Effect of plasma membrane ion permeability modulators on respiration and heat output of wheat roots

A study was made of changes in the rates of respiration, heat production, and membrane characteristics in cells of excised roots of wheat seedlings under the modulation of plasma membrane ion permeability by two membrane active compounds: valinomycin (20 microM (V50)) and chlorpromazine (50 microM (CP50) and 100 microM (CP100)). Both compounds increased the loss of potassium ions, which correlated with the lowering of membrane potential, rate of respiration, and heat production after a 2 h exposure. The differences in alteration of these parameters were due to specific action of either compound on the membrane and to the extent of ion homeostasis disturbance. V20 had a weak effect on the studied parameters. V50 caused an increase of the rate of respiration and heat production, which enhanced following a prolonged action (5 h) and were associated with ion homeostatis restoration. The extent of alteration of membrane characteristics (an increase of potassium loss by roots, and lowering of cell membrane potential) as well as energy expense under the action of CP50 during the first period were more pronounced than in the presence of V50. During a prolonged action of CP50, the increase of respiration intensity and heat production correlated with partial recovery of ion homeostatis in cells. Essential lowering of membrane potential and substantial loss of potassium by cells, starting from the early stages of their response reaction, were followed by inhibition of respiration rate and heat production. Alterations of the structure and functional characteristics of excised root cells indicate the intensification of the membrane-tropic effect of a prolonged action of CP100, and the lack of cell energy resources.     

Phenothiazines and related compounds disrupt mitochondrial energy production by a calmodulin-independent reaction

Phenothiazines and related compounds bind to mitochondrial membranes in approximate proportion to their affinities for calmodulin. Penfluridol (16 microM), pimozide (20 microM), or trifluoperazine (66 microM) completely inhibit ADP-stimulated respiration in isolated rat liver mitochondria, but exert no effect on either uncoupler- or Ca2+-stimulated respiration. The inhibition of ADP-stimulated respiration results from inhibition of the oligomycin-sensitive ATPase. Inhibition of the ATPase does not involve interaction of phenothiazine with calmodulin. The addition of calmodulin with or without calcium to mitochondrial inner membrane preparations has no effect on ATPase activity. The addition of EGTA and the ionophore A23187 prior to the addition of phenothiazine does not prevent the phenothiazine-induced inhibiton of the ATPase. Measurements of inner membrane calmodulin content by gel electrophoresis or cyclic nucleotide phosphodiesterase activation are negative. Despite the absence of calmodulin in the inner membrane preparations, 12.5 nmol trifluoperazine bind per 100 microgram of membrane protein with an association constant, K, of 6.5 . 10(4) M-1. We conclude that calmodulin-binding neuroleptic agents, when added to whole cells, have the potential to disrupt mitochondrial energy production by a reaction which apparently does not involve a phenothiazine-calmodulin interaction.     

Interaction of membrane proton conductivity,membrane and oxidation-reduction potential in Escherichia coli

It was shown that the proton conductivity of Escherichia coli membranes depends on pH and other conditions of bacterial growth. It is considerably lower in cells fermenting glucose and accomplishing the nitrate-nitrite respiration compared with cells accomplishing the oxygen respiration. Proton conductivity increases substantially with decreasing pH of medium. It was found that proton conductivity is related to the redox and membrane potentials of cells. The energy-dependent flux of protons from cells and the ATPase activity of membrane vesicles considerably vary depending on whether bacteria are grown under aerobic or anaerobic conditions. The H+ flux from cells fermenting glucose (pH 7.5) was 1.7 times greater than the H+ flux from cells that accomplish the nitrate-nitrite and oxygen respiration. The N,N'-dicyclohexylcarbodiimide (DCCD)-sensitive ATPase activity increased 2.5 times as K+ concentration increased to 100 mM (including residual K+ in potassium-free medium). The DCCD-sensitive ATPase activity considerably decreased with decreasing pH of medium, whereas the ATPase activity that was not suppressed by DCCD was stimulated. These results can be used for establishing the relationship between membrane proton conductivity and the energy-dependent H+ flux and ATPase activity.     

