Importance of F1-ATPase residue alpha-Arg-376 for catalytic transition state stabilization

The functional role of essential residue alpha-Arg-376 in the catalytic site of F1-ATPase was studied. The mutants alpha R376C, alpha R376Q, and alpha R376K were constructed, and combined with the mutation beta Y331W, to investigate catalytic site nucleotide-binding parameters, and to assess catalytic transition state formation by measurement of MgADP-fluoroaluminate binding. Each mutation caused large impairment of ATP synthesis and hydrolysis. Despite the apparent proximity of alpha-Arg-376 to bound nucleoside di- and triphosphate in published X-ray structures, the mutations had little effect on MgADP or MgATP binding affinities, particularly at the highest affinity catalytic site, site 1. Both Cys and Gln mutants abolished transition state formation, demonstrating that alpha-Arg-376 is normally involved at this step of catalysis. A model of the F1-ATPase catalytic transition state structure is presented and discussed. The Lys mutant, although severely impaired, supported transition state formation, suggesting that an additional essential role for the alpha-Arg-376 guanidinium group exists, likely in alpha/beta conformational signal transmission required for steady-state catalysis. Parallels between alpha-Arg-376 and GAP/G-protein "arginine finger" residues are evident.     

Kinetic characterization of the unisite catalytic pathway of seven beta-subunit mutant F1-ATPases from Escherichia coli

We have studied the kinetics of "unisite" ATP hydrolysis and synthesis in seven mutant Escherichia coli F1-ATPase enzymes. The seven mutations are distributed over a 105-residue segment of the catalytic nucleotide-binding domain in beta-subunit and are: G142S, K155Q, K155E, E181Q, E192Q, M209I, and R246C. We report forward and reverse rate constants and equilibrium constants in all seven mutant enzymes for the four steps of unisite kinetics, namely (i) ATP binding/release, (ii) ATP hydrolysis/synthesis, (iii) Pi release/binding, and (iv) ADP release/binding. The seven mutant enzymes displayed a wide range of deviations from normal in both rate and equilibrium constants, with no discernible common pattern. Notably, steep reductions in Kd ATP were seen in some cases, the value of Kd Pi was high, and K2 (ATP hydrolysis/synthesis) was relatively unaffected. Significantly, when the data from the seven mutations were combined with previous data from two other E. coli F1-beta-subunit mutations (D242N, D242V), normal E. coli F1, soluble and membranous mitochondrial F1, it was found that linear free energy relationships obtained for both ATP binding/release (log k+1 versus log K1) and ADP binding/release (log k-4 versus log K-4). Two conclusions follow. 1) The seven mutations studied here cause subtle changes in interactions between the catalytic nucleotide-binding domain and substrate ATP or product ADP. 2) The mitochondrial, normal E. coli, and nine total beta-subunit mutant enzymes represent a continuum in which subtle structural differences in the catalytic site resulted in changes in binding energy; therefore insights into the nature of energy coupling during ATP hydrolysis and synthesis by F1-ATPase may be ascertained by detailed studies of this group of enzymes.     

Importance of conserved N-domain residues Thr441, Glu442, Lys515, Arg560, and Leu562 of sarcoplasmic reticulum Ca2+-ATPase for MgATP binding and subsequent catalytic steps. Plasticity of the nucleotide-binding site

