Mechanical properties of BiP protein determined by nano‐rheology

Immunoglobulin Binding Protein (BiP) is a chaperone and molecular motor belonging to the Hsp70 family, involved in the regulation of important biological processes such as synthesis, folding and translocation of proteins in the Endoplasmic Reticulum. BiP has two highly conserved domains: the N‐terminal Nucleotide‐Binding Domain (NBD), and the C‐terminal Substrate‐Binding Domain (SBD), connected by a hydrophobic linker. ATP binds and it is hydrolyzed to ADP in the NBD, and BiP's extended polypeptide substrates bind in the SBD. Like many molecular motors, BiP function depends on both structural and catalytic properties that may contribute to its performance. One novel approach to study the mechanical properties of BiP considers exploring the changes in the viscoelastic behavior upon ligand binding, using a technique called nano‐rheology. This technique is essentially a traditional rheology experiment, in which an oscillatory force is directly applied to the protein under study, and the resulting average deformation is measured. Our results show that the folded state of the protein behaves like a viscoelastic material, getting softer when it binds nucleotides‐ ATP, ADP, and AMP‐PNP‐, but stiffer when binding HTFPAVL peptide substrate. Also, we observed that peptide binding dramatically increases the affinity for ADP, decreasing it dissociation constant (K_D) around 1000 times, demonstrating allosteric coupling between SBD and NBD domains.     

Escherichia coli dnaB protein. Affinity chromatography on immobilized nucleotides.

The purification of the Escherichia coli dnaB protein by affinity chromatography on nucleotides bound to agarose is described. The dnaB protein, which contains an associated ribonucleoside triphosphatase activity (Wickner, S., Wright, M., and Hurwitz, J. (1974) Proc. Natl. Acad. Sci. U. S. A. 71, 783-787) binds to immobilized ATP, ADP, and UDP, but not to AMP. The type of linkage of ATP to agarose influences the adsorption, elution, and purification of the enzyme. Optimal purification is achieved using ATP bound to agarose via its oxidized ribose moiety. By this means, the dnaB protein can be obtained at least 95% electrophoretically pure after only three purification steps. The enzyme can be eluted from immobilized nucleoside-5'-di- and -triphosphates by ATP, ADP, and pyrophosphate, but not by AMP or orthophosphate. ADP and pyrophosphate, as well as the substrate ATP in high concentration are at the same time inhibitors of the ribonucleoside triphosphatase. The dnaB complementing and ribonucleoside triphosphatase activities could not be separated from each other by affinity chromatography, supporting the finding of others that they both reside on the same protein complex, namely a dnaB multimer. The results indicate that the dnaB protein binds to immobilized nucleotides by means of its ribonucleoside triphosphatase, and that at least the pyrophosphate moiety is essential for adsorption as well as elution of the enzyme.     

Adenosine triphosphatase from rat liver mitochondria: separate sites involved in ATP hydrolysis and in the reversible, high affinity binding of ADP.

Homogeneous ATPase from rat liver mitochondria binds one mole of ADP per mole of enzyme reversibly, and with high affinity (K_D = 1–2 μM). The high affinity binding site is highly specific for ADP and dADP. AMP does not bind. Agents which inhibit ATP hydrolysis have little inhibitory effect on the high affinity binding of ADP. These agents include adenylyl imidodiphosphate (AMP-PNP), azide, sucrose, and the divalent cation Mg⁺⁺. AMP-PNP inhibits ATPase activity in phosphorylating membrane preparations of rat liver mitochondria by about 90 percent, but is without effect on ATP synthesis. These results are consistent with the view that the purified soluble, and the membrane-bound ATPase of rat liver mitochondria contain separate sites involved in ATP hydrolysis and in the reversible, high affinity binding of ADP.     

