Structure and Thermodynamics of Effector Molecule Binding to the Nitrogen Signal Transduction PII Protein GlnZ from Azospirillum brasilense

The trimeric P_II signal transduction proteins regulate the function of a variety of target proteins predominantly involved in nitrogen metabolism. ATP, ADP and 2-oxoglutarate (2-OG) are key effector molecules influencing P_II binding to targets. Studies of P_II proteins have established that the 20-residue T-loop plays a central role in effector sensing and target binding. However, the specific effects of effector binding on T-loop conformation have remained poorly documented. We present eight crystal structures of the Azospirillum brasilense P_II protein GlnZ, six of which are cocrystallized and liganded with ADP or ATP. We find that interaction with the diphosphate moiety of bound ADP constrains the N-terminal part of the T-loop in a characteristic way that is maintained in ADP-promoted complexes with target proteins. In contrast, the interactions with the triphosphate moiety in ATP complexes are much more variable and no single predominant interaction mode is apparent except for the ternary MgATP/2-OG complex. These conclusions can be extended to most investigated P_II proteins of the GlnB/GlnK subfamily. Unlike reported for other P_II proteins, microcalorimetry reveals no cooperativity between the three binding sites of GlnZ trimers for any of the three effectors under carefully controlled experimental conditions.     

A Novel Signal Transduction Protein PII Variant from Synechococcus elongatus PCC 7942 Indicates a Two-Step Process for NAGK-PII Complex Formation

P_II signal transduction proteins are highly conserved in bacteria, archaea and plants and have key functions in coordination of central metabolism by integrating signals from the carbon, nitrogen and energy status of the cell. In the cyanobacterium Synechococcus elongatus PCC 7942, P_II binds ATP and 2-oxoglutarate (2-OG) in a synergistic manner, with the ATP binding sites also accepting ADP. Depending on its effector molecule binding status, P_II (from this cyanobacterium and other oxygenic phototrophs) complexes and regulates the arginine-controlled enzyme of the cyclic ornithine pathway, N-acetyl-l-glutamate kinase (NAGK), to control arginine biosynthesis. To gain deeper insights into the process of P_II binding to NAGK, we searched for P_II variants with altered binding characteristics and found P_II variants I86N and I86T to be able to bind to an NAGK variant (R233A) that was previously shown to be unable to bind wild-type P_II protein. Analysis of interactions between these P_II variants and wild-type NAGK as well as with the NAGK R233A variant suggested that the P_II I86N variant was a superactive NAGK binder. To reveal the structural basis of this property, we solved the crystal structure of the P_II I86N variant at atomic resolution. The large T-loop, which prevails in most receptor interactions of P_II proteins, is present in a tightly bended conformation that mimics the T-loop of S. elongatus P_II after having latched onto NAGK. Moreover, both P_II I86 variants display a specific defect in 2-OG binding, implying a role of residue I86 in 2-OG binding. We propose a two-step model for the mechanism of P_II-NAGK complex formation: in an initiating step, a contact between R233 of NAGK and E85 of P_II initiates the bending of the extended T-loop of P_II, followed by a second step, where a bended T-loop deeply inserts into the NAGK clefts to form the tight complex.     

From PII Signaling to Metabolite Sensing: A Novel 2-Oxoglutarate Sensor That Details PII - NAGK Complex Formation

The widespread P_II signal transduction proteins are known for integrating signals of nitrogen and energy supply and regulating cellular behavior by interacting with a multitude of target proteins. The P_II protein of the cyanobacterium Synechococcus elongatus forms complexes with the controlling enzyme of arginine synthesis, N-acetyl-L-glutamate kinase (NAGK) in a 2-oxoglutarate- and ATP/ADP-dependent manner. Fusing NAGK and P_II proteins to either CFP or YFP yielded a FRET sensor that specifically responded to 2-oxoglutarate. The impact of the fluorescent tags on P_II and NAGK was evaluated by enzyme assays, surface plasmon resonance spectroscopy and isothermal calorimetric experiments. The developed FRET sensor provides real-time data on P_II - NAGK interaction and its modulation by the effector molecules ATP, ADP and 2-oxoglutarate in vitro. Additionally to its utility to monitor 2-oxoglutarate levels, the FRET assay provided novel insights into P_II - NAGK complex formation: (i) It revealed the formation of an encounter-complex between P_II and NAGK, which holds the proteins in proximity even in the presence of inhibitors of complex formation; (ii) It revealed that the P_II T-loop residue Ser49 is neither essential for complex formation with NAGK nor for activation of the enzyme but necessary to form a stable complex and efficiently relieve NAGK from arginine inhibition; (iii) It showed that arginine stabilizes the NAGK hexamer and stimulates P_II - NAGK interaction.     

