ATP Complex Research Articles

Functional Characterization of the Atypical Hsp70 Subunit of Yeast Ribosome-associated Complex

Eukaryotic ribosomes carry a stable chaperone complex termed ribosome-associated complex consisting of the J-domain protein Zuo1 and the Hsp70 Ssz1. Zuo1 and Ssz1 together with the Hsp70 homolog Ssb1/2 form a functional triad involved in translation and early polypeptide folding processes. Strains lacking one of these components display slow growth, cold sensitivity, and defects in translational fidelity. Ssz1 diverges from canonical Hsp70s insofar that neither the ability to hydrolyze ATP nor binding to peptide substrates is essential in vivo. The exact role within the chaperone triad and whether or not Ssz1 can hydrolyze ATP has remained unclear. We now find that Ssz1 is not an ATPase in vitro, and even its ability to bind ATP is dispensable in vivo. Furthermore, Ssz1 function was independent of ribosome-associated complex formation, indicating that Ssz1 is not merely a structural scaffold for Zuo1. Finally, Ssz1 function in vivo was inactivated when both nucleotide binding and Zuo1 interaction via the C-terminal domain were disrupted in the same mutant. The two domains of this protein thus cooperate in a way that allows for severe interference in either but not in both of them.

Structural Insight into AMPK Regulation: ADP Comes into Play

The AMP-activated protein kinase (AMPK), a sensor of cellular energy status found in all eukaryotes, responds to changes in intracellular adenosine nucleotide levels resulting from metabolic stresses. Here we describe crystal structures of a heterotrimeric regulatory core fragment from Schizosaccharomyces pombe AMPK in complex with ADP, ADP/AMP, ADP/ATP, and 5-aminoimidazole-4-carboxamide 1-beta-D-ribofuranotide (AICAR phosphate, or ZMP), a well-characterized AMPK activator. Prior crystallographic studies had revealed a single site in the gamma subunit that binds either ATP or AMP within Bateman domain B. Here we show that ZMP binds at this site, mimicking the binding of AMP. An analogous site in Bateman domain A selectively accommodates ADP, which binds in a distinct manner that also involves direct ligation to elements from the beta subunit. These observations suggest a possible role for ADP in regulating AMPK response to changes in cellular energy status.

Mitochondrial Ageing and the Beneficial Role of α-Lipoic Acid

Oxidative damage has been implicated to be a major causative factor in the decline in physiological functions that occur during the ageing process. Mitochondria are known to be a rich source for the production of free radicals and, consequently, mitochondrial components are susceptible to lipid peroxidation (LPO) that decreases respiratory activity. In the present investigation, we have evaluated mitochondrial LPO, 8-oxo-dG, oxidized glutathione, reduced glutathione, ATP, lipoic acid, TCA cycle enzymes and electron transport chain (ETC) complex activities in the brain of young versus aged rats. In aged rats, the contents of LPO, oxidized glutathione and 8-oxo-dG were high whereas reduced glutathione, ATP, lipoic acid, TCA cycle enzymes and ETC complex activities were found to be low. Lipoic acid administration to aged rats reduced the levels of mitochondrial LPO, 8-oxo-dG and oxidized glutathione and enhanced reduced glutathione, ATP, lipoic acid and ETC complex activities. In young rats lipoic acid administration showed only minimal lowering the levels of LPO, 8-oxo-dG and oxidized glutathione and slight increase in the levels of reduced glutathione, ATP, lipoic acid, TCA cycle enzymes and ETC complex activities. These findings suggest that the dithiol, lipoic acid, provides protection against age-related oxidative damage in the mitochondria of aged rats.

