Effect of Glutaraldehyde on Cell Viability, Triphenyltetrazolium Reduction, Oxygen Uptake, and β-Galactosidase Activity in Escherichia coli

Acid (pH 5) and alkaline (pH 8.5) glutaraldehyde solutions were compared for their effects on cell viability, oxygen uptake, and beta-galactosidase activities in Escherichia coli. The action of glutaraldehyde at pH 7 on dehydrogenase activity was also studied. Dehydrogenase activity was inhibited at aldehyde concentrations which had little effect on cell viability. In contrast, oxygen uptake and beta-galactosidase activity took place in cells killed by acid or alkaline glutaraldehyde. The effect of glutaraldehyde on dehydrogenase activity and beta-galactosidase activity of disrupted suspensions was also investigated. The dialdehyde was considerably less inhibitory to these enzyme systems than to those of whole cells, and it is thus feasible that the results with whole cells are a consequence of its interaction with, and strengthening of, the outer cell surface, thereby preventing ready access of substrate to enzyme.     

Establishment of an osseous cell line from fetal rat calvaria using an immunocytolytic method of cell selection: characterization of the cell line and of derived clones

Using selective media and complement-mediated lysis of primary cultures of a fetal rat calvarial cell population, we have developed a cell line (OBCK6) that exhibits osteoblastic characteristics. OBCK6 cells demonstrated enhanced parathyroid hormone (PTH)-stimulated adenylate cyclase activity relative to the primary calvarial population, production of alkaline phosphatase activity and type 1 collagen, and the capacity to form mineralized nodules in unsupplemented medium after prolonged (22-26 day) culture. Two sublines, CFK1 and CFK2, which were isolated by dilution cloning, differed morphologically and with respect to growth rate. CFK1 cells demonstrated high PTH and prostaglandin E2-stimulated adenylate cyclase activity, whereas only low PTH-stimulated activity was observed in CFK2 cells. Retinoic acid and 1,25-dihydroxyvitamin D3 [1,25(OH)2D3] each reduced PTH-stimulated adenylate cyclase activity in both the cell types. Retinoic acid and dexamethasone reduced and 1,25(OH)2D3 enhanced alkaline phosphatase activity in these cells. PTH significantly augmented alkaline phosphatase activity to a much greater extent in CFK1 than in CFK2 cells. Both CFK1 and CFK2 cells expressed type I but type III collagen, and neither expressed osteocalcin. Strong Alcian blue staining of CFK2 cells was suggestive of a cartilaginous phenotype. These three cell lines, therefore, demonstrated discrete characteristics of skeletal cell function and should provide important models for evaluation of mechanisms of mineralization and for control of skeletal cell growth and mesenchymal differentiation in vitro.     

Chemical inactivation of HIV on surfaces.

To assess whether alcohol and glutaraldehyde are effective disinfectants against dried HIV the virucidal effects of 70% alcohol (ethanol and industrial methylated spirit) and 1% and 2% alkaline glutaraldehyde were tested against cell associated and cell free HIV dried on to a surface. Virus stock (100 microliters) or 10,000 cultured C8166 T lymphocytes infected with HIV were dried onto sterile coverslips and immersed in 2% and 1% alkaline glutaraldehyde and 70% ethanol for 30 seconds and one, two, four, and 10 minutes, there being an additional time point of 20 minutes for cell free virus disinfected with 70% industrial methylated spirit. In addition, virus stock in neat serum was tested with 1% and 2% alkaline glutaraldehyde to see whether the fixative properties of glutaraldehyde impair its virucidal properties. Virus activity after disinfection was tested by incubating the coverslips (cell associated virus) or the coverslips and sonicated cell free virus with C8166 T lymphocytes. The lymphocytes were examined for the formation of syncytia and HIV antigens were assayed in the culture fluid. Both 2% and 1% alkaline glutaraldehyde inactivated cell free HIV within one minute; 2% alkaline glutaraldehyde also inactivated cell free virus in serum within two minutes, but a 1% solution was ineffective after 15 minutes'' immersion. Cell associated HIV was inactivated by 2% alkaline glutaraldehyde within two minutes. Seventy per cent industrial methylated spirit failed to inactivate cell free and cell associated HIV within 20 and 15 minutes, respectively, and 70% ethanol did not inactivate cell free virus within 10 minutes. Seventy per cent industrial methylated spirit and ethanol are not suitable for surface disinfection of HIV. Fresh 2% solutions of alkaline glutaraldehyde are effective, but care should be taken that they are not too dilute or have not become stale when used for disinfecting HIV associated with organic matter.     