The influence of plasma membrane ion permeability modulators on superoxide formation and bioelectrical characteristics of wheat root cells

Changes in superoxide radical formation and bioelectrical characteristics of excised wheat root cells under modification of plasma membrane ion permeability were studied. It was shown that a 2 h treatment of excised roots with valinomycin (Val, 20 microM), N, N'-dicyclohexylcarbodimide (DCCD, 100 microM), gramicidin S (Gr, 20 microM), chlorpromazine (CPZ, 100 microM) caused an increased loss of potassium by cells, lowering of membrane potential (MP) and electrical input resistance (Rin) of the cells. The superoxide formation by excised root cells diminished (under DCCD) or remained at the control level (under Val), which was accompanied by a minor decrease of MP and Rin of the cells, a small increase in potassium loss by excised roots, and in no change of pH of incubation medium. Significant depolarization of plasma membrane, dropping of Rin and essential loss of potassium ions by the cells correlated with a rise in the medium alkalinization and superoxide formation by excised roots (in the presence of Gr, CPZ). Ion channel blocker gadolinium (Gd3+, 200 microM) caused an increase of MP and Rin reduction of potassium loss by cells, and a decrease of pH of the incubation medium, and also enhancement of superoxide formation by excised root cells. It is suggested that upon plasma membrane ion permeability modification the activity of superoxide generating systems depends on the specificity and mechanisms of action of modulators, and is determined by their influence on redox state of plasma membrane as well as by peculiarities of ion transport disturbance.     

Iron-induced oxidative damage of corn root plasma membrane H(+)-ATPase

The effect of iron on the activity of the plasma membrane H(+)-ATPase (PMA) from corn root microsomal fraction (CRMF) was investigated. In the presence of either Fe(2+) or Fe(3+) (100-200 microM of FeSO(4) or FeCl(3), respectively), 80-90% inhibition of ATP hydrolysis by PMA was observed. Half-maximal inhibition was attained at 25 microM and 50 microM for Fe(2+) and Fe(3+), respectively. Inhibition of the ATPase activity was prevented in the presence of metal ion chelators such as EDTA, deferoxamine or o-phenanthroline in the incubation medium. However, preincubation of CRMF in the presence of 100 microM Fe(2+), but not with 100 microM Fe(3+), rendered the ATPase activity (measured in the presence of excess EDTA) irreversibly inhibited. Inhibition was also observed using a preparation further enriched in plasma membranes by gradient centrifugation. Addition of 0.5 mM ATP to the preincubation medium, either in the presence or in the absence of 5 mM MgCl(2), reduced the extent of irreversible inhibition of the H(+)-ATPase. Addition of 40 microM butylated hydroxytoluene and/or 5 mM dithiothreitol, or deoxygenation of the incubation medium by bubbling a stream of argon in the solution, also caused significant protection of the ATPase activity against irreversible inhibition by iron. Western blots of CRMF probed with a polyclonal antiserum against the yeast plasma membrane H(+)-ATPase showed a 100 kDa cross-reactive band, which disappeared in samples previously exposed to 500 microM Fe(2+). Interestingly, preservation of the 100 kDa band was observed when CRMF were exposed to Fe(2+) in the presence of either 5 mM dithiothreitol or 40 microM butylated hydroxytoluene. These results indicate that iron causes irreversible inhibition of the corn root plasma membrane H(+)-ATPase by oxidation of sulfhydryl groups of the enzyme following lipid peroxidation.     

