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.     

Generation of an active monomer of rabbit muscle creatine kinase by site-directed mutagenesis: the effect of quaternary structure on catalysis and stability

Cytosolic creatine kinase exists in native form as a dimer; however, the reasons for this quaternary structure are unclear, given that there is no evidence of active site communication and more primitive guanidino kinases are monomers. Three fully conserved residues found in one-half of the dimer interface of the rabbit muscle creatine kinase (rmCK) were selectively changed to alanine by site-directed mutagenesis. Four mutants were prepared, overexpressed, and purified: R147A, R151A, D209A, and R147A/R151A. Both the R147A and R147A/R151A were confirmed by size-exclusion chromatography and analytical ultracentrifugation to be monomers, whereas R151A was dimeric and D209A appeared to be an equilibrium mixture of dimers and monomers. Kinetic analysis showed that the monomeric mutants, R147A and R147A/R151A, showed substantial enzymatic activity. Substrate binding affinity by R147A/R151A was reduced approximately 10-fold, although k(cat) was 60% of the wild-type enzyme. Unlike the R147A/R151A, the kinetic data for the R147A mutant could not be fit to a random-order rapid-equilibrium mechanism characteristic of the wild-type, but could only be fit to an ordered mechanism with creatine binding first. Substrate binding affinities were also significantly lower for the R147A mutant, but k(cat) was 11% that of the native enzyme. Fluorescence measurements using 1-anilinonaphthalene-8-sufonate showed that increased amounts of hydrophobic surface area are exposed in all of the mutants, with the monomeric mutants having the greatest amounts of unfolding. Thermal inactivation profiles demonstrated that protein stability is significantly decreased in the monomeric mutants compared to wild-type. Denaturation experiments measuring lambda(max) of the intrinsic fluorescence as a function of guanidine hydrochloride concentration helped confirm the quaternary structures and indicated that the general unfolding pathway of all the mutants are similar to that of the wild-type. Collectively, the data show that dimerization is not a prerequisite for activity, but there is loss of structure and stability upon formation of a CK monomer.     

Two fused proteins combining Stichopus japonicus arginine kinase and rabbit muscle creatine kinase

Two fused proteins of dimeric arginine kinase (AK) from sea cucumber and dimeric creatine kinase (CK) from rabbit muscle, named AK-CK and CK-AK, were obtained through the expression of fused AK and CK genes. Both AK-CK and CK-AK had about 50% AK activity and about 2-fold K _m values for arginine of native AK, as well as about 50% CK activity and about 2-fold K _m values for creatine of native CK. This indicated that both AK and CK moieties are fully active in the two fused proteins. The structures of AK, CK, AK-CK, and CK-AK were compared by collecting data of far-UV circular dichroism, intrinsic fluorescence, 1-anilinonaphthalene-8-sulfonate binding fluorescence, and size-exclusion chromatography. The results indicated that dimeric AK and CK differed in the maximum emission wavelength, the exposure extent of hydrophobic surfaces, and molecular size, though they have a close evolutionary relationship. The structure and thermodynamic stability of AK, CK, AK-CK, and CK-AK were compared by guanidine hydrochloride (GdnHCl) titration. Dimeric AK was more dependent on the cooperation of two subunits than CK according to the analysis of residual AK or CK activity with GdnHCl concentration increase. Additionally, AK and CK had different denaturation curves induced by GdnHCl, but almost the same thermodynamic stability. The two fused proteins, AK-CK and CK-AK, had similar secondary structure, tertiary structure, molecular size, structure, and thermodynamic stability, which indicated that the expression order of AK and CK genes might have little effect on the characteristics of the fused proteins and might further verify the close relationship of dimeric AK and CK. Published in Russion in Biokhimiya, 2006, Vol. 71, No. 9, pp. 1208–1214.     

Crystal structure of a C-terminal deletion mutant of human protein kinase CK2 catalytic subunit

