Kinetic mechanism of nucleotide cofactor binding to Escherichia coli replicative helicase DnaB protein. stopped-flow kinetic studies using fluorescent, ribose-, and base-modified nucleotide analogues

The kinetic mechanism of binding nucleotide cofactors to the Escherichia coli primary replicative helicase DnaB protein has been studied, using the fluorescence stopped-flow technique. The experiments have been performed with fluorescent ATP and ADP analogues bearing the modification on the ribose, MANT-AMP-PNP and MANT-ADP, and on the base, epsilonAMP-PNP and epsilonADP. Association of the DnaB helicase with nucleotide cofactors is characterized by four relaxation times that indicate that the binding occurs by a minimum of four-steps. The simplest mechanism which can describe the data is a four-step sequential process where the bimolecular binding step is followed by three isomerization steps. This mechanism is described by the following equation: [equation in text]. The binding mechanism is independent of the location of the nucleotide cofactor modification and is an intrinsic property of the DnaB helicase-nucleotide system. Quantitative amplitude analyses, using the matrix projection operator technique, allowed us to determine specific fluorescence changes accompanying the formation of all intermediates relative to the fluorescence of the free nucleotide. It shows that the major conformational change of the DnaB helicase-nucleotide complex occurs in the formation of the (H-N)(1). Moreover, the value of the bimolecular rate constant, k(1), is 3-4 orders of magnitude lower than the value expected for the diffusion-controlled reaction. These results indicate that the determined first step includes formation of the collision and an additional transition of the enzyme-nucleotide complex. The obtained results provide evidence of profoundly different conformational states of the ribose and base regions of the nucleotide-binding site in different intermediates. The sequential nature of the mechanism of the nucleotide binding to the DnaB helicase indicates the lack of the existence of a kinetically significant conformational equilibrium of the helicase protomer and the DnaB hexamer prior to the binding. The significance of these results for the functioning of the DnaB helicase is discussed.     

Global conformation of the Escherichia coli replication factor DnaC protein in absence and presence of nucleotide cofactors

Global conformational and oligomeric states of the Escherichia coli replicative factor DnaC protein in the absence and presence of magnesium and nucleotide cofactors, ATP and ADP, and their fluorescent analogues, MANT-ATP and MANT-ADP, have been examined using analytical sedimentation velocity and time-dependent fluorescence anisotropy techniques. In solution, the DnaC protein exists exclusively as a monomer over a large protein concentration range. The value of s(degrees) (20, w)= 2.45 +/- 0.07 S indicates that the protein molecule has an elongated shape. When modeled as a prolate ellipsoid of revolution, the hydrated DnaC protein has an axial ratio of 4.0 +/- 0.6 with long axis a = 112 A and the short axis b = 28 A, respectively. The presence of magnesium or nucleotide cofactors, ATP or ADP, does not affect the global conformation of the protein and its monomeric state. These data indicate that recently found cooperative interactions between the DnaC molecules, in the complex with the DnaB helicase, are induced by the binding to the helicase, i.e., they are not the intrinsic property of the DnaC protein. Fluorescence anisotropy decays of the DnaC-MANT-ATP and DnaC-MANT-ADP complexes indicate that the protein has a rigid global structure on the nanosecond time scale, little affected by the nucleotide cofactors. Nevertheless, the complex with ATP has a more flexible structure, while the complex with ADP is more rigid, with the protein molecule assuming a more elongated shape. Magnesium exerts control only on the complex with the ATP analogue. In the absence of magnesium, the ATP analogue is firmly held in the binding site. In the presence of Mg(2+), this fixed location is released and the analogue is allowed to assume a flexible conformational state. The significance of the results for the functioning of the DnaC protein is discussed.     