Nine single mutations were introduced to amino acid residues Thr441, Glu442, Lys515, Arg560, Cys561, and Leu562 located in the nucleotide-binding domain of sarcoplasmic reticulum Ca2+-ATPase, and the functional consequences were studied in a direct nucleotide binding assay, as well as by steady-state and transient kinetic measurements of the overall and partial reactions of the transport cycle. Some partial reaction steps were also examined in mutants with alterations to Phe487, Arg489, and Lys492. The results implicate all these residues, except Cys561, in high affinity nucleotide binding at the substrate site. Mutations Thr441 --> Ala, Glu442 --> Ala, and Leu562 --> Phe were more detrimental to MgATP binding than to ATP binding, thus pointing to a role for these residues in the binding of Mg2+ or to a difference between the interactions with MgATP and ATP. Subsequent catalytic steps were also selectively affected by the mutations, showing the involvement of the nucleotide-binding domain in these reactions. Mutation of Arg560 inhibited phosphoryl transfer but enhanced the E1PCa2 --> E2P conformational transition, whereas mutations Thr441 --> Ala, Glu442 --> Ala, Lys492 --> Leu, and Lys515 --> Ala inhibited the E1PCa2 --> E2P transition. Hydrolysis of the E2P phosphoenzyme intermediate was enhanced in Glu442 --> Ala, Lys492 --> Leu, Lys515 --> Ala, and Arg560 --> Glu. None of the mutations affected the low affinity activation by nucleotide of the phosphoenzyme-processing steps, indicating that modulatory nucleotide interacts differently from substrate nucleotide. Mutation Glu442 --> Ala greatly enhanced reaction of Lys515 with fluorescein isothiocyanate, indicating that the two residues form a salt link in the native protein.     

Eight amino acids form the ATP recognition site of Na(+)/K(+)-ATPase

Point mutations of a part of the H(4)-H(5) loop (Leu(354)-Ile(604)) of Na(+)/K(+)-ATPase have been used to study the ATP and TNP-ATP binding affinities. Besides the previously reported amino acid residues Lys(480), Lys(501), Gly(502), and Cys(549), we have found four more amino acid residues, viz., Glu(446), Phe(475), Gln(482), and Phe(548), completing the ATP-binding pocket of Na(+)/K(+)-ATPase. Moreover, mutation of Arg(423) has also resulted in a large decrease in the extent of ATP binding. This residue, localized outside the binding pocket, seems to play a key role in supporting the proper structure and shape of the binding site, probably due to formation of a hydrogen bond with Glu(472). On the other hand, only some minor effects were caused by mutations of Ile(417), Asn(422), Ser(445), and Glu(505).     

The defective proton-ATPase of uncD mutants of Escherichia coli. Identification by DNA sequencing of residues in the beta-subunit which are essential for catalysis or normal assembly

Six mutant uncD alleles, affecting essential residues of the beta-subunit of Escherichia coli proton-ATPase, have been identified by intragenic complementation mapping, cloning, and DNA sequencing. Five of the mutations impair catalysis but do not cause structural perturbation of F1-ATPase. The amino acid substitutions found were as follows: uncD412, Gly-142----Ser; uncD430 and uncD431, both Arg-246----Cys; uncD478, Ser-174----Phe; and uncD484, Met-209----Ile. Kinetic characteristics of each corresponding mutant F1-ATPase are described or reviewed. In each case, the major determinant of impaired catalysis appears to be an attenuation of positive catalytic site cooperativity. Additionally, each mutation affects intrinsic properties of the catalytic site, including affinity for ATP, the ratio between unisite-bound substrate and products, and the rate of release of product inorganic phosphate under unisite ATP hydrolysis conditions. These effects are discussed in terms of a structural model of the catalytic nucleotide-binding domain of beta-subunit proposed recently (Duncan, T.M., Parsonage, D., and Senior, A.E. (1986) FEBS Lett. 208, 1-6). Each of the mutations lies within that domain. The uncD409 allele abolishes normal assembly of F1-ATPase. The amino acid substitution is Gly-214----Arg, which is suggested to affect a beta-turn connecting a beta-strand and an alpha-helix in the predicted nucleotide-binding domain of the beta-subunit.     