Parathyroid cell polarity as revealed by cytochemical localization of ATPases, alkaline phosphatase and 5'-nucleotidase

Activities of Ca2(+)-dependent ATPase, Mg2(+)-dependent ATPase, Na(+)-K(+)-dependent ATP-ase, alkaline phosphatase, and 5'-nucleotidase were demonstrated after incubation of 40-microns vibratome sections of bovine parathyroids and subsequent visualization by electron microscopy. Prior to sectioning, parathyroid tissue was fixed with 1% glutaraldehyde for localization of alkaline phosphatase, and with 2% formaldehyde and 1% glutaraldehyde for demonstration activities of ATPases and 5'-nucleotidase. The activities of the five enzymes were found at the apicolateral domain of the plasma membrane in parathyroid cells, i.e. at the site parathyroid cells face neighbouring parenchymal cells. Ca2(+)-ATPase activity was also seen on mitochondria, Golgi complex and RER. The presence of these plasma membrane associated enzymes at the apicolateral domain only indicate polarity in parathyroid cells. It further suggests that many processes including transmembrane transport take place at the apicolateral domain, the site of parathyroid cells opposing blood capillaries.     

Simultaneous demonstration of bone alkaline and acid phosphatase activities in plastic-embedded sections and differential inhibition of the activities

Summary Bone alkaline (AlP) and acid phosphatase (AcP) activities were simultaneusly demonstrated in tissue sections obtained from mice, rats, and humans. The method involved tissue fixation in ethanol, embedding in glycol methacrylate (GMA), and demonstration of AlP and AcP activities employing a simultaneous coupling azo dye technique using substituted naphthol phosphate as a substrate. AlP activity was demonstrated first followed by AcP activity. Both enzyme activities were demonstrated in tissue sections from bones fixed and/or stored in acetone or 70% ethanol for up to 14 days or stored in GMA for 2 months. AlP activity in tissue sections from bones fixed in 10% formalin, 2% glutaraldehyde, or formal-calcium, however, was markedly inhibited after 3–7 days and was no longer detectable after 14 days of fixation. Moreover, AlP activity was diminished in tissue sections from bones fixed in 70% ethanol or 10% formalin and subsequently demineralized in 10% EDTA (pH7) for 2 days, and the activity was completely abolished in tissue sections from bones subsequently demineralized in 5% formic acid: 20% sodium citrate (1:1, pH 4.2) for 2 days. Methyl methacrylate (MMA) embedding at concentrations above 66% completely inhibited AlP activity. AcP activity, however, was only partially inhibited by formalin, glutaraldehyde, or formal-calcium after 7 or 14 days of fixation or by MMA embedding and was unaffected by the demineralizing agent formic acid-citrate for 2 days. While AcP activity was preserved in bones fixed in formalin and subsequently demineralized in EDTA, the activity was completely abolished when EDTA demineralization was carried out on bones previously fixed in 70% ethanol. These results indicate that bone AlP and AcP activities can be demonstrated simultaneously in the same section using a simple tissue preparation technique and that the activities are retained in tissues fixed and/or stored in acetone, 70% ethanol or GMA, but are differentially inactivated by other fixatives studied, and by EDTA, formic acid-citrate, and MMA embedding.Abbreviations AcP acid phosphatase - AlP alkaline phosphatase - GMA glycol methacrylate - MMA methyl methacrylate - EDTA ethylenediaminetetraacetic acid     

Human bone cell enzyme expression and cellular heterogeneity: correlation of alkaline phosphatase enzyme activity with cell cycle