Interactions of nucleotide cofactors with the Escherichia coli replication factor DnaC protein

Quantitative analyses of the interactions of nucleotide cofactors with the Escherichia coli replicative factor DnaC protein have been performed using thermodynamically rigorous fluorescence titration techniques. This approach allowed us to obtain stoichiometries of the formed complexes and interaction parameters, without any assumptions about the relationship between the observed signal and the degree of binding. The stoichiometry of the DnaC-nucleotide complex has been determined in direct binding experiments with fluorescent nucleotide analogues, MANT-ATP and MANT-ADP. The stoichiometry of the DnaC complexes with unmodified ATP and ADP has been determined using the macromolecular competition titration method (MCT). The obtained results established that at saturation the DnaC protein binds a single nucleotide molecule per protein monomer. Analyses of the binding of fluorescent analogues and unmodified nucleotides to the DnaC protein show that ATP and ADP have the same affinities for the nucleotide-binding site, albeit the corresponding complexes have different structures, specifically affected by the presence of magnesium cations in solution. Although the presence of the gamma-phosphate does not affect the affinity, the structure of the triphosphate group is critical. While the affinity of ATP-gamma-S is the same as the affinity of ATP, the affinities of AMP-PNP and AMP-PCP are approximately 2 and approximately 4 orders lower than that of ATP, respectively. Moreover, the ribose plays a significant role in forming a stable complex. The binding constants of dATP and dADP are approximately 2 orders of magnitude lower than those for ribose nucleotides. The nucleotide-binding site of the DnaC protein is highly base specific. The intrinsic affinity of adenosine triphosphates and diphosphates is at least 3-4 orders of magnitude higher than for any of the other examined nucleotides. The obtained data indicate that the recognition mechanism of the nucleotide by the structural elements of the binding site is complex with the base providing the specificity and the ribose, as well as the second phosphate group contributing to the affinity. The significance of the results for the functioning of the DnaC protein is discussed.     

Binding of six nucleotide cofactors to the hexameric helicase RepA protein of plasmid RSF1010. 2. Base specificity, nucleotide structure, magnesium, and salt effect on the cooperative binding of the cofactors

Interactions of the RepA hexameric helicase with nucleotide cofactors have been examined using nucleotide analogues, TNP-ADP and TNP-ATP, and unmodified nucleotides. Thermodynamic parameters for the interactions of modified and unmodified nucleotides have been obtained using quantitative fluorescence titration and competition titration methods. The intrinsic binding constant of ATP is by a factor of approximately 10 and approximately 1000 higher than the value observed for ADP and PO(4)(-). The data suggest that helicase acquires free-energy transducing capabilities when associated with the ssDNA, thus, forming a "holoenzyme". ATP binding is characterized by significantly stronger negative cooperativity than ADP. The cooperative interactions are predominantly induced through the specific interactions of the gamma phosphate and the ribose with the protein. The salt effect on cofactor binding indicates a very different nature of the intrinsic and cooperative interactions. Surprisingly, binding of Mg(2+), to both the cofactor and helicase, predominantly controls the ADP-RepA interactions. Mg(2+) cations seem to play a role in affecting the distribution of high and low ssDNA-affinity states, through the strong effect on the diphosphate versus triphosphate binding. The data indicate that Mg(2+) has a dual function in nucleotide-helicase interactions. At low [Mg(2+)], NTP binds stronger than NDP and the enzyme is predominantly in the high ssDNA-affinity state. At higher [Mg(2+)], NTP binds weaker than NDP and the helicase subunits can exist in alternating low- and high-affinity states that facilitate the efficient dsDNA unwinding. The RepA helicase shows a preference toward purine nucleotides. The cooperative interactions are independent of the type of the base.     

The Escherichia coli PriA helicase has two nucleotide-binding sites differing dramatically in their affinities for nucleotide cofactors. 1. Intrinsic affinities, cooperativities, and base specificity of nucleotide cofactor binding

