Streptococcus faecalis mutants defective in regulation of cytoplasmic pH.

We have isolated two acid-sensitive mutants of Streptococcus faecalis (ATCC 9790), designated AS13 and AS25, which grew at pH 7.5 but not at pH below 6.0. The ionophore gramicidin D, which collapsed the pH gradient between the cytoplasm and the medium, had little effect on the growth of these mutants, indicating that growing cells maintain only a small pH gradient. In the presence of gramicidin D the growth rates of the parent and mutant strains were identical over a range of pH values. When glucose was added to a cell suspension at pH 6.4, the parent strain generated a pH gradient of 1.0 unit, interior alkaline; AS13 generated a pH gradient of only 0.5 units, and AS25 generated no measurable pH gradient. The proton permeability of the mutant strains was the same as that of the parent strain. These results suggest that a cytoplasmic pH of around 7.5 is required for the growth of the cells and that the mutant strains are unable to establish a neutral cytoplasmic pH in acidic medium because of damage to the regulatory system of the cytoplasmic pH. Mutant strains also have a reduced capacity to extrude protons and take up potassium. Therefore, it is likely that these cation transport systems are involved in the regulation of cytoplasmic pH.     

Bioenergetic properties and viability of alkalophilic Bacillus firmus RAB as a function of pH and Na+ contents of the incubation medium.

The bioenergetic properties and viability of obligately alkalophilic Bacillus firmus RAB have been examined upon incubation in alkaline and neutral buffers in the presence or absence of added Na+. At pH 10.5, cells incubated in the absence of Na+ exhibited an immediate rise in cytoplasmic pH from less than 9.5 to 10.5, and they lost viability very rapidly. Viability experiments in the presence or absence of an energy source further suggested that the Na+-dependent mechanism for pH homeostasis is an energy-requiring function. The Na+/H+ antiporter, which catalyzes the vital proton accumulation at alkaline pH, was only slightly operational at pH 7.0; both whole cells and vesicles exhibited net proton extrusion even in the presence of Na+. Moreover, cells incubated in buffer at pH 7.0 were actually more viable in the presence of Na+ than in its absence. Thus, the inability of B. firmus RAB to grow at neutral pH is not due to excessive acidification of the cytoplasm. Rather, the transmembrane electrical potential, delta psi, generated at pH 7.0 was found to be much lower than at alkaline pH. The very low delta psi compromised several cell functions, e.g., Na+/solute symport and motility, which in this and other alkalophiles specifically depend upon delta psi and Na+.     

Pleiotropic plasma membrane ATPase mutations of Saccharomyces cerevisiae.

We isolated a large number of mutations in the structural gene for the plasma membrane ATPase (PMA1) of Saccharomyces cerevisiae. These mutations were selected by their resistance to the aminoglycoside antibiotic hygromycin B. Biochemical analysis of purified membrane preparations showed that the plasma membrane ATPase activity of the mutants was reduced as much as 75%. Intragenic complementation of pma1 mutants suggested that the yeast plasma membrane ATPase was a multimeric enzyme. The pma1 mutants were apparently defective in maintaining internal pH; more than half of the mutants were unable to grow either at a low pH or in the presence of a weak acid. Most pma1 mutants were also osmotic pressure sensitive. At a very low temperature (5 degrees C) many pma1 mutants were unable to grow and were arrested as unbudded cells. The three most severely affected mutants were also unable to grow in the presence of NH4+. The most extreme mutant exhibited a severe defect in progression through the cell cycle; on synthetic medium, the cells progressively accumulated nucleus-containing small buds that generally failed to complete bud enlargement and cytokinesis. Most of the pleiotropic phenotypes of pma1 mutants could be suppressed by the addition of 50 mM KCl but not NaCl to the medium.     

Physiological role of the chaA gene in sodium and calcium circulations at a high pH in Escherichia coli.

