Mutational analysis of the Helicobacter pylori carbonic anhydrases

In the gastric microenvironment, Helicobacter pylori is exposed to bicarbonate, urea and acid. Here it is demonstrated that both H. pylori carbonic anhydrases (CAs) are required for maintaining urease activity and therefore influence H. pylori urea resistance at neutral pH. Furthermore, the beta-CA is required for acid resistance as indicated by a growth defect of the corresponding mutant at low pH. The alpha- and beta-CA mutants as well as the double mutant were more resistant to bicarbonate, indicating that both enzymes are involved in bicarbonate metabolism. These phenotypes support important CA-functions in H. pylori urea and bicarbonate metabolism and acid resistance. Thus, both CA enzymes might be required for survival in the gastric niche.     

Stoichiometry of the H+-ATPase of growing and resting, aerobic Escherichia coli

The H+/ATP stoichiometry of the proton-translocating ATPase was investigated in growing and nongrowing, respiring cells of Escherichia coli. The protonmotive force, delta p, was determined by measuring the transmembrane chemical gradient of protons, delta pH, from the cellular accumulation of benzoate anions, and the electrical gradient, delta psi, from the accumulation of the lipophilic cation tetraphenylphosphonium (TPP+). The accumulation of lactose was also used to calculate the delta p in this lactose operon constitutive beta-galactosidase negative mutant. The phosphorylation potential, delta GP', was determined by measuring the cellular concentration of ATP, ADP, and inorganic phosphate. According to chemiosmotic principles, at steady state the phosphorylation potential is in thermodynamic equilibrium with the protonmotive force, and thus the ratio delta p/delta GP' can be used to determine the H+/ATP ratio. Respiring E. coli cells, in mid-exponential phase of growth or incubated in buffer, at external pHs from 6.25 to 8.25 had a constant delta GP' of about 500 mV. The H+/ATP ratio was found to be 3 when the delta p value derived from lactose accumulation levels was used. However, when the delta p values derived from delta pH and delta psi were used in the calculations, the H+/ATP ratio varied from about 2.5 at external pH 6.25 to about 4 at pH 8.25. Arguments are presented for the hypothesis that the delta psi values obtained from the TPP+ measurements are likely to be inaccurate and that a value of 3 H+/ATP, independent of the external pH, is likely to be the valid stoichiometry.     

Hydrogenosomes in the rumen protozoon Dasytricha ruminantium Schuberg.

The vacuo-lysosomes of Hevea brasiliensis (rubber tree) constitute a suitable model system for the study of active transport and energization at the level of the membrane of plant vacuoles. The pH gradient (delta pH) and the membrane potential (delta psi) of vacuo-lysosomes were determined by means of the weak base methylamine and the lipophilic cation tetraphenylphosphonium. The values obtained depended strongly on the experimental conditions such as medium pH or K+ concentration. Under experimental conditions, i.e., pH 7.5 outside and low K+, the delta pH amounts to about 0.9 unit, interior acid, and the delta psi to -120 mV, interior negative. The delta psi is presumably caused by the imposed K+ gradient, and the internal acidification might be a consequence of the passive proton inflow along the electric field. This explanation is sustained by the ineffectiveness of carbonyl cyanide p-trifluoromethoxyphenylhydrazone in destroying the delta pH and delta psi, whereas higher K+ concentration decreased both. Under conditions existing in vivo, the membrane potential might be significantly lower. The presence of ATP increased the acidification of the intravesicular space by 0.5pH unit to a delta pH of up to 1.4 and shifts the membrane potential at least 60mV to a more positive value. The change of the protonmotive potential did not occur with ADP; the pH-dependence of the change was identical with the pH-dependence of a vacuo-lysosomal membrane-bound ATPase, and the effect of ATPase was prevented by the presence of the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone. The change of protonmotive potential difference, brought about by the ATPase, was at least 90 mV. This is evidence that a vacuo-lysosomal ATPase in plants can function as an electrogenic proton pump that transfers protons into the vacuo-lysosomal space.     