Interactions of the Escherichia coli PriA helicase with nucleotide cofactors have been studied using the fluorescence titration and analytical ultracentrifugation techniques. Binding of unmodified cofactors was characterized by the fluorescence competition titration method. The obtained data establish that at saturation the PriA helicase binds two nucleotide molecules per protein monomer. This result corroborates with the primary structure of the protein, which contains sequence motifs implicated as putative nucleotide-binding sites. The intrinsic affinities of the binding sites differ by 2-4 orders of magnitude. Thus, the PriA helicase has a strong and a weak nucleotide-binding site. The binding sites differ dramatically in their properties. The strong site is highly specific for adenosine cofactors, while the weak site shows very modest base specificity. The affinities of the strong and weak binding sites for ATP are lower than the affinities for ADP, although both sites have similar affinity for the inorganic phosphate group. Unlike the weak site, the affinity of the strong site profoundly depends on the structure of the phosphate group of the ATP cofactor. Binding of unmodified nucleotides indicates the presence of positive cooperative interactions between bound cofactors (i.e., the existence of communication between the two sites). Magnesium cations are specifically involved in controlling the cofactor affinity for the strong site, while the affinity of the weak site is predominantly determined by interactions between the phosphate group and ribose regions of the cofactor and the protein matrix. The significance of these results for the activities of the PriA helicase is discussed.     

The nucleotide-binding site of the Escherichia coli DnaC protein

The structure of the nucleotide-binding site of the Escherichia coli replication factor DnaC protein and the effect of the nucleotide cofactor on the protein structure have been examined using ultraviolet, steady-state, and time-dependent fluorescence spectroscopy. Emission spectra and quenching studies of the fluorescent nucleotide analogs, 3′-O-(N-methylantraniloyl)-5′-triphosphate (MANT-ATP) and 3′-O-(N-methylantraniloyl)-5′-diphosphate (MANT-ADP), bound to the DnaC protein indicate that the nucleotide-binding site forms a hydrophobic cleft on the surface of the protein. Fluorescence decays of free and bound MANT-ATP and MANT-ADP indicate that cofactors exist in two different conformations both, free and bound to the protein. However, the two conformations of the bound nucleotides differ in their solvent accessibilities. Moreover, there are significant differences in the solvent accessibility between ATP and ADP complexes. Specific binding of magnesium to the protein controls the structure of the binding site, particularly, in the case of the ATP complex, leading to additional opening of the binding site cleft. Both tyrosine and tryptophan residues are located on the surface of the protein. The tryptophans are clustered at a large distance from the nucleotide-binding site. However, in spite of a large spatial separation, binding of both cofactors induces significant and different changes in the structure of the environment of tryptophans, indicating long-range structural effects through the DnaC molecule. Moreover, only ATP induces changes in the distribution of the tyrosine residues on the surface of the protein. The data reveal that the nucleotide-DnaC protein complex is a sophisticated allosteric system, responding differently to the ATP and ADP binding.     

Quantitative analysis of binding of single-stranded DNA by Escherichia coli DnaB helicase and the DnaB x DnaC complex

DnaB helicase is responsible for unwinding duplex DNA during chromosomal DNA replication and is an essential component of the DNA replication apparatus in Escherichia coli. We have analyzed the mechanism of binding of single-stranded DNA (ssDNA) by the DnaB x DnaC complex and DnaB helicase. Binding of ssDNA to DnaB helicase was significantly modulated by nucleotide cofactors, and the modulation was distinctly different for its complex with DnaC. DnaB helicase bound ssDNA with a high affinity [Kd = (5.09 +/- 0.32) x 10(-8) M] only in the presence of ATPgammaS, a nonhydrolyzable analogue of ATP, but not other nucleotides. The binding was sensitive to ionic strength but not to changes in temperature in the range of 30-37 degrees C. On the other hand, ssDNA binding in the presence of ADP was weaker than that observed with ATPgammaS, and the binding was insensitive to ionic strength. DnaC protein hexamerizes to form a 1:1 complex with the DnaB hexamer and loads it onto the ssDNA by forming a DnaB6 x DnaC6 dodecameric complex. Our results demonstrate that the DnaB6 x DnaC6 complex bound ssDNA with a high affinity [Kd = (6.26 +/- 0.65) x 10(-8) M] in the presence of ATP, unlike the DnaB hexamer. In the presence of ATPgammaS or ADP, binding of ssDNA by the DnaB6 x DnaC6 complex was a lower-affinity process. In summary, our results suggest that in the presence of ATP in vivo, the DnaB6 x DnaC6 complex should be more efficient in binding DNA as well as in loading DnaB onto the ssDNA than DnaB helicase itself.     