Structural Basis and Target-specific Modulation of ADP Sensing by the Synechococcus elongatus PII Signaling Protein

P_II signaling proteins comprise one of the most versatile signaling devices in nature and have a highly conserved structure. In cyanobacteria, PipX and N-acetyl-l-glutamate kinase are receptors of P_II signaling, and these interactions are modulated by ADP, ATP, and 2-oxoglutarate. These effector molecules bind interdependently to three anti-cooperative binding sites on the trimeric P_II protein and thereby affect its structure. Here we used the P_II protein from Synechococcus elongatus PCC 7942 to reveal the structural basis of anti-cooperative ADP binding. Furthermore, we clarified the mutual influence of P_II-receptor interaction and sensing of the ATP/ADP ratio. The crystal structures of two forms of trimeric P_II, one with one ADP bound and the other with all three ADP-binding sites occupied, revealed significant differences in the ADP binding mode: at one site (S1) ADP is tightly bound through side-chain and main-chain interactions, whereas at the other two sites (S2 and S3) the ADP molecules are only bound by main-chain interactions. In the presence of the P_II-receptor PipX, the affinity of ADP to the first binding site S1 strongly increases, whereas the affinity for ATP decreases due to PipX favoring the S1 conformation of P_II-ADP. In consequence, the P_II-PipX interaction is highly sensitive to subtle fluctuations in the ATP/ADP ratio. By contrast, the P_II-N-acetyl-l-glutamate kinase interaction, which is negatively affected by ADP, is insensitive to these fluctuations. Modulation of the metabolite-sensing properties of P_II by its receptors allows P_II to differentially perceive signals in a target-specific manner and to perform multitasking signal transduction.     

Uridylylation of Herbaspirillum seropedicae GlnB and GlnK proteins is differentially affected by ATP, ADP and 2-oxoglutarate in vitro

PII are signal-transducing proteins that integrate metabolic signals and transmit this information to a large number of proteins. In proteobacteria, PII are modified by GlnD (uridylyltransferase/uridylyl-removing enzyme) in response to the nitrogen status. The uridylylation/deuridylylation cycle of PII is also regulated by carbon and energy signals such as ATP, ADP and 2-oxoglutarate (2-OG). These molecules bind to PII proteins and alter their tridimensional structure/conformation and activity. In this work, we determined the effects of ATP, ADP and 2-OG levels on the in vitro uridylylation of Herbaspirillum seropedicae PII proteins, GlnB and GlnK. Both proteins were uridylylated by GlnD in the presence of ATP or ADP, although the uridylylation levels were higher in the presence of ATP and under high 2-OG levels. Under excess of 2-OG, the GlnB uridylylation level was higher in the presence of ATP than with ADP, while GlnK uridylylation was similar with ATP or ADP. Moreover, in the presence of ADP/ATP molar ratios varying from 10/1 to 1/10, GlnB uridylylation level decreased as ADP concentration increased, whereas GlnK uridylylation remained constant. The results suggest that uridylylation of both GlnB and GlnK responds to 2-OG levels, but only GlnB responds effectively to variation on ADP/ATP ratio.     

