Rat liver ATP synthase. Relationship of the unique substructure of the F1 moiety to its nucleotide binding properties, enzymatic states, and crystalline form

Nitration of tyrosine residues 368 and 345 in the β-subunit elicits FoF1-ATPase activity loss

Tyrosine nitration is a covalent post-translational protein modification associated with various diseases related to oxidative/nitrative stress. A role for nitration of tyrosine in protein inactivation has been proposed; however, few studies have established a direct link between this modification and loss of protein function. In the present study, we determined the effect of nitration of Tyr345 and Tyr368 in the β-subunit of the F1-ATPase using site-directed mutagenesis. Nitration of the β-subunit, achieved by using TNM (tetranitromethane), resulted in 66% ATPase activity loss. This treatment resulted in the modification of several asparagine, methionine and tyrosine residues. However, nitrated tyrosine and ATPase inactivation were decreased in reconstituted F1 with Y368F (54%), Y345F (28%) and Y345,368F (1%) β-subunits, indicating a clear link between nitration at these positions and activity loss, regardless of the presence of other modifications. Kinetic studies indicated that an F1 with one nitrated tyrosine residue (Tyr345 or Tyr368) or two Tyr368 residues was sufficient to grant inactivation. Tyr368 was four times more reactive to nitration due to its lower pKa. Inactivation was attributed mainly to steric hindrance caused by adding a bulky residue more than the presence of a charged group or change in the phenolic pKa due to the introduction of a nitro group. Nitration at this residue would be more relevant under conditions of low nitrative stress. Conversely, at high nitrative stress conditions, both tyrosine residues would contribute equally to ATPase inactivation.

Sodium arsenite induces heat shock protein 70 expression and protects against secretagogue-induced trypsinogen and NF-kappaB activation

Heat shock proteins (HSPs), induced by a variety of stresses, are known to protect against cellular injury. Recent studies have demonstrated that prior beta-adrenergic stimulation as well as thermal or culture stress induces HSP70 expression and protects against cerulein-induced pancreatitis. The goal of our current studies was to determine whether or not a non-thermal, chemical stressor like sodium arsenite also upregulates HSP70 expression in the pancreas and prevents secretagogue-induced trypsinogen and NF-kappaB activation. We examined the effects of sodium arsenite preadministration on the parameters of cerulein-induced pancreatitis in rats and then monitored the effects of preincubating pancreatic acini with sodium arsenite in vitro. Our results showed that sodium arsenite pretreatment induced HSP70 expression both in vitro and in vivo and significantly ameliorated the severity of cerulein-induced pancreatitis, as evidenced by the markedly reduced degree of hyperamylasemia, pancreatic edema, and acinar cell necrosis. Sodium arsenite pretreatment not only inhibited trypsinogen activation and the subcellular redistribution of cathepsin B, but also prevented NF-kappaB translocation to the nucleus by inhibiting the IkappaBalpha degradation both in vivo and in vitro. We also examined the effect of sodium arsenite pretreatment in a more severe model of pancreatitis induced by L-arginine and found a similarly protective effect. Based on our observations we conclude that, like thermal stress, chemical stressors such as sodium arsenite also induce HSP70 expression in the pancreas and protect against acute pancreatitis. Thus, non-thermal pharmacologically induced stress can help prevent or treat pancreatitis.

The nucleotide-independent Fe(III)-binding site is located on β subunit of the mitochondrial F1-ATPase

Upon separation of a crude preparation of beta subunit ("beta fraction") from mitochondrial F(1)-ATPase containing one equivalent of Fe(III) in the nucleotide-independent site (1Fe(III)-loaded MF(1)), Fe(III) is almost completely recovered. CD spectra show that "beta fraction" maintains the structural changes induced by Fe(III) in the whole enzyme. In accordance, EPR reveals that the Fe(III) site geometry is conserved in "beta fraction." Moreover, the EPR spectra of 1Fe(III)-loaded MF(1) and its "beta fraction" undergo similar changes of the line-shape upon Pi binding at the catalytic site, indicating that the Pi and Fe(III) are proximal on beta. Highly purified beta in nucleotide-free form binds 1mol of Fe(III)/mol of protein. MF(1) "freezed" by inhibitors with two beta in closed conformation and one beta in open or half-closed conformation binds 1mol of Fe(III)/mol of enzyme. Therefore, the Fe(III) site location in the unique beta subunit not adopting the closed conformation is proposed.