Equilibrium and kinetic analysis of nucleotide binding to the DEAD-box RNA helicase DbpA

The Escherichia coli DEAD-box protein A (DbpA) is an RNA helicase that utilizes the energy from ATP binding and hydrolysis to facilitate structural rearrangements of rRNA. We have used the fluorescent nucleotide analogues, mantADP and mantATP, to measure the equilibrium binding affinity and kinetic mechanism of nucleotide binding to DbpA in the absence of RNA. Binding generates an enhancement in mant-nucleotide fluorescence and a corresponding reduction in intrinsic DbpA fluorescence, consistent with fluorescence resonance energy transfer (FRET) from DbpA tryptophan(s) to bound nucleotides. Fluorescent modification does not significantly interfere with the affinities and kinetics of nucleotide binding. Different energy transfer efficiencies between DbpA-mantATP and DbpA-mantADP complexes suggest that DbpA adopts nucleotide-dependent conformations. ADP binds (K(d) approximately 50 microM at 22 degrees C) 4-7 times more tightly than ATP (K(d) approximately 400 microM at 22 degrees C). Both nucleotides bind with relatively temperature-independent association rate constants (approximately 1-3 microM(-1) s(-1)) that are much lower than predicted for a diffusion-limited reaction. Differences in the binding affinities are dictated primarily by the dissociation rate constants. ADP binding occurs with a positive change in the heat capacity, presumably reflecting a nucleotide-induced conformational rearrangement of DbpA. At low temperatures (<22 degrees C), the binding free energies are dominated by favorable enthalpic and unfavorable entropic contributions. At physiological temperatures (>22 degrees C), ADP binding occurs with positive entropy changes. We favor a mechanism in which ADP binding increases the conformational flexibility and dynamics of DbpA.     

Probing the nucleotide binding domain of the osmoregulator EnvZ using fluorescent nucleotide derivatives

EnvZ is a histidine protein kinase important for osmoregulation in bacteria. While structural data are available for this enzyme, the nucleotide binding pocket is not well characterized. The ATP binding domain (EnvZB) was expressed, and its ability to bind nucleotide derivatives was assessed using equilbrium and stopped-flow fluorescence spectroscopy. The fluorescence emission of the trinitrophenyl derivatives, TNP-ATP and TNP-ADP, increase upon binding to EnvZB. The fluorescence enhancements were quantitatively abolished in the presence of excess ADP, indicating that the fluorescent probes occupy the nucleotide binding pocket. Both TNP-ATP and TNP-ADP bind to EnvZB with high affinity (K(d) = 2-3 microM). The TNP moiety attached to the ribose ring does not impede access of the fluorescent nucleotide into the binding pocket. The association rate constant for TNP-ADP is 7 microM(-1) s(-1), a value consistent with those for natural nucleotides and the eucaryotic protein kinases. Using competition experiments, it was found that ATP and ADP bind 30- and 150-fold more poorly, respectively, than the corresponding TNP-derivatized forms. Surprisingly, the physiological metal Mg(2+) is not required for ADP binding and only enhances ATP affinity by 3-fold. Although portions of the nucleotide pocket are disordered, the recombinant enzyme is highly stable, unfolding only at temperatures in excess of 70 degrees C. The unusually high affinity of the TNP derivatives compared to the natural nucleotides suggests that hydrophobic substitutions on the ribose ring enforce an altered binding mode that may be exploited for drug design strategies.     

Role of the dimethylbenzimidazole tail in the reaction catalyzed by coenzyme B12-dependent methylmalonyl-CoA mutase