Differing Conformational Pathways Before and After Chemistry for Insertion of dATP versus dCTP Opposite 8-OxoG in DNA Polymerase β

To elucidate how human DNA polymerase β (pol β) discriminates d ATP from d CTP when processing 8-oxoguanine (8-oxo G), we analyze a series of dynamics simulations before and after the chemical step with d ATP and d CTP opposite an 8-oxo G template started from partially open complexes of pol β. Analyses reveal that the thumb closing of pol β before chemistry is hampered when the incorrect nucleotide d ATP is bound opposite 8-oxo G; the unfavorable interaction between active-site residue Tyr 271 and d ATP that causes an anti to syn change in the 8-oxo G ( syn):d ATP complex explains this slow motion, in contrast to the 8-oxo G ( anti):d CTP system. Such differences in conformational pathways before chemistry for mismatched versus matched complexes help explain the preference for correct insertion across 8-oxo G by pol β. Together with reference studies with a nonlesioned G template, we propose that 8-oxo G leads to lower efficiency in pol β's incorporation of d CTP compared with G by affecting the requisite active-site geometry for the chemical reaction before chemistry. Furthermore, because the active site is far from ready for the chemical reaction after partial closing or even full thumb closing, we suggest that pol β is tightly controlled not only by the chemical step but also by a closely related requirement for subtle active-site rearrangements after thumb movement but before chemistry.

ATPase‐Coupled Release Control from Polyion Complex Capsules Encapsulating Muscle Proteins

In the present study, a muscle contractile protein complex, actomyosin, has been successfully encapsulated into gellan-chitosan polyion complex (PIC) capsules. The recovery of the myosin-ATPase activity is approximately 50% and the Mg2+-ATPase activity is stimulated by the presence of F-actin, which implies the formation of the actomyosin complex inside the capsule. Furthermore, encapsulation could protect the myosin, F-actin, and actomyosin inside from hydrolysis by proteases. Two small proteins, myoglobin and cytochrome c, have been used in the release tests. The release of myoglobin is not affected by the ionic strength of the external solution, while the release of cytochrome c increases with increasing ionic strength. The maximal releases are found in the external pH solution close to the isoelectric points of each protein. The Mg2+-ATP complex itself reduces the release percentages of the small proteins from the PIC capsule. The release amounts further decrease when coexisting with Mg2+-ATP and the encapsulated actomyosin, which indicates the release regulation by actomyosin. The present study suggests that the ATPase-coupled sliding motion of the myosin-F-actin filaments modifies the pore size of the polymer networks in the PIC capsule membranes.

Structure, substrate recognition and reactivity of Leishmania major mevalonate kinase

BackgroundIsoprenoid precursor synthesis via the mevalonate route in humans and pathogenic trypanosomatids is an important metabolic pathway. There is however, only limited information available on the structure and reactivity of the component enzymes in trypanosomatids. Since isoprenoid biosynthesis is essential for trypanosomatid viability and may provide new targets for therapeutic intervention it is important to characterize the pathway components.ResultsPutative mevalonate kinase encoding genes from Leishmania major (LmMK) and Trypanosoma brucei (TbMK) have been cloned, over-expressed in and proteins isolated from procyclic-form T. brucei. A highly sensitive radioactive assay was developed and shows ATP-dependent phosphorylation of mevalonate. Apo and (R)-mevalonate bound crystal structures of LmMK, from a bacterial expression system, have been determined to high resolution providing, for the first time, information concerning binding of mevalonate to an MK. The mevalonate binds in a deep cavity lined by highly conserved residues. His25 is key for binding and for discrimination of (R)- over (S)-mevalonate, with the main chain amide interacting with the C3 hydroxyl group of (R)-mevalonate, and the side chain contributing, together with Val202 and Thr283, to the construction of a hydrophobic binding site for the C3 methyl substituent. The C5 hydroxyl, where phosphorylation occurs, points towards catalytic residues, Lys18 and Asp155. The activity of LmMK was significantly reduced compared to MK from other species and we were unable to obtain ATP-binding data. Comparisons with the rat MK:ATP complex were used to investigate how this substrate might bind. In LmMK, helix α2 and the preceding polypeptide adopt a conformation, not seen in related kinase structures, impeding access to the nucleotide triphosphate binding site suggesting that a conformational rearrangement is required to allow ATP binding.ConclusionOur new structural information, consistent with data on homologous enzymes allows a detailed description of how mevalonate is recognized and positioned for catalysis in MK. The mevalonate-binding site is highly conserved yet the ATP-binding site is structurally distinct in LmMK. We are unable to provide a definitive explanation for the low activity of recombinant protein isolated from a bacterial expression system compared to material isolated from procyclic-form Trypanosoma brucei.