Serine protease inhibitor causes F-actin redistribution and inhibition of calcium-mediated secretion in pancreatic acini

BACKGROUND & AIMS

The present study was undertaken to evaluate the role of serine proteases in regulating digestive enzyme secretion in pancreatic acinar cells.

METHODS

Isolated acini were stimulated by various secretagogues in the presence or absence of cell-permeant serine protease inhibitors 4-(2-aminoethyl)-benzenesulfonyl fluoride and N(alpha)-p-tosyl-L-phenylalanine chloromethyl ketone. F-actin distribution was studied after staining with rhodamine phalloidin.

RESULTS

Both cell-permeant serine protease inhibitors blocked amylase secretion in response to secretagogues that use calcium as a second messenger (e.g., cerulein, carbamylcholine, and bombesin) but not to those that use adenosine 3',5'-cyclic monophosphate (cAMP) as a second messenger (e.g., secretin and vasoactive intestinal polypeptide). Incubation of the acini with these inhibitors also resulted in a dramatic redistribution of the F-actin cytoskeleton. This redistribution was energy dependent. Similar redistribution of F-actin from the apical to the basolateral region was also observed when acini were incubated with a supramaximally stimulating concentration of cerulein, which is known to inhibit secretion.

CONCLUSIONS

These results suggest that a serine protease activity is essential for maintaining the normal apical F-actin distribution; its inhibition redistributes F-actin from the apical to the basolateral region and blocks secretion induced by secretagogues that act via calcium. cAMP reverses the F-actin redistribution and hence cAMP-mediated secretion is not affected.

Mitochondrial F(0)F(1) ATP synthase. Subunit regions on the F1 motor shielded by F(0), Functional significance, and evidence for an involvement of the unique F(0) subunit F(6)

Studies reported here were undertaken to gain greater molecular insight into the complex structure of mitochondrial ATP synthase (F(0)F(1)) and its relationship to the enzyme's function and motor-related properties. Significantly, these studies, which employed N-terminal sequence, mass spectral, proteolytic, immunological, and functional analyses, led to the following novel findings. First, at the top of F(1) within F(0)F(1), all six N-terminal regions derived from alpha + beta subunits are shielded, indicating that one or more F(0) subunits forms a "cap." Second, at the bottom of F(1) within F(0)F(1), the N-terminal region of the single delta subunit and the C-terminal regions of all three alpha subunits are shielded also by F(0). Third, and in contrast, part of the gamma subunit located at the bottom of F(1) is already shielded in F(1), indicating that there is a preferential propensity for interaction with other F(1) subunits, most likely delta and epsilon. Fourth, and consistent with the first two conclusions above that specific regions at the top and bottom of F(1) are shielded by F(0), further proteolytic shaving of alpha and beta subunits at these locations eliminates the capacity of F(1) to couple a proton gradient to ATP synthesis. Finally, evidence was obtained that the F(0) subunit called "F(6)," unique to animal ATP synthases, is involved in shielding F(1). The significance of the studies reported here, in relation to current views about ATP synthase structure and function in animal mitochondria, is discussed.