The recent structures of cobalamin-dependent methionine synthase and methylmalonyl-CoA mutase have revealed a striking conformational change that accompanies cofactor binding to these proteins. Alkylcobalamins have octahedral geometry in solution at physiological pH, and the lower axial coordination position is occupied by the nucleotide, dimethylbenzimidazole ribose phosphate, that is attached to one of the pyrrole rings of the corrin macrocycle via an aminopropanol moiety. In contrast, in the active sites of these two B12-dependent enzymes, the nucleotide tail is held in an extended conformation in which the base is far removed from the cobalt in cobalamin. Instead, a histidine residue donated by the protein replaces the displaced intramolecular base. This unexpected mode of cofactor binding in a subgroup of B12-dependent enzymes has raised the question of what role the nucleotide loop plays in cofactor binding and catalysis. To address this question, we have synthesized and characterized two truncated cofactor analogues: adenosylcobinamide and adenosylcobinamide phosphate methyl ester, lacking the nucleotide and nucleoside moieties, respectively. Our studies reveal that the nucleotide tail has a modest effect on the strength of cofactor binding, contributing approximately 1 kcal/mol to binding. In contrast, the nucleotide has a profound influence on organizing the active site for catalysis, as evidenced by the retention of the base-off conformation in the truncated cofactor analogues bound to the mutase and by their inability to support catalysis. Characterization of the kinetics of adenosylcobalamin (AdoCbl) binding by stopped-flow fluorescence spectroscopy reveals a pH-sensitive step that titrates to a pKa of 7.32 +/- 0.19 that is significantly different from the pKa of 3.7 for dimethylbenzimidazole in free AdoCbl. In contrast, the truncated cofactors associate very rapidly with the enzyme at rates that are too fast to measure. Based on these observations, we propose a model in which the base-on to base-off conformational change is slow and is assisted by the enzyme, and is followed by a rapid docking of the cofactor in the active site.     

Conformational dynamics of DnaB helicase upon DNA and nucleotide binding: analysis by intrinsic tryptophan fluorescence quenching

DnaB helicase of E. coli unwinds duplex DNA in the replication fork using the energy of ATP hydrolysis. We have analyzed structural and conformational changes in the DnaB protein in various nucleotides and DNA bound intermediate states by fluorescence quenching analysis of intrinsic fluorescence of native tryptophan (Trp) residues in DnaB. Fluorescence quenching analysis indicated that Trp48 in domain alpha is in a hydrophobic environment and resistant to fluorescence quenchers such as potassium iodide (KI). In domain beta, Trp294 was found to be in a partially hydrophobic environment, whereas Trp456 in domain gamma appeared to be in the least hydrophobic environment. Binding of oligonucleotides to DnaB helicase resulted in a significant attenuation of the fluorescence quenching profile, indicating a change in conformation. ATPgammaS or ATP binding appeared to lead to a conformation in which Trp residues had a higher degree of solvent exposure and fluorescence quenching. However, the most dramatic increase of Trp fluorescence quenching was observed with ADP binding with a possible conformational relaxation. Site-specific Trp --> Cys mutants of DnaB helicase demonstrated that conformational change upon ADP binding could be attributed exclusively to a conformational transition in the alpha domain leading to an increase in the solvent exposure of Trp48. However, formation of DnaB.ATPgammaS.DNA ternary complex led to a conformation with a fluorescence quenching profile similar to that observed with DnaB alone. The DnaB.ADP.DNA ternary complex produced a quenching curve similar to that of DnaB.ADP complex pointing to a change in conformation due to ATP hydrolysis. There are at least four identifiable structural/conformational states of DnaB helicase that are likely important in the helicase activity. The noncatalytic alpha domain in the N-terminus appeared to undergo the most significant conformational changes during nucleotide binding and hydrolysis. This is the first reported elucidation of the putative role of domain alpha, which is essential for DNA helicase action. We have correlated these results with partial structural models of alpha, beta, and gamma domains     

Kinetics of the E. coli replication factor DnaC protein-nucleotide interactions. II. Fluorescence anisotropy and transient,dynamic quenching stopped-flow studies of the reaction intermediates

