Complexes of yeast adenylate kinase and nucleotides investigated by 1H NMR.

The role of one of the histidine residues present in many adenylate kinases (H36 in the porcine cytosolic enzyme) is highly disputed. We thus studied the yeast enzyme (AKye) containing this His residue. AKye is highly homologous to the Escherichia coli enzyme (AKec), a protein that is already well characterized by NMR [Vetter et al. (1990) Biochemistry 29, 7459-7467] and does not contain the His residue in question. In addition, discrepancies between solution structural and X-ray crystallographic studies on the location of the nucleotide binding sites of adenylate kinases are clarified. One- and two-dimensional nuclear magnetic resonance (NMR) spectroscopy was used to investigate AKye and its complex with the bisubstrate analogue P1,P5-bis(5'-adenosyl)pentaphosphate (AP5A). The well-resolved spectra of AKye allowed identification of nearly all detectable resonances originating from aromatic side chain protons (12 out of 15 spin systems). From these studies, all aromatic residues of AKec involved in the binding of ATP.Mg2+ have functional analogues in AKye. The AMP site seems to make no contacts to aromatic side chains, neither in the AKye.AP5A.Mg2+ nor in the AKec.AP5A.Mg2+ complexes, so that it is presently not possible to localize this binding site by NMR. The ATP site of AKye is located near residues W210 and H143 in a position similar to the ATP site of the E. coli enzyme. In combination with the recent X-ray results on the AP5A complexes AKye and AKec and the GMP complex of guanylate kinase [Stehle, T., & Schultz, G. E. (1990) J. Mol. Biol. 221, 255-269], the latter one leading to the definition of the monophosphate site, the problem of the location of the nucleotide sites can be considered to be solved in a way contradicting earlier work [for a review, see Mildvan, A. S. (1989) FASEB J. 3, 1705-1714] and denying the His residue homologous to H36 in porcine adenylate kinase a direct role in substrate binding.     

Complexes of Escherichia coli adenylate kinase and nucleotides: 1H NMR studies of the nucleotide sites in solution

One- and two-dimensional nuclear magnetic resonance (NMR) studies, in particular substrate--protein nuclear Overhauser effect (NOESY) measurements, as well as nucleotide and P1,P5-bis-(5'-adenosyl) pentaphosphate (AP5A) titrations and studies of the temperature-dependent unfolding of the tertiary structure of Escherichia coli adenylate kinase (AKEC) were performed. These experiments and comparison with the same type of experiments performed with the porcine enzyme [R?sch, P., Klaus, W., Auer, M., & Goody, R. S. (1989) Biochemistry 28, 4318-4325] led us to the following conclusions: (1) At pH 8 and concentrations of approximately 2.5-3 mM, AKEC is partially unfolded at 318 K. (2) ATP.Mg2+ binds to the ATP site with a dissociation constant of approximately 40 microM under the assumption that ATP binds to one nucleotide site only. (3) AP5A.Mg2+ binds to both nucleotide sites and thus simulates the active complex. (4) The ATP.Mg2+ adenine in the AKEC.AP5A.Mg2+ complex is located close to His134 and Phe19. (5) The AKEC "G-loop" with bound ATP.Mg2+ is structurally highly homologous to the loop region in the oncogene product p21 with bound GTP.Mg2+.     

15N-labeled tRNA. Identification of 4-thiouridine in Escherichia coli tRNASer1 and tRNATyr2 by 1H-15N two-dimensional NMR spectroscopy