Electrostatic interactions play a significant role in the affinity of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase for Mn

Phosphoenolpyruvate (PEP) carboxykinases catalyse the reversible formation of oxaloacetate (OAA) and ATP (or GTP) from PEP, ADP (or GDP) and CO₂. They are activated by Mn²⁺, a metal ion that coordinates to the protein through the ?-amino group of a lysine residue, the N_?-2-imidazole of a histidine residue, and the carboxylate from an aspartic acid residue. Neutrality in the ?-amino group of Lys213 of Saccharomyces cerevisiae PEP carboxykinase is expected to be favoured by the vicinity of ionised Lys212. Glu272 and Glu284, located close to Lys212, should, in turn, electrostatically stabilise its positive charge and hence assist in keeping the ?-amino group of Lys213 in a neutral state. The mutations Glu272Gln, Glu284Gln, and Lys212Met increased the activation constant for Mn²⁺ in the main reaction of the enzyme up to seven-fold. The control mutation Lys213Gln increased this constant by ten-fold, as opposed to control mutation Lys212Arg, which did not affect the Mn²⁺ affinity of the enzyme. These observations indicate a role for Glu272, Glu284, and Lys212 in assisting Lys213 to properly bind Mn²⁺. In an unexpected result, the mutations Glu284Gln, Lys212Met and Lys213Gln changed the nucleotide-independent OAA decarboxylase activity of S. cerevisiae PEP carboxykinase into an ADP-requiring activity, implying an effect on the OAA binding characteristics of PEP carboxykinase.     

Importance of Glu(282) in transmembrane segment M3 of the Na(+),K(+)-ATPase for control of cation interaction and conformational changes

Glu(282) located in the NH(2)-terminal part of transmembrane helix M3 of the Na(+),K(+)-ATPase was replaced by alanine, glycine, leucine, lysine, aspartate, or glutamine, and the effects of the mutations on the overall and partial reactions of the enzyme were analyzed. The mutations affected at least 3 important functions of the Na(+),K(+)-ATPase: (i) the conformational transitions between E(1) and E(2) forms of dephospho- and phosphoenzyme, (ii) Na(+) binding at the cytoplasmically facing sites of E(1), and (iii) long-range interaction controlling dephosphorylation. In mutants Glu(282) --> Lys and Glu(282) --> Asp, the E(1) form was favored during ATP hydrolysis, whereas the E(2) form was favored in Glu(282) --> Ala and Glu(282) --> Gly. Regardless of the change of conformational equilibrium, all the mutants displayed a reduced apparent affinity for Na(+), at least 3-fold for Glu(282) --> Lys and Glu(282) --> Asp, suggesting a direct effect on the Na(+) binding properties of E(1). Glu(282) --> Ala and Glu(282) --> Gly exhibited an extraordinary high rate of ATP hydrolysis in the mere presence of Na(+) without K(+) ("Na(+)-ATPase activity"), because of an increased rate of dephosphorylation of E(2)P. These results are in accordance with the hypothesis that Glu(282) is involved in the communication between the cation binding pocket and the catalytic site and in control of the cytoplasmic entry pathway for Na(+).     

E. coli F1-ATPase: site-directed mutagenesis of the beta-subunit

Residues beta Glu-181 and beta Glu-192 of E. coli F1-ATPase (the DCCD-reactive residues) were mutated to Gln. Purified beta Gln-181 F1 showed 7-fold impairment of 'unisite' Pi formation from ATP and a large decrease in affinity for ATP. Thus the beta-181 carboxyl group in normal F1 significantly contributes to catalytic site properties. Also, positive catalytic site cooperativity was attenuated from 5 X 10(4)- to 548-fold in beta Gln-181 F1. In contrast, purified beta Gln-192 F1 showed only 6-fold reduction in 'multisite' ATPase activity. Residues beta Gly-149 and beta Gly-154 were mutated to Ile singly and in combination. These mutations, affecting residues which are strongly conserved in nucleotide-binding proteins, were chosen to hinder conformational motion in a putative 'flexible loop' in beta-subunit. Impairment of purified F1-ATPase ranged from 5 to 61%, with the double mutant F1 less impaired than either single mutant. F1 preparations containing beta Ile-154 showed 2-fold activation after release from membranes, suggesting association with F0 restrained turnover on F1 in these mutants.     