Cation-stimulated ATPase activity in purified plasma membranes from tobacco hornworm midgut

Purified goblet cell apical membranes from Manduca sexta larval midgut exhibit a specific ATPase activity approx. 20-fold higher than that in the 100 000 X g pellet of a midgut homogenate. The already substantial ATPase activity in this plasma membrane segment is doubled in the presence of 20-50 mM KCl. At ATP concentrations ranging from 0.1 to 3.0 mM, the presence of 20 mM KCl leads to a 10-fold increase in the enzyme's affinity for ATP. ATPase activity is greatest at a pH of approx. 8. In addition to ATP, GTP serves as a substrate, but CTP, ADP, AMP and p-nitrophenyl phosphate do not. Either Mg2+ or Mn2+ is required for activity and cannot be replaced by Ca2+ or Zn2+. The ATPase activity of goblet cell apical membranes is inhibited by neither the typical (Na+ + K+)-ATPase inhibitors, ouabain and orthovanadate, nor by the typical mitochondrial F1F0-ATPase inhibitors, azide and oligomycin. Although 1.5 microM DCCD is ineffective, 150 microM DCCD leads to total inhibition of ATPase activity. The ATPase activity of goblet cell apical membranes is stimulated not only by K+, but also, in order of decreasing effectiveness, by Rb+, Li+, Na+ and even Mg2+. Replacement of Cl- by Br-, F- and HCO3- has less influence than variation of the cations. However, replacement of Cl- by NO3- inhibits strongly this ATPase activity. The ATPase activity described above is characteristic of the alkali metal ion pump containing apical membranes of goblet cells and is not enhanced to a similar degree in other purified midgut epithelial cell plasma membrane segments. Its localization, its broad cation specificity and its insensitivity to ouabain all mimic properties of active ion transport by the lepidopteran midgut and suggest this ATPase as a possible key component of the lepidopteran electrogenic alkali metal ion pump.     

Effects of trialkyllead compounds on growth, respiration and ion transport in Escherichia coli K12

Triethyllead and tripropyllead cations affected growth, energy metabolism and ion transport in Escherichia coli K12. The tripropyllead compound was more liposoluble than the triethyl analogue and was also more effective in inhibiting cell growth and the oxygen uptake of both intact cells and membrane particles. Triethyllead acetate (5 microM) inhibited growth on non-fermentable carbon sources, such as glycerol and succinate, more markedly than on glucose. At higher concentrations, triethyllead caused significant inhibition of respiration rates of intact cells; the concentration giving 50% inhibition was 60 microM for glycerol-grown cells and 150 microM for glucose-grown cells. Oxidation of succinate by membrane particles was less sensitive to inhibition by the tripropyl- or triethyllead compounds than were the oxidations of DL-lactate or NADH. Triethyllead acetate [1.9 mumol (mg membrane protein)-1] inhibited the reduction by NADH of cytochromes; evidence for more than one site of inhibition in the respiratory chain was obtained. Membrane-bound ATPase activity was strongly inhibited by triethyllead acetate in the absence or presence of Cl-. The concentration of inhibitor giving 50% inhibition [0.02 mumol (mg membrane protein)-1] was about two orders of magnitude lower than that required for 50% inhibition of substrate oxidation rates in membranes. Triethyllead acetate (1 microM) induced swelling of spheroplasts in iso-osmotic solutions of either NH4Cl or NH4Br, presumably as a result of the mediation by the organolead compound of Cl-/OH- and Br-/OH- antiports across the cytoplasmic membrane. Similar exchanges of OH- for F-, NO3- or SO4(2)- or the uniport of H+ could not be demonstrated. Comparisons are drawn between the effects of trialkyllead compounds and those of the more widely studied trialkyltin compounds.     

Proton pumping by tomato roots. Effect of Fe deficiency and hormones on the activity and distribution of plasma membrane H+-ATPase in rhizodermal cells