Ohyama et al. previously isolated Escherichia coli mutant RS1, which had a negligible activity for sodium ion extrusion at alkaline pH (T. Ohyama, R. Imaizumi, K. Igarashi, and H. Kobayashi, J. Bacteriol. 174:7743-7749, 1992). Our present study showed that the mutation of RS1 was compensated for by a cloned chaA gene. It has been proposed that sodium ion extrusion by ChaA is prevented under physiological conditions (D. M. Ivey, A. A. Guffanti, J. Zemsky, E. Pinner, R. Karpel, E. Padan, S. Schuldiner, and T. A. Krulwich, J. Biol. Chem. 268:11296-11303, 1993). In order to clarify the physiological role of chaA in sodium ion circulation at alkaline pH, we constructed a delta chaA mutant. The resultant mutant, TO112, deficient in both nhaA and chaA, was unable to grow at pH 8.5 in medium containing 0.1 M sodium chloride and had negligible sodium ion extrusion activity. However, TO112 grew at pH 7.0 in medium containing 0.4 M sodium chloride. Sodium ions were extruded from TO112 cells at neutral pH. The extrusion activity at pH 7.5 was greatly reduced by the deletion of nhaB. These data demonstrate that the activity of nhaB is low at high pH and that ChaA extrudes sodium ions at alkaline pH. The uptake of calcium ions by everted membrane vesicles prepared from the delta chaA mutant TO110 was 60% of the activity observed in the vesicles of the wild-type strain at pH 8.5, but the activity at neutral pH was not reduced by the deletion of chaA. Therefore, it was also suggested that ChaA plays a role in calcium ion circulation at alkaline pH.     

Novel streptococcal mutants defective in the regulation of H+-ATPase biosynthesis and in F0 complex

In Streptococcus faecalis (faecium), the cytoplasmic pH is regulated by proton extrusion via a proton translocating F1F0-ATPase; the level of this enzyme increases in response to cytoplasmic acidification (Kobayashi, H., Suzuki, T., and Unemoto, T. (1986) J. Biol. Chem. 261, 627-630). We describe here two novel acid-sensitive mutants, designated AS8 and AS17, that contain ATPase activity but fail to grow on acid media. Our data suggested that in mutant AS17, acidification of the cytoplasm stimulates synthesis of the F0 sector of the ATPase but not the F1 sector. The accumulation in the plasma membrane of F0 sectors devoid of F1 results in enhanced proton permeability, and as a consequence mutant AS17 is unable to regulate the cytoplasmic pH in acid media. The genetic defect may reside in a gene that regulates expression of the F1F0-ATPase. Mutant AS8 does not generate a proton motive force. Our results suggest that the F1F0-ATPase can hydrolyze ATP but fails to translocate protons due to a defect in one of the subunits of the F0 sector.     

Subcellular localization and properties of lipase activities in human polymorphonuclear leukocytes

A fluorimetric assay for lipase activity has been optimized for measurement of the enzyme in human neutrophils. Activity was maximal at acid (4.5) and alkaline (9.5) pH, although there was also a neutral peak of activity at pH 6.5. Neutrophils were homogenised in isotonic sucrose and subjected to analytical subcellular fractionation by sucrose density gradient centrifugation. The gradient fractions were assayed for acid, neutral and alkaline lipase activity and for the principal organelle marker enzymes. Neutral lipase showed a unimodal distribution with an equilibrium density of 1.19 g . cm-3, corresponding to the distribution of particulate leucine aminopeptidase. Acid and alkaline lipase activities showed very similar distribution profiles to each other with both soluble components and a broad peak of particulate activity. The broad modal density of 1.19-1.22 g . cm-3 suggests that acid and alkaline lipase activities could be localised to more than one population of cytoplasmic granule. Fractionation experiments with neutrophils homogenised in sucrose medium containing digitonin confirmed the localisation of neutral lipase and leucine aminopeptidase to the same cytoplasmic granule, and suggested that at least part of the acid lipase activity was localised to the specific granule. No lipase activity could be attributed to the alkaline phosphatase-containing granule. Neutrophils were isolated from control subjects, patients with chronic granulocytic leukaemia and women in the third trimester of pregnancy. The specific activity of acid, neutral and alkaline lipase, and leucine aminopeptidase, in contrast to that of alkaline phosphatase, were similar in the three patient groups.     