Alkaline phosphatase, long implicated in biomineralization, is a feature of the osteoblast phenotype. Yet in cultured bone cells, only a fraction stain positive histochemically. To determine whether osteoblast enzyme expression reflects cellular heterogeneity with respect to cell cycle distribution or length of time in culture, the activities of alkaline phosphatase, tartrate-resistant and -sensitive acid phosphatases, and non-specific esterases were assayed kinetically and histochemically. In asynchronous subconfluent cultures, less than 15% of the cells stained positive and assayed activity was 0.04 IU/10(6) cells/cm2. After 1 week, the percent of alkaline phosphatase positive-staining cells increased 5-fold, while activity increased 10-fold. Non-specific esterases and tartrate-sensitive acid phosphatase were constitutive throughout time in culture, whereas tartrate-resistant acid phosphatase activity appeared after 2 weeks. Cell cycle analysis of human bone cells revealed a growth fraction of 80%, an S phase of 8.5 h, G2 + 1/2 M of 4 h, and a G1 of 25-30 h. In synchronous cultures induced by a thymidine-aphidicolin protocol, alkaline phosphatase activity dropped precipitously at M phase and returned during G1. A majority of the alkaline phosphatase activity lost from the cell surface at mitosis was recovered in the medium. Tartrate-sensitive acid phosphatase and non-specific esterase levels were relatively stable throughout the cell cycle, while tartrate-resistant acid phosphatase activity was not assayable at the density used in synchronous cultures. From these data, variations in alkaline phosphatase activity appear to reflect the distribution of cells throughout the cell cycle.     

Glutaraldehyde: its uptake by sporing and non-sporing bacteria, rubber, plastic and an endoscope

Uptake of glutaraldehyde to bacterial spores, germinating and outgrowing spores, vegetative cells (sporing and non-sporing bacteria), various types of rubber, plastic and an endoscope was investigated. Escherichia coli NCTC 10418 exhibited greatest uptake, followed by Bacillus subtilis NCTC 8236 vegetative cells and Staphylococcus aureus NCTC 6571. Germinated and outgrowing B. subtilis spores adsorbed more glutaraldehyde than resting spores, but less than vegetative cells. Low concentrations of alkaline and acid glutaraldehyde increased the surface hydrophobicity and inhibited the germination of bacterial spores, the alkaline solution to a greater extent in both cases.
Rubbers exhibited varying degrees of uptake and are listed in decreasing order of uptake: red rubber, fluorinated rubber (Vinescol), silicone rubber (Silescol), butyl rubber (Butyl XX). Polypropylene, the only plastic examined, was found not to adsorb any glutaraldehyde. The endoscope adsorbed more glutaraldehyde (per gram) than fluorinated rubber but less than red rubber. No damage was observed.     

Glutaraldehyde: its uptake by sporing and non-sporing bacteria, rubber, plastic and an endoscope

Uptake of glutaraldehyde to bacterial spores, germinating and outgrowing spores, vegetative cells (sporing and non-sporing bacteria), various types of rubber, plastic and an endoscope was investigated. Escherichia coli NCTC 10418 exhibited greatest uptake, followed by Bacillus subtilis NCTC 8236 vegetative cells and Staphylococcus aureus NCTC 6571. Germinated and outgrowing B. subtilis spores adsorbed more glutaraldehyde than resting spores, but less than vegetative cells. Low concentrations of alkaline and acid glutaraldehyde increased the surface hydrophobicity and inhibited the germination of bacterial spores, the alkaline solution to a greater extent in both cases. Rubbers exhibited varying degrees of uptake and are listed in decreasing order of uptake: red rubber, fluorinated rubber (Vinescol), silicone rubber (Silescol), butyl rubber (Butyl XX). Polypropylene, the only plastic examined, was found not to adsorb any glutaraldehyde. The endoscope adsorbed more glutaraldehyde (per gram) than fluorinated rubber but less than red rubber. No damage was observed.     

Chemical modification of Bacillus thuringiensis subsp. thuringiensis (HD-524) trypsin-activated endotoxin: implication of tyrosine residues in lepidopteran cell lysis

A purified protein fraction from a solubilized and trypsin-digested extract of Bacillus thuringiensis subsp. thuringiensis (HD-524) fermentation powder was lytic to cells from several lepidopteran lines. Maximum yield was obtained by alkaline carbonate-thiocyanate solubilization of washed powder followed by trypsin digestion and Sephacryl (S-300) chromatography. The alkaline carbonate-solubilized fraction consisted predominantly of two bands on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with MW of 144 +/- 0.9 kDa and 134 +/- 1.4 kDa. After trypsin treatment and column chromatography, the cytolytic fraction consisted of a major band with a MW of 60.0 +/- 1.8 kDa and a minor band of 69 +/- 0.9 kDa. Cells from Trichoplusia ni (TN368) were most susceptible to lysis with 50% of cells lysed at 3 micrograms/ml, followed by Spodoptera frugiperda cells (SF21AE) exhibiting 50% cell lysis at 5 micrograms/ml and Lymantria dispar cells (Ld652Y) showing 40% lysis at 10 micrograms/ml. Chemical modification of the polypeptides was performed to determine the role of certain amino acid residues in the cytolytic activity. The group-specific reagent tetranitromethane was used to nitrate and oxidize tyrosine and cysteine residues, respectively. Cysteine residues alone were also modified with p-hydroxymercuribenzoic acid. Lysine residues were modified with O-methylisourea. Of the three types of amino acid residues, only the modification of tyrosine resulted in reduced cell lysis.     