In vivo analysis of the lumenal binding protein (BiP) reveals multiple functions of its ATPase domain

The endoplasmic reticulum (ER) chaperone binding protein (BiP) binds exposed hydrophobic regions of misfolded proteins. Cycles of ATP hydrolysis and nucleotide exchange on the ATPase domain were shown to regulate the function of the ligand-binding domain in vitro. Here we show that ATPase mutants of BiP with defective ATP-hydrolysis (T46G) or ATP-binding (G235D) caused permanent association with a model ligand, but also interfered with the production of secretory, but not cytosolic, proteins in vivo. Furthermore, the negative effect of BiP(T46G) on secretory protein synthesis was rescued by increased levels of wild-type BiP, whereas the G235D mutation was dominant. Unexpectedly, expression of a mutant BiP with impaired ligand binding also interfered with secretory protein production. Although mutant BiP lacking its ATPase domain had no detrimental effect on ER function, expression of an isolated ATPase domain interfered with secretory protein synthesis. Interestingly, the inhibitory effect of the isolated ATPase was alleviated by the T46G mutation and aggravated by the G235D mutation. We propose that in addition to its role in ligand release, the ATPase domain can interact with other components of the protein translocation and folding machinery to influence secretory protein synthesis.     

ATP:AMP phosphotransferase activity, a new characteristic of Catharanthus roseus tonoplasts

The ATPase activity of Catharanthus roseus tonoplasts was examined using HPLC separation and quantification of adenine nucleotides. ATP seemed to be degraded into ADP and AMP by tonoplast vesicles. When ADP was the initial substrate, the appearance of AMP and concomitant ATP synthesis were observed; these reactions were inhibited by Ap⁵A. The apparent degradation of ATP into AMP was also inhibited by Ap⁵A. These results indicated that AMP arose from an ATP:AMP phosphotransferase activity and excluded the possibility of the hydrolysis of ADP into AMP by the tonoplast ATPase. AMP was degraded by the microsomal fraction from protoplasts or by the cytosol while the tonoplast vesicles did not hydrolyze it. This observation was used to assess the purity of tonoplasts.     

An inhibitory high affinity binding site for ADP in the oligomycin-sensitive ATPase of beef heart submitochondrial particles.

Kinetic evidence are presented for the existence of a high affinity inhibitory site for ADP /K_i < 10^?7 M/ in the oligomycin-sensitive ATPase of beef heart submitochondrial particles. The ATPase·ADP complex is completely inactive in the ATPase reaction; it can be converted into active ATPase in a slow ATP-dependent reaction. The dependence of a first order rate constant for activation of the enzyme·ADP complex on concentration of ATP gives a K_m value equal to that for ATP in the ATPase reaction. The data obtained suggest that the membrane-bound ATPase complex contains two kinetically distinct nucleotide-binding centers, i.e. center 1 binds ATP or ADP with a formation of enzyme-substrate or enzyme-competitive inhibitor complexes: center 2 binds ADP with a formation of a complex which is able to bind ATP in center 1 and unable to hydrolyze the bound ATP. The binding of ATP or ADP in center 1 changes the reactivity of center 2 towards ADP.     

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.     

Asymmetric ATP binding and hydrolysis activity of the Thermus aquaticus MutS dimer is key to modulation of its interactions with mismatched DNA

Prokaryotic MutS and eukaryotic Msh proteins recognize base pair mismatches and insertions or deletions in DNA and initiate mismatch repair. These proteins function as dimers (and perhaps higher order oligomers) and possess an ATPase activity that is essential for DNA repair. Previous studies of Escherichia coli MutS and eukaryotic Msh2-Msh6 proteins have revealed asymmetry within the dimer with respect to both DNA binding and ATPase activities. We have found the Thermus aquaticus MutS protein amenable to detailed investigation of the nature and role of this asymmetry. Here, we show that (a) in a MutS dimer one subunit (S1) binds nucleotide with high affinity and the other (S2) with 10-fold weaker affinity, (b) S1 hydrolyzes ATP rapidly while S2 hydrolyzes ATP at a 30-50-fold slower rate, (c) mismatched DNA binding to MutS inhibits ATP hydrolysis at S1 but slow hydrolysis continues at S2, and (d) interaction between mismatched DNA and MutS is weakened when both subunits are occupied by ATP but remains stable when S1 is occupied by ATP and S2 by ADP. These results reveal key MutS species in the ATPase pathway; S1(ADP)-S2(ATP) is formed preferentially in the absence of DNA or in the presence of fully matched DNA, while S1(ATP)-S2(ATP) and S1(ATP)-S2(ADP) are formed preferentially in the presence of mismatched DNA. These MutS species exhibit differences in interaction with mismatched DNA that are likely important for the mechanism of MutS action in DNA repair.     

