Desoxycorticosterone pivalate-salt treatment leads to non-dipping hypertension in Per1 knockout mice.

AIM: Increasing evidence demonstrates that circadian clock proteins are important regulators of physiological functions including blood pressure. An established risk factor for developing cardiovascular disease is the absence of a blood pressure dip during the inactive period. The goal of the present study was to determine the effects of a high salt diet plus mineralocorticoid on PER1-mediated blood pressure regulation in a salt-resistant, normotensive mouse model, C57BL/6J. METHODS: Blood pressure was measured using radiotelemetry. After control diet, wild-type (WT) and Per1 (KO) knockout mice were given a high salt diet (4% NaCl) and the long-acting mineralocorticoid deoxycorticosterone pivalate. Blood pressure and activity rhythms were analysed to evaluate changes over time. RESULTS: Blood pressure in WT mice was not affected by a high salt diet plus mineralocorticoid. In contrast, Per1 KO mice exhibited significantly increased mean arterial pressure (MAP) in response to a high salt diet plus mineralocorticoid. The inactive/active phase ratio of MAP in WT mice was unchanged by high salt plus mineralocorticoid treatment. Importantly, this treatment caused Per1 KO mice to lose the expected decrease or 'dip' in blood pressure during the inactive compared to the active phase. CONCLUSION: Loss of PER1 increased sensitivity to the high salt plus mineralocorticoid treatment. It also resulted in a non-dipper phenotype in this model of salt-sensitive hypertension and provides a unique model of non-dipping. Together, these data support an important role for the circadian clock protein PER1 in the modulation of blood pressure in a high salt/mineralocorticoid model of hypertension.

Early progress in epigenetic regulation of endothelin pathway genes.

Control of gene transcription is a major regulatory determinant for function of the endothelin pathway. Epigenetic mechanisms act on tissue-specific gene expression during development and in response to physiological stimuli. Most of the limited evidence available on epigenetic regulation of the endothelin pathway focuses on the EDN1 and EDNRB genes. Examination of whole genome databases suggests that both genes are influenced by histone modifications and DNA methylation. This interpretation is supported by studies directed at detecting epigenetic action on the two genes. The clearest illustration of epigenetic factors altering endothelin signalling is DNA methylation-associated EDNRB silencing during tumourigenesis. This review summarizes our current understanding of epigenetic regulation of the endothelin pathway genes. LINKED ARTICLES This article is part of a themed section on Endothelin. To view the other articles in this section visit http://dx.doi.org/10.1111/bph.2013.168.issue-1.

Immunohistochemical localization of H-K-ATPase alpha(2c)-subunit in rabbit kidney.

The rabbit kidney possesses mRNA for the H-K-ATPase alpha(1)-subunit (HKalpha(1)) and two splice variants of the H-K-ATPase alpha(2)-subunit (HKalpha(2)). The purpose of this study was to determine the specific distribution of one of these, the H-K-ATPase alpha(2c)-subunit isoform (HKalpha(2c)), in rabbit kidney by immunohistochemistry. Chicken polyclonal antibodies against a peptide based on the NH(2) terminus of HKalpha(2c) were used to detect HKalpha(2c) immunoreactivity in tissue sections. Immunohistochemical localization of HKalpha(2c) revealed intense apical immunoreactivity in a subpopulation of cells in the connecting segment, cortical collecting duct, and outer medullary collecting duct in both the outer and inner stripe. An additional population of cells exhibited a thin apical band of immunolabel. Immunohistochemical colocalization of HKalpha(2c) with carbonic anhydrase II, the Cl(-)/HCO exchanger AE1, and HKalpha(1) indicated that both type A and type B intercalated cells possessed intense apical HKalpha(2c) immunoreactivity, whereas principal cells and connecting segment cells had only a thin apical band of HKalpha(2c). Labeled cells were evident through the middle third of the inner medullary collecting duct in the majority of animals. Immunolabel was also present in papillary surface epithelial cells, cells in the cortical thick ascending limb of Henle's loop (cTAL), and the macula densa. Thus in the rabbit kidney, apical HKalpha(2c) is present and may contribute to acid secretion or potassium uptake throughout the connecting segment and collecting duct in both type A and type B intercalated cells, principal cells, and connecting segment cells, as well as in cells in papillary surface epithelium, cTAL, and macula densa.