Metabolic depletion inhibits the uptake of nontransferrin-bound iron by K562 cells

The effect of metabolic inhibitors on nontransferrin bound iron transport by K562 cells was investigated. Incubation with 1 microM rotenone, 10 microM antimycin, or 0.5 mM 2,4-dinitrophenol effectively reduced ATP levels by approximately 50%. Both the rate and extent of Fe+3 uptake were impaired in ATP-depleted cells, which display a reduced Vmax for uptake. K562 cell ferrireductase activity was also lowered by metabolic inhibitors, suggesting that the apparent energy requirements for transport reside in the reduction of Fe+3 to Fe+2. However, ATP depletion was found to inhibit the rate and extent of Fe+2 uptake as well. Thus, the transbilayer passage of Fe+2 and/or Fe+3 appears to be an energy-requiring process. These features possibly reflect properties of the transport mechanism associated with a recently identified K562 cell transport protein, called SFT for "Stimulator of Fe Transport," since exogenous expression of its activity is also affected by ATP depletion.     

Temperature-Induced Changes in the Sporicidal Activity and Chemical Properties of Glutaraldehyde

Freshly prepared 2% acid and alkaline glutaraldehyde solutions were stored at 4, 20, and 37 C. At intervals, samples were removed and changes in pH, ultraviolet spectrum, and sporicidal activity (against Bacillus pumilus spores) were recorded. Alkaline solutions stored at 4 C showed little changes in these properties, whereas such solutions stored at 37 C became turbid and showed a decrease in pH, marked changes in ultraviolet spectrum, and an almost complete loss of sporicidal activity. Intermediate results were obtained with alkaline solutions stored at 20 C. In contrast, acid 2% glutaraldehyde solutions (initial pH 3.5) showed comparatively few changes in their properties. Treatment of spores with freshly prepared glutaraldehyde solutions (0.5%) at temperature above 40 C reduced the effect of pH on sporicidal activity.     

Effect of Glutaraldehyde on the Outer Layers of Escherichia coli

S ummary : Sodium lauryl sulphate (SLS) at pH 3 and 8 lysed cell walls of Escherichia coli. Pretreatment with glutaraldehyde at pH 3 and at pH 8 prevented this lysis. SLS induced maximum lysis of E. coli cells at 40°; pretreatment of cells with glutaraldehyde prevented this lysis also. Electrophoretic studies indicated that glutaraldehyde accumu lated on the surface of E. coli cells more rapidly in acid than in alkaline conditions, and that it blocked amino groups on the surface layer of Bacillus subtilis spores. The relationship of these findings to the bactericidal efficiency of glutaraldehyde in acid and alkaline solution is discussed.     

Modification of erythrocyte physicochemical properties by millimolar concentrations of glutaraldehyde.

The effects of low levels of glutaraldehyde uptake (less than 120 mumol/10(10) cells) on the physicochemical properties of human red blood cells (RBC) were investigated. Salient effects include: by different measures of cell deformability, the extent of glutaraldehyde uptake required to decrease cellular deformability was shown to range from approximately 8 to 30 mumol/10(10) cells; osmotically stressed red cells exhibit complete hemolysis when the level of glutaraldehyde uptake is less than 28 mumol/10(10) cells and no hemolysis when uptake is less than 70 mumol/10(10) cells with the extent of hemolysis decreasing in an approximately linear manner with glutaraldehyde uptake between these limits; glutaraldehyde uptake of up to 58 mumol/10(10) cells does not change the cells' density, mean cell volume or ability to retain potassium.     