Protein kinase CK2 (formerly called: casein kinase 2) is a heterotetrameric enzyme composed of two separate catalytic chains (CK2alpha) and a stable dimer of two non-catalytic subunits (CK2beta). CK2alpha is a highly conserved member of the superfamily of eukaryotic protein kinases. The crystal structure of a C-terminal deletion mutant of human CK2alpha was solved and refined to 2.5A resolution. In the crystal the CK2alpha mutant exists as a monomer in agreement with the organization of the subunits in the CK2 holoenzyme. The refined structure shows the helix alphaC and the activation segment, two main regions of conformational plasticity and regulatory importance in eukaryotic protein kinases, in active conformations stabilized by extensive contacts to the N-terminal segment. This arrangement is in accordance with the constitutive activity of the enzyme. By structural superimposition of human CK2alpha in isolated form and embedded in the human CK2 holoenzyme the loop connecting the strands beta4 and beta5 and the ATP-binding loop were identified as elements of structural variability. This structural comparison suggests that the ATP-binding loop may be the key region by which the non-catalytic CK2beta dimer modulates the activity of CK2alpha. The beta4/beta5 loop was found in a closed conformation in contrast to the open conformation observed for the CK2alpha subunits of the CK2 holoenzyme. CK2alpha monomers with this closed beta4/beta5 loop conformation are unable to bind CK2beta dimers in the common way for sterical reasons, suggesting a mechanism to protect CK2alpha from integration into CK2 holoenzyme complexes. This observation is consistent with the growing evidence that CK2alpha monomers and CK2beta dimers can exist in vivo independently from the CK2 holoenzyme and may possess physiological roles of their own.     

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.     

Sequence homology and structure predictions of the creatine kinase isoenzymes

Comparisons of the protein sequences and gene structures of the known creatine kinase isoenzymes and other guanidino kinases revealed high homology and were used to determine the evolutionary relationships of the various guamidino kinases. A CK framework is defined, consisting of the most conserved sequence blocks, and diagnostic boxes are identified which are characteristic for anyone creatine kinase isoenzyme (e.g. for vertebrate B-CK) and which may serve to distinguish this isoenzyme from all others (e.g. from M-CKs and Mi-CKs). Comparison of the guanidino kinases by near-UV and far-UV circular dichroism further indicates pronounced conservation of secondary structure as well as of aromatic amino acids that are involved in catalysis.Abbreviations GuaK guanidino kinase - CK creatine kinase - B-and M-CK brain and muscle cytosolic CK isoenzyme - Mi-CK mitochondrial CK isoenzyme - ArgK arginine kinase - Cr creatine - PCr phosphorylcreatine - PArg phosphorylarginine     

The 2.1 A structure of Torpedo californica creatine kinase complexed with the ADP-Mg(2+)-NO(3)(-)-creatine transition-state analogue complex

Creatine kinase (CK) catalyzes the reversible conversion of creatine and ATP to phosphocreatine and ADP, thereby helping maintain energy homeostasis in the cell. Here we report the first X-ray structure of CK bound to a transition-state analogue complex (CK-TSAC). Cocrystallization of the enzyme from Torpedo californica (TcCK) with ADP-Mg(2+), nitrate, and creatine yielded a homodimer, one monomer of which was liganded to a TSAC complex while the second monomer was bound to ADP-Mg(2+) alone. The structures of both monomers were determined to 2.1 A resolution. The creatine is located with the guanidino nitrogen cis to the methyl group positioned to perform in-line attack at the gamma-phosphate of ATP-Mg(2+), while the ADP-Mg(2+) is in a conformation similar to that found in the TSAC-bound structure of the homologue arginine kinase (AK). Three ligands to Mg(2+) are contributed by ADP and nitrate and three by ordered water molecules. The most striking difference between the substrate-bound and TSAC-bound structures is the movement of two loops, comprising residues 60-70 and residues 323-332. In the TSAC-bound structure, both loops move into the active site, resulting in the positioning of two hydrophobic residues (one from each loop), Ile69 and Val325, near the methyl group of creatine. This apparently provides a specificity pocket for optimal creatine binding as this interaction is missing in the AK structure. In addition, the active site of the transition-state analogue complex is completely occluded from solvent, unlike the ADP-Mg(2+)-bound monomer and the unliganded structures reported previously.     

Cloning and expression of a lombricine kinase from an echiuroid worm: insights into structural correlates of substrate specificity