The nature of the intermediates in the binding of MANT-ATP and MANT-ADP to the E. coli replicative factor DnaC protein (accompanying paper) has been examined using the fluorescence intensity, anisotropy, and transient dynamic quenching stopped-flow techniques. Using molar fluorescence intensities of individual intermediates of the reaction, we derived the Stern-Volmer equation that provides a direct method to quantitatively address the quenching of the fluorescence of a transient intermediate by an external, neutral quencher. The data indicate that in the first intermediate, (C)(1), the solvent has full access to the MANT group. Thus, the nucleotide-binding site is located on the surface of the protein, fully open to the solvent. Moreover, formation of the first intermediate does not affect the structure of the binding site. On the other hand, in the second intermediate, (C)(2), the entire binding site changes its conformation, resulting in diminished access of the solvent to the bound nucleotide. The time course of the fluorescence anisotropy in the reaction provides direct, unique insight into the mobility of bound nucleotides in each intermediate. The analysis is facilitated by the fact that the anisotropy can be expressed as a function of the relative molar intensities and steady-state anisotropies of the individual intermediates. The major decrease of the nucleotide mobility occurs in the formation of the first intermediate and reflects the fact that the MANT group is immobilized to a similar extent as the ribose region of the bound nucleotides. Transition to the second intermediate and closing of the binding site leads to only a moderate, additional decrease of nucleotide mobility. The temperature effect on the studied interactions indicates that the formation of individual intermediates is accompanied by very different enthalpy and entropy changes predominantly generated from the structural changes of the protein. Analysis of the salt effect indicates that the net release of a single ion, observed in equilibrium studies, occurs in the formation of the first intermediate. The lack of any salt effect on the (C)(1) <--> (C)(2) transition indicates that the closing of the binding site does not include a net ion release or uptake. Moreover, prior to the nucleotide binding, the conformational transition of the DnaC protein is exclusively controlled by the nucleotide binding and release.     

Cofactor‐binding sites in proteins of deviating sequence: Comparative analysis and clustering in torsion angle,cavity, and fold space

Small molecules are recognized in protein‐binding pockets through surface‐exposed physicochemical properties. To optimize binding, they have to adopt a conformation corresponding to a local energy minimum within the formed protein–ligand complex. However, their conformational flexibility makes them competent to bind not only to homologous proteins of the same family but also to proteins of remote similarity with respect to the shape of the binding pockets and folding pattern. Considering drug action, such observations can give rise tounexpected and undesired cross reactivity. In this study, datasets of six different cofactors (ADP, ATP, NAD(P)(H), FAD, and acetyl CoA, sharing an adenosine diphosphate moiety as common substructure), observed in multiple crystal structures of protein–cofactor complexes exhibiting sequence identity below 25%, have been analyzed for the conformational properties of the bound ligands, the distribution of physicochemical properties in the accommodating protein‐binding pockets, and the local folding patterns next to the cofactor‐binding site. State‐of‐the‐art clustering techniques have been applied to group the different protein–cofactor complexes in the different spaces. Interestingly, clustering in cavity (Cavbase) and fold space (DALI) reveals virtually the same data structuring. Remarkable relationships can be found among the different spaces. They provide information on how conformations are conserved across the host proteins and which distinct local cavity and fold motifs recognize the different portions of the cofactors. In those cases, where different cofactors are found to be accommodated in a similar fashion to the same fold motifs, only a commonly shared substructure of the cofactors is used for the recognition process. Proteins 2012. © 2011 Wiley Periodicals, Inc.     

In Vitro Reassembly of the Ribose ATP-binding Cassette Transporter Reveals a Distinct Set of Transport Complexes

Bacterial ATP-binding cassette (ABC) importers are primary active transporters that are critical for nutrient uptake. Based on structural and functional studies, ABC importers can be divided into two distinct classes, type I and type II. Type I importers follow a strict alternating access mechanism that is driven by the presence of the substrate. Type II importers accept substrates in a nucleotide-free state, with hydrolysis driving an inward facing conformation. The ribose transporter in Escherichia coli is a tripartite complex consisting of a cytoplasmic ATP-binding cassette protein, RbsA, with fused nucleotide binding domains; a transmembrane domain homodimer, RbsC₂; and a periplasmic substrate binding protein, RbsB. To investigate the transport mechanism of the complex RbsABC₂, we probed intersubunit interactions by varying the presence of the substrate ribose and the hydrolysis cofactors, ATP/ADP and Mg²⁺. We were able to purify a full complex, RbsABC₂, in the presence of stable, transition state mimics (ATP, Mg²⁺, and VO₄); a RbsAC complex in the presence of ADP and Mg²⁺; and a heretofore unobserved RbsBC complex in the absence of cofactors. The presence of excess ribose also destabilized complex formation between RbsB and RbsC. These observations suggest that RbsABC₂ shares functional traits with both type I and type II importers, as well as possessing unique features, and employs a distinct mechanism relative to other ABC transporters.     