Purification and characterization of BiP/Kar2 protein from Saccharomyces cerevisiae.

Using specific anti-BiP/Kar2 antibody as the probe, we have developed an efficient purification method of BiP/Kar2 protein from the total cell extract of Saccharomyces cerevisiae. Overproduction of BiP/Kar2 protein was achieved by the cloning of the KAR2 gene on multicopy plasmids and the treatment of cells harboring the cloned KAR2 gene with tunicamycin. Freeze-thaw treatment, hydroxyapatite high pressure liquid chromatography, and ATP-agarose column chromatography of crude extract yielded homogeneous BiP/Kar2 protein (including less than 0.2% of degradative derivative) with a 430-fold purification and 28% recovery. Edman degradation of purified BiP/Kar2 suggests that the mature protein corresponds to a processed product with the removal of a 42-amino acid presequence. It is active as a homodimer and exhibits ATPase activity with a specific activity of 2 pmol/min/micrograms of protein. Protease susceptibility indicated that the ADP form of BiP/Kar2 is more resistant than the ATP form to the chymotrypsin digestion and that BiP/Kar2 required the presence of ATP to avoid the irreversible denaturation. Synthesis of BiP/Kar2 was induced by the inducible expression of an aberrant heterologous protein, yeast killer prepro-signal mouse alpha-amylase fusion protein.     

ATP binding modulates the nucleic acid affinity of hepatitis C virus helicase

The helicase of hepatitis C virus (HCV) unwinds nucleic acid using the energy of ATP hydrolysis. The ATPase cycle is believed to induce protein conformational changes to drive helicase translocation along the length of the nucleic acid. We have investigated the energetics of nucleic acid binding by HCV helicase to understand how the nucleotide ligation state of the helicase dictates the conformation of its nucleic acid binding site. Because most of the nucleotide ligation states of the helicase are transient due to rapid ATP hydrolysis, several compounds were analyzed to find an efficient unhydrolyzable ATP analog. We found that the beta-gamma methylene/amine analogs of ATP, ATPgammaS, or [AlF4]ADP were not effective in inhibiting the ATPase activity of HCV helicase. On the other hand, [BeF3]ADP was found to be a potent inhibitor of the ATPase activity, and it binds tightly to HCV helicase with a 1:1 stoichiometry. Equilibrium binding studies showed that HCV helicase binds single-stranded nucleic acid with a high affinity in the absence of ATP or in the presence of ADP. Upon binding to the ATP analog, a 100-fold reduction in affinity for ssDNA was observed. The reduction in affinity was also observed in duplex DNA with 3' single-stranded tail and in RNA but not in duplex DNA. The results of this study indicate that the nucleic acid binding site of HCV helicase is allosterically modulated by the ATPase reaction. The binding energy of ATP is used to bring HCV helicase out of a tightly bound state to facilitate translocation, whereas ATP hydrolysis and product release steps promote tight rebinding of the helicase to the nucleic acid. On the basis of these results we propose a Brownian motor model for unidirectional translocation of HCV helicase along the nucleic acid length.     

Changes in energy charge and block of protein synthesis in rabbit reticulocytes under the action of valinomycin

Valinomycin blocks protein synthesis at the elongation stage in intact reticulocyte while being without action on a cell free system. We demonstrate here that this membrane mediated inhibition is accompanied by a change of the energy charge (ATP/ADP/AMP ratio) of the cells. There seems to be an accumulation of AMP without a proportional gain in ADP. The change in energy charge in itself can be the cause of the inhibition of protein synthesis. We show also that valinomycin can cause a decrease of the energy charge at concentrations where its action as an ionophore is not seen and independent of a possible activation of the Na-K dependent ATPase.Present address: Meir Hospital, Kfar Saba, Israel     