Phosphagen kinases constitute a large family of enzymes catalyzing the reversible phosphorylation of guanidino acceptor compounds. These guanidino substrates differ substantially in size and chemical properties. In spite of the appearance of X-ray crystal structures for two members of this family, creatine kinase (CK) and arginine kinase (AK), the structural correlates of substrate specificity remain to be fully elucidated. We have determined the cDNA and deduced amino acid sequences for lombricine (guanidinethylphosphoserine) kinase (LK) from the echiuroid worm Urechis caupo and expressed the cDNA in Escherichia coli. The recombinant protein was purified by affinity chromatography and showed high capacity for phosphorylation of lombricine. Phosphagen kinases consist of a small, N-terminal domain and a much larger domain connected by a linker sequence. A key event in catalysis in CK and AK, and certainly all other phosphagen kinases, is a large conformational change involving involving a rotation of the two domains and the movement of two highly conserved flexible loops (one located in the small domain; the other located in the large domain of these enzymes) which clamp down on the substrates. Multiple sequence alignments of Urechis LK with the only other LK sequence available and CK, AK and glycocyamine kinase sequences, confirm the importance of the small flexible loop located in the N-terminal domain of phosphagen kinases as one component of the structural determinants of guanidine specificity. The role of the other flexible loop in the large domain in terms of substrate specificity remains questionable.     

Hypotaurocyamine kinase evolved from a gene for arginine kinase

Hypotaurocyamine kinase (HTK) is a member of the highly conserved family of phosphagen kinases that includes creatine kinase (CK) and arginine kinase (AK). HTK is found only in sipunculid worms, and it shows activities for both the substrates hypotaurocyamine and taurocyamine. Determining how HTK evolved in sipunculids is particularly insightful because all sipunculid-allied animals have AK and only some sipunculids have HTK. We determined the cDNA sequence of HTK from the sipunculid worm Siphonosoma cumanense for the first time, cloned it in pMAL plasmid and expressed it in E. coli as a fusion protein with maltose-binding protein. The cDNAderived amino acid sequence of Siphonosoma HTK showed high amino acid identity with molluscan AKs. Nevertheless, the recombinant enzyme of Siphonosoma HTK showed no activity for the substrate arginine, but showed activity for taurocyamine. Comparison of the amino acid sequences of HTK and AK indicated that the amino acid residues necessary for the binding of the substrate arginine in AK have been completely lost in Siphonosoma HTK sequence. The phylogenetic analysis indicated that the HTK amino acid sequence was placed just outside the molluscan AK cluster, which formed a sister group with the arthropod and nematode AKs. These results suggest that Siphonosoma HTK evolved from a gene for molluscan AK. Moreover, to confirm this assertion, we determined by PCR that the gene for Siphonosoma HTK has a 5-exon/4-intron structure, which is homologous with that of the molluscan AK genes. Further, the positions of splice junctions were conserved exactly between the two genes. Thus, we conclude that Siphonosoma HTK has evolved from a primordial gene for molluscan AK.     

Reactivation and refolding of reassociated dimers of rabbit muscle creatine kinase

Creatine kinase (ATP:creatine N-phosphotransferase, EC 2.7.3.2) is a good model for studying dissociation and reassociation during unfolding and refolding. This study compares self-reassociated CK dimers and CK dimers that contain hybrid dimers under proper conditions. Creatine kinase forms a monomer when denatured in 6 M urea for 1 h which will very quickly form a dimer when the denaturant is diluted under suitable conditions. After modification by DTNB, CK was denatured in 6 M urea to form a modified CK monomer. Dimerization of this modified subunit of CK occurred upon dilution into a suitable buffer containing DTT. Therefore, three different types of reassociated CK dimers including a hybrid dimer can be made from two different CK monomers in the proper conditions. The CK monomers are from a urea-denatured monomer of DTNB-modified CK and from an unmodified urea dissociated monomer. Equal enzyme concentration ratios of these two monomers were mixed in the presence of urea, then diluted into the proper buffer to form the three types of reassociated CK dimers including the hybrid dimer. Reassociated CK dimers including all three different types recover about 75% activity following a two-phase course (k ₁ = 4.88 × 10^–3 s^–1, k ₂ = 0.68 × 10^–3 s^–1). Intrinsic fluorescence spectra of the three different CK monomers which were dissociated in 6 M urea, dissociated in 6 M urea after DTNB modification, and a mixture of the first two dissociated enzymes were studied in the presence of the denaturant urea. The three monomers had different fluorescence intensities and emission maxima. The intrinsic fluorescence maximum intensity changes of the reassociated CK dimers were also studied. The refolding processes also follow biphasic kinetics (k ₁ = 3.28 × 10^–3 s^–1, k ₂ = 0.11 × 10^–3 s ^–1) after dilution in the proper solutions. Tsou's method [Tsou (1988), Adv. Enzymol. Rel. Areas Mol. Biol. 61, 381–436] was also used to measure the kinetic reactivation rate constants for the different three types of reassociated CK dimers, with different kinetic reactivation rate constants observed for each type. CK dissociation and reassociation schemes are suggested based on the results.     