The Walker B motif of the second nucleotide-binding domain (NBD2) of CFTR plays a key role in ATPase activity by the NBD1-NBD2 heterodimer

CFTR (cystic fibrosis transmembrane conductance regulator), a member of the ABC (ATP-binding cassette) superfamily of membrane proteins, possesses two NBDs (nucleotide-binding domains) in addition to two MSDs (membrane spanning domains) and the regulatory 'R' domain. The two NBDs of CFTR have been modelled as a heterodimer, stabilized by ATP binding at two sites in the NBD interface. It has been suggested that ATP hydrolysis occurs at only one of these sites as the putative catalytic base is only conserved in NBD2 of CFTR (Glu1371), but not in NBD1 where the corresponding residue is a serine, Ser573. Previously, we showed that fragments of CFTR corresponding to NBD1 and NBD2 can be purified and co-reconstituted to form a heterodimer capable of ATPase activity. In the present study, we show that the two NBD fragments form a complex in vivo, supporting the utility of this model system to evaluate the role of Glu1371 in ATP binding and hydrolysis. The present studies revealed that a mutant NBD2 (E1371Q) retains wild-type nucleotide binding affinity of NBD2. On the other hand, this substitution abolished the ATPase activity formed by the co-purified complex. Interestingly, introduction of a glutamate residue in place of the non-conserved Ser573 in NBD1 did not confer additional ATPase activity by the heterodimer, implicating a vital role for multiple residues in formation of the catalytic site. These findings provide the first biochemical evidence suggesting that the Walker B residue: Glu1371, plays a primary role in the ATPase activity conferred by the NBD1-NBD2 heterodimer.     

Binding of the transition state analog MgADP-fluoroaluminate to F1-ATPase

Escherichia coli F1-ATPase from mutant betaY331W was potently inhibited by fluoroaluminate plus MgADP but not by MgADP alone. beta-Trp-331 fluorescence was used to measure MgADP binding to catalytic sites. Fluoroaluminate induced a very large increase in MgADP binding affinity at catalytic site one, a smaller increase at site two, and no effect at site three. Mutation of either of the critical catalytic site residues beta-Lys-155 or beta-Glu-181 to Gln abolished the effects of fluoroaluminate on MgADP binding. The results indicate that the MgADP-fluoroaluminate complex is a transition state analog and independently demonstrate that residues beta-Lys-155 and (particularly) beta-Glu-181 are important for generation and stabilization of the catalytic transition state. Dicyclohexylcarbodiimide-inhibited enzyme, with 1% residual steady-state ATPase, showed normal transition state formation as judged by fluoroaluminate-induced MgADP binding affinity changes, consistent with a proposed mechanism by which dicyclohexylcarbodiimide prevents a conformational interaction between catalytic sites but does not affect the catalytic step per se. The fluorescence technique should prove valuable for future transition state studies of F1-ATPase.     

Mutations in the beta-subunit Thr(159) and Glu(184) of the Rhodospirillum rubrum F(0)F(1) ATP synthase reveal differences in ligands for the coupled Mg(2+)- and decoupled Ca(2+)-dependent F(0)F(1) activities