Helicobacter pylori utilises urea for amino acid synthesis

Abstract Helicobacter pylori has one of the highest urease activities of all known bacteria. Its enzymatic production of ammonia protects the organism from acid damage by gastric juice. The possibility that the urease activity allows the bacterium to utilise urea as a nitrogen source for the synthesis of amino acids was investigated. H. pylori (NCTC 11638) was incubated with 50 mM urea, enriched to 5 atom% excess ¹⁵N, that is the excess enrichment of ¹⁵N above the normal background, in the presence of either NaCl pH 6.0, or 0.2M citrate pH 6.0. E. coli (NCTC 9001) was used as a urease-negative control. ¹⁵N enrichment was detected by isotope ratio mass spectrometry. H. pylori showed intracellular incorporation of ¹⁵N in the presence of citrate buffer pH 6.0 but there was no significant incorporation of ¹⁵N in unbuffered saline or by E. coli in either pH 6.0 citrate buffer or unbuffered saline. The intracellular fate of the urea-nitrogen was determined by means of gas chromatography/mass spectrometry following incubation with ¹⁵N enriched 5 mM urea in the presence of either 0.2 M citrate buffer pH 6.0 or 0.2 M acetate buffer pH 6.0. After 5 min incubation in either buffer the ¹⁵n label appeared in glutamate, glutamine, phenylalanine, aspartate and alanine. It appears, therefore, that at pH and urea concentrations typical of the gastric mucosal surface, H. pylori utilises exogenous urea as a nitrogen source for amino acid synthesis. The ammonia produced by H. pylori urease activity thus facilitates the organism's nitrogen metabolism at neutral pH as well as protecting it from acid damage at low pH.     

The changes of proteomes components of Helicobacter pylori in response to acid stress without urea

Acid stress is the most obvious challenge Helicobacter pylori encounters in human stomach. The urease system is the basic process used to maintain periplasmic and cytoplasmic pH near neutrality when H. pylori is exposed to acidic condition. However, since the urea concentration in gastric juice is approximately 1 mM, considered possibly insufficient to ensure the survival of H. pylori, it is postulated that additional mechanisms of pH homeostasis may contribute to the acid adaptation in H. pylori. In order to identify the acid-related proteins other than the urease system we have compared the proteome profiles of H. pylori strain 26695 exposed to different levels of external pH (7.4, 6.0, 5.0, 4.0, 3.0, and 2.0) for 30 min in the absence of urea using 2-DE. Differentially expressed proteins were identified by MALDI-TOF-TOF-MS analysis, which turned out to be 36 different proteins. The functions of these proteins included ammonia production, molecular chaperones, energy metabolism, cell envelope, response regulator and some proteins with unknown function. SOM analysis indicated that H. pylori responds to acid stress through multi-mechanisms involving many proteins, which depend on the levels of acidity the cells encounter.     

Oxidative phosphorylation by membrane vesicles from Bacillus alcalophilus

ADP and Pi-loaded membrane vesicles from t-malate-grown Bacillus alcalophilus synthesized ATP upon energization with ascorbate/N,N,N',N'-tetra-methyl-P-phenylenediamine. ATP synthesis occurred over a range of external pH from 6.0 to 11.0, under conditions in which the total protonmotive force delta-mu-H+ was as low as -30 mV. The phosphate potentials (delta Gp) were calculated to be 11 and 12 kcal/mol at pH 10.5 and 9.0, respectively, whereas the delta-mu-H+ values in vesicles at these two pH values were quite different (-40 +/- 20 mV at pH 10.5 and -125 +/- 20 mV at pH 9.0). ATP synthesis was inhibited by KCN, gramicidin, and by N,N1-dicyclohexylcarbodiimide. Inward translocation of protons, concomitant with ATP synthesis, was demonstrated using direct pH monitoring and fluorescence methods. No dependence upon the presence of Na+ or K+ was found. Thus, ATP synthesis in B. alcalophilus appears to involve a proton-translocating ATPase which functions at low delta-mu-H+.     

Are proton symports in yeast directly linked to H(+)-ATPase acidification?

Transport of amino acids in Saccharomyces cerevisiae is an H(+)-driven secondary active transport. Inhibitors of the plasma membrane H(+)-ATPase, particularly heavy water, diethylstilbestrol and suloctidil, were shown to affect the H(+)-extruding ATPase activity as well as the ATP-hydrolyzing activity, to a similar degree as they inhibited the transport of amino acids. The inhibitors had virtually no effect on the membrane electric potential or on the delta pH which constitute the thermodynamically relevant source of energy for these transports. Transport of acidic amino acids was affected much more than that of the neutral and especially of the basic ones. The effects were greater with higher amino acid concentrations. All this is taken as evidence that the amino acid carriers respond kinetically to the presence of protons directly at the membrane site where they are extruded by the H(+)-ATPase, rather than to the overall protonmotive force.     