H~＋－ATPase单位点水解过程中Fo构象的变化

利用Ｈ＾＋－ＡＴＰ酶复合中的Ｆｏ的色氨酸荧光,观察了复合体中Ｆ１结合ＡＴＰ或ＡＤＰ时,Ｆｏ的荧光猝灭常数的变化结果表明Ｆ１结合ＡＴＰ或ＡＤＰ时Ｆｏ可得到不同的猝来常数,也就是Ｆｏ会产生不同的构象变化。这些结果说明了Ｈ＾＋ＡＴＰ酶合ＡＴＰ合成的过程中Ｆ１与Ｆｏ之间存在着构象之间的通信与传递。     

H~＋－ATPase单位点水解过程中Fo构象的变化

利用Ｈ＋－ＡＴＰ酶复合体（也称ＡＴＰ合成酶）中的Ｆｏ的色氨酸荧光,观察了复合体中Ｆ１结合ＡＴＰ或ＡＤＰ（酶蛋白与底物分子比为１：１）时,Ｆｏ的荧光猝灭常数的变化（用竹红菌乙作为膜区蛋白荧光的猝灭剂）结果表明Ｆ１结合ＡＴＰ或ＡＤＰ时Ｆｏ可得到不同的猝灭常数（Ｋｓｖ）,也就是Ｆｏ会产生不同的构象变化。加入二价金属离子起动ＡＴＰ水解反应结束后：ＡＴＰ＋Ｈ２Ｏ→ＡＤＰ＋Ｐｉ,这时可以在Ｆｏ观察到与ＡＤＰ加Ｍｇ２＋时相同猝灭常数Ｋｓｖ;用荧光强度随时间进程变化的实验可观察到Ｆ１水解过程中导致Ｆｏ构象变化的动力学过程。这些结果说明了Ｈ＋－ＡＴＰ酶复合体ＡＴＰ合成的过程中Ｆ１与Ｆｏ之间存在着构象之间的通信与传递。     

Induced fit on sugar binding activates ribokinase.

The enzyme ribokinase phosphorylates ribose at O5* as the first step in its metabolism. The original X-ray structure of Escherichia coli ribokinase represented the ternary complex including ribose and ADP. Structures are presented here for the apo enzyme, as well as the ribose-bound state and four new ternary complex forms. Combined, the structures suggest that large and small conformational changes play critical roles in the function of this kinase. An initially open apo form can allow entry of the ribose substrate. After ribose binding, the active site lid is observed in a closed conformation, with the sugar trapped underneath. This closure and associated changes in the protein appear to assist ribokinase in recognition of the co-substrate ATP as the next step. Binding of the nucleotide brings about further, less dramatic adjustments in the enzyme structure. Additional small movements are almost certainly required during the phosphoryltransfer reaction. Evidence is presented that some types of movements of the lid are allowed in the ternary complex, which may be critical to the creation and breakdown of the transition state. Similar events are likely to take place during catalysis by other related carbohydrate kinases, including adenosine kinase.     

Nucleotide binding to the chaperonin GroEL: non-cooperative binding of ATP analogs and ADP, and cooperative effect of ATP

Chaperonin-assisted protein folding proceeds through cycles of ATP binding and hydrolysis by GroEL, which undergoes a large structural change by the ATP binding or hydrolysis. One of the main concerns of GroEL is the mechanism of the productive and cooperative structural change of GroEL induced by the nucleotide. We studied the cooperative nature of GroEL by nucleotide titration using isothermal titration calorimetry and fluorescence spectroscopy. Our results indicated that the binding of ADP and ATP analogs to a single ring mutant (SR1), as well as that to GroEL, was non-cooperative. Only ATP induces an apparently cooperative conformational change in both proteins. Furthermore, the fluorescence changes of pyrene-labeled GroEL indicated that GroEL has two kinds of nucleotide binding sites. The fluorescence titration result fits well with a model in which two kinds of binding sites are both non-cooperative and independent of each other. These results suggest that the binding and hydrolysis of ATP may be necessary for the cooperative transition of GroEL.     

