitochondrial CK function together with phosphocreatine and phosphoglycocyamine to enable cells to respond quickly to a sudden large energy requirement.

The tryptophane residues of dimeric arginine kinase: roles of Trp-208 and Trp-218 in active site and conformation stability

Roles of the two tryptophane residues of dimeric arginine kinase (AK) were individually investigated by site-directed mutagenesis. Both residues were fully conserved in the phosphogen kinase family and the mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, fluorescence quenching experiments, thermal stability and conformational stability. Our studies revealed that Trp-218 was located at the active site of AK and was the major fluorescence contributor (96.9%). Single replacement of this residue by alanine led to almost complete inactivation of the enzyme. In addition, a decrease in the melting temperature in differential scanning calorimetry (DSC) profiles and the equilibrium studies in guanidine hydrochloride (GdnHCl) denaturation after mutagenesis also suggested that Trp-218 takes part in stabilizing the conformational structure of AK. Although another tryptophane, Trp-208 was not located at the active sites, it may take part in maintaining the correct dimer conformation for catalysis. Replacement of this tryptophane by alanine decreased the activity to 70.3% and made it susceptible to heat and denaturants, such as GdnHCl. In addition, Trp-208 also seemed to play an important role in correct protein folding.

Alternative splicing produces transcripts coding for alpha and beta chains of a hetero-dimeric phosphagen kinase

Glycocyamine kinase (GK) catalyzes the reversible phosphorylation of glycocyamine (guanidinoacetate), a reaction central to cellular energy homeostasis in certain animals. GK is a member of the phosphagen kinase enzyme family and appears to have evolved from creatine kinase (CK) early in the evolution of multi-cellular animals. Prior work has shown that GK from the polychaete Neanthes (Nereis) diversicolor exits as a hetero-dimer in vivo and that the two polypeptide chains (termed alpha and beta) are coded for by unique transcripts. In the present study, we demonstrate that the GK from a congener Nereis virens is also hetero-dimeric and is coded for by alpha and beta transcripts, which are virtually identical to the corresponding forms in N. diversicolor. The GK gene from N. diversicolor was amplified by PCR. Sequencing of the PCR products showed that the alpha and beta chains are the result of alternative splicing of the GK primary mRNA transcript. These results also strongly suggest that this gene underwent an early tandem exon duplication event. Full-length cDNAs for N. virens GKalpha and GKbeta were individually ligated into expression vectors and the resulting constructs used to transform Escherichia coli expression hosts. Regardless of expression conditions, minimal GK activity was observed in both GKalpha and GKbeta constructs. Inclusion bodies for both were harvested, unfolded in urea and alpha chains, beta chains and mixtures of alpha and beta chains were refolded by sequential dialysis. Only modest amounts of GK activity were observed when alpha and beta were refolded individually. In contrast, when refolded the alpha and beta mixture yielded highly active hetero-dimers, as validated by size exclusion chromatography, electrophoresis and mass spectrometry, with a specific activity comparable to that of natural GK. The above evidence suggests that there is a preference for hetero-dimer formation in the GKs from these two polychaetes. The evolution of the alternate splicing and an additional exon in these GKs, producing alpha and beta transcripts, can be viewed as a possible compensation for a mutation(s) in the original gene, which most likely coded for a homo-dimeric protein.