Crystal Structure of Tryptophanyl-tRNA Synthetase Complexed with Adenosine-5′ Tetraphosphate: Evidence for Distributed Use of Catalytic Binding Energy in Amino Acid Activation by Class I Aminoacyl-tRNA Synthetases

Tryptophanyl-tRNA synthetase (TrpRS) is a functionally dimeric ligase, which specifically couples hydrolysis of ATP to AMP and pyrophosphate to the formation of an ester bond between tryptophan and the cognate tRNA. TrpRS from Bacillus stearothermophilus binds the ATP analogue, adenosine-5′ tetraphosphate (AQP) competitively with ATP during pyrophosphate exchange. Estimates of binding affinity from this competitive inhibition and from isothermal titration calorimetry show that AQP binds 200 times more tightly than ATP both under conditions of induced-fit, where binding is coupled to an unfavorable conformational change, and under exchange conditions, where there is no conformational change. These binding data provide an indirect experimental measurement of +3.0 kcal/mol for the conformational free energy change associated with induced-fit assembly of the active site. Thermodynamic parameters derived from the calorimetry reveal very modest enthalpic changes, consistent with binding driven largely by a favorable entropy change. The 2.5 Å structure of the TrpRS:AQP complex, determined de novo by X-ray crystallography, resembles that of the previously described, pre-transition state TrpRS:ATP complexes. The anticodon-binding domain untwists relative to the Rossmann-fold domain by 20% of the way toward the orientation observed for the Products complex. An unexpected tetraphosphate conformation allows the γ and δd phosphate groups to occupy positions equivalent to those occupied by the β and γ phosphates of ATP. The β-phosphate effects a 1.11 Å extension that relocates the α-phosphate toward the tryptophan carboxylate while the PPi mimic moves deeper into the KMSKS loop. This configuration improves interactions between enzyme and nucleotide significantly and uniformly in the adenosine and PPi binding subsites. A new hydrogen bond forms between S194 from the class I KMSKS signature sequence and the PPi mimic. These complementary thermodynamic and structural data are all consistent with the conclusion that the tetraphosphate mimics a transition-state in which the KMSKS loop develops increasingly tight bonds to the PPi leaving group, weakening linkage to the Pα as it is relocated by an energetically favorable domain movement. Consistent with extensive mutational data on Tyrosyl-tRNA synthetase, this aspect of the mechanism develops high transition-state affinity for the adenosine and pyrophosphate moieties, which move significantly, relative to one another, during the catalytic step.

Structures of the Ca 2+–ATPase complexes with ATP, AMPPCP and AMPPNP. An FTIR study

We studied binding of ATP and of the ATP analogs adenosine 5′-(β,γ-methylene)triphosphate (AMPCP) and β,γ-imidoadenosine 5′-triphosphate (AMPPNP) to the Ca 2+–ATPase of the sarcoplasmic reticulum membrane (SERCA1a) with time-resolved infrared spectroscopy. In our experiments, ATP reacted with ATPase which had AMPPCP or AMPPNP bound. These experiments monitored exchange of ATP analog by ATP and phosphorylation to the first phosphoenzyme intermediate Ca 2E1P. These reactions were triggered by the release of ATP from caged ATP. Only small differences in infrared absorption were observed between the ATP complex and the complexes with AMPPCP and AMPPNP indicating that overall the interactions between nucleotide and ATPase are similar and that all complexes adopt a closed conformation. The spectral differences between ATP and AMPPCP complex were more pronounced at high Ca 2+ concentration (10 mM). They are likely due to a different position of the γ-phosphate which affects the β-sheet in the P domain.