Uridine is uniquely conserved at position 8 in elongator tRNAs and binds to A14 to form a reversed Hoogsteen base pair which folds the dihydrouridine loop back into the core of the L-shaped molecule. On the basis of 1H NMR studies, Hurd and co-workers (Hurd, R. E., Robillard, G. T., and Reid, B. R. (1977) Biochemistry 16, 2095-2100) concluded that the interaction between positions 8 and 14 is absent in Escherichia coli tRNAs with only 3 base pairs in the dihydrouridine stem. We have taken advantage of the unique 15N chemical shift of N3 in thiouridine to identify 1H and 15N resonances for the imino units of S4U8 and s4U9 in E. coli tRNASer1 and tRNATyr2. Model studies with chloroform-soluble derivatives of uridine and 4-thiouridine show that the chemical shifts of the protons in the imino moieties move downfield from 7.9 to 14.4 ppm and from 9.1 to 15.7 ppm, respectively; whereas, the corresponding 15N chemical shifts move downfield from 157.5 to 162.5 ppm and from 175.5 to 180.1 ppm upon hydrogen bonding to 5'-O-acetyl-2',3'-isopropylidene adenosine. The large difference in 15N chemical shifts for U and s4U allows one to unambiguously identify s4U imino resonances by 15N NMR spectroscopy. E. coli tRNASer1 and tRNATyr2 were selectively enriched with 15N at N3 of all uridines and modified uridines. Two-dimensional 1H-15N chemical shift correlation NMR spectroscopy revealed that both tRNAs have resonances with 1H and 15N chemical shifts characteristic of s4UA pairs. The 1H shift is approximately 1 ppm upfield from the typical s4U8 resonance at 14.8 ppm, presumably as a result of local diamagnetic anisotropies. An additional s4U resonance with 1H and 15N shifts typical of interaction of a bound water or a sugar hydroxyl group with s4U9 was discovered in the spectrum of tRNATyr2. Our NMR results for tRNAs with 3-base pair dihydrouridine stems suggest that these molecules have an U8A14 tertiary interaction similar to that found in tRNAs with 4-base pair dihydrouridine stems.     

1H, 13C and 15N NMR assignments of the Escherichia coli Orf135 protein

Escherichia coli Orf135 protein is thought to be an enzyme that efficiently hydrolyzes oxidatively damaged nucleotides such as 2-hydroxy-dATP, 8-hydroxy-dGTP and 5-hydroxy-CTP, in addition to 5-methyl-dCTP, dCTP and CTP, thus preventing mutations in cells caused by unfavorable base pairing. Nucleotide pool sanitization by Orf135 is important since organisms are continually subjected to potential damage by reactive oxygen species produced during respiration. It is known that the frequency of spontaneous and H₂O₂-induced mutations is two to threefold higher in the orf135 ^- strain compared with the wild-type. Orf135 is a member of the Nudix family of proteins which hydrolyze nucleoside diphosphate derivatives. Nudix hydrolases are characterized by the presence of a conserved motif, although they recognize various substrates and possess a variety of substrate binding pockets. We are interested in delineating the mechanism by which Orf135 recognizes oxidatively damaged nucleotides. To this end, we are investigating the tertiary structure of Orf135 and its interaction with substrate using NMR. Herein, we report on the ¹H, ¹³C and ¹⁵N resonance assignments of Orf135, which should contribute towards a structural understanding of Orf135 and its interaction with substrate.     

Assignments of backbone 1H, 13C, and 15N resonances and secondary structure of ribonuclease H from Escherichia coli by heteronuclear three-dimensional NMR spectroscopy.

The assignments of individual magnetic resonances of backbone nuclei of a larger protein, ribonuclease H from Escherichia coli, which consists of 155 amino acid residues and has a molecular mass of 17.6 kDa are presented. To remove the problem of degenerate chemical shifts, which is inevitable in proteins of this size, three-dimensional NMR was applied. The strategy for the sequential assignment was, first, resonance peaks of amides were classified into 15 amino acid types by 1H-15N HMQC experiments with samples in which specific amino acids were labeled with 15N. Second, the amide 1H-15N peaks were connected along the amino acid sequence by tracing intraresidue and sequential NOE cross peaks. In order to obtain unambiguous NOE connectivities, four types of heteronuclear 3D NMR techniques, 1H-15N-1H 3D NOESY-HMQC, 1H-15N-1H 3D TOCSY-HMQC, 13C-1H-1H 3D HMQC-NOESY, and 13C-1H-1H 3D HMQC-TOCSY, were applied to proteins uniformly labeled either with 15N or with 13C. This method gave a systematic way to assign backbone nuclei (N, NH, C alpha H, and C alpha) of larger proteins. Results of the sequential assignments and identification of secondary structure elements that were revealed by NOE cross peaks among backbone protons are reported.     