In the crystal structure of the mitochondrial F(1)-ATPase, the beta-Thr(163) residue was identified as a ligand to Mg(2+) and the beta-Glu(188) as directly involved in catalysis. We replaced the equivalent beta-Thr(159) of the chromatophore F(0)F(1) ATP synthase of Rhodospirillum rubrum with Ser, Ala, or Val and the Glu(184) with Gln or Lys. The mutant beta subunits were isolated and tested for their capacity to assemble into a beta-less chromatophore F(0)F(1) and restore its lost activities. All of them were found to bind into the beta-less enzyme with the same efficiency as the wild type beta subunit, but only the beta-Thr(159) --> Ser mutant restored the activity of the assembled enzyme. These results indicate that both Thr(159) and Glu(184) are not required for assembly and that Glu(184) is indeed essential for all the membrane-bound chromatophore F(0)F(1) activities. A detailed comparison between the wild type and the beta-Thr(159) --> Ser mutant revealed a rather surprising difference. Although this mutant restored the wild type levels and all specific properties of this F(0)F(1) proton-coupled ATP synthesis as well as Mg- and Mn-dependent ATP hydrolysis, it did not restore at all the proton-decoupled CaATPase activity. This clear difference between the ligands for Mg(2+) and Mn(2+), where threonine can be replaced by serine, and Ca(2+), where only threonine is active, suggests that the beta-subunit catalytic site has different conformational states when occupied by Ca(2+) as compared with Mg(2+). These different states might result in different interactions between the beta and gamma subunits, which are involved in linking F(1) catalysis with F(0) proton-translocation and can thus explain the complete absence of Ca-dependent proton-coupled F(0)F(1) catalytic activity.     

Functional consequences of alterations to amino acids located in the hinge domain of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis of the sarcoplasmic reticulum Ca(2+)-ATPase was used to investigate the functional roles of 18 amino acid residues located at or near the "hinge-domain," a highly conserved region of the cation-transporting ATPases. Mutation of Lys684 to arginine, alanine, histidine, and glutamine resulted in complete loss of calcium transport function and ATPase activity. For the Lys684----Ala, histidine, and glutamine mutants, this coincided with a loss of the ability to form a phosphorylated intermediate from ATP or Pi. The Lys684----Arg mutant retained the ability to phorphorylate from ATP with normal apparent affinity, demonstrating the importance of the positive charge. On the other hand, no phosphorylation was observed with Pi as substrate in this mutant. Examination of the partial reactions after phosphorylation from ATP in the Lys684----Arg mutant demonstrated a reduction of the rate of transformation of the ADP-sensitive phosphoenzyme intermediate (E1P) to the ADP-insensitive phosphoenzyme intermediate (E2P), which could account for the loss of transport function. Once accumulated, the E2P intermediate was able to decompose rapidly in the presence of K+ at neutral pH. These results may be interpreted in terms of a preferential destabilization of protein phosphate interactions in the E2P form of this mutant. The Asp703----Ala and Asn-Asp707----Ala-Ala mutants were completely inactive and unable to form phosphoenzyme intermediates from ATP or Pi. In these mutants as well as in the Lys684----Ala mutant, nucleotides were found to protect with normal affinity against intramolecular cross-linking induced with glutaraldehyde, indicating that the nucleotide binding site was intact. Mutation of Glu646, Glu647, Asp659, Asp660, Glu689, Asp695, Glu696, Glu715, and Glu732 to alanine did not affect the maximum rates of calcium transport and ATP hydrolysis or the apparent affinities for calcium and ATP. Mutation of the 2 highly conserved proline residues, Pro681 and Pro709, as well as Lys728, to alanine resulted in partially inhibited Ca(2+)-ATPase enzymes with retention of the ability to form a phosphoenzyme intermediate from ATP or Pi and with normal apparent affinities for ATP and calcium. The proline mutants retained the biphasic ATP concentration dependence of ATPase activity, characteristic of the wild-type, and therefore the partial inhibition of turnover could not be ascribed to a disruption of the low affinity modulatory ATP site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of a mutation in Escherichia coli F1-ATPase beta-subunit conferring resistance to aurovertin

A mutation conferring aurovertin resistance on Escherichia coli F1-ATPase was identified as R398----H in the F1 beta-subunit. Beta-subunit from the mutant does not bind aurovertin; therefore our results suggest the region of sequence around residue beta-398 is involved in aurovertin binding. Since nucleotide and aurovertin binding to isolated beta-subunit are not mutually exclusive, the data further suggest that the beta-subunit catalytic nucleotide-binding domain does not include residue 398. The mutation prevented aurovertin inhibition of ATPase at pH 6 and 8.5, implying charge on the arginine side-chain is not a major determinant of aurovertin binding or that the pK of R398 is shifted due to a peculiar environment. The equivalent residue is usually arginine in F1 beta-subunits of different species; notably in the aurovertin-insensitive thermophilic bacterium PS3 F1-ATPase, this residue is phenylalanine.     