Structure, function and localization of Helicobacter pylori urease.

Helicobacter pylori is the causative agent of most cases of gastritis. Once acquired, H. pylori establishes chronic persistent infection; it is this long-term infection that, is a subset of patients, leads to gastric or duodenal ulcer, gastric cancer or gastric MALT lymphoma. All fresh isolates of H. pylori express significant urease activity, which is essential to survival and pathogenesis of the bacterium. A significant fraction of urease is associated with the surface of H. pylori both in vivo and in vitro. Surface-associated urease is essential for H. pylori to resist exposure to acid in the presence of urea. The mechanism whereby urease becomes associated with the surface of H. pylori is unique. This process, which we term "altruistic autolysis," involves release of urease (and other cytoplasmic proteins) by genetically programmed autolysis with subsequent adsorption of the released urease onto the surface of neighboring intact bacteria. To our knowledge, this is the first evidence of essential communal behavior in pathogenic bacteria; such behavior is crucial to understanding the pathogenesis of H. pylori.     

Glutamate uptake into synaptic vesicles of bovine cerebral cortex and electrochemical potential difference of proton across the membrane.

Measurements have been made of the ATP-dependent membrane potential (delta psi) and pH gradient (delta pH) across the membranes of the synaptic vesicles purified from bovine cerebral cortex, using the voltage-sensitive dye bis[3-propyl-5-oxoisoxazol-4-yl]pentamethine oxanol and the delta pH-sensitive fluorescent dye 9-aminoacridine respectively. A pre-existing small delta pH (inside acidic) was detected in the synaptic vesicles, but no additional significant contribution by MgATP to delta pH was observed. In contrast, delta psi (inside positive) increased substantially upon addition of MgATP. This ATP-dependent delta psi was reduced by thiocyanate anion (SCN-), a delta psi dissipator, or carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP), a protonmotive-force dissipator. Correspondingly, a substantially larger glutamate uptake occurred in the presence of MgATP, which was inhibited by SCN- and FCCP. A nonhydrolysable analogue of ATP, adenosine 5'-[beta gamma-methylene]triphosphate, did not substitute for ATP in either delta psi generation or glutamate uptake. The results support the hypothesis that a H+-pumping ATPase generates a protonmotive force in the synaptic vesicles at the expense of ATP hydrolysis, and the protonmotive force thus formed provides a driving force for the vesicular glutamate uptake. The delta psi generation by ATP hydrolysis was not affected by orthovanadate, ouabain or oligomycin, but was inhibited by N-ethylmaleimide, quercetin, trimethyltin, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid. These results indicate that the H+-pumping ATPase in the synaptic vesicle is similar to that in the chromaffin granule, platelet granule and lysosome.     

The Helicobacter pylori UreI protein: role in adaptation to acidity and identification of residues essential for its activity and for acid activation

Helicobacter pylori is a human gastric pathogen that survives the strong acidity of the stomach by virtue of its urease activity. This activity produces ammonia, which neutralizes the bacterial microenvironment. UreI, an inner membrane protein, is essential for resistance to low pH and for the gastric colonization of mice by H. pylori. In the heterologous Xenopus oocytes expression system, UreI behaves like an H+-gated urea channel, and His-123 was found to be important for low pH activation. We investigated the role of UreI directly in H. pylori and showed that, in the presence of urea, strains expressing wild-type UreI displayed very rapid stimulation of extracellular ammonia production upon exposure to pH 相似文献   

Energetics of Helicobacter pylori and its implications for the mechanism of urease-dependent acid tolerance at pH 1

In the presence of urea the neutrophilic human pathogen Helicobacter pylori survives for several hours at pH 1 with concomitant cytoplasmic pH homeostasis. To study this effect in detail, the transmembrane proton motive force and cytoplasmic urease activity of H. pylori were determined at various pH values. In the absence of urea, the organism maintained a close-to-neutral cytoplasm and an internally negative membrane potential at external pH values greater than 4 to 5. In the presence of urea, H. pylori accomplished cytoplasmic pH homeostasis down to an external pH of 1.2. At this external pH, the cytoplasmic pH was 4.9 and the membrane potential was slightly negative inside. The latter finding is in contrast to the situation in acidophiles, which develop inside-positive membrane potentials under similar conditions. Measurements of the time course of the membrane potential confirmed that addition of urea to the cells led to hyperpolarization. Most likely, this effect was due to electrogenic export of ammonium cations from the cytoplasm. The urease activity of intact cells increased nearly exponentially with decreasing external pH. This activation was not due to enhanced gene expression at low external pH values. In cell extracts the pH optimum of urease activity was dependent on the buffer system and was about pH 5 in sodium citrate buffer. Since this is the cytoplasmic pH of the cells at pH 1 to 2, we propose that cytoplasmic pH is a factor in the in vivo activation of the urease at low external pH values. The mechanism by which urease activity leads to cytoplasmic pH homeostasis in H. pylori is discussed.     