Role of quaternary structure in muscle creatine kinase stability: Tryptophan 210 is important for dimer cohesion

A mutant of the dimeric rabbit muscle creatine kinase (MM-CK) in which tryptophan 210 was replaced has been studied to assess the role of this residue in dimer cohesion and the importance of the dimeric state for the native enzyme stability. Wild-type protein equilibrium unfolding induced by guanidine hydrochloride occurs through intermediate states with formation of a molten globule and a premolten globule. Unlike the wild-type enzyme, the mutant inactivates at lower denaturant concentration and the loss of enzymatic activity is accompanied by the dissociation of the dimer into two apparently compact monomers. However, the Stokes radius of the monomer increases with denaturant concentration as determined by size exclusion chromatography, indicating that, upon monomerization, the protein structure is destabilized. Binding of 8-anilinonaphthalene-1-sulfonate shows that the dissociated monomer exposes hydrophobic patches at its surface, suggesting that it could be a molten globule. At higher denaturant concentrations, both wild-type and mutant follow similar denaturation pathways with formation of a premolten globule around 1.5-M guanidine, indicating that tryptophan 210 does not contribute to a large extent to the monomer conformational stability, which may be ensured in the dimeric state through quaternary interactions. Proteins 32:43–51, 1998. © 1998 Wiley-Liss, Inc.     

Proteolytic susceptibility of creatine kinase isozymes and arginine kinase

The time course and dose-response to proteolysis of three dimeric isozymes of creatine kinase, CK-MM (muscle), CK-BB (brain), and CK-MB (heart) and the homologous monomer, arginine kinase were compared. Chymotrypsin and trypsin cause a rapid and significant loss of intact CK-BB, but limited hydrolysis of CK-MM. After 1h of hydrolysis by chymotrypsin, 80% of CK-MM is intact as judged by quantification of monomers after electrophoresis in sodium dodecyl sulfate. While 50% of the intact monomers of CK-MB remain under these conditions, no CK-BB monomers are detected. These results indicate that treatment with chymotrypsin leads to a CK-MB devoid of the B-subunit. When treated with trypsin for 1h, CK-MM is totally resistant to hydrolysis and all CK-BB is highly degraded. However, CK-MB exhibits approximately 90% intact monomers, indicating survival of intact B-subunit in CK-MB. This suggests that heterodimerization of a B-subunit with an M-subunit may have a protective effect against hydrolysis by trypsin. In view of the considerably larger number of potentially tryptic sensitive sites on the muscle isozyme, the resistance of CK-MM and susceptibility of CK-BB dimers to trypsin implies that differences in subunit tertiary structure are a factor in proteolysis of the homodimeric isozymes. Arginine kinase is rapidly degraded by trypsin, but is minimally affected by chymotrypsin. The finding that both a monomeric (arginine kinase) and dimeric (CK-BB) phosphagen kinase are highly susceptible to proteolysis by trypsin indicates that quaternary structure is not, in and of itself, an advantage in resistance to proteolysis. Since both arginine kinase and muscle creatine kinase are resistant to chymotryptic hydrolysis, it seems unlikely that in general, the increased packing density, which may result from dimerization can account for the stability of CK-MM towards trypsin.     

The role of phosphagen specificity loops in arginine kinase

Phosphagen kinases catalyze the reversible transfer of a phosphate between ATP and guanidino substrates, a reaction that is central to cellular energy homeostasis. Members of this conserved family include creatine and arginine kinases and have similar reaction mechanisms, but they have distinct specificities for different guanidino substrates. There has not been a full structural rationalization of specificity, but two loops have been implicated repeatedly. A small domain loop is of length that complements the size of the guanidino substrate, and is located where it could mediate a lock-and-key mechanism. The second loop contacts the substrate with a valine in the methyl-substituted guanidinium of creatine, and with a glutamate in the unsubstituted arginine substrate, leading to the proposal of a discriminating hydrophobic/hydrophilic minipocket. In the present work, chimeric mutants were constructed with creatine kinase loop elements inserted into arginine kinase. Contrary to the prior rationalizations of specificity, most had measurable arginine kinase activity but no creatine kinase activity or enhanced phosphocreatine binding. Guided by structure, additional mutations were introduced in each loop, recovering arginine kinase activities as high as 15% and 64% of wild type, respectively, even though little activity would be expected in the constructs if the implicated sites had dominant roles in specificity. An atomic structure of the mismatched complex of arginine kinase with creatine and ADP indicates that specificity can also be mediated by an active site that allows substrate prealignment that is optimal for reactivity only with cognate substrates and not with close homologs that bind but do not react.     