The a subunit ala-217 --> arg substitution affects catalytic activity of F(1)F(0) ATP synthase.

A large number of mutations affecting the F(0) sector of Escherichia coli F(1)F(0) ATP synthase have been constructed and characterized. A subset of the missense mutations resulted in fully assembled enzyme complexes blocked in proton translocation and displaying marked decreases in ATP hydrolysis activity. The catalytic activities of one such mutant enzyme, a(ala-217-->arg), have been determined using both multisite and unisite catalysis conditions. As expected, the V(max) of the a(ala-217-->arg) enzyme was reduced under conditions of saturating substrate concentration. However, the F(0) sector amino acid substitution did not affect nucleotide occupancy of the noncatalytic sites. Moreover, the microscopic rate constants measured using unisite methods yielded no significant differences between the intact wild type F(1)F(0) ATP synthase and the a(ala-217-->arg) mutant enzyme. In general, the values for unisite activities in both preparations were very similar to numbers reported in the literature for E. coli F(1)-ATPase. The results suggest that the a(ala-217-->arg) substitution resulted in a defect in catalytic cooperativity and most likely altered the enzyme by inhibiting the rotational mechanism of F(1)F(0) ATP synthase.

Mutagenic analysis of the F0 stator subunits.

The a and b subunits constitute the stator elements in the F0 sector of F1F0-ATP synthase. Both subunits have been difficult to study by physical means, so most of the information on structure and function relationships in the a and b subunits has been obtained using mutagenesis in combination with biochemical methods. These approaches were used to demonstrate that the a subunit in association with the ring of c subunits houses the proton channel through F1F0-ATP synthase. The map of the amino acids contributing to the proton channel is probably complete. The two b subunits dimerize, forming an extended flexible unit in the peripheral stalk linking the F1 and F0 sectors. The unique characteristics of specific amino acid substitutions affecting the a and b subunits suggested differential effects on rotation during F1F0-ATPase activity.

Lengthening the second stalk of F(1)F(0) ATP synthase in Escherichia coli.

In Escherichia coli F(1)F(0) ATP synthase, the two b subunits dimerize forming the peripheral second stalk linking the membrane F(0) sector to F(1). Previously, we have demonstrated that the enzyme could accommodate relatively large deletions in the b subunits while retaining function (Sorgen, P. L., Caviston, T. L., Perry, R. C., and Cain, B. D. (1998) J. Biol. Chem. 273, 27873-27878). The manipulations of b subunit length have been extended by construction of insertion mutations into the uncF(b) gene adding amino acids to the second stalk. Mutants with insertions of seven amino acids were essentially identical to wild type strains, and mutants with insertions of up to 14 amino acids retained biologically significant levels of activity. Membranes prepared from these strains had readily detectable levels of F(1)F(0)-ATPase activity and proton pumping activity. However, the larger insertions resulted in decreasing levels of activity, and immunoblot analysis indicated that these reductions in activity correlated with reduced levels of b subunit in the membranes. Addition of 18 amino acids was sufficient to result in the loss of F(1)F(0) ATP synthase function. Assuming the predicted alpha-helical structure for this area of the b subunit, the 14-amino acid insertion would result in the addition of enough material to lengthen the b subunit by as much as 20 A. The results of both insertion and deletion experiments support a model in which the second stalk is a flexible feature of the enzyme rather than a rigid rod-like structure.

Molecular identification of the renal H+,K+-ATPases.

The pharmacological properties of H+,K+-ATPase activity described in the kidney were not necessarily consistent with the properties of the well-characterized gastric H+,K+-ATPase. Recent molecular biology experiments suggest that renal H+,K+-ATPase activity may be the product of several closely related P-type ATPases. At least 3 different pumps containing the HKalpha1, HKalpha2a, and HKalpha2c subunits have been detected in rabbit kidney. The current view is that these HKalpha subunits arose through gene duplication early in evolution and the proteins evolved their differing activities over time. The HKbeta protein associates with HKalpha1 in gastric tissues and is the likely mate for the HKalpha1 subunit in renal tissues. Three distinct beta subunits have been implicated as possible partners for the HKalpha2 subunits, but it remains to be determined which beta subunit predominantly associates with the HKalpha2 subunits in vivo. Sequence analysis suggests the beta subunit was constrained by size and shape of the protein rather than specific amino acid content during the course of evolution. Multiple H+,K+-ATPases in the kidney may be an important adaptation providing redundancy for the essential physiological function of maintaining ionic balance.