Nucleotide and Mg2+ dependency of the thermal denaturation of mitochondrial F1-ATPase

The influence of adenine nucleotides and Mg2+ on the thermal denaturation of mitochondrial F1-ATPase (MF1) was analyzed. Differential scanning calorimetry in combination with ATPase activity experiments revealed the thermal unfolding of MF1 as an irreversible and kinetically controlled process. Three significant elements were analyzed during the thermal denaturation process: the endothermic calorimetric transition, the loss of ATP hydrolysis activity, and the release of tightly bound nucleotides. All three processes occur in the same temperature range, over a wide variety of conditions. The purified F1-ATPase, which contains three tightly bound nucleotides, denatures at a transition temperature (Tm) of 55 degrees C. The nucleotide and Mg2+ content of MF1 strongly influence the thermal denaturation process. First, further binding of nucleotides and/or Mg2+ to MF1 increases the thermal denaturation temperature, whereas the thermal stability of the enzyme is decreased upon removal of the endogenous nucleotides. Second, the stabilizing effect induced by nucleotides is smaller after hydrolysis of ATP (i.e., in the presence of ADP . Mg2+) than under nonhydrolytical conditions (i.e., absence of Mg2+ or using the nonhydrolyzable analog 5'-adenylyl-imidodiphosphate). Third, whereas the thermal denaturation of MF1 fully loaded with nucleotides follows an apparent two-state kinetic process, denaturation of MF1 with a low nucleotide content follows more complex kinetics. Nucleotide content is therefore an important factor in determining the thermal stability of the MF1 complex, probably by strengthening existing intersubunit interactions or by establishing new ones.

The 2.8-A structure of rat liver F1-ATPase: configuration of a critical intermediate in ATP synthesis/hydrolysis

During mitochondrial ATP synthesis, F1-ATPase-the portion of the ATP synthase that contains the catalytic and regulatory nucleotide binding sites-undergoes a series of concerted conformational changes that couple proton translocation to the synthesis of the high levels of ATP required for cellular function. In the structure of the rat liver F1-ATPase, determined to 2.8-A resolution in the presence of physiological concentrations of nucleotides, all three beta subunits contain bound nucleotide and adopt similar conformations. This structure provides the missing configuration of F1 necessary to define all intermediates in the reaction pathway. Incorporation of this structure suggests a mechanism of ATP synthesis/hydrolysis in which configurations of the enzyme with three bound nucleotides play an essential role.

Subunit 9 of the mitochondrial ATP synthase of Trypanosoma brucei is nuclearly encoded and developmentally regulated

We have previously shown that the mitochondrial ATP synthase is developmentally regulated through the life cycle of Trypanosoma brucei. The mechanism of this regulation is as yet unknown. We are currently examining regulation of expression of several key subunits of the ATP synthase to investigate this mechanism. In the work presented here, we have cloned, sequenced, and confirmed the identity of the ATPase subunit 9 homologue from T. brucei. The ATPase subunit 9 gene that we have identified from T. brucei has between 40 and 600% identity with subunit 9 from a variety of organisms. This gene possesses a putative mitochondrial import sequence at the N terminus of the encoded protein sequence. The protein expressed from this gene by in vitro transcription/translation comigrates with native protein isolated from inner mitochondrial membrane vesicles from T. brucei. We have shown that the cDNA identifies a copy of this gene in the nuclear genome, but does not identify a similar gene in kinetoplast DNA (kDNA) prepared from T. brucei. This gene does not show homology to any published sequence data from maxicircle DNA or edited maxicircle derived sequences. Steady state transcripts of a single size have been identified by Northern analysis and demonstrate significant developmental regulation through the T. brucei life cycle. Northern analysis and quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) results show that the transcript is 10-14-fold higher in procyclic form than in early and late bloodstream forms.

Intramolecular rotation in ATP synthase: dynamic and crystallographic studies on thermophilic F1

A single molecule of ATP synthase (F0F1) is by itself a rotary motor, the smallest ever found, and this biomotor is driven by an electrochemical potential of H+ (delta microH+). F0F1 is composed of an ion-conducting portion (F0) and a catalytic portion (F1). The major breakthroughs in studies on the mechanochemical coupling have been the direct observation of the rotation of a stable alpha 3 beta 3 gamma complex of thermophilic F1 (TF1), and X-ray crystallography of the alpha 3 beta 3 gamma portion of mitochondrial F1 (MF1) and the alpha 3 beta 3 oligomer of TF1. This review focuses on the dynamics of TF1, demonstrated by a crucial experiment. The torque of the rotation was estimated to be 42 pN.nm from the delta microH+ and frictional force. Important unsolved problems are the crystallography of F0, elastic energy conversion, and the stator and rotor of this biomotor.