Phosphoenolpyruvate carboxylase from the cyanobacterium Synechocystis sp. PCC 6803 is under global metabolic control by PII signaling

Phosphoenolpyruvate carboxylase (PEPC) is the second major carbon-fixing enzyme in photoautotrophic organisms. PEPC is required for the synthesis of amino acids of the glutamate and aspartate family by replenishing the TCA cycle. Furthermore, in cyanobacteria, PEPC, together with malate dehydrogenase and malic enzyme, forms a metabolic shunt for the synthesis of pyruvate from PEP. During this process, CO₂ is first fixed and later released again. Due to its central metabolic position, it is crucial to fully understand the regulation of PEPC. Here, we identify PEPC from the cyanobacterium Synechocystis sp. PCC 6803 (PEPC) as a novel interaction partner for the global signal transduction protein P_II. In addition to an extensive characterization of PEPC, we demonstrate specific P_II–PEPC complex formation and its enzymatic consequences. PEPC activity is tuned by the metabolite-sensing properties of P_II: Whereas in the absence of P_II, PEPC is subjected to ATP inhibition, it is activated beyond its basal activity in the presence of P_II. Furthermore, P_II–PEPC complex formation is inhibited by ADP and PEPC activation by P_II-ATP is mitigated in the presence of 2-OG, linking PEPC regulation to the cell's global carbon/nitrogen status. Finally, physiological relevance of the in vitro measurements was proven by metabolomic analyses of Synechocystis wild-type and P_II-deficient cells.     

Energy transduction in photosynthetic bacteria. VIII. Activation of the energy-transducing ATPase by inorganic phosphate

ATPase activity and ATP-induced energization of photosynthetic membranes from Rhodopseudomonas capsulata are stimulated by phosphate; the maximum stimulatory effect occurs at a concentration between 1 and 2 mM.The sensitivity of the ATPase to oligomycin increases in the presence of phosphate since all the P_i-stimulated activity is inhibited by this antibiotic. Aurovertin, which has no effect on ATPase in the absence of phosphate, inhibits completely the activity elicited by this anion.The addition of P_i induces a substantial increase in the V of ATPase activity without changing the affinity of the enzyme for ATP or ADP.Arsenate, at the same concentrations, produces effects very similar to those of phosphate. The stimulation by arsenate of the transfer of energy from ATP to the membrane suggests a non-hydrolytic role of this anion as a modifier of the ATPase activity.     

The ATPase cycle mechanism of the DEAD-box rRNA helicase, DbpA

DEAD-box proteins are ATPase enzymes that destabilize and unwind duplex RNA. Quantitative knowledge of the ATPase cycle parameters is critical for developing models of helicase activity. However, limited information regarding the rate and equilibrium constants defining the ATPase cycle of RNA helicases is available, including the distribution of populated biochemical intermediates, the catalytic step(s) that limits the enzymatic reaction cycle, and how ATP utilization and RNA interactions are linked. We present a quantitative kinetic and equilibrium characterization of the ribosomal RNA (rRNA)-activated ATPase cycle mechanism of DbpA, a DEAD-box rRNA helicase implicated in ribosome biogenesis. rRNA activates the ATPase activity of DbpA by promoting a conformational change after ATP binding that is associated with hydrolysis. Chemical cleavage of bound ATP is reversible and occurs via a γ-phosphate attack mechanism. ADP-P_i and RNA binding display strong thermodynamic coupling, which causes DbpA-ADP-P_i to bind rRNA with > 10-fold higher affinity than with bound ATP, ADP or in the absence of nucleotide. The rRNA-activated steady-state ATPase cycle of DbpA is limited both by ATP hydrolysis and by P_i release, which occur with comparable rates. Consequently, the predominantly populated biochemical states during steady-state cycling are the ATP- and ADP-P_i-bound intermediates. Thermodynamic linkage analysis of the ATPase cycle transitions favors a model in which rRNA duplex destabilization is linked to strong rRNA and nucleotide binding. The presented analysis of the DbpA ATPase cycle reaction mechanism provides a rigorous kinetic and thermodynamic foundation for developing testable hypotheses regarding the functions and molecular mechanisms of DEAD-box helicases.     