Modeling the Leigh syndrome nt8993 T-->C mutation in Escherichia coli F1F0 ATP synthase.

The mutations in human mitochondrial DNA at nt8993 are associated with a range of neuromuscular disorders. One mutation encodes a proline in place of a leucine conserved in all animal mitochondrial ATPase-6 subunits and bacterial a subunits of F1F0 ATP synthases. This conserved site is leu-156 and leu-207 in humans and Escherichia coli, respectively. An aleu-207-->pro substitution mutation has been constructed in the E. coli F1F0 ATP synthase in order to model the biochemical basis of the human disease mutation. The phenotype of the aleu-207-->pro substitution has been compared to that of the previously studied aleu-207-->arg substitution (Hartzog and Cain, 1993, Journal of Biological Chemistry 268, 12250-12252). The leu-207-->pro mutation resulted in approximately a 35% decrease in the number of intact enzyme complexes as determined by N, N'-dicyclohexylcarbodiimide-sensitive membrane associated ATP hydrolysis activity and western analysis using an anti-a subunit antibody. A 75% reduction in the efficiency of proton translocation through F1F0 ATP synthase was observed in ATP-driven proton pumping assays. Interestingly, the loss in F1F0 ATP synthase activity resulting from the leu-207-->pro substitution was markedly less dramatic than had been observed for the leu-207-->arg mutation studied earlier. By analogy, the human enzyme may also be affected by the leu-156-->pro substitution to a lesser extent than the leu-156-->arg substitution, and this would account for the milder clinical manifestations of the human leu-156-->pro disease mutations.

H-K-ATPase in the RCCT-28A rabbit cortical collecting duct cell line.

In the present study, we demonstrate that the rabbit cortical collecting duct cell line RCCT-28A possesses three distinct H-K-ATPase catalytic subunits (HKalpha). Intracellular measurements of RCCT-28A cells using the pH-sensitive dye 2', 7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) indicated that the mechanism accounting for recovery from an acid load exhibited both K+ dependence and sensitivity to Sch-28080 characteristic of H-K-ATPases. Recovery rates were 0.022 +/- 0.005 pH units/min in the presence of K+, 0.004 +/- 0.002 in the absence of K+, and 0.002 +/- 0.002 in the presence of Sch-28080. The mRNAs encoding the HKalpha1 subunit and the H-K-ATPase beta-subunit (HKbeta) were detected by RT-PCR. In addition, two HKalpha2 species were found by RT-PCR and 5' rapid amplification of cDNA ends (5'-RACE) in the rabbit renal cortex. One was homologous to HKalpha2 cDNAs generated from other species, and the second was novel. The latter, referred to as HKalpha2c, encoded an apparent 61-residue amino-terminal extension that bore no homology to reported sequences. Antipeptide antibodies were designed on the basis of this extension, and these antibodies recognized a protein of the appropriate mass in both rabbit renal tissue samples and RCCT-28A cells. Such findings constitute very strong evidence for expression of the HKalpha2c subunit in vivo. The results suggest that the rabbit kidney and RCCT-28A cells express at least three distinct H-K-ATPases.

Amino acid substitutions in the a subunit affect the epsilon subunit of F1F0 ATP synthase from Escherichia coli.

Amino acid substitutions at many positions in the a subunit of F1F0 ATP synthase result in impaired proton translocation and altered catalytic activity. In this work, we demonstrate that amino acid substitutions in the a subunit affect the epsilon subunit. In mutant F1F0 ATP synthases, the epsilon subunit was studied by determining its sensitivity to proteolysis and by chemical crosslinking under conditions of active turnover and in quiescent enzyme. Like native F1F0 ATP synthase, the epsilon subunit in enzymes carrying either the aarg-210-->ile or agly-218-->asp substitutions proved resistant to trypsin digestion during ATP hydrolysis. In each case, the epsilon subunit was rapidly digested in the presence of a nonhydrolyzable ligand, but this did not result in the activation of hydrolytic activity typically seen in wild-type enzyme. In enzyme carrying the aala-217-->arg substitution, the trypsin digestion of the epsilon subunit occurred regardless of ligand and was accompanied by a limited hydrolytic activation. Relative to the native F1F0 ATP synthase, the aala-217-->arg substitution resulted in reduced efficiency of crosslinking between the epsilon and beta subunits using 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. These observations indicate that the structural changes resulting from amino acid substitutions in the a subunit are propagated to the epsilon subunit and are specific to the individual substitutions.