Frontiers in research on cystic fibrosis: understanding its molecular and chemical basis and relationship to the pathogenesis of the disease

In recent years a new family of transport proteins called ABC transporters has emerged. One member of this novel family, called CFTR (cystic fibrosis transmembrane conductance regulator), has received special attention because of its association with the disease cystic fibrosis (CF). This is an inherited disorder affecting about 1 in 2000 Caucasians by impairing epithelial ion transport, particularly that of chloride. Death may occur in severe cases because of chronic lung infections, especially by Pseudomonas aeruginosa, which cause a slow decline in pulmonary function. The prospects of ameliorating the symptoms of CF and even curing the disease were greatly heightened in 1989 following the cloning of the CFTR gene and the discovery that the mutation (deltaF508), which causes most cases of CF, is localized within a putative ATP binding/ATP hydrolysis domain. The purpose of this introductory review in this minireview series is to summarize what we and others have learned during the past eight years about the structure and function of the first nucleotide binding domain (NBF1 or NBD1) of the CFTR protein and the effect thereon of disease-causing mutations. The relationship of these new findings to the pathogenesis of CF is also discussed.

Quantification of muscle mitochondrial oxidative phosphorylation enzymes via histochemical staining of blue native polyacrylamide gels

Blue native-polyacrylamide gel electrophoresis is a powerful technique that enables the separation of intact multi-subunit complexes. However, positive identification of particular enzymes generally requires further separation in a second dimension on a denaturing polyacrylamide gel. Histochemical staining is widely used to demonstrate enzyme activities in tissues, including oxidative phosphorylation enzymes. In this report, we demonstrate that the two techniques can be combined to quantify in situ mitochondrial enzymes, separated on nondenaturing polyacrylamide gels. The method gives quantitative results with human skeletal muscle as well as heart that contains higher mitochondrial numbers. Comparison of muscle from patients with oxidative phosphorylation enzyme deficiencies, such as those of two riboflavin-responsive patients, before and after vitamin treatment, gives results in agreement with those obtained by analyzing the activity of the mitochondrial enzymes in muscle homogenates.

Characterization and subunit structure of the ATP synthase of the halophilic archaeon Haloferax volcanii and organization of the ATP synthase genes

The archaeal ATPase of the halophile Haloferax volcanii synthesizes ATP at the expense of a proton gradient, as shown by sensitivity to the uncoupler carboxyl cyanide p-trifluoromethoxyphenylhydrazone, to the ionophore nigericin, and to the proton channel-modifying reagent N,N'-dicyclohexylcarbodiimide. The conditions for an optimally active ATP synthase have been determined. We were able to purify the enzyme complex and to identify the larger subunits with antisera raised against synthetic peptides. To identify additional subunits of this enzyme complex, we cloned and sequenced a gene cluster encoding five hydrophilic subunits of the A1 part of the proton-translocating archaeal ATP synthase. Initiation, termination, and ribosome-binding sequences as well as the result of a single transcript suggest that the ATPase genes are organized in an operon. The calculated molecular masses of the deduced gene products are 22. 0 kDa (subunit D), 38.7 kDa (subunit C), 11.6 kDa (subunit E), 52.0 kDa (subunit B), and 64.5 kDa (subunit A). The described operon contains genes in the order D, C, E, B, and A; it contains no gene for the hydrophobic, so-called proteolipid (subunit c, the proton-conducting subunit of the A0 part). This subunit has been isolated and purified; its molecular mass as deduced by SDS-polyacrylamide gel electrophoresis is 9.7 kDa.