Contribution of active site residues to the activity and thermal stability of ribonuclease Sa

We have used site-specific mutagenesis to study the contribution of Glu 74 and the active site residues Gln 38, Glu 41, Glu 54, Arg 65, and His 85 to the catalytic activity and thermal stability of ribonuclease Sa. The activity of Gln38Ala is lowered by one order of magnitude, which confirms the involvement of this residue in substrate binding. In contrast, Glu41Lys had no effect on the ribonuclease Sa activity. This is surprising, because the hydrogen bond between the guanosine N1 atom and the side chain of Glu 41 is thought to be important for the guanine specificity in related ribonucleases. The activities of Glu54Gln and Arg65Ala are both lowered about 1000-fold, and His85Gln is totally inactive, confirming the importance of these residues to the catalytic function of ribonuclease Sa. In Glu74Lys, k(cat) is reduced sixfold despite the fact that Glu 74 is over 15 A from the active site. The pH dependence of k(cat)/K(M) is very similar for Glu74Lys and wild-type RNase Sa, suggesting that this is not due to a change in the pK values of the groups involved in catalysis. Compared to wild-type RNase Sa, the stabilities of Gln38Ala and Glu74Lys are increased, the stabilities of Glu41Lys, Glu54Gln, and Arg65Ala are decreased and the stability of His85Gln is unchanged. Thus, the active site residues in the ribonuclease Sa make different contributions to the stability.     

Experimental and computational investigations of Ser10 and Lys13 in the binding and cleavage of DNA substrates by Escherichia coli DNA topoisomerase I

Ser10 and Lys13 found near the active site tyrosine of Escherichia coli DNA topoisomerase I are conserved among the type IA topoisomerases. Site-directed mutagenesis of these two residues to Ala reduced the relaxation and DNA cleavage activity, with a more severe effect from the Lys13 mutation. Changing Ser10 to Thr or Lys13 to Arg also resulted in loss of DNA cleavage and relaxation activity of the enzyme. In simulations of the open form of the topoisomerase–DNA complex, Lys13 interacts directly with Glu9 (proposed to be important in the catalytic mechanism). This interaction is removed in the K13A mutant, suggesting the importance of lysine as either a proton donor or a stabilizing cation during strand cleavage, while the Lys to Arg mutation significantly distorts catalytic residues. Ser10 forms a direct hydrogen bond with a phosphate group near the active site and is involved in direct binding of the DNA substrate; this interaction is disturbed in the S10A and S10T mutants. This combination of a lysine and a serine residue conserved in the active site of type IA topoisomerases may be required for correct positioning of the scissile phosphate and coordination of catalytic residues relative to each other so that DNA cleavage and subsequent strand passage can take place.     