The sodium/proton antiport system in a newly isolated alkalophilic Bacillus sp.

The pH homeostasis and the sodium/proton antiport system have been studied in the newly isolated alkalophilic Bacillus sp. strain N-6, which could grow on media in a pH range from 7 to 10, and in its nonalkalophilic mutant. After a quick shift in external pH from 8 to 10 by the addition of Na2CO3, the delta pH (inside acid) in the cells of strain N-6 was immediately established, and the pH homeostatic state was maintained for more than 20 min in an alkaline environment. However, under the same conditions, the pH homeostasis was not observed in the cells of nonalkalophilic mutant, and the cytoplasmic pH immediately rose to pH 10. On the other hand, the results of the rapid acidification from pH 9 to 7 showed that the internal pH was maintained as more basic than the external pH in a neutral medium in both strains. The Na+/H+ antiport system has been characterized by either the effect of Na+ on delta pH formation or 22Na+ efflux in Na+-loaded right-side-out membrane vesicles of strain N-6. Na+- or Li+-loaded vesicles exhibited a reversed delta pH (inside acid) after the addition of electron donors (ascorbate plus tetramethyl-p-phenylenediamine) at both pH 7 and 9, whereas choline-loaded vesicles generated delta pHs of the conventional orientation (inside alkaline). 22Na+ was actively extruded from 22Na+-loaded vesicles whose potential was negative at pH 7 and 9. The inclusion of carbonyl cyanide m-chlorophenylhydrazone inhibited 22Na+ efflux in the presence of electron donors. These results indicate that the Na+/H+ antiport system in this strain operates electrogenically over a range of external pHs from 7 to 10 and plays a role in pH homeostasis at the alkaline pH range. The pH homeostasis at neutral ph was studied in more detail. K+ -depleted cells showed no delta pH (acid out) in the neutral conditions in the absence of K+, whereas these cells generated a delta pH if K+ was present in the medium. This increase of internal pH was accompanied by K+ uptake from the medium. These results suggest that electrogenic K+ entry allows extrusion of H+ from cells by the primary proton pump at neutral pH.     

Artificial control of cytoplasmic pH and its bearing on cytoplasmic streaming,electrogenesis and excitability of characeae cells

Effects of changing the cytoplasmic pH on the cytoplasmic streaming, membrane potential and membrane excitability were studied in tonoplast-free cells ofChara australis andNitellopsis obtusa. The cytoplasmic pH was varied by internal perfusion of pH-buffered media.Nitellopsis cells were perfused only once, whileChara cells were perfused twice to control the pH more accurately. In both materials the rate of cytoplasmic streaming was maximum at about pH 7, low at pH 8.5–9 and almost zero at pH 5–5.5. The membrane potential was most negative at about pH 7. InChara the membrane potential supported by Mg·ATP was strongly inhibited at pH 5.5, and almost zero at pH 9, supporting the results obtained by Fujiiet al. (1979) on cells ofChara australis which were perfused once. The action potential could be induced by electrical stimulation inChara at pH 6.0–9.0 and inNitellopsis at pH 6.6–7.9. The membrane resistance ofNitellopsis was high at acidic and neutral pH values and low at alkaline pH, while that ofChara was low at both acidic and alkaline pH values.     

Role of the KcsA channel cytoplasmic domain in pH-dependent gating

The KcsA channel is a representative potassium channel that is activated by changes in pH. Previous studies suggested that the region that senses pH is entirely within its transmembrane segments. However, we recently revealed that the cytoplasmic domain also has an important role, because its conformation was observed to change dramatically in response to pH changes. Here, to investigate the effects of the cytoplasmic domain on pH-dependent gating, we made a chimera mutant channel consisting of the cytoplasmic domain of the KcsA channel and the transmembrane region of the MthK channel. The chimera showed a pH dependency similar to that of KcsA, indicating that the cytoplasmic domain can act as a pH sensor. To identify how this region detects pH, we substituted certain cytoplasmic domain amino acids that are normally negatively charged at pH 7 for neutral ones in the KcsA channels. These mutants opened independently of pH, suggesting that electrostatic charges have a major role in the cytoplasmic domain's ability to sense and respond to pH.     