Properties of a plasmalemma ATPase of the maize scutellum

Properties of a plasmalemma phosphatase of the maize scutellum, tentatively identified as an ATPase in a previous paper, were investigated. Fresh and frozen-thawed scutellum slices, that had been treated with 10 mM HCl to destroy acid phosphatases, were used as a source of enzyme. With the exceptions of the Na⁺, K⁺ and dinitrophenol experiments, the two kinds of slices gave similar results. ATP and CTP were the best substrates for the enzyme followed by TTP, UTP, CDP, ADP and GTP. UDP, nucleoside monophosphates, sugar phosphates, inorganic pyrophosphate and p-nitrophenyl phosphate were relatively ineffective as substrates. The K_m's for ATP and ADP were 0.65 and 5 mM, respectively, but the two substrates gave the same V_max (49.8 μmol P_i/hr/g slices). Previously, it was shown that the products of ATP hydrolysis are ADP, AMP and P_i. Using these previous results and from the time courses of ATP disappearance from the bathing solution and the appearance of P_i and ADP, it was concluded that ATP and ADP were hydrolysed by the same enzyme. The ATPase was not inhibited by oligomycin. N-N′-Dicyclohexylcarbodiimide (DCCD) was a poor inhibitor, and a water soluble analog of DCCD, 1-ethyl-3 (3 dimethyl-aminopropyl)-carbodiimide, gave only 33% inhibition. The relative effectiveness of divalent cations for stimulating ATPase activity was Mn²⁺ > Mg²⁺ ? Ca²⁺ > Co²⁺ · Na⁺ and K⁺ gave a small additional stimulation in the presence of Mg²⁺. However, Na⁺ and K⁺ gave a much greater stimulation when no divalent cation was added, and this occurred only when fresh slices were used. Dinitrophenol also increased ATPase activity only when fresh slices were used. Since it is likely that both the uptake of Na⁺ and K⁺ and the action of dinitrophenol would lower the electrochemical gradient of protons across the plasmalemma, the different results obtained with fresh slices indicate that the ATPase in these slices was under the constraint of a proton gradient.     

Requirement of medium ADP for the steady-state hydrolysis of ATP by the proton-translocating Paracoccus denitrificans Fo·F1-ATP synthase

F_o·F₁-ATP synthase in inside-out coupled vesicles derived from Paracoccus denitrificans catalyzes P_i-dependent proton-translocating ATPase reaction if exposed to prior energization that relieves ADP·Mg²⁺-induced inhibition (Zharova, T.V. and Vinogradov, A.D. (2004) J. Biol. Chem.,279, 12319–12324). Here we present evidence that the presence of medium ADP is required for the steady-state energetically self-sustained coupled ATP hydrolysis. The initial rapid ATPase activity is declined to a certain level if the reaction proceeds in the presence of the ADP-consuming, ATP-regenerating system (pyruvate kinase/phosphoenol pyruvate). The rate and extent of the enzyme de-activation are inversely proportional to the steady-state ADP concentration, which is altered by various amounts of pyruvate kinase at constant ATPase level. The half-maximal rate of stationary ATP hydrolysis is reached at an ADP concentration of 8 × 10⁻⁶ M. The kinetic scheme is proposed explaining the requirement of the reaction products (ADP and P_i), the substrates of ATP synthesis, in the medium for proton-translocating ATP hydrolysis by P. denitrificans F_o·F₁-ATP synthase.     

H-ATPase Activity from Storage Tissue of Beta vulgaris: III. Modulation of ATPase Activity by Reaction Substrates and Products

Two distinct membrane fractions containing H⁺-ATPase activity were prepared from red beet. One fraction contained a H⁺-ATPase activity that was inhibited by NO₃⁻ while the other contained a H⁺-ATPase inhibited by vanadate. We have previously proposed that these H⁺-ATPases are associated with tonoplast (NO₃⁻-sensitive) and plasma membrane (vanadate-sensitive), respectively. Both ATPase were examined to determine to what extent their activity was influenced by variations in the concentration of ATPase substrates and products. The substrate for both ATPase was MgATP²⁻, and Mg²⁺ concentrations in excess of ATP had only a slight inhibitory effect on either ATPase. Both ATPases were inhibited by free ATP (i.e. ATP concentrations in excess of Mg²⁺) and ADP but not by AMP. The plasma membrane ATPase was more sensitive than the tonoplast ATPase to free ATP and the tonoplast ATPase was more sensitive than the plasma membrane ATPase to ADP.