Acid resistance of Helicobacter pylori depends on the UreI membrane protein and an inner membrane proton barrier

ureI encodes an inner membrane protein of Helicobacter pylori. The role of the bacterial inner membrane and UreI in acid protection and regulation of cytoplasmic urease activity in the gastric microorganism was studied. The irreversible inhibition of urease when the organism was exposed to a protonophore (3,3',4', 5-tetrachlorsalicylanide; TCS) at acidic pH showed that the inner membrane protected urease from acid. Isogenic ureI knockout mutants of several H. pylori strains were constructed by replacing the ureI gene of the urease gene cluster with a promoterless kanamycin resistance marker gene (kanR). Mutants carrying the modified ureAB-kanR-EFGH operon all showed wild-type levels of urease activity at neutral pH in vitro. The mutants resisted media of pH > 4.0 but not of pH < 4.0. Whereas wild-type bacteria showed high levels of urease activity below pH 4.0, this ability was not retained in the ureI mutants, resulting in inhibition of metabolism and cell death. Gene complementation experiments with plasmid-derived H. pylori ureI restored wild-type properties. The activation of urease activity found in structurally intact but permeabilized bacteria treated with 0.01% detergent (polyoxy-ethylene-8-laurylether; C12E8), suggested a membrane-limited access of urea to internal urease at neutral pH. Measurement of 14C-urea uptake into Xenopus oocytes injected with ureI cRNA showed acid activation of uptake only in injected oocytes. Acceleration of urea uptake by UreI therefore mediates the increase of intracellular urease activity seen under acidic conditions. This increase of urea permeability is essential for H. pylori survival in environments below pH 4.0. ureI-independent urease activity may be sufficient for maintenance of bacterial viability above pH 4.0.     

Acidic conditions enhance bactericidal effects of sodium bisulfite on Helicobacter pylori

BACKGROUND: The Brucella broth medium, which is often used for the cultivation of microaerobic bacteria including Helicobacter pylori. It contains sodium bisulfite to decrease oxygen content in the medium. The growth of H. pylori, however, is inhibited by sodium bisulfite. In this study, the effect of sodium bisulfite was compared with several antioxidants and quantified under acidic conditions, mimicking the gastric environment. METHODS: Growth of H. pylori in the presence of several antioxidants was evaluated at OD655 nm. Effect of sodium bisulfite on H. pylori under acidic conditions was evaluated by measuring colony forming units (cfu). RESULTS: Under neutral conditions, sodium bisulfite was a more potent suppressor of H. pylori. Resveratrol, a polyphenol found in wine, exhibited the most potent inhibitory activity. To quantify the effect of sodium bisulfite on H. pylori under acidic conditions, the bacteria were grown at 37 degrees C for 30 minutes in 0.15 mol/l HCl/KCl (pH 2.0) with or without urea and sodium bisulfite. Sodium bisulfite (0.5 mmol/l) did not affect the viability at neutral pH 7.0, however, it killed H. pylori under acidic conditions, even if urea, the key substance enabling H. pylori to survive under acidic conditions, was present. The bacteria, which had been incubated under acidic conditions in the presence of urea, could survive a subsequent 30 minute-incubation at pH 2.0 without urea. Presence of sodium bisulfite, however, in the subsequent 30 minute-incubation, killed the bacteria. CONCLUSIONS: The bactericidal effect of sodium bisulfite on H. pylori was greater under acidic conditions and independent of urease activity.     

A requirement for ATP for beta-galactoside transport by Bacillus alcalophilus.