Role of Divalent Metal Cations in ATP Hydrolysis Catalyzed by the Hepatitis C Virus NS3 Helicase: Magnesium Provides a Bridge for ATP to Fuel Unwinding

This study investigates the role of magnesium ions in coupling ATP hydrolysis to the nucleic acid unwinding catalyzed by the NS3 protein encoded by the hepatitis C virus (HCV). Analyses of steady-state ATP hydrolysis rates at various RNA and magnesium concentrations were used to determine values for the 15 dissociation constants describing the formation of a productive enzyme–metal–ATP–RNA complex and the four rate constants describing hydrolysis of ATP by the possible enzyme–ATP complexes. These values coupled with direct binding studies, specificity studies and analyses of site-directed mutants reveal only one ATP binding site on HCV helicase centered on the catalytic base Glu291. An adjacent residue, Asp290, binds a magnesium ion that forms a bridge to ATP, reorienting the nucleotide in the active site. RNA stimulates hydrolysis while decreasing the affinity of the enzyme for ATP, magnesium, and MgATP. The binding scheme described here explains the unusual regulation of the enzyme by ATP that has been reported previously. Binding of either free magnesium or free ATP to HCV helicase competes with MgATP, the true fuel for helicase movements, and leads to slower hydrolysis and nucleic acid unwinding.

Molecular Dynamics Simulations Show That Bound Mg2+ Contributes to Amino Acid and Aminoacyl Adenylate Binding Specificity in Aspartyl-tRNA Synthetase through Long Range Electrostatic Interactions

Molecular recognition between the aminoacyl-tRNA synthetase enzymes and their cognate amino acid ligands is essential for the faithful translation of the genetic code. In aspartyl-tRNA synthetase (AspRS), the co-substrate ATP binds preferentially with three associated Mg2+ cations in an unusual, bent geometry. The Mg2+ cations play a structural role and are thought to also participate catalytically in the enzyme reaction. Co-binding of the ATP x Mg3(2+) complex was shown recently to increase the Asp/Asn binding free energy difference, indicating that amino acid discrimination is substrate-assisted. Here, we used molecular dynamics free energy simulations and continuum electrostatic calculations to resolve two related questions. First, we showed that if one of the Mg2+ cations is removed, the Asp/Asn binding specificity is strongly reduced. Second, we computed the relative stabilities of the three-cation complex and the 2-cation complexes. We found that the 3-cation complex is overwhelmingly favored at ordinary magnesium concentrations, so that the protein is protected against the 2-cation state. In the homologous LysRS, the 3-cation complex was also strongly favored, but the third cation did not affect Lys binding. In tRNA-bound AspRS, the single remaining Mg2+ cation strongly favored the Asp-adenylate substrate relative to Asn-adenylate. Thus, in addition to their structural and catalytic roles, the Mg2+ cations contribute to specificity in AspRS through long range electrostatic interactions with the Asp side chain in both the pre- and post-adenylation states.

Evaluation of health risks caused by radio frequency accelerated carcinogenesis: the importance of processes driven by the calcium ion signal

The acceleration of carcinogenesis, which was induced either by radio frequency radiation from a cellular telephone or by the ferric-ATP complex, was similar in a mouse strain characterized by age-determined carcinogenesis of lymphoid tissues. Organ hypertrophy, the presence of lymphoid blood and ascites, the development of solid tumours, and mortality were very different to those found in control animals. These results emphasize the role of calcium ion signal influx in the activation of oncogenes and the failure of thymus-determined immune defences.

Nucleotide specificity of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase : Kinetics, fluorescence spectroscopy, and molecular simulation studies

Phosphoenolpyruvate carboxykinases, depending on the enzyme origin, preferentially use adenine or guanine nucleotides as substrates. In this work, analyses of the substrate specificity of the Saccharomyces cerevisiae ATP-dependent enzyme have been carried out. Kinetics studies gave relative values of k cat/ K m for the nucleoside triphosphate complexes in the order ATP ≫ GTP > ITP > UTP > CTP. For the nucleoside diphosphate complexes the order is ADP ≫ GDP > IDP ≅ UDP > CDP. This shows that the enzyme has a strong preference for ADP (or ATP) over other nucleotides, being this preference about an order of magnitude higher for the diphosphorylated than for the triphosphorylated nucleosides. The calculated binding free energies (kcal mol −1) at 25 °C are 7.39 and 6.51 for ATP and ADP, respectively. These values decrease with the nucleotide structure in the same order than the kinetic specificity. The binding energy for any triphosphorylated nucleoside is more favourable than for the corresponding diphosphorylated compound, showing the relevance of the P γ for nucleotide binding. Homology models of the adenine and guanine nucleotides in complex with the enzyme show that the base adopts a similar conformation in the diphosphorylated nucleosides while in the triphosphorylated nucleosides the sugar-base torsion angle is 61° for ATP and −53° for GTP. Differences are also noted in the distance between P β and Mn 2+ at site 1. This distance is almost the same in the ATP, GTP, and UTP complexes, however in the ADP, GDP and UDP complexes it is 2.9, 5.1, and 7 Å, respectively. Experimental data obtained with a Thr463Ala mutant enzyme agree with molecular simulation predictions. The results here presented are discussed in terms of the proposed interactions of the nucleotides with the protein.