Kinetics of allosteric conformational transition of a macromolecule prior to ligand binding

Two fundamentally different mechanisms of ligand binding are commonly encountered in biological kinetics. One mechanism is a sequential multistep reaction in which the bimolecular binding step is followed by first-order steps. The other mechanism includes the conformational transition of the macromolecule, before the ligand binding, followed by the ligand binding process to one of the conformational states. In stopped-flow kinetic studies, the reaction mechanism is established by examining the behavior of relaxation times and amplitudes as a function of the reactant concentrations. A major diagnostic tool for detecting the presence of a conformational equilibrium of the macromolecule, before the ligand binding, is the decreasing value of one of the reciprocal relaxation times with the increasing [ligand]. The sequential mechanism cannot generate this behavior for any of the relaxation times. Such dependence is intuitively understood on the basis of approximate expressions for the relaxation times that can be comprehensively derived, using the characteristic equation of the coefficient matrix and polynomial theory. Generally, however, the used approximations may not be fulfilled. On the other hand, the two kinetic mechanisms can always be distinguished, using the approach based on the combined application of pseudo-first-order conditions, with respect to the ligand and the macromolecule. The two experimental conditions differ profoundly in the extent of the effect of the ligand on the protein conformational equilibrium. In a large excess of the ligand, the conformational equilibrium of the macromolecule, before the ligand binding, is strongly affected by the binding process. However, in a large excess of the macromolecule, ligand binding does not perturb the internal equilibrium of the macromolecule. As a result, the normal mode, affected by the conformational transition, is absent in the observed relaxation process. In the case of a sequential mechanism, the number of relaxation times is not altered by different pseudo-first-order conditions. Thus, the approach provides a strong diagnostic criterion for detecting the presence of the conformational transition of the macromolecule and establishing the correct mechanism. Application of this approach is illustrated for the binding of 3'-O-(N-methylantraniloyl)-5'-diphosphate to the E. coli DnaC protein.     

Kinetic mechanisms of the nucleotide cofactor binding to the strong and weak nucleotide-binding site of the Escherichia coli PriA helicase. 2

Kinetics of the nucleotide binding to the strong (S) and weak (W) nucleotide-binding site of the Escherichia coli PriA helicase have been studied using the fluorescence stopped-flow technique. Experiments were performed with TNP-ADP and TNP-ATP analogues. Binding of the ADP analogue to the strong binding site is a four-step sequential reaction: (PriA)S + D (k1)<-->(k(-1)) + (S)1 (k2)<-->(k(-2)) (S)2 (k3)<-->(k(-3)) (S)3 (k4)<-->(k(-4)) (S)4. Association of TNP-ATP proceeds through an analogous three-step mechanism. The first two steps and intermediates are similar for both cofactors. However, the (S)3 intermediate is dramatically different for ADP and ATP analogues. Its emission is close to the emission of the free TNP-ADP, while it is by a factor of approximately 16 larger than the free TNP-ATP fluorescence. Thus, only the ADP analogue passes through an intermediate where it leaves the hydrophobic cleft of the site. This behavior corroborates with the fact that ADP leaves the ATPase site without undergoing a chemical change. The fast bimolecular step and the sequential mechanism indicate that the site is easily accessible to the cofactor, and it does not undergo an adjustment prior to binding. The subsequent step is also fast and stabilizes the complex. Magnesium profoundly affects the population of intermediates. The data indicate that the dominant (S)2 species is a part of the ATP catalytic cycle. ADP analogue binding to the weak nucleotide-binding site proceeds in a simpler two-step mechanism: (PriA)W + D (k1)<-->(k(-1)) (W)1 (k2)<-->(k(-2)) (W)2 with (W)1 being a dominant intermediate both in the presence and in the absence of Mg2+. The results indicate that the weak site is an allosteric control site in the functioning of the PriA helicase.