Lys300 plays a major role in the catalytic mechanism of maize polyamine oxidase

Maize polyamine oxidase (MPAO) is a flavin adenine dinucleotide (FAD)-dependent enzyme that catalyses the oxidation of spermine and spermidine at the secondary amino groups. The structure of MPAO indicates a 30-A long U-shaped tunnel that forms the catalytic site, with residues Glu62 and Glu170 located close to the enzyme-bound FAD and residue Tyr298 in close proximity to Lys300, which in turn is hydrogen-bonded to the flavin N(5) atom via a water molecule (HOH309). To provide insight into the role of these residues in the catalytic mechanism of FAD reduction, we have performed steady-state and stopped-flow studies with wild-type, Glu62Gln, Glu170Gln, Tyr298Phe, and Lys300Met MPAO enzymes. We show that the steady-state enzyme activity is governed by an ionisable group with a macroscopic pK(a) of approximately 5.8. Kinetic analysis of the Glu62Gln, Glu170Gln, and Tyr298Phe MPAO enzymes have indicated (i) only small perturbations in catalytic activity as a result of mutation and (ii) steady-state pH profiles essentially unaltered when compared to the wild-type enzyme, suggesting that these residues do not play a critical role in the reaction mechanism. These kinetic observations are consistent with computational calculations that suggest that Glu62 and Glu170 are protonated over the pH range accessible to kinetic studies. Substitution of Lys300 with Met in MPAO resulted in a 1400-fold decrease in the rate of flavin reduction and a 160-fold decrease in the equilibrium dissociation constant for the Lys300Met-spermidine complex, consistent with a major role for this residue in the mechanism of substrate oxidation. A sizable solvent isotope effect (SIE = 5) accompanies FAD reduction in the wild-type enzyme and steady-state turnover (SIE = 2.3) of MPAO, consistent with the reductive half-reaction of MPAO making a major contribution to rate limitation in steady-state turnover. Studies using the enzyme-monitored turnover method indicate that oxidized FAD is the prominent form during steady-state turnover, consistent with the reductive half-reaction being rate-limiting. Our studies indicate the importance of Lys300 and probable importance of HOH309 to the mechanism of flavin reduction in MPAO. Possible roles for Lys300 and water in the mechanism of flavin reduction are discussed.     

Mutagenesis of the yeast plasma membrane H(+)-ATPase. A novel expression system.

The plasma membrane H(+)-ATPase of the yeast Saccharomyces cerevisiae is a prototype for the mutagenic analysis of structure-function relationships in P-type cation pumps. Because a functional H+ pump is required for viability, wild-type ATPase must be maintained in the plasma membrane for normal cell growth. Our expression strategy involves a rapid switch in expression from the wild-type ATPase gene to a mutant allele followed by entrapment of the newly synthesized mutant enzyme in an internal, secretory vesicle pool. The isolated vesicles prove to be ideally suited for the study of the catalytic and transport properties of the ATPase. Work to date has focused on conserved residues in the vicinity of the aspartyl-phosphate reaction intermediate. Substitution of Asp378 with Glu, Ser, or Asn and of Lys379 with Gln prevents normal biogenesis of the mutant ATPase. The more conservative Lys379----Arg mutation was tolerated, but with a sixfold loss of activity and substantial alterations in Km for ATP and Ki for vanadate. Nonconservative replacement of Thr380, Thr382, or Thr384 with Ala led to inactive enzyme, whereas the conservative change to Ser caused a two to threefold reduction in ATP hydrolysis and H(+)-pumping. Taken together, the results are consistent with an essential role for these invariant residues in phosphate-binding and ATP hydrolysis.     

Mutational analysis of the K+-competitive inhibitor site of gastric H,K-ATPase.