Interaction of yeast iso-1-cytochrome c with cytochrome c peroxidase investigated by [15N, 1H] heteronuclear NMR spectroscopy

The interaction of yeast iso-1-cytochrome c with its physiological redox partner cytochrome c peroxidase has been investigated using heteronuclear NMR techniques. Chemical shift perturbations for both 15N and 1H nuclei arising from the interaction of isotopically enriched 15N cytochrome c with cytochrome c peroxidase have been observed. For the diamagnetic, ferrous cytochrome c, 34 amides are affected by binding, corresponding to residues at the front face of the protein and in agreement with the interface observed in the 1:1 crystal structure of the complex. In contrast, for the paramagnetic, ferric protein, 56 amides are affected, corresponding to residues both at the front and toward the rear of the protein. In addition, the chemical shift perturbations were larger for the ferric protein. Using experimentally observed pseudocontact shifts the magnetic susceptibility tensor of yeast iso-1-cytochrome c in both the free and bound forms has been calculated with HN nuclei as inputs. In contrast to an earlier study, the results indicate that there is no change in the geometry of the magnetic axes for cytochrome c upon binding to cytochrome c peroxidase. This leads us to conclude that the additional effects observed for the ferric protein arise either from a difference in binding mode or from the more flexible overall structure causing a transmittance effect upon binding.     

1H and 15N NMR resonance assignments and preliminary structural characterization of Escherichia coli apocytochrome b562

The 1H and 15N resonances of uniformly enriched apocytochrome b562 (106 residues) have been assigned. The assignment work began with the identification of the majority of HN-H alpha-H beta subspin systems in two-dimensional DQF-COSY and TOCSY spectra of unlabeled protein in D2O and in 95% H2O/5% D2O buffer. Intraresidue and interresidue NOE connectivities were then searched for in two-dimensional homonuclear NOESY spectra recorded on unlabeled protein and in the three-dimensional NOESY-HMQC spectrum recorded on uniformly 15N-enriched protein. Those data, combined with the main-chain-directed assignment strategy (MCD), led to the assignment of the main-chain and many side-chain resonances of 103 of the 106 residues. Qualitatively, the helical conformation is found to be the dominant secondary structure in apocytochrome b562 as it is in holocytochrome b562. The helical segments in apocytochrome b562 overlap extensively with the helical regions defined in the crystal structure of ferricytochrome b562. In addition, a number of tertiary NOEs have been identified which indicate that the global fold of the apoprotein at least partially resembles the four-helix bundle of the holoprotein. The results presented here, together with the evidence obtained with other methods [Feng and Sligar (1991) Biochemistry (submitted)], support the notion that the interior of the protein is fluid and may correspond to a molten globule state.     

Multidimensional1H and15N NMR investigation of glutamine-binding protein ofEscherichia coli

Summary Specific and uniform¹⁵N labelings along with site-directed mutagenesis of glutamine-binding protein have been utilized to obtain assignments of the His¹⁵⁶, Trp³² and Trp.²²⁰ residues. These assignments have been made not only to further study the importance of these 3 amino acid residues in protein-ligand and protein-protein interactions associated with the active transport ofl-glutamine across the cytoplasmic membrane ofEscherichia coli, but also to serve as the starting points in the sequence-specific backbone assignment. The assignment of H₂ of His¹⁵⁶ refines the earlier, model where this particular proton formas an intermolecular hydrogen bond to the -carbonyl ofl-glutamine, while assignments of both Trp³² and Trp²²⁰ show the variation in local structures which ensure the specificity in ligand binding and protein-protein interaction. Using 3D NOESY-HMQC NMR, amide connectivities can be traced along 8–9 amino acid residues at a time. This paper illustrates the usefulness of combining¹⁵N isotopic labeling and multinuclear, multidimensional NMR techniques for a structural investigation of a protein with a molecular weight of 25 000.     