A novel family of yeast chaperons involved in the distribution of V-ATPase and other membrane proteins.

Null mutations in genes encoding V-ATPase subunits in Saccharomyces cerevisiae result in a phenotype that is unable to grow at high pH and is sensitive to high and low metal-ion concentrations. Treatment of these null mutants with ethylmethanesulfonate causes mutations that suppress the V-ATPase null phenotype, and the mutant cells are able to grow at pH 7.5. The suppressor mutants were denoted as svf (suppressor of V-ATPase function). The frequency of svf is relatively high, suggesting a large target containing several genes for the ethylmethanesulfonate mutagenesis. The suppressors' frequency is dependent on the individual genes that were inactivated to manifest the V-ATPase null mutation. The svf mutations are recessive, because crossing the svf mutants with their corresponding V-ATPase null mutants resulted in diploid strains that are unable to grow at pH 7.5. A novel gene family in which null mutations cause pleiotropic effects on metal-ion resistance or sensitivity and distribution of membrane proteins in different targets was discovered. The family was defined as VTC (Vacuolar Transporter Chaperon) and it contains four genes in the S. cerevisiae genome. Inactivation of one of them, VTC1, in the background of V-ATPase null mutations resulted in svf phenotype manifested by growth at pH 7.5. Deletion of the VTC1 gene (DeltaVTC1) results in a reduced amount of V-ATPase in the vacuolar membrane. These mutant cells fail to accumulate quinacrine into their vacuoles, but they are able to grow at pH 7.5. The VTC1 null mutant also results in a reduced amount of the plasma membrane H(+)-ATPase (Pma1p) in membrane preparations and possibly mis-targeting. This observation may provide an explanation for the svf phenotype in the double disruptant mutants of DeltaVTC1 and DeltaVMA subunits.     

Maintenance of a neutral cytoplasmic pH is not obligatory for growth of Escherichia coli and Streptococcus faecalis at an alkaline pH

Both Escherichia coli and Streptococcus faecalis grew in an alkaline medium containing 100 microM carbonyl cyanide m-chlorophenylhydrazone (CCCP). Our data suggested that CCCP functioned as a protonophore at a high pH and that the proton-motive force was dissipated almost completely under such conditions. The pH gradient measured with dimethyloxazolidine-2,4-dione and acetylsalicylic acid was very small in both bacteria at a high pH above 8, and was not affected significantly by the addition of CCCP. Based on these findings, we propose that the maintenance of neutral cytoplasmic pH is not obligatory for the growth of E. coli and S. faecalis in an alkaline medium.     

Roles of K+ and Na+ in pH homeostasis and growth of the marine bacterium Vibrio alginolyticus.

The marine bacterium Vibrio alginolyticus, containing 470 mM-K+ and 70 mM-Na+ inside its cells, was able to regulate the cytoplasmic pH (pH(in)) in the narrow range 7.6-7.8 over the external pH (pH(out)) range 6.0-9.0 in the presence of 400 mM-Na+ and 10 mM-K+. In the absence of external K+, however, pHin was regulated only at alkaline pH(out) values above 7.6. When the cells were incubated in the presence of unusually high K+ (400 mM) and 4 mM Na+, the pH(in) was regulated only at acidic pH(out) values below 7.6. These results could be explained by postulating a K+/H+ antiporter as the regulator of pH(in) over the pH(out) range 6.0-9.0. When Na(+)-loaded/K(+)-depleted cells were incubated in 400 mM-Na+ in the absence of K+, an inside acidic delta pH was generated at pH(out) values above 7.0. After addition of diethanolamine the inside acidic delta pH collapsed transiently and then returned to the original value concomitant with the extrusion of Na+, suggesting the participation of a Na+/H+ antiporter for the generation of an inside acidic delta pH. In the presence of 400 mM-K+, at least 5 mM-Na+ was required to support cell growth at pH(out) below 7.5. An increase in Na+ concentration allowed the cells to grow at a more alkaline pH(out). Furthermore, cells containing more Na+ inside could more easily adapt to grow at alkaline pH(out). These results indicated the importance of Na+ in acidification of the cell interior via a Na+/H+ antiporter in order to support cell growth at alkaline pH(out) under conditions where the activity of a K+/H+ antiporter is marginal.     