The gastric H,K-ATPase is inhibited selectively and K(+)-competitively from its luminal surface by protonated imidazo[1,2alpha]pyridines (e.g., SCH28080). Identification of the amino acids in the membrane domain that affect SCH28080 inhibition should provide a template for modeling a luminally directed vestibule in this enzyme, based on the crystal structure of the sr Ca-ATPase. Five conserved carboxylic residues, Glu343, Glu795, Glu820, Asp824, Glu936, and unique Lys791 in the H,K-ATPase were mutated, and the effects of mutations on the K(i) for SCH28080, V(max), and K(m,app)[NH(4)(+)] were measured. A kinetic analysis of the ATP hydrolysis data indicated that all of these residues significantly affect the interaction of NH(4)(+) ions with the protein but only three of them, Glu795, Glu936, and Lys791, greatly affected SCH28080 inhibition. A Glu795Asp mutation increased the K(i) from 64 +/- 11 to 700 +/- 110 nM. Since, however, the mutation Glu795Gln did not change the K(i) (86 +/- 31 nM), this site has a significant spatial effect on inhibitor kinetics. A Glu936Asp mutation resulted in noncompetitive kinetics while Gln substitution had no effect either on inhibitor affinity or on the nature of the kinetics, suggesting that the length of the Glu936 side chain is critical for the exclusive binding of the ion and SCH28080. Mutation of Lys791 to Ser, the residue present in the SCH28080-insensitive Na,K-ATPase, resulted in a 20-fold decrease in SCH28080 affinity, suggesting an important role of this residue in SCH28080 selectivity of the H,K-ATPase versus Na,K-ATPase. Mutations of Asp824, Glu343, and Glu820 increased the K(i) 2-3-fold, implying a relatively minor role for these residues in SCH28080 inhibition. It appears that the imidazopyridine moiety of SCH28080 in the protonated state interacts with residues near the negatively charged residues of the empty ion site from the luminal side (TM4, -5, -6, and -8) while the hydrophobic phenyl ring interacts with TM1 or TM2 (the latter conclusion based on previous data from photoaffinity labeling). The integrity of the SCH28080 binding site depends on the presence of Lys791, Glu936, and Glu795 in H,K-ATPase. A computer-generated model of this region illustrates the possible involvement of the residues previously shown to affect SCH28080 inhibition (Cys813, Ile816, Thr823, Met334, Val337) and may predict other residues that line the SCH28080 binding vestibule in the E(2) conformation of the pump.     

The role of beta-Arg-182, an essential catalytic site residue in Escherichia coli F1-ATPase.

Beta-Arg-182 in Escherichia coli F1-ATPase (beta-Arg-189 in bovine mitochondrial F1) is a residue which lies close to catalytic site bound nucleotide (Abrahams et al. (1994) Nature 370, 621-628). Here we investigated the role of this residue by characterizing two mutants, betaR182Q and betaR182K. Oxidative phosphorylation and steady-state ATPase activity of purified F1 were severely impaired by both mutations. Catalytic site nucleotide-binding parameters were measured using the fluorescence quench of beta-Trp-331 that occurred upon nucleotide binding to purified F1 from betaR182Q/betaY331W and betaR182K/betaY331W double mutants. It was found that (a) beta-Arg-182 interacts with the gamma-phosphate of MgATP, particularly at catalytic sites 1 and 2, (b) beta-Arg-182 has no functional interaction with the beta-phosphate of MgADP or with the magnesium of the magnesium-nucleotide complex in the catalytic sites, and (c) beta-Arg-182 is directly involved in the stabilization of the catalytic transition state. In these features the role of beta-Arg-182 resembles that of another positively charged residue in the catalytic site, the conserved lysine of the Walker A motif, beta-Lys-155. A further role of beta-Arg-182 is suggested, namely involvement in conformational change at the catalytic site beta-alpha subunit interface that is required for multisite catalysis.     

Molecular model and ATPase activity of carboxyl-terminal nucleotide binding domain from human P-glycoprotein

ATP binding and hydrolysis are required for P-glycoprotein mediated multidrug resistance. To investigate the molecular mechanism involved in ATP binding and hydrolysis, a three-dimensional model of the carboxyl-terminal nucleotide binding domain (NBD2) was built by homology modeling. Modeling revealed the human P-glycoprotein ATP-binding site and the possible role of conserved Gln1118 residue. Recombinant NBD2 was overexpressed in Escherichia coli and the conserved Gln1118 residue was mutated to an alanine residue. The Vmax for ATP hydrolysis by the mutant NBD2 was approximately 56% of the Vmax of wild-type NBD2. But both proteins displayed similar affinity for ATP, with Km of 479 and 466 microM for mutant and wild-type NBD2, respectively. These results suggest that the possible role of Gln1118 is as an activating residue for ATP hydrolysis. The molecular model also provided structural information about the interactions between NBD2 and the chemosensitizer quercetin. The complex indicated that quercetin was tightly bound to the ATP-binding site and competed for binding. The three-dimensional model of NBD2 can be used to both guide enzymological studies and provide a theoretical basis for the design of potential multidrug resistance reversers.