The ATP synthase--a splendid molecular machine

An X-ray structure of the F1 portion of the mitochondrial ATP synthase shows asymmetry and differences in nucleotide binding of the catalytic beta subunits that support the binding change mechanism with an internal rotation of the gamma subunit. Other structural and mutational probes of the F1 and F0 portions of the ATP synthase are reviewed, together with kinetic and other evaluations of catalytic site occupancy and behavior during hydrolysis or synthesis of ATP. Subunit function as related to proton translocation and rotational catalysis is considered. Physical demonstrations of the gamma subunit rotation have been achieved. The findings have implications for other enzymatic catalyses.

ATP synthase. Conditions under which all catalytic sites of the F1 moiety are kinetically equivalent in hydrolyzing ATP

Conditions have been reported under which the F1 moiety of bovine heart ATP synthase catalyzes the hydrolysis of ATP by an apparently cooperative mechanism in which the slow rate of hydrolysis at a single catalytic site (unisite catalysis) is enhanced more than 10(6)-fold when ATP is added in excess to occupy one or both of the other two catalytic sites (multisite catalysis) (Cross, R. L., Grubmeyer, C., and Penefsky, H. S. (1982) J. Biol. Chem. 257, 12101-12105). In the novel studies reported here, and in contrast to the earlier report, we have (a) monitored the kinetics of ATP hydrolysis of F1 by using nucleotide-depleted preparations and a highly sensitive chemiluminescent assay; (b) followed the reaction immediately upon addition of F1 to ATP, rather than after prior incubation with ATP; and (c) used a reaction medium with Pi as the only buffer. The following observations were noted. First, regardless of the source of enzyme, bovine or rat, and catalytic conditions (unisite or multisite), the rates of hydrolysis depend on ATP concentration to the first power. Second, the first order rate constant for ATP hydrolysis remains relatively constant under both unisite and multisite conditions declining only slightly at high ATP concentration. Third, the initial rates of ATP hydrolysis exhibit Michaelis-Menten kinetic behavior with a single Vmax exceeding 100 micromol of ATP hydrolyzed per min/mg of F1 (turnover number = 635 s-1) and a single Km for ATP of about 57 microM. Finally, the reaction is inhibited markedly by low concentrations of ADP. It is concluded that, under the conditions described here, all catalytic sites that participate in the hydrolysis of ATP within the F1 moiety of mitochondrial ATP synthase function in a kinetically equivalent manner.

The coupling of the relative movement of the a and c subunits of the F0 to the conformational changes in the F1-ATPase

F0F1-ATPase structural information gained from X-ray crystallography and electron microscopy has activated interest in a rotational mechanism for the F0F1-ATPase. Because of the subunit stoichiometry and the involvement of both a- and c-subunits in the mechanism of proton movement, it is argued that relative movement must occur between the subunits. Various options for the arrangement and structure of the subunits involved are discussed and a mechanism proposed.

Frontiers in ATP synthase research: understanding the relationship between subunit movements and ATP synthesis

How biological systems make ATP has intrigued many scientists for well over half the 20th century, and because of the importance and complexity of the problem it seems likely to continue to be a source of fascination to both senior and younger investigators well into the 21st century. Scientific battles fought to unravel the vast secrets by which ATP synthases work have been fierce, and great victories have been short-lived, tempered with the realization that more structures are needed, additional subunits remain to be conquered, and that during ATP synthesis, not one, but several subunits may undergo either significant conformational changes, repositioning, or perhaps even physical "rotation" similar to bacterial flagella (1,2). In this introductory article, the author briefly summarizes our current knowledge about the complex substructure of ATP synthases, what we have learned from X-ray crystallography of the F1 unit, and current evidence for subunit movements.