Lactose-grown cells of Bacillus alcalophilus actively transported methylthio-beta, D-galactoside (TMG) in a range of pH values from 7.5 to 10.5 with a pH optimum at 8.5. The TMG was accumulated in a chemically unmodified form, and cell extracts failed to catalyze either ATP or P-enolpyruvate-dependent phosphorylation of TMG. At pH 8.5, the lactose-grown cells exhibited a transmembrane proton gradient (deltapH) of 1.38 units, interior acid, and a transmembrane electrical potential (delta psi) of -132 mV. Accordingly, the total protonmotive force at this pH was very low, -51mV. Several lines of evidence indicate that the protonmotive force or delta psi did not directly energize TMG transport but, rather, that ATP was directly required: (a) in cells treated with arsenate so that the delta psi was unaffected and cellular ATP levels were markedly lowered, TMG transport was inhibited in proportion to the reduction of cellular ATP, while electrogenic alpha-aminoisobutyric acid transport was not; (b) when a valinomycin-induced potassium diffusion potential was established in starved cells, alpha-aminoisobutyric acid transport, but not TMG transport, was stimulated; and (c) in a series of experiments in which the delta psi was rapidly abolished by treatment with gramicidin, ATP levels declined slowly and the rate of TMG transport correlated directly with ATP levels rather than with the delta psi. Consumption of cellular ATP concomitant with TMG transport could be demonstrated.     

Photosensitive phosphoproteins in Halobacteria: regulatory coupling of transmembrane proton flux and protein dephosphorylation

A photoregulated reversible protein phosphorylation system controlled by the halobacterial rhodopsins was recently reported. The results presented in this paper identify the initial steps in the pathway from the absorption of light to the photoregulated protein phosphorylation and dephosphorylation reactions. Action spectrum, biochemical, and genetic analyses show that the proton pump bacteriorhodopsin mediates light-induced dephosphorylation of three photoregulated phosphoproteins. Light absorbed by bacteriorhodopsin is used to establish a proton efflux from the cells. The increase in the inwardly directed protonmotive force (pmf) from this efflux induces dephosphorylation of the three phosphoproteins, as demonstrated by the effects of the protonophore CCCP and of artificially imposed transmembrane pH gradients. Upon darkening the cells, cessation of the proton efflux through bacteriorhodopsin causes a decrease in pmf, which induces rephosphorylation of the proteins. Pmf appears to function as a regulator rather than a driving force in this system. Measurements of pmf-driven ATP synthesis in our conditions indicate the regulation of protein phosphorylation by pmf is probably not a consequence of proton flux through the H+ ATPase, a known energy coupling structure in these cells. The properties of this system may indicate the existence of a pmf detector which regulates kinase or phosphatase activity; i.e., a regulatory coupling device.     

Urease-mediated destruction of bacteria is specific for Helicobacter urease and results in total cellular disruption

Abstract The survival of Helicobacter mustelae, Proteus mirabilis, Escherichia coli and Campylobacter jejuni in the presence of urea and citrate at pH 6.0 was examined. H. mustelae , which has urease activity similar to H. pylori , had a markedly reduced survival, median 2.5% (0–78%) ( P <0.001) when incubated nder these conditions. Only 7% of the ammonia produced by H. mutelae urease activity was recovered from the buffer, a similar percentage to that previously reported with H. pylori . None of the other organisms, all of which had lower urease activity, had impaired survival under these conditions. Electron microscopical studies demonstrated extensive structural damage to H. pylori following exposure to urea and citrate at pH 6.0. This structural damage to the organisms makes it unlikely that the low recovery of ammonia was due to retention of ammonia within the bacteria and suggests that the ammonia may have been incorporated into glutamate or other amino acids. Incorporation of ammonia into these compounds would deplete the cell of the key metabolic intermediate α-ketoglutarate and could thus explain the mechanism of the urease-dependent destruction of the organism.     

The effect of sorbic acid and esters of p-hydroxybenzoic acid on the protonmotive force in Escherichia coli membrane vesicles

The effect of three food preservatives, sorbic acid and methyl and butyl esters of p-hydroxybenzoic acid, on the protonmotive force in Escherichia coli membrane vesicles was investigated. Radioactive chemical probes were used to determine the two components of the protonmotive force: delta pH (pH difference) and delta psi (membrane potential). Both types of compound selectively eliminated delta pH across the membrane, while leaving delta psi much less disturbed indicating that transport inhibition by neutralization of the protonmotive force cannot be the only mechanism of action for the food preservatives tested.     