Binding of nucleotides to the ATP-dependent protease La from Escherichia coli

A critical enzyme in protein breakdown in Escherichia coli is the ATP-hydrolyzing protease La, the lon gene product. In order to clarify the role of ATP in proteolysis, we studied ATP and ADP binding to this enzyme using rapid gel filtration to separate free from bound ligands. In the presence of Mg2+ or Mn2+ and 10 microM ATP, two molecules of ATP were bound to the tetrameric enzyme, while at 100 microM ATP (or higher), four ATP molecules were bound, both at 0 and 37 degrees C. Protease La thus has two high affinity sites (S0.5 less than 10(-7) M) for ATP and two lower affinity sites (S0.5 = 12-15 microM). Binding was reversible. In the absence of a divalent ion, ATP bound to only two sites. However, much lower Mg2+ concentrations (50 microM) were required for maximal ATPase binding than for maximal proteolytic and ATPase activity (2 mM). Decavanadate, which is a potent inhibitor of proteolysis, also blocked ATP binding, but orthovanadate had neither effect. Different ATP analogs bind to these sites in distinct ways. Adenyl-5'-yl imidodiphosphate binds to only one high affinity site, while adenyl-5'-yl methylene monophosphonate binds to two. Nevertheless, both non-metabolizable analogs can activate oligopeptide hydrolysis as well as ATP. Although binding of a single nucleotide can activate peptide hydrolysis, occupancy of all four sites appears necessary for maximal protein breakdown. The ATP molecules on all four sites are hydrolyzed rapidly. The Pi is released, but ADP remains on the enzyme. ADP binds to the same four sites, but this process does not require divalent ions. Protease La shows higher affinity for ADP than for ATP. Therefore, in vivo, ADP should inhibit ATP binding and protease La function.     

The human erythrocyte sugar transporter is also a nucleotide binding protein

We have previously shown that ATP interacts with an intracellular, stereoselective, regulatory site(s) on the human erythrocyte sugar transport system to modify transport function in a hydrolysis-independent manner. This present study examines the nucleotide binding properties of the human erythrocyte sugar transport system. We demonstrate by transport studies in ghosts, by nucleotide binding studies with purified transport protein by measurements of nucleotide inhibition of 8-azidoadenosine 5'-[gamma-32P]triphosphate (azido-ATP) photoincorporation into purified carrier, and by analysis of nucleotide inhibition of carboxyl-terminal peptide antisera binding to purified glucose carrier than the glucose transport protein binds (with increasing order of affinity) AMP, ADP, ATP, 5'-adenylyl imidodiphosphate (AMP-PNP), and 1,N6-ethenoadenosine 5'-triphosphate (EATP) at a single site. The carrier lacks detectable ATPase activity and GTP binding capacity. While AMP and ADP bind to the carrier protein and act as competitive inhibitors of ATP binding, these nucleotides are unable to mimic the ability of ATP, AMP-PNP, and EATP to modify the catalytic properties of the sugar transport system. Limited tryptic digestion of azido-ATP-photolabeled carrier suggests that the region of the glucose transport protein containing the intracellular cytochalasin B binding and extracellular bis(mannose) binding domains [residues 270-456; Holman, G. D., & Rees, W. D. (1987) Biochim. Biophys. Acta 897, 395-405] may also contain the intracellular ATP binding site.     

The dnaB protein of Escherichia coli: mechanism of nucleotide binding, hydrolysis, and modulation by dnaC protein

The mechanism of nucleotide binding and hydrolysis by dnaB protein and dnaB X dnaC protein complex has been studied by using fluorescent nucleotide analogues. Binding of trinitrophenyladenosine triphosphate (TNP-ATP) or the corresponding diphosphate (TNP-ADP) results in a blue shift of the emission maximum and a severalfold amplification of the fluorescence emission of the nucleotide analogues. Scatchard analysis of TNP-ATP binding indicates that TNP-ATP binds with a high affinity (Kd = 0.87 microM) and a 8.5-fold enhancement of fluorescence emission of the nucleotide. Only three molecules of TNP-ATP or TNP-ADP bind per hexamer of dnaB protein in contrast to six molecules of ATP or ADP binding to a dnaB hexamer. TNP-ATP and TNP-ADP are both competitive inhibitors of single-stranded (SS) DNA-dependent ATPase activity of dnaB protein. TNP-AMP neither binds to dnaB protein nor inhibits the ATPase activity. Formation of dnaB X dnaC complex by dnaC protein results in diminution of the TNP-ATP fluorescence enhancement and a concomitant decrease in the SS DNA-dependent ATPase activity. Kinetic analysis of the ATPase activity of dnaB X dnaC complex indicates that the decrease in the ATPase activity on complex formation is due to a reduction of the maximal velocity (Vmax). The dnaB protein hydrolyzes both TNP-ATP and dATP, however, with an extremely slow rate in the presence of single-stranded M13 DNA. The 2'-OH group of the nucleotide most likely plays an important role in the hydrolysis reaction but not in the nucleotide binding.     