PEG和镍处理对水稻细胞磷酸脂酶活性及再生的影响

以水稻为材料研究了PEG和镍处理对组织培养细胞现分化及其磷酸脂酶活性的影响,结果表明18mg/L或30mg/LPEG,10mg/LNiCl2处理14d均能明显促进细胞再生,但20mg/LiCl2处理降低细胞再生能力,水稻细胞再生率与其酸性磷酸脂酶活性成显著正相关。     

Simultaneous demonstration of bone alkaline and acid phosphatase activities in plastic-embedded sections and differential inhibition of the activities

Bone alkaline (AlP) and acid phosphatase (AcP) activities were simultaneously demonstrated in tissue sections obtained from mice, rats, and humans. The method involved tissue fixation in ethanol, embedding in glycol methacrylate (GMA), and demonstration of AlP and AcP activities employing a simultaneous coupling azo dye technique using substituted naphthol phosphate as a substrate. AlP activity was demonstrated first followed by AcP activity. Both enzyme activities were demonstrated in tissue sections from bones fixed and/or stored in acetone or 70% ethanol for up to 14 days or stored in GMA for 2 months. AlP activity in tissue sections from bones fixed in 10% formalin, 2% glutaraldehyde, or formal-calcium, however, was markedly inhibited after 3-7 days and was no longer detectable after 14 days of fixation. Moreover, AlP activity was diminished in tissue sections from bones fixed in 70% ethanol or 10% formalin and subsequently demineralized in 10% EDTA (pH 7) for 2 days, and the activity was completely abolished in tissue sections from bones subsequently demineralized in 5% formic acid: 20% sodium citrate (1:1, pH 4.2) for 2 days. Methyl methacrylate (MMA) embedding at concentrations above 66% completely inhibited AlP activity. AcP activity, however, was only partially inhibited by formalin, glutaraldehyde, or formal-calcium after 7 or 14 days of fixation or by MMA embedding and was unaffected by the demineralizing agent formic acid-citrate for 2 days. While AcP activity was preserved in bones fixed in formalin and subsequently demineralized in EDTA, the activity was completely abolished when EDTA demineralization was carried out on bones previously fixed in 70% ethanol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphate uptake in Chlorella pyrenoidosa : II. Effect of pH and of SH reagents.

The sensitivity of the phosphate transport system to pCMPS after phosphate starvation is dependent on protein synthesis. This fact is related to the development of transport activity at alkaline pH. In non-starved cells, the presence of only one peak of maximal activity for phosphate uptake at neutral pH (at low and high concentration) has been observed. However, in phosphate starved cells, two peaks of maximal activity (at low phosphate concentration) at neutral and alkaline pH are present. In starved cells, pCMPS inhibits more intensely the phosphate transport activity at alkaline pH than at neutral pH. By contrast, NEM inhibits the phosphate transport more strongly at neutral than at alkaline pH. Phosphate uptake at neutral and alkaline pH are sensitive to osmotic shock, but phosphate uptake at alkaline pH is decreased more than at neutral pH. The results could be interpreted either by assuming that the membrane surroundings change during phosphate starvation or that two transport systems are present in starved cells whereas only one transport system exists in non-starved cells.     

Transport ATPase cytochemistry: ultrastructural localization of potassium-dependent and potassium-independent phosphatase activities in rat kidney cortex

A cytochemical method for the light and electron microscope localization of the K- and Mg-dependent phosphatase component of the Na-K-ATPase complex was applied to rat kidney cortex, utilizing p-nitrophenylphosphate (NPP) as substrate. Localization of K-N-ATPase activity in kidneys fixed by perfusion with 1% paraformaldehyde -0.25% glutaraldehyde demonstrated that distal tubules are the major cortical site for this sodium transport enzyme. Cortical collecting tubules were moderately reactive, whereas activity in proximal tubules was resolved only after short fixation times and long incubations. In all cases, K-NPPase activity was restricted to the cytoplasmic side of the basolateral plasma membranes, which are characterized in these neplron segments by elaborate folding of the cell surface. Although the rat K-NPPase appeared almost completely insensitive to ouabain with this cytochemical medium, parallel studies with the more glycoside-sensitive rabbit kidney indicated that K-NPPase activity in these nephron segments is sensitive to this inhibitor. In addition to K-NPPase, nonspecific alkaline phosphatase also hydrolyzed NPP. The latter could be differentiated cytochemically from the specific phosphatase, since alkaline phosphatase was K-independent, insensitive to ouabain, and specifically inhibited by cysteine. Unlike K-NPPPase, alkaline phosphatase was localized primarily to the extracellular side of the microvillar border of proximal tubules. A small amount of cysteine-sensitive activity was resolved along peritubular surfaces of proximal tubules. Distal tubules were unreactive. In comparative studies, Mg-ATPase activity was localized along the extracellular side of the luminal and basolateral surfaces of proximal and distal tubules and the basolateral membranes of collecting tubules.     