Differences between two tight ADP binding sites of the chloroplast coupling factor 1 and their effects on ATPase activity

Purified chloroplast ATP synthase (CF1) contains 1.2-2 mol of tightly bound ADP/mol of enzyme that resists removal by gel filtration or dialysis. CF1 was depleted of its endogenous nucleotide by treatment with alkaline phosphatase. Tightly bound nucleotide was demonstrated not to have an essential structural role. CF1 depleted of endogenous nucleotide retains its ability to catalyze Ca2+- and Mg2+-dependent ATPase activity and is not more sensitive to cold inactivation than untreated CF1. 2'(3')-O-Trinitrophenyladenosine 5'-diphosphate (TNP-ADP) binds tightly to two sites on nucleotide-depleted CF1, binding to either site at a faster rate than that of exchange of bound nucleotide for medium nucleotide. The nucleotide-depleted enzyme binds about one additional mol of TNP-ADP/mol of CF1, indicating that there is a tight TNP-ADP binding site that does not exchange readily with medium nucleotide. It is MgADP in this nonexchanging site, not the easily exchanging ADP binding site, that is responsible for the MgADP-induced inhibition of the ATPase activity. The rate of exchange of tightly bound ADP from CF1 matches the rate at which the Mg2+ATPase activity of CF1 is activated but is not itself responsible for the activation.

The first nucleotide binding fold of the cystic fibrosis transmembrane conductance regulator can function as an active ATPase

Cystic fibrosis is caused by mutations in the cell membrane protein called CFTR (cystic fibrosis transmembrane conductance regulator) which functions as a regulated Cl- channel. Although it is known that CFTR contains two nucleotide domains, both of which exhibit the capacity to bind ATP, it has not been demonstrated directly whether one or both domains can function as an active ATPase. To address this question, we have studied the first CFTR nucleotide binding fold (NBF1) in fusion with the maltose-binding protein (MBP), which both stabilizes NBF1 and enhances its solubility. Three different ATPase assays conducted on MBP-NBF1 clearly demonstrate its capacity to catalyze the hydrolysis of ATP. Significantly, the mutations K464H and K464L in the Walker A consensus motif of NBF1 markedly impair its catalytic capacity. MBP alone exhibits no ATPase activity and MBP-NBF1 fails to catalyze the release of phosphate from AMP or ADP. The Vmax of ATP hydrolysis (approximately 30 nmol/min/mg of protein) is significant and is markedly inhibited by azide and by the ATP analogs 2'-(3')-O-(2,4,6-trinitrophenyl)-adenosine-5'-triphosphate and adenosine 5'-(beta, gamma-imido)triphosphate. As inherited mutations within NBF1 account for most cases of cystic fibrosis, results reported here are fundamental to our understanding of the molecular basis of the disease.

Asymmetry of Escherichia coli F1-ATPase as a function of the interaction of alpha-beta subunit pairs with the gamma and epsilon subunits

The asymmetry of Escherichia coli F1-ATPase (ECF1) has been explored in chemical modification experiments involving two mutant enzyme preparations. One mutant contains a cysteine (Cys) at position 149 of the beta subunit, along with conversion of a Val to Ala at residue 198 to suppress the deleterious effect of the Cys for Gly at 149 mutation (mutant beta G149C:V198A). The second mutant has these mutations and also Cys residues at positions 381 of beta and 108 of the epsilon subunit (mutant beta G149C:V198A:E381C/epsilon S108C). On CuCl2 treatment of this second mutant, there is cross-linking of one copy of the beta subunit to gamma via the Cys at 381, a second to the epsilon subunit (between beta Cys381 and epsilon Cys108), while the third beta subunit in the ECF1 complex is mostly free (some cross-linking to delta); thereby distinguishing the three beta subunits as beta gamma, beta epsilon, and beta free, respectively. Both mutants have ATPase activities similar to wild-type enzyme. Under all nucleotide conditions, including with essentially nucleotide-free enzyme, the three different beta subunits were found to react differently with N-ethylmaleimide (NEM) which reacts with Cys149, dicyclohexyl carbodiimide (DCCD) which reacts with Glu192, and 7-chloro-4-nitrobenzofurazan (NbfCl) which reacts with Tyr297. Thus, beta gamma reacted with DCCD but not NEM or NbfCl; beta free was reactive with all three reagents; beta epsilon reacted with NEM, but was poorly reactive to DCCD or NbfCl. There was a strong nucleotide dependence of the reaction of Cys149 in beta epsilon (but not in beta free) with NEM, indicative of the important role that the epsilon subunit plays in functioning of the enzyme.