Isolation of proteins that speifically interact with the ATPase domain of mammalian ER chaperone,BiP

BiP, immunoglobulin binding protein, is an ER homologue of Hsp 70. However, unlike other Hsp70 proteins, regulatory protein(s) for BiP has not been identified. Here, we demonstrated the presence of potential regulatory proteins for BiP using a pull-down assay. Since BiP can bind any unfolded protein, only the ATPase domain of BiP was used for the pull-down assay in order to minimize nonspecific binding. The ATPase domain was cloned to produce recombinant protein, which was then conjugated to CNBr-activated agarose. The structural conformation and ATP hydrolysis activity of the recombinant ATPase domain were similar to those of the native protein. Eight proteins from metabolically labeled mouse plasmacytoma cells specifically bound to the recombinant ATPase protein. The binding of these proteins was inhibited by excess amounts of free ATPase protein, and was dependent on the presence of ATP. These proteins were eluted by ADP. Of these proteins, Grp 170 and BiP where identified, while the others were not identified as known ER proteins, from Western blot analyses. The presence of the ATPase-binding proteins for Bip was first demonstrated in this study, and our data suggest similar regulatory machinery for BiP may exist in the ER, as found in prokaryotes and other cellular compartments.     

Affinity chromatography of H+-translocating adenosine triphosphatase isolated by chloroform extraction of Rhodospirillum rubrum chromatophores. Modification of binding affinity by divalent cations and activating anions.

1. ATPase isolated from Rhodospirillum rubrum by chloroform extraction and purified by gel filtration or affinity chromatography shows three bands (alpha, beta and gamma) upon electrophoresis in sodium dodecyl sulphate. 2. Ca2+-ATPase activity of the preparation is inhibited by aurovertin and efrapeptin but not by oligomycin. Activity may be inhibited by treatment with 4-chloro-7-nitrobenzofurazan and subsequently restored by dithiothreitol. 3. The enzyme fails to reconstitute photophosphorylation in chromatophores depleted of ATPase by sonic irradiation. 4. Most of the active protein from the crude chloroform extract binds to an affinity chromatography column bearing an immobilised ADP analogue but not to a column bearing immobilised pyrophosphate. 5. In the absence of divalent cations, a component with a very high specific activity for Ca2+-ATPase is eluted from the column by 1.6 mM ATP. This protein migrates asa single band on 5% polyacrylamide gel electrophoresis and only possesses three subunits. At 12 mM ATP an inactive protein is eluted which does not run on acid or alkali polyacrylamide gels and shows a complex subunit structure. 6. ATPase preparations prepared by acetone extraction or by sonic irradiation of chromatophores may also be purified 10-fold by affinity chromatography. 7. The inclusion of 5 mM MgCl2 or CaCl2 during affinity chromatography of chloroform ATPase increases the capacity of the column for the enzyme and demands a higher eluting concentration of ATP. 8. When the enzyme is more than 90% inhibited by efrapeptin or 4-chloro-7-nitrobenzofurazan, the binding characteristics of the enzyme are not affected. 9. 10 mM Na2SO3, which greatly stimulates the Ca2+- and Mg2+-dependent ATPase activity of the enzyme and increases Ki (ADP) for Ca2+-ATPase from 50 to 850 micron, prevents binding to the affinity column. Binding may be restored by the addition of divalent cations. 10. Na2SO3 increases the rate of ATP hydrolysis, ATP-driven H+ translocation and ATP-driven transhydrogenase in chromatophores. 11. It is proposed that anions such as sulphite convert the chromatophore ATPase into a form which is a more efficient energy transducer.     