Crystal Structure of Lipoate-Protein Ligase A Bound with the Activated Intermediate: INSIGHTS INTO INTERACTION WITH LIPOYL DOMAINS

Lipoic acid is the covalently attached cofactor of several multi-component enzyme complexes that catalyze key metabolic reactions. Attachment of lipoic acid to the lipoyl-dependent enzymes is catalyzed by lipoate-protein ligases (LPLs). In Escherichia coli, two distinct enzymes lipoate-protein ligase A (LplA) and lipB-encoded lipoyltransferase (LipB) catalyze independent pathways for lipoylation of the target proteins. The reaction catalyzed by LplA occurs in two steps. First, LplA activates exogenously supplied lipoic acid at the expense of ATP to lipoyl-AMP. Next, it transfers the enzyme-bound lipoyl-AMP to the epsilon-amino group of a specific lysine residue of the lipoyl domain to give an amide linkage. To gain insight into the mechanism of action by LplA, we have determined the crystal structure of Thermoplasma acidophilum LplA in three forms: (i) the apo form; (ii) the ATP complex; and (iii) the lipoyl-AMP complex. The overall fold of LplA bears some resemblance to that of the biotinyl protein ligase module of the E. coli biotin holoenzyme synthetase/bio repressor (BirA). Lipoyl-AMP is bound deeply in the bifurcated pocket of LplA and adopts a U-shaped conformation. Only the phosphate group and part of the ribose sugar of lipoyl-AMP are accessible from the bulk solvent through a tunnel-like passage, whereas the rest of the activated intermediate is completely buried inside the active site pocket. This first view of the activated intermediate bound to LplA allowed us to propose a model of the complexes between Ta LplA and lipoyl domains, thus shedding light on the target protein/lysine residue specificity of LplA.

A Family Portrait of the RIO Kinases

The RIO family of atypical serine protein kinases has been first characterized only recently. It consists of enzymes that contain a unique domain with a characteristic kinase sequence motif and usually some additional domains. At least two RIO proteins, Rio1 and Rio2, are present in organisms varying from Archaea to humans, with a third Rio3 subfamily present only in multicellular eukaryotes. Yeast Rio1 and Rio2 proteins have been implicated in the processing of 20 S pre-rRNA and are necessary for survival of the cells. Crystal structures of Archaeoglobus fulgidus Rio1 and Rio2 have shown that whereas the overall fold of these enzymes resembles typical protein kinases, some of the structural domains, particularly those involved in peptide substrate binding, are not present. The mode of binding of nucleotides also differs from that found in typical protein kinases. Although it has been shown that both Rio1 and Rio2 have the enzymatic activity of kinases and are capable of autophosphorylation, the biological substrates of RIO proteins and their full biological role still remain to be discovered.