AMP promotes oxygen consumption and ATP synthesis in heart mitochondria through the adenylate kinase reaction: an NMR spectroscopy and polarography study

Adenylate kinase plays an important role in cellular energy homeostasis by catalysing the interconversion of adenine nucleotides. The goal of present study was to evaluate the contribution of the adenylate kinase reaction to oxidative ATP synthesis by direct measurements of ATP using ³¹P NMR spectroscopy. Results show that AMP can stimulate ATP synthesis in the presence or absence of ADP. In particular, addition of 1 mM AMP to the 0.6 mM ADP superfusion system of isolated superfused mitochondria (contained and maintained in agarose beads) led to a 25% increase in ATP synthesis as measured by the increase in βATP signal. More importantly, we show that AMP can support ATP synthesis in the absence of ADP, demonstrated as follows. Superfusion of mitochondria without ADP led to the disappearance of ATP γ, α and β signals and the increase of P_i. Addition of AMP to the medium restored the production of ATP, as demonstrated by the reappearance of γ, α and β ATP signals, in conjunction with a decrease in P_i, which is being used for ATP synthesis. Polarographic studies showed Mg²⁺ dependence of this process, confirming the specificity of the adenylate kinase reaction. Furthermore, data obtained from this study demonstrate, for the first time, that different aspects of the adenylate kinase reaction can be evaluated with ³¹P NMR spectroscopy. Copyright © 2015 John Wiley & Sons, Ltd. SIGNIFICANCE OF RESEARCH PARAGRAPH The data generated in the present study indicate that ³¹P NMR spectroscopy can effectively be used to study the adenylate kinase reaction under a variety of conditions. This is important because understanding of adenylate kinase function and/or malfunction is essential to understanding its role in health and disease. The data obtained with ³¹P NMR were confirmed by polarographic studies, which further strengthens the robustness of the NMR findings. In summary, ³¹P NMR spectroscopy provides a sensitive tool to study adenylate kinase activity in different physiological and pathophysiological conditions, including but not exclusive of, cancer, ischemic injury, hemolytic anemia and neurological problems such as sensorineural deafness.     

Human platelet factor 4 monomer-dimer-tetramer equilibria investigated by 1H NMR spectroscopy

As a function of protein concentration, proton NMR spectra of human platelet factor 4 (PF4) differ. Correlation with low-angle laser light scattering data has allowed identification of concentration-dependent NMR spectral changes to PF4 aggregation, with tetramers being the largest aggregates formed. Well-resolved aromatic ring proton NMR resonances were assigned to Tyr-60, His-I, and His-II in monomer, dimer, and tetramer states. Since Tyr-60 3.5 ring proton resonances are well resolved from state to state, estimation of fractional populations in each state was possible. By varying the PF4 concentration, changes in these populations when plotted according to the Hill equation show a bimolecular mechanism of aggregation which proceeds from monomers to tetramers through a dimer intermediate. Equilibrium constants for dimer association (KD) and tetramer association (KT) have been estimated as a function of pH and ionic strength. At pH 4, where KD and KT approach the same value, resonances associated with all three aggregate states are observed. Lowering the pH shifts the equilibrium to the monomer state, while raising the pH shifts the equilibrium to dimer and tetramer states. Analysis of the pH dependence of KD and KT suggests that electrostatic interactions, probably arising from Glu/Asp and Lys/Arg side chains, play a role in the binding process. Increasing the solvent ionic strength stabilizes the tetramer state especially at low pH, suggesting that intersubunit, repulsive electrostatic interactions probably between/among cationic side chains (Lys/Arg) attenuate the aggregation process. Information based primarily on histidine pKa values and photo-CIDNP 1H NMR data suggests that Tyr-60 and His-I, but not His-II, are significantly affected by the aggregation process.     