Rapid screening method for Mycobactericidal activity of chemical germicides that uses Mycobacterium terrae expressing a green fluorescent protein gene

The slow growth of mycobacteria in conventional culture methods impedes the testing of chemicals for mycobactericidal activity. An assay based on expression of the green fluorescent protein (GFP) by mycobacteria was developed as a rapid alternative. Plasmid pBEN, containing the gene encoding a red-shifted, high-intensity GFP mutant, was incorporated into Mycobacterium terrae (ATCC 15755), and GFP expression was observed by epifluorescence microscopy. Mycobactericidal activity was assessed by separately exposing a suspension of M. terrae(pBEN) to several dilutions of test germicides based on 7.5% hydrogen peroxide, 2.4% alkaline glutaraldehyde, 10% acid glutaraldehyde, and 15.5% of a phenolic agent for contact times ranging from 10 to 20 min (22 degrees C), followed by culture of the exposed cells in broth (Middlebrook 7H9) and measurement of fluorescence every 24 h. When the fluorescence was to be compared with CFU, the samples were plated on Middlebrook 7H11 agar and incubated for 4 weeks. No increase in fluorescence or CFU occurred in cultures in which the cells had been inactivated by the germicide concentrations tested. Where the test bacterium was exposed to ineffective levels of the germicides, fluorescence increased after a lag period of 1 to 7 days, corresponding to the level of bacterial inactivation. In untreated controls, fluorescence increased rapidly to reach a peak in 2 to 4 days. A good Pearson correlation coefficient (r > or =0.85) was observed between the intensity of fluorescence and the number of CFU. The GFP-based fluorescence assay reduced the turnaround time in the screening of chemical germicides for mycobactericidal activity to < or =7 days.     

A histochemical study on the adrenal components of the teleost Cirrhinus mrigala (Ham.)

The adrenal components of C. mrigala are embedded in the pronephric cephalic kidney around the post cardinal vein. The cortical cells responded positively to the lipids, ascorbic acid, delta 5-3 beta-HSD, G-6-PD, MAO, acid and alkaline phosphatase tests. The presence of intense MAO activity may suggest the possible involvement of monoamines in the adrenocortical function. Localization of lipids and delta 5-3 beta-HSD show the sites of corticosteroid synthesis. In the chromaffin cells, MAO, acid and alkaline phosphatase activity was moderate whereas they gave a strong reaction to ascorbic acid test in comparison to the cortical cells. Noradrenaline (NA) and adrenaline (A) storing cells were differentiated adopting glutaraldehyde silver, dichromate and iodate techniques. NA and A storing cells are almost totally depleted of their contents after reserpine treatment. The histochemical response of the adrenal gland of this species is largely comparable to that of higher vertebrates.     

Identification of membrane domains of the Na+/H+ antiporter (NhaA) protein from Helicobacter pylori required for ion transport and pH sensing

The Na+/H+ antiporter from Helicobacter pylori (HP NhaA) is normally active within the pH range 6.0-8.5. In contrast, the NhaA from Escherichia coli (EC NhaA) is active only within the alkaline pH range 7.5-8.5. We studied structures of HP NhaA involved in ion transport and pH sensing by analyzing mutants with defects in NhaA activity. The 36 mutants were classified into three types. The first type exhibited very low or null activity at all pH levels and had amino acid substitutions in the transmembrane segments (TM) 4, 5, 10, and 11, implicating these TMs in ion transport. The second type, which had amino acid substitutions at Met-138, Phe-144, and Lys-347 in TM 4 and 10, exhibited very low antiporter activity at acidic pH but had significantly higher activity at alkaline pH. These results imply that TM 4 (Met-138 and Phe-144) and 10 (Lys-347) are involved in supporting transport activity at acidic pH, in addition to their essential role in the overall transport mechanism. The third type of mutant exhibited very low antiporter activity at alkaline pH but relatively normal activity at acidic pH and had amino acid substitutions in loop 7 (a hydrophilic region between TM 7 and 8) as well as in TM 8, suggesting that these regions are involved in antiporter activation at alkaline pH. Three revertants that suppress a Lys-347 mutation were identified. Two of three suppressor mutations were located in loops 2 and 4, suggesting a functional interaction between these regions (loops 2 and 4 and TM 10). Thus, HP NhaA activity may be modulated by two independent factors that are dependent on pH: an activation mechanism at acidic pH, which is regulated by residues within TM 4 and 10 and another mechanism functioning at alkaline pH regulated by residues within loop 7 and TM 8.