Deletions in the second stalk of F1F0-ATP synthase in Escherichia coli.

In Escherichia coli F1F0-ATP synthase, the two b subunits form the second stalk spanning the distance between the membrane F0 sector and the bulk of F1. Current models predict that the stator should be relatively rigid and engaged in contact with F1 at fixed points. To test this hypothesis, we constructed a series of deletion mutations in the uncF(b) gene to remove segments from the middle of the second stalk of the subunit. Mutants with deletions of 7 amino acids were essentially normal, and those with deletions of up to 11 amino acids retained considerable activity. Membranes prepared from these strains had readily detectable levels of F1-ATPase activity and proton pumping activity. Removal of 12 or more amino acids resulted in loss of oxidative phosphorylation. Levels of membrane-associated F1-ATPase dropped precipitously for the longer deletions, and immunoblot analysis indicated that reductions in activity correlated with reduced levels of b subunit in the membranes. Assuming the likely alpha-helical conformation for this area of the b subunit, the 11-amino acid deletion would result in shortening the subunit by approximately 16 A. Since these deletions did not prevent the b subunit from participating in productive interactions with F1, we suggest that the b subunit is not a rigid rodlike structure, but has an inherent flexibility compatible with a dynamic role in coupling.

Identification of an uncoupling mutation affecting the b subunit of F1F0 ATP synthase in Escherichia coli.

A specific b subunit arginine, b(Arg-36) in Escherichia coli, displays evolutionary conservation among bacterial F1F0 ATP synthases. Site-directed mutagenesis was used to generate a collection of mutations affecting b(Arg-36). The phenotype differed depending upon the substitution, and the b(Arg-36-Glu) and b(Arg-36-Ile) substitutions virtually abolished enzyme function. Although the total amounts of F1F0 ATP synthase present in the membranes prepared from mutant strains were reduced, the primary effect of the b(Arg-36) substitutions was on the activities of the intact enzyme complexes. The most interesting result was that the b(Arg-36-Glu) substitution results in the uncoupling of a functional F0 from F1 ATP hydrolysis activity.

Formation of the b subunit dimer is necessary for interaction with F1-ATPase.

In earlier work, we [McCormick, K. A., et al. (1993) J. Biol. Chem. 268, 24683-24691] observed that mutations at Ala-79 of the b subunit affect assembly of F1F0 ATP synthase. Polypeptides modeled on the soluble portion of the b subunit (bsol) with substitutions at the position corresponding to Ala-79 have been used to investigate secondary structure and dimerization of the b subunit. Circular dichroism spectra and chymotrypsin digestion experiments suggested that the recombinant polypeptides with Ala-79 substitutions assumed conformations similar to the bsol polypeptide. However, cross-linking studies of the Ala-79 substitution bsol polypeptides revealed defects in dimerization. The efficiency of dimer formation appeared to be related to the capacity of the altered bsol polypeptides for competing with F1-ATPase for binding to F1-depleted membrane vesicles. Ala-79 substitution polypeptides displaying limited dimerization, such as bsol Ala-79-->Leu, were shown to elute with F1-ATPase during size exclusion chromatography, suggesting a specific interaction. Sedimentation equilibrium studies indicated that 8% of the bsol Ala-79-->Leu polypeptide was in the form of a 30.6 kDa dimer and 92% a 15.3 kDa monomer. When the dimer concentration of bsol Ala-79-->Leu was normalized to the concentration of bsol, both had virtually identical capacities for competing with F1-depleted membrane vesicles for binding F1-ATPase. The result indicated that the amount of dimer formed is directly proportional to its ability to bind F1-ATPase. This suggests that formation of the b subunit dimer may be a necessary step preceding F1-ATPase binding in the assembly of the enzyme complex.

In situ hybridization of H-K-ATPase beta-subunit mRNA in rat and rabbit kidney.