Mutations in the nucleotide binding loop of adenylate kinase of Escherichia coli

The adk gene of Escherichia coli has been used to overexpress the adenylate kinase protein in two ways: (1) by cloning the adk gene with its own promoter into pEMBL plasmids, which have an increased copy number, and (2) by deleting the adk promoter and cloning the gene behind the regulatable tac promoter. Adenylate kinase comprises up to 40% of the soluble cellular extracts from E. coli strains containing these plasmids. Mutations have been introduced into the gene by site-directed mutagenesis to exchange amino acids in the nucleotide binding loop, which is highly conserved in many mononucleotide binding proteins. The mutation of Lys13----Gln is nearly inactive, whereas the Pro9----Leu and the Gly10----Val mutant proteins have an increased Km for both substrates and a Vmax that is similar to wild type. Proton NMR measurements of the proteins show that a major structural change seems to have taken place for the Pro9----Leu and Gly10----Val mutants. The results are discussed in the light of the kinetic mechanism for adenylate kinase and the three-dimensional structure of the protein.     

Investigation of adenylate kinase from Escherichia coli and its interaction with nucleotides by Fourier transform infrared spectroscopy

The secondary structure of adenylate kinase (EC 2.7.4.3) from E. coli was investigated under various conditions using Fourier transform infrared spectroscopy. The overall band contour of the conformation-sensitive amide I mode indicates that in HEPES buffer (pH 7.4) the major structure of the protein is alpha-helical. A more detailed estimate obtained from decomposition of the amide I band into its constituent component bands gives 50% alpha-helix, 26% beta-structure, 15% turns and loops, and about 9% nonrepetitive unordered structures. Binding of nucleotide (e.g., ATP) to the donor site decreases the beta-content and shifts the amide I band to higher wavenumbers, whereas binding of nucleotide (e.g., AMP) to the acceptor site does not produce any change in conformation of the protein. These results agree with the protection by ATP and lack of protection by AMP when adenylate kinase is digested with trypsin. The effect of protein denaturing agents and conditions (temperature, high pH, sodium dodecyl sulfate) on changes in the protein conformation as revealed by the conformation-sensitive amide I bands is discussed.     

Interaction of local anesthetics with lipid bilayers investigated by 1H MAS NMR spectroscopy

The membrane location of the local anesthetics (LA) lidocaine, dibucaine, tetracaine, and procaine hydrochloride as well as their influence on phospholipid bilayers were studied by ³¹P and ¹H magic-angle spinning (MAS) NMR spectroscopy. The ³¹P NMR spectra of the LA/lipid preparations confirmed that the overall bilayer structure of the membrane remained preserved. The relation between the molecular structure of the LAs and their membrane localization and orientation was investigated quantitatively using induced chemical shifts, nuclear Overhauser enhancement spectroscopy, and paramagnetic relaxation rates. All three methods revealed an average location of the aromatic rings of all LAs in the lipid-water interface of the membrane, with small differences between the individual LAs depending on their molecular properties. While lidocaine is placed in the upper chain/glycerol region of the membrane, for dibucaine and procaine the maximum of the distribution are slightly shifted into the glycerol region. Finally for tetracaine the aromatic ring is placed closest to the aqueous phase in the glycerol/headgroup region of the membrane. The hydrophobic side chains of the LA molecules dibucaine and tetracaine were located deeper in the membrane and showed an orientation towards the hydrocarbon core. In contrast the side chains of lidocaine and procaine are oriented towards the aqueous phase.     

Sequence-specific NMR assignments of the trp repressor from Escherichia coli using three-dimensional 15N/1H heteronuclear techniques.