Isolation and Properties of Enterococcus hirae Mutants Defective in the Potassium/Proton Antiport System

A K+/H+ antiporter regulates cytoplasmic pH in Enterococcus hirae growing at alkaline pH. Mutants defective in this antiport activity were alkaline pH sensitive. One mutant, Pop1, lacked both K+/methylamine exchange at pH 9.5 and concomitant acidification of cytoplasmic pH. Pop1 grew well at pHs below 8 but did not at pHs above 9, conditions under which cytoplasmic pH was not fully acidified.     

Inducible and constitutive expression of pMOL28-encoded nickel resistance in Alcaligenes eutrophus N9A.

The nickel and cobalt resistance plasmid pMOL28 was transferred by conjugation from its natural host Alcaligenes eutrophus CH34 to the susceptible A. eutrophus N9A. Strain N9A and its pMOL28-containing transconjugant M220 were studied in detail. At a concentration of 3.0 mM NiCl2, the wild-type N9A did not grow, while M220 started to grow at its maximum exponential growth rate after a lag of 12 to 24 h. When grown in the presence of subinhibitory concentrations (0.5 mM) of nickel salt, M220 grew actively at 3 mM NiCl2 without a lag, indicating that nickel resistance is an inducible property. Expression of nickel resistance required active growth in the presence of nickel salts at a concentration higher than 0.05 mM. Two mutants of M220 were isolated which expressed nickel resistance constitutively. When the plasmids, pMOL28.1 and pMOL28.2, carried by the mutants were transferred to strains H16 and CH34, the transconjugants expressed constitutive nickel resistance. This indicates that the mutation is plasmid located. Both mutants expressed constitutive resistance to nickel and cobalt. Physiological studies revealed the following differences between strain N9A and its pMOL28.1-harboring mutant derivatives. (i) The uptake of 63NiCl2 occurred more rapidly in the susceptible strain and reached a 30- to 60-fold-higher amount that in the pMOL28.1-harboring mutant; (ii) in intact cells of the susceptible strain N9A, the cytoplasmic hydrogenase was inhibited by 1 to 5 nM NiCl2, whereas 10 mM Ni2+ was needed to inhibit the hydrogenase of mutant cells; (iii) the minimal concentration of nickel chloride for the derepressed synthesis of cytoplasmic hydrogenase was lower in strain N9A (1 to 3 microM) than in the constitutive mutant (8 to 10 microM).     

Characterizing the pH-dependent stability and catalytic mechanism of the family 11 xylanase from the alkalophilic Bacillus agaradhaerens

The xylanase, BadX, from the alkalophilic Bacillus agaradhaerens was cloned, expressed and studied in comparison to a related family 11 xylanase, BcX, from B. circulans. Despite the alkaline versus neutral conditions under which these bacteria grow, BadX and BcX both exhibit optimal activity near pH 5.6 using the substrate o-nitrophenyl beta-xylobioside. Analysis of the bell-shaped activity profile of BadX yielded apparent pK(a) values of 4.2 and 7.1, assignable to its nucleophile Glu94 and general acid Glu184, respectively. In addition to having an approximately 10-fold higher k(cat)/K(m) value with this substrate at pH 6 and 40 degrees C, BadX has significantly higher thermal stability than BcX under neutral and alkaline conditions. This enhanced stability, rather than a shift in its pH-optimum, may allow BadX to hydrolyze xylan under conditions of elevated temperature and pH.     