Through a variety of techniques, several investigators have demonstrated the presence of an H-K-adenosinetriphosphatase (H-K-ATPase) enzyme in the renal collecting duct, suggesting that this enzyme serves an important physiological role in the regulation of acid-base balance and potassium excretion by the kidney. The present study was designed to localize cells expressing H-K-ATPase beta-subunit mRNA in rat and rabbit kidney by nonradioactive in situ hybridization. A 570-bp DNA fragment of rabbit renal H-K-ATPase beta-subunit was used to produce digoxigenin-labeled riboprobes by in vitro transcription. Northern blot hybridization demonstrated transcripts in rat gastric oxyntic mucosa and kidney. In situ hybridization on kidney tissue sections demonstrated H-K-ATPase beta-subunit mRNA localization in epithelial cells, including intercalated cells in the connecting segment and cortical and medullary collecting duct, principal cells in the inner stripe of the outer medullary collecting duct, and inner medullary collecting duct cells in both the rat and the rabbit. These observations provide evidence that H-K-ATPase beta-subunit mRNA is present throughout the collecting duct of the kidney. The distribution of this message is consistent with a role for H-K-ATPase in bicarbonate absorption in both the outer and inner medullary collecting duct.

Renal expression of the gene encoding the gastric H(+)-K(+)-ATPase beta-subunit.

The gastric mucosal parietal cells and cells of the renal collecting duct both possess H(+)-K(+)-adenosinetriphosphatase (H(+)-K(+)-ATPase) activities. In the stomach, the H(+)-K(+)-ATPase (EC 3.6.1.3) is responsible for acidification of luminal contents. The kidney H(+)-K(+)-ATPase protein(s) contribute to potassium reabsorption and secretion of hydrogen ions to maintain potassium and acid-base homeostasis. The stomach H(+)-K(+)-ATPase is well defined and consists of an alpha-catalytic subunit of apparent molecular mass of 95 kDa and a highly glycosylated beta-subunit of 60-90 kDa. The molecular identity of the protein that mediates the H(+)-K(+)-ATPase activity in the kidney has been addressed in this paper. A combination of RNA hybridizations, polymerase chain reaction analysis of kidney RNA, and sequence analysis of cDNAs indicated that gastric H(+)-K(+)-ATPase beta-subunit mRNA is present in kidney. Immunoblotting with antibodies specific for the gastric H(+)-K(+)-ATPase beta-subunit detected proteins, which, after deglycosylation, had the same molecular mass as the gastric beta-subunit in membrane protein preparations from rabbit, pig, rat, and mouse kidneys. Furthermore, we have used transgenic mice to demonstrate that the gastric H(+)-K(+)-ATPase beta-subunit gene contains cis-acting regulatory sequences that are active in both gastric parietal cells and the renal collecting ducts. Overall, these data indicate that the gastric H(+)-K(+)-ATPase beta-subunit is found in the kidney and probably associates with the gastric H(+)-K(+)-ATPase alpha-subunit and/or other P-type ATPase alpha-subunits, thus contributing to acid-base and potassium homeostasis.

Second-site suppressor mutations at glycine 218 and histidine 245 in the alpha subunit of F1F0 ATP synthase in Escherichia coli.

The alpha-like subunits of F1F0 ATP synthases share primary structural homology in two segments near their carboxyl termini. However, the amino acids at the functionally important positions occupied by alpha Gly-218 and alpha His-245 in Escherichia coli vary depending upon organism and organelle. The alpha G218-->D,H245-G and alpha G218-->K,H245-->G double mutations were constructed in the E. coli uncB(alpha) gene to model the chloroplast ATPase IV subunit and alkaliphilic bacterial alpha subunit, respectively. Strains carrying each of the single mutations, alpha G218-->D, alpha G218-->K, and alpha H245-->G, had marked reductions in F1F0 ATP synthase function. The alpha G218-->K mutation was alone sufficient to virtually eliminate enzyme function. Membranes prepared from the alpha G218-->D mutant exhibited increased levels of ATP hydrolysis activity without a corresponding increase in active proton transport, suggesting a mechanistic uncoupling of catalytic activity and proton translocation. However, much of the lost F1F0 ATP synthase activity was restored in the alpha G218-->D,H245-->G and alpha G218-->K,H245-->G double mutant strains demonstrating that these mutations act as mutual intragenic second-site suppressors. The evidence is consistent with a close spatial interaction between alpha Gly-218 and alpha His-245.

Exploring the microtubule-binding region of bovine microtubule-associated protein-2 (MAP-2): cDNA sequencing, bacterial expression, and site-directed mutagenesis.