Sequence-specific 15N and 1H assignments for the trp holorepressor from Escherichia coli are reported. The trp repressor consists of two identical 107-residue subunits which are highly helical in the crystal state [Schevitz, R., Otwinowski, Z., Joachimiak, A., Lawson, C. L. & Sigler, P. B. (1985) Nature 317, 782-786]. The high helical content and the relatively large size of the protein (Mr = 25,000) make it difficult to assign even the main-chain resonances by conventional homonuclear two-dimensional NMR methods. However, we have now assigned the main-chain resonances of 94% of the residues by using three-dimensional 15N/1H heteronuclear experiments on a sample of protein uniformly labelled with 15N. The additional resolution obtained by spreading out the signals into three dimensions proved indispensable in making these assignments. In particular, we have been able to resolve signals from residues in the N-terminal region of the A helix for the first time in solution. The observed NOE results confirm that the repressor is highly helical in solution, and contains no extended chain conformations.     

Domain flexibility in ligand-free and inhibitor-bound Escherichia coli adenylate kinase based on a mode-coupling analysis of 15N spin relaxation

Adenylate kinase from Escherichia coli (AKeco), consisting of a 23.6-kDa polypeptide chain folded into domains CORE, AMPbd, and LID catalyzes the reaction AMP + ATP <--> 2ADP. The domains AMPbd and LID execute large-amplitude movements during catalysis. Backbone dynamics of ligand-free and AP(5)A-inhibitor-bound AKeco is studied with slowly relaxing local structure (SRLS) (15)N relaxation, an approach particularly suited when the global (tau(m)) and the local (tau) motions are likely to be coupled. For AKeco tau(m) = 15.1 ns, whereas for AKeco*AP(5)A tau(m) = 11.6 ns. The CORE domain of AKeco features an average squared order parameter, , of 0.84 and correlation times tau(f) = 5-130 ps. Most of the AKeco*AP(5)A backbone features = 0.90 and tau(f) = 33-193 ps. These data are indicative of relative rigidity. Domains AMPbd and LID of AKeco, and loops beta(1)/alpha(1), alpha(2)/alpha(3), alpha(4)/beta(3), alpha(5)/beta(4), and beta(8)/alpha(7) of AKeco*AP(5)A, feature a novel type of protein flexibility consisting of nanosecond peptide plane reorientation about the C(i-1)(alpha)-C(i)(alpha) axis, with correlation time tau(perpendicular) = 5.6-11.3 ns. The other microdynamic parameters underlying this dynamic model include S(2) = 0.13-0.5, tau(parallel) on the ps time scale, and a diffusion tilt beta(MD) ranging from 12 to 21 degrees. For the ligand-free enzyme the tau(perpendicular) mode was shown to represent segmental domain motion, accompanied by conformational exchange contributions R(ex) < or = 4.4 s(-1). Loop alpha(4)/beta(3) and alpha(5)/beta(4) dynamics in AKeco*AP(5)A is related to the "energetic counter-balancing of substrate binding" effect apparently driving kinase catalysis. The other flexible AKeco*AP(5)A loops may relate to domain motion toward product release.     

Uniform 15N labeling of a fungal peptide: the structure and dynamics of an alamethicin by 15N and 1H NMR spectroscopy.