Identification of an unusual AT(D)Pase-like activity in multifunctional NAD glycohydrolase from the venom of Agkistrodon acutus

NAD-glycohydrolases (NADases) are ubiquitous enzymes that possess NAD glycohydrolase, ADPR cyclase or cADPR hydrolase activity. All these activities are attributed to the NADase-catalyzed cleavage of C-N glycosyl bond. AA-NADase purified from the venom of Agkistrodon acutus is different from the known NADases, for it consists of two chains linked with disulfide-bond(s) and contains one Cu(2+) ion. Here, we show that AA-NADase is not only able to cleave the C-N glycosyl bond of NAD to produce ADPR and nicotinamide, but also able to cleave the phosphoanhydride linkages of ATP, ADP and AMP-PNP to yield AMP. AA-NADase selectively cleaves the P-O-P bond of ATP, ADP and AMP-PNP without the cleavage of P-O-P bond of NAD. The hydrolysis reactions of NAD, ATP and ADP catalyzed by AA-NADase are mutually competitive. ATP is the excellent substrate for AA-NADase with the highest specificity constant k(cat)/K(m) of 293+/-7mM(-1)s(-1). AA-NADase catalyzes the hydrolysis of ATP to produce AMP with an intermediate ADP. AA-NADase binds with one AMP with high affinity determined by isothermal titration calorimetry (ITC). AMP is an efficient inhibitor against NAD. AA-NADase has so far been identified as the first unique multicatalytic enzyme with both NADase and AT(D)Pase-like activities.     

Nucleotide exchange from the high-affinity ATP-binding site in SecA is the rate-limiting step in the ATPase cycle of the soluble enzyme and occurs through a specialized conformational state

We have characterized the kinetic and thermodynamic consequences of adenine nucleotide interaction with the low-affinity and high-affinity nucleotide-binding sites in free SecA. ATP binds to the hydrolytically active high-affinity site approximately 3-fold more slowly than ADP when SecA is in its conformational ground state, suggesting that ATP binding probably occurs when the enzyme is in another conformational state during the productive ATPase/transport cycle. The steady-state ATP hydrolysis rate is equivalent to the rate of ADP release from the high-affinity site under a number of conditions, indicating that this process is the rate-limiting step in the ATPase cycle of the free enzyme. Because efficient protein translocation requires at least a 100-fold acceleration in the ATPase rate, the rate-limiting process of ADP release from the high-affinity site is likely to play a controlling role in the conformational reaction cycle of SecA. This release process involves a large enthalpy of activation, suggesting that it involves a protein conformational change, and two observations indicate that this conformational change is different from the well-characterized endothermic conformational transition believed to gate the binding of SecA to SecYEG. First, nucleotide binding to the low-affinity site strongly inhibits the endothermic transition but does not reduce the rate of ADP release. Second, removal of Mg(2+) from an allosteric binding site on SecA does not perturb the endothermic transition but produces a 10-fold acceleration in the rate of ADP release. These divergent effects suggest that a specialized conformational transition mediates the rate-limiting ADP-release process in SecA. Finally, ADP, 2'-O-(N-methylanthraniloyl)-adenosine-5'-diphosphate (MANT-ADP), and adenosine 5'-O-(3-thiotriphosphate) (ATP-gamma-S) bind with similar affinities to the high-affinity site and also to the low-affinity site as inferred from their consistent effects in inhibiting the endothermic transition. In contrast, adenosine 5'-(beta,gamma-imino)triphosphate (AMPPNP) shows 100-fold weaker affinity than ADP for the high-affinity site and no detectable interaction with the low-affinity site at concentrations up to 1 mM, suggesting that this nonhydrolyzable analogue may not be a faithful mimic of ATP in its interactions with SecA.     

Analysis of nucleotide binding to P97 reveals the properties of a tandem AAA hexameric ATPase

p97, an essential chaperone in endoplasmic reticulum-associated degradation and organelle biogenesis, contains two AAA domains (D1 and D2) and assembles as a stable hexamer. We present a quantitative analysis of nucleotide binding to both D1 and D2 domains of p97, the first detailed study of nucleotide binding to both AAA domains for this type of AAA+ ATPase. We report that adenosine 5'-O-(thiotriphosphate) (ATPgammaS) binds with similar affinity to D1 and D2, but ADP binds with higher affinity to D1 than D2, offering an explanation for the higher ATPase activity in D2. Stoichiometric measurements suggest that although both ADP and ATPgammaS can saturate all 6 nucleotide binding sites in D1, only 3-4 of the 6 D2 sites can bind ATPgammaS simultaneously. ATPgammaS binding triggers a downstream cooperative conformational change of at least three monomers, which involves conserved arginine fingers and is necessary for ATP hydrolysis.