Dynamical properties of the loop 320s of substrate-free and substrate-bound muscle creatine kinase by NMR: evidence for independent subunits

Muscle creatine kinase (MCK; EC2.7.3.2) is a 86 kDa homodimer that belongs to the family of guanidino kinases. MCK has been intensively studied for several decades, but it is still not known why it is a dimer because this quaternary structure does not translate into obvious structural or functional advantages over the homologous monomeric arginine kinase. In particular, it remains to be demonstrated whether MCK subunits are independent. Here, we describe NMR chemical-shift perturbation and relaxation experiments designed to study the active site 320s flexible loop of this enzyme. The analysis was performed with the enzyme in its ligand-free and MgADP-complexed forms, as well as with the transition-state analogue abortive complex (MCK-Mg-ADP-creatine-nitrate ion). Our data indicate that each subunit can bind substrates independently.     

The role of Arg-96 in Danio rerio creatine kinase in substrate recognition and active center configuration

In creatine kinases (CKs), the amino acid residue-96 is a strictly conserved arginine. This residue is not directly associated with substrate binding, but it is located close to the binding site of the substrate creatine. On the other hand, the residue-96 is known to be involved in expression in the substrate specificity of various other phosphagen (guanidino) kinases, since each enzyme has a specific residue at this position: arginine kinase (Tyr), glycocyamine kinase (Ile), taurocyamine kinase (His) and lombricine kinase (Lys). To gain a greater understanding of the role of residue-96 in CKs, we replaced this residue in zebra fish Danio rerio cytoplasmic CK with other 19 amino acids, and expressed these constructs in Escherichia coli. All the twenty recombinant enzymes, including the wild-type, were obtained as soluble form, and their activities were determined in the forward direction. Compared with the activity of wild-type, the R96K mutant showed significant activity (8.3% to the wild-type), but 10 mutants (R96Y, A, S, E, H, T, F, C, V and N) showed a weak activity (0.056–1.0%). In the remaining mutants (R96Q, G, M, P, L, W, D and I), the activity was less than 0.05%. Our mutagenesis studies indicated that Arg-96 in Danio CK can be substituted for partially by Lys, but other replacements caused remarkable loss of activity. From careful inspection of the crystal structures (transition state analog complex (TSAC) and open state) of Torpedo cytoplasmic CK, we found that the side chain of R96 forms hydrogen bonds with A339 and D340 only in the TSAC structure. Based on the assumption that CKs consist of four dynamic domains (domains 1–3, and fixed domain), the above hydrogen bonds act to link putative domains 1 and 3 in TSAC structure. We suggest that residue-96 in CK and equivalent residues in other phosphagen kinases, which are structurally similar, have dual roles: (1) one involves in distinguishing guanidino substrates, and (2) the other plays a key role in organizing the hydrogen-bond network around residue-96 which offers an appropriate active center for the high catalytic turnover. The mode of development of the network appears to be unique each phosphagen kinase, reflecting evolution of each enzyme.     

The mouse muscle creatine kinase cDNA and deduced amino acid sequences: Comparison to evolutionarily related enzymes

Summary The nucleotide sequence of cloned DNA corresponding to full-length mouse muscle creatine kinase mRNA has been determined. This 1415 base pair DNA sequence and the deduced 381 amino acid sequence of the protein have been compared to creatine kinase sequences from other vertebrate species and to invertebrate guanidino kinase sequences. These comparisons show that the vertebrate muscle creatine kinases constitute a remarkably conserved protein family with a unit evolutionary period of 30. The creatine kinases also retain marked sequence similarity with the more distantly related invertebrate guanidino kinases. A portion of the sequence, presumably part of the ATP binding site, shows similarity to other nucleotide binding proteins with diverse functions. Comparisons of the untranslated regions of the creatine kinase cDNA sequences show that the 5 untranslated regions are more highly conserved than are the 3 untranslated regions; this may point to some regulatory function in the 5 region.     