An alamethicin, secreted by the fungus Trichoderma viride and containing a glutamine at position 18 instead of the usual glutamic acid, has been uniformly labeled with 15N and purified by HPLC. The extent of 15N incorporation at individual backbone and side-chain sites was found to vary from 85% to 92%, as measured by spin-echo difference spectroscopy. The proton NMR spectrum of the peptide dissolved in methanol was assigned using correlation spectroscopies and nuclear Overhauser enhancements (NOE) measured in the rotating frame. The 15N resonances were assigned by the 2D 1H-15N correlation via heteronuclear multiple-quantum coherence experiment. NOEs and 3JNHC alpha H coupling constants strongly suggest that, in methanol, from Aib-3 to Gly-11, the peptide adopts a predominantly helical conformation, in agreement with previous 1H NMR studies [Esposito, G., Carver, J.A, Boyd, J., & Campbell, I.D. (1987) Biochemistry 26, 1043-1050; Banerjee, U., Tsui, F.-P., Balasubramanian, T.N., Marshall, G.R., & Chan, S I. (1983) J. Mol. Biol. 165, 757-775]. The conformation of the carboxyl terminus (12-20) is less well determined, partly because the amino acid composition reduces the number of NOEs and coupling constants which can be determined by 1H NMR spectroscopy. The 3JNHC alpha H in the C-terminus suggest the possibility of conformational averaging at Leu-12, Val-15, and Gln-19, an interpretation which is supported by a recent molecular dynamics simulation of the peptide [Fraternalli, F. (1990) Biopolymers 30, 1083-1099].(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural and catalytic characteristics of Escherichia coli adenylate kinase

The adk gene encoding adenylate kinase in Escherichia coli was cloned in pBR322. Adenylate kinase represented about 4% of total proteins in extracts of cells containing the pBR322:adk plasmid. This allowed preparation of more than 90% pure enzyme in a single-step purification procedure. Amino acid analysis, high performance liquid chromatography separation of trypsin digests, sequence analysis of most peptides, and determination of the N-terminal sequence of the whole protein confirmed the primary structure of E. coli adenylate kinase predicted from the nucleotide sequence of the adk gene (Brune, M., Schumann, R., and Wittinghofer, F. (1985) Nucleic Acids Res. 13, 7139-7151). 2-Nitro-5-thiocyanatobenzoic acid reacted with the single cysteine residue of E. coli adenylate kinase. The cyanylated protein was cleaved upon exposure to alkaline pH, yielding two peptides corresponding to residues 1-76 and 77-214, respectively. A mixture of purified peptides tended to reassociate, recovering both catalytic activity and binding properties for adenine nucleotides. E. coli adenylate kinase has a broader specificity for nucleoside monophosphates than does the mammalian enzyme. In addition to 2'-dAMP, other nucleoside monophosphates such as 3'-dAMP, adenine-9-beta-D-arabinofuranoside 5'-monophosphate, and 7-deazaadenosine (tubercidine) 5'-monophosphate were able to replace AMP as substrate.     

Backbone dynamics of escherichia coli adenylate kinase at the extreme stages of the catalytic cycle studied by (15)N NMR relaxation

Adenylate kinase from Escherichia coli (AKeco), consisting of a single 23.6 kDa polypeptide chain folded into domains CORE, AMPbd, and LID, catalyzes the reaction AMP + ATP --> 2ADP. Domains LID and AMPbd execute large-scale movements during catalysis. Backbone dynamics of ligand-free and AP(5)A-inhibitor-bound AKeco were studied comparatively with (15)N NMR relaxation methods. Overall diffusion with correlation times of 15.05 (11.42) ns and anisotropy D(parallel)/D(perp) = 1.25 (1.10), and fast internal motions with correlation times up to 100 ps (50 ps), were determined for AKeco (AKecoAP(5)A). Fast internal motions affect 93% of the AKeco sites, with pronounced preference for domains AMPbd and LID, and 47% of the AKecoAP(5)A sites, with limited variability along the chain. The mean squared generalized order parameters, , of secondary structure elements and loops are affected by ligand binding differentially and in a domain-specific manner. Nanosecond motions predominate within AMPbd. Prominent exchange contributions, associated in particular with residue G10 of the nucleotide-binding P-loop motif, are interpreted to reflect hydrogen-bond dynamics at the inhibitor-binding site. The hypothesis of energetic counter balancing of substrate binding based on crystallographic data is strongly supported by the solution NMR results. Correlations between backbone dynamics and domain displacement are established.