Inhibition of both ATPases by free ATP was complex. Inhibition of the plasma membrane ATPase by ADP was competitive whereas the tonoplast ATPase demonstrated a sigmoidal dependence on MgATP²⁻ in the presence of ADP. Inorganic phosphate moderately inhibited both ATPases in a noncompetitive manner.

Calcium inhibited the plasma membrane but not the tonoplast ATPase, apparently by a direct interaction with the ATPase rather than by disrupting the MgATP²⁻ complex.

The sensitivity of both ATPases to ADP suggests that under conditions of restricted energy supply H⁺-ATPase activity may be reduced by increases in ADP levels rather than by decreases in ATP levels per se. The sensitivity of both ATPases to ADP and free ATP suggests that modulation of cytoplasmic Mg²⁺ could modulate ATPase activity at both the tonoplast and plasma membrane.

     

Role of CFTR’s intrinsic adenylate kinase activity in gating of the Cl− channel

The cystic fibrosis transmembrane conductance regulator (CFTR) is a Cl^?channel in the ATP-binding cassette (ABC) transporter protein family. CFTR features the modular design characteristic of ABC transporters, which includes two membrane-spanning domains forming the channel pore, and two ABC nucleotide-binding domains that interact with ATP and contain the enzymatic activity coupled to normal gating. Like other ABC transporters CFTR is an ATPase (ATP + H₂O → ADP + P_i). Recent work has shown that CFTR also possesses intrinsic adenylate kinase activity (ATP + AMP ? ADP + ADP). This finding raises important questions: How does AMP influence CFTR gating? Why does ADP inhibit CFTR current? Which enzymatic activity gates CFTR in vivo? Are there implications for other ABC transporters? This minireview attempts to shed light on these questions by summarizing recent advances in our understanding of the role of the CFTR adenylate kinase activity for channel gating.     

The regulation of the rate of ATP hydrolysis by H-meromyosin

The effect of N-ethylmaleimide on the ATPase activity and ADP binding of tryptic H-meromyosin was studied at 6 and 23 °C temperatures. The affinity constant of H-meromyosin for ADP with Mg as activator was increased by small concentrations of N-ethylmaleimide (2.25 moles per mole of enzyme) at both temperatures, accompanied by activation of ATP hydrolysis at 25 °C and inhibition at 6 °C. With higher N-ethylmaleimide concentrations, the ATPase activity was inhibited at both temperatures, without comparable inhibition of ADP binding. Rapid kinetic analysis of the rate of development of difference spectrum after the addition of ATP or ADP to H-meromyosin indicates, that blocking of the S₁ and S₂ SH groups of H-meromyosin decreases both the formation (k₁) and the dissociation (k₂) rate constants of H-meromyosin substrate complex. At 6 °C, in the presence of Mg, the value of k₂ for ADP is similar to the turnover number of ATP hydrolysis, suggesting that dissociation of ADP from the active site may be the rate-limiting step of ATP hydrolysis. At 23 °C, the turnover number of Mg-moderated ATP hydrolysis is much smaller than k₂, indicating that the rate limitation shifted so another, so far unidentified, step.     

Interaction of homogeneous mitochondrial ATPase from rat liver with adenine nucleotides and inorganic phosphate

Mitochondrial ATPase from rat liver mitochondria contains multiple nucleotide binding sites. At low concentrations ADP binds with high affinity (1 mole/mole ATPase, K_D = 1–2 μM). At high concentrations, ADP inhibits ATP hydrolysis presumably by competing with ATP for the active site (K_I = 240–300 μM). As isolated, mitochondrial ATPase contains between 0.6 and 2.5 moles ATP/mole ATPase. This “tightly bound” ATP can be removed by repeated precipitations with ammonium sulfate without altering hydrolytic activity of the enzyme. However, the ATP-depleted enzyme must be redissolved in high concentrations of phosphate to retain activity. AMP-PNP (adenylyl imidodiphosphate) replaces tightly bound ATP removed from the enzyme and inhibits ATP hydrolysis. AMP-PNP has little effect on high affinity binding of ADP. Kinetic studies of ATP hydrolysis reveal hyperbolic velocity vs. ATP plots, provided assays are done in bicarbonate buffer or buffers containing high concentrations of phosphate. Taken together, these studies indicate that sites on the enzyme not directly associated with ATP hydrolysis bind ATP or ADP, and that in the absence of bound nucleotide, P_i can maintain the active form of the enzyme.     