A 1.1 kilobase fragment of bovine microtubule-associated protein-2 (MAP-2) cDNA coding for bovine MAP-2 microtubule-binding region (MTBR) was sequenced. Relative to mouse, rat, and human MAP-2, we observed striking preservation of primary structure, even beyond the sequence and spacing of the three nonidentical peptide repeats responsible for microtubule-binding interactions. For further analysis of microtubule-MAP interactions using site-directed mutagenesis, we developed a bacterial expression system coding for the MT-binding fragment of MAP-2 starting at the thrombin cleavage site (position 1629) and continuing to the C-terminus. This MT-binding fragment was purified to homogeneity by taking advantage of the unusual heat-stability and isoelectric properties of this cytomatrix component. We found that the MT-binding domain readily promoted tubulin polymerization, and the critical tubulin concentration was reduced in the presence of this recombinant protein. Because a second repeated sequence analogue can promote tubulin polymerization as well as displace the MT-binding region of MAP-2, this study was designed to learn more about the importance of each repeated sequence in MT binding. Accordingly, we mutated the first and third sequences to resemble the second repeated sequence, thereby generating the mutants designed m12-m2-m3, m1-m32, and m12-m2-m32. These recombinant proteins bound with an affinity comparable to or slightly better than equal concentrations of wild-type MT-binding fragment. Likewise, when the first or third sequence was replaced by an exact copy of the second octadecapeptide repeat, there was little, if any, increase in binding affinity, as reflected in the ability of mutant MT-binding fragments to promote tubulin polymerization.(ABSTRACT TRUNCATED AT 250 WORDS)

Mutations in the delta subunit influence the assembly of F1F0 ATP synthase in Escherichia coli.

Missense mutations affecting Asp-161 and Ser-163 in the delta subunit of F1F0 ATP synthase have been generated. Although most substitutions allowed substantial enzyme function, the delta Asp-161-->Pro substitution resulted in a loss of enzyme activity. The loss of activity was attributable to a structural failure altering assembly of the enzyme complex.

Characterization of mutations in the b subunit of F1F0 ATP synthase in Escherichia coli.

Site-directed mutagenesis was used to investigate the restrictions on Ala-79 of the b subunit in F1F0 adenosine triphosphate synthase. This amino acid had been previously identified as particularly sensitive to mutation (McCormick, K. A., and Cain, B. D. (1991) J. Bacteriol. 173, 7240-7248). Mutant uncF (b) genes were placed under control of the lac promoter and monitored for F1F0 ATP synthase function in an uncF(b) deletion strain. Three deleterious bAla-79 mutations were moved to the unc operon in the chromosome by homologous recombination. Decreases in enzymatic activity in the uncF (b) mutant strains resulted from reduced amounts of enzyme. With the exception of the bAla-79-->Pro mutation, high expression of mutant uncF (b) genes resulted in increases in F1F0 ATP synthase activity which were sufficient to overcome the defects. In addition to the decrease in the amount of enzyme, the bAla-79-->Lys mutation affected ATP synthesis to a much greater extent than ATP-driven proton translocation. The evidence supports our earlier hypothesis, in which bAla-79 was proposed to play an important, but not essential, structural role in F1F0 ATP synthase assembly or stability.

The aleu207-->arg mutation in F1F0-ATP synthase from Escherichia coli. A model for human mitochondrial disease.

The mitochondrial ATPase 6 gene encodes a subunit of F1F0 adenosine triphosphate (ATP) synthase. A mutation in the ATPase 6 gene has been genetically linked to two maternally inherited genetic diseases: neurological muscle weakness, ataxia, and retinitis pigmentosa (NARP) and certain cases of subacute necrotizing encephalopathy (SNE). Although the severity of both NARP and SNE disease were correlated with the quantity of the ATPase 6leu156-->arg mutation in each patient, the mutation could not be shown to alter F1F0-ATP synthase activity. To investigate the biochemical effects of the ATPase 6leu156-->arg mutation on F1F0-ATP synthase, the aleu207-->arg mutation was constructed in the F1F0-ATP synthase from Escherichia coli to serve as a model for the disease mutation. Characterization of the model bacterial enzyme revealed that the mutation abolishes detectable ATP synthesis via oxidative phosphorylation. The aleu207-->arg mutation results in a structural perturbation blocking proton translocation through F1F0-ATP synthase. The results suggest that a structural defect in human F1F0-ATP synthase is the biochemical basis for NARP and SNE.