Control of the protonmotive force in Rhodopseudomonas sphaeroides in the light and dark and its effect on the initiation of flagellar rotation

The addition of low concentrations of the uncoupler of CCP (0.01−0.1 μM) to actinically illuminated, photosynthetically grown Rhodopseudomonas sphaeroides did not inhibit motility. When CCCP addition was followed by a period of dark, anaerobic incubation the bacteria became nonmotile, and motility was not regained immediately on actinic re-illumination. The length of the delay before the onset of motility on re-illumination was proportional to the concentration of uncoupler added, until at higher concentrations (0.5−5 μM) maximum motility was not regained. Flagellar rotation depends on the protonmotive force, therefore the total pmf and the electrical and chemical components were measured under a variety of environmental conditions. The addition of the uncoupler to dark-incubated bacteria caused the collapse of the respiratory protonmotive force, but had no effect on the rapid reformation of the full protonmotive force on re-illumination. The time-course of protonmotive force generation was very similar to that measured in untreated bacteria and showed little change with increasing concentrations of uncoupler, although the size of the induced protonmotive force was eventually reduced. The ΔpH component of the protonmotive force developed more slowly than the Δψ component, but the time taken for the development of the ΔpH did not increase as the CCCP concentration increased. The delay in motility was longer under conditions where ΔpH was the sole or major component of the protonmotive force. ATP is required for taxis but not motility in bacteria. The addition of CCCP to dark-incubated bacteria caused a rapid fall in intracellular ATP which recovered rapidly on re-illumination. At high uncoupler concentrations the ATP content fell as the protonmotive force was reduced. However, the delay in resumption of motility was observed at CCCP concentrations which did not affect either the protonmotive force or the ATP concentration reached on illumination. There was no delay in recovery of motility when protonmotive force was increased but ATP levels reduced by the addition of the ATPase inhibitor venturicidin. In its proposed that initiation of flagellar rotation involves a protonmotive force dependent modification of the motor and that this modification acts as the on-off switch for the motor.     

Unique mechanism of Helicobacter pylori for colonizing the gastric mucus

Helicobacter pylori is a human gastric pathogen causing chronic infection. Urease and motility using flagella are essential factors for its colonization. Urease of H. pylori exists both on the surface and in the cytoplasm, and is involved in neutralizing gastric acid and in chemotactic motility. H. pylori senses the concentration gradients of urea in the gastric mucus layer, then moves toward the epithelial surface by chemotactic movement. The energy source for the flagella movement is the proton motive force. The hydrolysis of urea by the cytoplasmic urease possibly generates additional energy for the flagellar rotation in the mucus gel layer.     

Ammonium/urea-dependent generation of a proton electrochemical potential and synthesis of ATP in Bacillus pasteurii.

The influence of ammonium and urea on the components of the proton electrochemical potential (delta p) and de novo synthesis of ATP was studied with Bacillus pasteurii ATCC 11859. In washed cells grown at high urea concentrations, a delta p of -56 +/- 29 mV, consisting of a membrane potential (delta psi) of -228 +/- 19 mV and of a transmembrane pH gradient (delta pH) equivalent to 172 +/- 38 mV, was measured. These cells contained only low amounts of potassium, and the addition of ammonium caused an immediate net decrease of both delta psi and delta pH, resulting in a net increase of delta p of about 49 mV and de novo synthesis of ATP. Addition of urea and its subsequent hydrolysis to ammonium by the cytosolic urease also caused an increase of delta p and ATP synthesis; a net initial increase of delta psi, accompanied by a slower decrease of delta pH in this case, was observed. Cells grown at low concentrations of urea contained high amounts of potassium and maintained a delta p of -113 +/- 26 mV, with a delta psi of -228 +/- 22 mV and a delta pH equivalent to 115 +/- 20 mV. Addition of ammonium to such cells resulted in the net decrease of delta psi and delta pH without a net increase in delta p or synthesis of ATP, whereas urea caused an increase of delta p and de novo synthesis of ATP, mainly because of a net increase of delta psi. The data reported in this work suggest that the ATP-generating system is coupled to urea hydrolysis via both an alkalinization of the cytoplasm by the ammonium generated in the urease reaction and a net increase of delta psi that is probably due to an efflux of ammonium ions. Furthermore, the findings of this study show that potassium ions are involved in the regulation of the intracellular pH and that ammonium ions may functionally replace potassium to a certain extent in reducing the membrane potential and alkalinizing the cytoplasm.