Mechanism of Mss116 ATPase reveals functional diversity of DEAD-Box proteins

Mss116 is a Saccharomyces cerevisiae mitochondrial DEAD-box RNA helicase protein that is essential for efficient in vivo splicing of all group I and group II introns and for activation of mRNA translation. Catalysis of intron splicing by Mss116 is coupled to its ATPase activity. Knowledge of the kinetic pathway(s) and biochemical intermediates populated during RNA-stimulated Mss116 ATPase is fundamental for defining how Mss116 ATP utilization is linked to in vivo function. We therefore measured the rate and equilibrium constants underlying Mss116 ATP utilization and nucleotide-linked RNA binding. RNA accelerates the Mss116 steady-state ATPase ∼ 7-fold by promoting rate-limiting ATP hydrolysis such that inorganic phosphate (P_i) release becomes (partially) rate-limiting. RNA binding displays strong thermodynamic coupling to the chemical states of the Mss116-bound nucleotide such that Mss116 with bound ADP-P_i binds RNA more strongly than Mss116 with bound ADP or in the absence of nucleotide. The predominant biochemical intermediate populated during in vivo steady-state cycling is the strong RNA-binding Mss116-ADP-P_i state. Strong RNA binding allows Mss116 to fulfill its biological role in the stabilization of group II intron folding intermediates. ATPase cycling allows for transient population of the weak RNA-binding ADP state of Mss116 and linked dissociation from RNA, which is required for the final stages of intron folding. In cases where Mss116 functions as a helicase, the data collectively favor a model in which ATP hydrolysis promotes a weak-to-strong RNA binding transition that disrupts stable RNA duplexes. The subsequent strong-to-weak RNA binding transition associated with P_i release dissociates Mss116-RNA complexes, regenerating free Mss116.     

The ATPase Cycle of PcrA Helicase and Its Coupling to Translocation on DNA

The superfamily 1 bacterial helicase PcrA has a role in the replication of certain plasmids, acting with the initiator protein (RepD) that binds to and nicks the double-stranded origin of replication. PcrA also translocates single-stranded DNA with discrete steps of one base per ATP hydrolyzed. Individual rate constants have been determined for the DNA helicase PcrA ATPase cycle when bound to either single-stranded DNA or a double-stranded DNA junction that also has RepD bound. The fluorescent ATP analogue 2′(3′)-O-(N-methylanthraniloyl)ATP was used throughout all experiments to provide a complete ATPase cycle for a single nucleotide species. Fluorescence intensity and anisotropy stopped-flow measurements were used to determine rate constants for binding and release. Quenched-flow measurements provided the kinetics of the hydrolytic cleavage step. The fluorescent phosphate sensor MDCC-PBP was used to measure phosphate release kinetics. The chemical cleavage step is the rate-limiting step in the cycle and is essentially irreversible and would result in the bound ATP complex being a major component at steady state. This cleavage step is greatly accelerated by bound DNA, producing the high activation of this protein compared to the protein alone. The data suggest the possibility that ADP is released in two steps, which would result in bound ADP also being a major intermediate, with bound ADP·P_i being a very small component. It therefore seems likely that the major transition in structure occurs during the cleavage step, rather than P_i release. ATP rebinding could then cause reversal of this structural transition. The kinetic mechanism of the PcrA ATPase cycle is very little changed by potential binding to RepD, supporting the idea that RepD increases the processivity of PcrA by increasing affinity to DNA rather than affecting the enzymatic properties per se.