Activation of Human Meiosis-specific Recombinase Dmc1 by Ca2+

Rad51 and its meiotic homolog Dmc1 are key proteins of homologous recombination in eukaryotes. These proteins form nucleoprotein complexes on single-stranded DNA that promote a search for homology and that perform DNA strand exchange, the two essential steps of genetic recombination. Previously, we demonstrated that Ca2+ greatly stimulates the DNA strand exchange activity of human (h) Rad51 protein (Bugreev, D. V., and Mazin, A. V. (2004) Proc. Natl. Acad. Sci. U. S. A. 101, 9988-9993). Here, we show that the DNA strand exchange activity of hDmc1 protein is also stimulated by Ca2+. However, the mechanism of stimulation of hDmc1 protein appears to be different from that of hRad51 protein. In the case of hRad51 protein, Ca2+ acts primarily by inhibiting its ATPase activity, thereby preventing self-conversion into an inactive ADP-bound complex. In contrast, we demonstrate that hDmc1 protein does not self-convert into a stable ADP-bound complex. The results indicate that activation of hDmc1 is mediated through conformational changes induced by free Ca2+ ion binding to a protein site that is distinct from the Mg2+.ATP-binding center. These conformational changes are manifested by formation of more stable filamentous hDmc1.single-stranded DNA complexes. Our results demonstrate a universal role of Ca2+ in stimulation of mammalian DNA strand exchange proteins and reveal diversity in the mechanisms of this stimulation.

Role of T-loop Phosphorylation in PDK1 Activation, Stability, and Substrate Binding

3-Phosphoinositide-dependent protein kinase-1 (PDK1) phosphorylates the T-loop of several AGC (cAMP-dependent, cGMP-dependent, protein kinase C) family protein kinases, resulting in their activation. Previous structural studies have revealed that the alpha C-helix, located in the small lobe of the kinase domain of PDK1, is a key regulatory element, as it links a substrate interacting site termed the hydrophobic motif (HM) pocket with the phosphorylated Ser-241 in the T-loop. In this study we have demonstrated by mutational analysis that interactions between the phosphorylated Ser-241 and the alpha C-helix are not required for PDK1 activity or substrate binding through the HM-pocket but are necessary for PDK1 to be activated or stabilized by a peptide that binds to this site. The structure of an inactive T-loop mutant of PDK1, in which Ser-241 is changed to Ala, was also determined. This structure, together with surface plasmon resonance binding studies, demonstrates that the PDK1(S241A)-inactive mutant possesses an intact HM-pocket as well as an ordered alpha C-helix. These findings reveal that the integrity of the alpha C-helix and HM-pocket in PDK1 is not regulated by T-loop phosphorylation.

Probing the binding of the coumarin drugs using peptide fragments of DNA gyrase B protein

Bacterial DNA gyrase, has been identified as the target of several antibacterial agents, including the coumarin drugs. The coumarins inhibit the gyrase action by competitive binding to the ATP-binding site of DNA gyrase B (GyrB) protein. The high in vitro inhibitory potency of coumarins against DNA gyrase reactions has raised interest in studies on coumarin-gyrase interactions. In this context, a series of low-molecular weight peptides, including the coumarin resistance-determining region of subunit B of Escherichia coli gyrase, has been designed and synthesized. The first peptide model was built using the natural fragment 131-146 of GyrB and was able to bind to novobiocin (K(a) = 1.8 +/- 0.2 x 10(5)/m) and ATP (K(a) = 1.9 +/- 0.4 x 10(3)/m). To build the other sequences, changes in the Arg(136) residue were introduced so that the binding to the drug was progressively reduced with the hydrophobicity of this residue (K(a) = 1.3 +/- 0.1 x 10(5)/m and 1.0 +/- 0.2 x 10(5)/m for Ser and His, respectively). No binding was observed for the change Arg(136) to Leu. In contrast, the binding to ATP was not altered, independently of the changes promoted. On the contrary, for peptide-coumarin and peptide-ATP complexes, Mg(2+) appears to modulate the binding process. Our results demonstrate the crucial role of Arg(136) residue for the stability of coumarin-gyrase complex as well as suggest a different binding site for ATP and in both cases the interactions are mediated by magnesium ions.

The catalytic mechanism of glutamyl-tRNA synthetase of Escherichia coli. A steady-state kinetic investigation.