Ultracytochemical evidence for a proton-pump adenosine triphosphatase in chick osteoclasts

Summary The distribution of Mg^{+ +}-ATPase in osteoclasts along the endosteal surface of the chick tibia was investigated by neutral and alkaline pH cytochemical methods at the electron-microscopic level. Reaction product was observed in mitochondria, cytoplasmic vesicles, and ruffled-border membrane. Levamisole, ouabain, and vanadate did not affect the enzymatic activity. Para-chloromercuribenzoic acid (PCMB) prevented staining of mitochondria, ruffled border, and most cytoplasmic vesicles. Tri-n-butyltin decreased the amount of reaction product in cytoplasmic vesicles and ruffled-border membrane, but did not inhibit reaction product formation within mitochondria. Duramycin, which is a potent inhibitor for proton-pump ATPase, blocked reaction-product formation along the ruffled-border membrane, in mitochondria, and in cytoplasmic vesicles at alkaline pH, but not at neutral pH. It is concluded that the alkaline pH method for Mg^{+ +}-ATPase appears to demonstrate sites of proton-pump ATPase activity.     

Lowering of cytoplasmic pH is essential for growth of Streptococcus faecalis at high pH.

The growth of Streptococcus faecalis at high pH was significantly stimulated by carbonate. In the absence of added carbonate the cells were unable to grow at a pH above 9.5, but in media containing 50 mM HCO3- they grew even at pH 10.5. Both rate and yield of growth at pH 9.5 were significantly stimulated by as little as 5 mM carbonate. The cytoplasmic pH in growing cells was maintained at about 7.8 to 8.2, whereas the medium pH ranged from 8.4 to 9.5. Nigericin and gramicidin D, ionophores which conduct protons, blocked growth at pH 9.5 but not at pH 7.5. These results indicate that lowering of the cytoplasmic pH is essential for the growth of this organism at high pH.     

Mutations that alter the signal sequence of alkaline phosphatase in Escherichia coli.

A phoA-lacZ gene fusion was used to isolate mutants altered in the alkaline phosphatase signal sequence. This was done by selecting Lac+ mutants from a phoA-lacZ fusion strain that produces a membrane-bound hybrid protein and is unable to grow on lactose. Two such mutant derivatives were characterized. The mutations lie within the phoA portion of the fused gene and cause internalization of the hybrid protein. When the mutations were genetically recombined into an otherwise wild-type phoA gene, they interfered with export of alkaline phosphatase to the periplasm. The mutant alkaline phosphatase protein was found instead in the cytoplasm in precursor form. DNA sequence analysis demonstrated that both mutations lead to amino acid alterations in the signal sequence of alkaline phosphatase.     

Cell-dependent requirement of human immunodeficiency virus type 1 gp41 cytoplasmic tail for Env incorporation into virions

Growth kinetics in lymphocytic H9 and M8166 cells of two mutants of human immunodeficiency virus type 1 (HIV-1) with deleted gp41 cytoplasmic tails were examined. While the mutant viruses designated CTdel-44 and CTdel-144 were able to grow in M8166 cells, they were unable to grow in H9 cells. Transfection and single-round infectivity assays demonstrated that they are defective in the early phase of viral replication in H9 cells. Analysis of the mutant virions revealed drastically reduced incorporation of Env gp120 (compared with the incorporation of wild-type virions) in H9 cells but normal incorporation in M8166 cells. These results indicate that the HIV-1 cytoplasmic tail of gp41 determines virus infectivity in a cell-dependent manner by affecting incorporation of Env into virions and suggest the involvement of a host cell factor(s) in the Env incorporation.     

Sequential cold-sensitive mutations in Aspergillus fumigatus.

Mutants of thermotolerant fungus Aspergillus fumigatus I-21 (ATCC 32722) unable to grow at 37 degrees C were sought. Cold-sensitive mutants were enriched from progeny spores of gamma-irradiated conidia by two or more incubations at various nonpermissive temperatures alternating with filtrations through chessecloth. The approximate minimum, optimum, and maximum growth temperatures of the parent were 12, 40, and 50 degrees C, respectively. Mutants unable to grow at 37 degrees C were not successfully isolated directly from the wild type. A mutant unable to grow at 25 degrees C was isolated and mutations further increasing the cold sensitivity by increments of 3-5 degrees C were found to occur. Mutants completely unable to grow at 37 degrees C were obtained by five sequential mutations. All mutants grew as fast as the wild-type parent at 45 degrees C and higher. Each mutant produced revertants able to grow not only at the nonpermissive temperature used for its isolation but also at lower temperatures.