The roles of C-terminal loop residues of dimeric arginine kinase from sea cucumber Stichopus japonicus in catalysis, specificity and structure

Arginine kinase (AK) catalyzes the reversible phosphorylation of arginine by MgATP to form a high-energy compound phosphoarginine (Parg) and MgADP in forward reaction in invertebrates. To detect the different catalytical mechanisms among Stichopus-AK (dimer) and Limulus-AK (monomer) and Torpedo creatine kinase (dimeric CK) and to reveal the structural role of the C-terminal domain loop (C-loop) of dimeric AK, six single-site mutants, E314D, E314Q, E314V, F315A, F315H and F315Y were constructed as well as two multi-site variants, S312R/F315H/V319E (formed by substituting the C-loop of monomeric AK for that of dimeric AK, termed the AAloop) and S312G/E314V/F315D/E317A/S318A/G321S (formed by substituting the C-loop of dimeric CK for that of dimeric AK, termed the ACloop). The AK activity of the three mutants at Glu³¹⁴ decreased significantly, from 60- to 500-fold. The ACloop showed only slight AK activity, unlike the same construction in Limulus-AK. In addition, all Phe³¹⁵ mutants including the AAloop which retained Glu³¹⁴ had modest AK activity (5–84% of the wild type). All the results above suggested that Glu³¹⁴ played a more significant role in catalysis in dimeric AK than in the monomer. In addition, ANS profiles indicated that the tolerance of the three Glu³¹⁴ mutants to denaturant decreased slightly compared with wild type AK. Though monomeric AK has a His residue at site 315, mutants F315H and the AAloop could not resist any perturbation of denaturant, and the mutants showed a Gibbs free energy of about 2.7 kJ/mol lower than wild type AK. Therefore Phe³¹⁵ in dimeric AK has a different role from His³¹⁵ in monomeric AK. This might contribute to the stabilization of the native conformation, while His³¹⁵ in Limulus AK directly binded to the carboxylate of arginine. Taking all the results above together, we suggested a unique mechanism in dimeric AK, different from both monomeric AK and dimeric CK.     

Phosphagen kinase evolution. Expression in echinoderms

Arginine kinase and creatine kinase that catalyze the transfer of a phosphate group between ATP and arginine and creatine, respectively, play an important role in cellular energetics. In contrast to most animals which exhibit a single phosphagen kinase activity (creatine kinase in chordates and arginine kinase in protostomians), echinoderms exhibit both arginine kinase and creatine kinase activities, sometimes in the same tissue. In contrast to chordates in which creatine kinases are dimers (consisting of two subunits of 40 kDa) and protostomians in which arginine kinases are usually monomers (40 kDa), echinoids contain specific phosphagen kinases: a dimeric arginine kinase (consisting of two subunits of 42 kDa) in eggs and a monomeric creatine kinase (145 kDa) in sperm. We have examined echinoderms from the five existing classes (echinoids, asteroids, ophiuroids, holothurians and crinoids) for the expression of these specific phosphagen kinases in different tissues. Gel filtration was used to determine the molecular masses of the native enzymes. Antibodies specific for arginine kinase or for creatine kinase were used to characterize the subunit composition of arginine kinase and creatine kinase after SDS/PAGE and transfer. In all echinoderms analyzed, arginine kinase always occurred as an enzyme of about 81 kDa consisting of two subunits of 42 kDa and creatine kinase as a monomeric enzyme of 140-155 kDa. The occurrence in echinoderms of both phosphagen kinases with distinct specificities and specific molecular structures is discussed from both a developmental and evolutionary point of view.     

Induced fit in guanidino kinases--comparison of substrate-free and transition state analog structures of arginine kinase

Arginine kinase (AK) is a member of the guanidino kinase family that plays an important role in buffering ATP concentration in cells with high and fluctuating energy demands. The AK specifically catalyzes the reversible phosphoryl transfer between ATP and arginine. We have determined the crystal structure of AK from the horseshoe crab (Limulus polyphemus) in its open (substrate-free) form. The final model has been refined at 2.35 A with a final R of 22.3% (R(free) = 23.7%). The structure of the open form is compared to the previously determined structure of the transition state analog complex in the closed form. Classically, the protein would be considered two domain, but dynamic domain (DynDom) analysis shows that most of the differences between the two structures can be considered as the motion between four rigid groups of nonsequential residues. ATP binds near a cluster of positively charged residues of a fixed dynamic domain. The other three dynamic domains close the active site with separate hinge rotations relative to the fixed domain. Several residues of key importance for the induced motion are conserved within the phosphagen kinase family, including creatine kinase. Substantial conformational changes are induced in different parts of the enzyme as intimate interactions are formed with both substrates. Thus, although induced fit occurs in a number of phosphoryl transfer enzymes, the conformational changes in phosphagen kinases appear to be more complicated than in prior examples.