The sequence of substrate binding and of end-product dissociation at the steady state of the catalytic process of tRNAGlu aminoacylation by glutamyl-tRNA synthetase from Escherichia coli has been investigated using bisubstrate kinetics, dead-end and end-product inhibition studies. The nature of the kinetic patterns indicates that ATP and tRNAGlu bind randomly to the free enzyme, whereas glutamate binds only to the ternary enzyme . tRNAGlu . ATP complex. Binding of ATP to the enzyme hinders that of tRNAGlu and vice versa. After interconversion of the quaternary enzyme . substrates complex the end-products dissociate in the following order: PPi first, AMP second and Glu-tRNA last. In addition to its role as substrate and as effector with ATP for the binding of glutamate, tRNAGlu promotes the catalytically active enzyme state. Whereas at saturating tRNAGlu concentration the catalysis is rate-determining, this conformational change can be rate-determining at low tRNAGlu concentrations. The results are discussed in the light of the two-step aminoacylation pathway catalyzed by this synthetase.

Analysis of ATP Binding to CheA Containing Tryptophan Substitutions near the Active Site

Signal transduction in the chemotaxis system of Escherichia coli involves an autophosphorylating protein histidine kinase, CheA. At the active site of CheA, phenylalanine residues 455 and 459 occupy positions near the ATP-binding pocket, immediately adjacent to one of the hinge regions of a loop that undergoes an ATP-induced conformational change ("lid closure") that has been characterized previously in X-ray crystal structures [Bilwes et al. (2001) Nat. Struct. Biol. 8, 353-360]. We generated versions of CheA carrying F455W and F459W replacements and investigated whether the fluorescence properties of the introduced tryptophan side chains were affected by nucleotide binding in a manner that would provide a signal for investigating the dynamics of active site events, such as ATP binding and lid closure. Our results indicate that CheA(F455W) is useful in this regard, but CheA(F459W) is not. CheA(F455W) retained full catalytic activity and exhibited easily monitored fluorescence changes upon binding nucleotide: we observed a 25-30% decrease in CheA(F455W) fluorescence emission intensity at 330 nm upon binding ATP in the absence of Mg(2+); in the presence of Mg(2+), the emission spectrum of the CheA(F455W):ATP complex was red-shifted by 5 nm and exhibited an increased intensity (approximately 20% higher at 345 nm relative to that of uncomplexed CheA(F455W)). Different fluorescence changes were observed when two ATP analogues (ADPNP and ADPCP) were used instead of ATP and when Mn(2+) or Ca(2+) was used in place of Mg(2+). We exploited the fluorescence changes induced by Mg(2+)-ATP to explore the kinetics and mechanism of nucleotide binding by CheA(F455W). In the absence of Mg(2+), binding appears to involve a simple one-step equilibrium (k(assn) = 0.7 microM(-1) s(-1) and k(dissn) = 270 s(-1) at 4 degrees C). In the presence of Mg(2+), the binding mechanism involves at least two steps: (i) rapid, relatively weak binding followed by (ii) a rapid, reversible step (k(forward) = 300 s(-1) and k(reverse) =15 s(-1) at 4 degrees C) that enhanced the overall affinity of the complex and generated an increase in W455 fluorescence. This second step could reflect a conformational change at the CheA active site, such as lid closure. These results provide the first insight into the dynamics of nucleotide binding and substrate-induced conformational changes at the active site of a protein histidine kinase.

Structures of the SUMO E1 provide mechanistic insights into SUMO activation and E2 recruitment to E1

E1 enzymes facilitate conjugation of ubiquitin and ubiquitin-like proteins through adenylation, thioester transfer within E1, and thioester transfer from E1 to E2 conjugating proteins. Structures of human heterodimeric Sae1/Sae2-Mg.ATP and Sae1/Sae2-SUMO-1-Mg.ATP complexes were determined at 2.2 and 2.75 A resolution, respectively. Despite the presence of Mg.ATP, the Sae1/Sae2-SUMO-1-Mg.ATP structure reveals a substrate complex insomuch as the SUMO C-terminus remains unmodified within the adenylation site and 35 A from the catalytic cysteine, suggesting that additional changes within the adenylation site may be required to facilitate chemistry prior to adenylation and thioester transfer. A mechanism for E2 recruitment to E1 is suggested by biochemical and genetic data, each of which supports a direct role for the E1 C-terminal ubiquitin-like domain for E2 recruitment during conjugation.