The immunocytochemical localization of the plasma membrane H⁺‐ATPase in epidermal cells of tomato roots was studied using a monoclonal antibody raised against purified maize P‐type H⁺‐ATPase. Plants subjected to iron starvation exhibited increased proton extrusion that was confined to the root elongation zones. Immunogold labelling of the H⁺‐ATPase on the plasma membrane was considerably higher in rhizodermal cells within zones with intense proton extrusion than in non‐acidifying areas of the roots. Transfer cells were formed in rhizodermal cells of Fe‐deficient plants. Quantitative determination of immunolabelling revealed that the density of PM H⁺‐ATPase in transfer cells was about twice that of ordinary epidermal cells. In transfer cells, H⁺‐ATPase was most abundant on the plasma membrane lining the labyrinthine invaginations of the peripheral cell wall. While the number of immunologically detectable ATPase molecules in transfer cells was not spatially correlated with proton extrusion activity, the frequency of transfer cells was considerably higher in acidifying root areas relative to non‐active segments. Split‐root experiments indicated that both the steady‐state level of plasma membrane H⁺‐ATPase and proton extrusion activity are systemically regulated, indicating inter‐organ regulation of rhizosphere acidification. Exogenous application of the auxin analog 2,4‐dichlorophenoxyacetic acid and the ethylene precursor 1‐aminocyclopropane‐1‐carboxlic acid caused the formation of transfer cells at a frequency similar to that observed in Fe‐deficient roots. However, the number of proton pumps was not affected by the hormone treatment, suggesting that both responses are regulated independently. It is concluded that transfer cells in the rhizodermis may be important but not crucial for rhizosphere acidification.     

A loss in the plasma membrane ATPase activity and its recovery coincides with incipient freeze-thaw injury and postthaw recovery in onion bulb scale tissue

Plasma membrane ATPase has been proposed to be functionally altered during early stages of injury caused by a freeze-thaw stress. Complete recovery from freezing injury in onion cells during the postthaw period provided evidence in support of this proposal. During recovery, a simultaneous decrease in ion leakage and disappearance of water soaking (symptoms of freeze-thaw injury) has been noted. Since reabsorption of ions during recovery must be an active process, recovery of plasma membrane ATPase (active transport system) functions has been implicated. In the present study, onion (Allium cepa L. cv Downing Yellow Globe) bulbs were subjected to a freeze-thaw stress which resulted in a reversible (recoverable) injury. Plasma membrane ATPase activity in the microsomes (isolated from the bulb scales) and ion leakage rate (efflux/hour) from the same scale tissue were measured immediately following thawing and after complete recovery. In injured tissue (30-40% water soaking), plasma membrane ATPase activity was reduced by about 30% and this was paralleled by about 25% higher ion leakage rate. As water soaking disappeared during recovery, the plasma membrane ATPase activity and the ion leakage rate returned to about the same level as the respective controls. Treatment of freeze-thaw injured tissue with vanadate, a specific inhibitor of plasma membrane ATPase, during postthaw prevented the recovery process. These results indicate that recovery of freeze-injured tissue depends on the functional activity of plasma membrane ATPase.     

Early effects of triadimefon on water relations, sterol composition and plasma membrane ATPase in white spruce (Picea glauca) seedlings

Seedlings of white spruce ( Picea glauca [Moench] Voss.) were treated with triadimefon solution applied to the soil, and their early responses studied from 12 h to 7 days after treatment. Transpiration rates declined and respiration rates increased immediately after the commencement of triadimefon treatment. Photosynthetic rates declined less than transpiration rates, resulting in an increase in water use efficiency, whereas root and shoot water potentials remained unchanged during the first 5 days of triadimefon treatment. Triadimefon decreased root hydraulic conductivity and inhibited the activity of the plasma membrane ATPase. In addition, triadimefon-treated roots drastically increased the ratios between free sterols and sterol esters and decreased the ratios between sterol esters and acylated sterol glycosides.     

Rhodamine 123 as a probe of transmembrane potential in isolated rat-liver mitochondria: spectral and metabolic properties

The spectral and metabolic properties of Rhodamine 123, a fluorescent cationic dye used to label mitochondria in living cells, were investigated in suspensions of isolated rat-liver mitochondria. A red shift of Rhodamine 123 absorbance and fluorescence occurred following mitochondrial energization. Fluorescence quenching of as much as 75% also occurred. The red shift and quenching varied linearly with the potassium diffusion potential, but did not respond to delta pH. These energy-linked changes were accompanied by dye uptake into the matrix space. Concentration ratios, in-to-out, approached 4000:1. A large fraction of internalized dye was bound. At concentrations higher than those needed to record these spectral changes, Rhodamine 123 inhibited ADP-stimulated (State 3) respiration of mitochondria (Ki = 12 microM) and ATPase activity of inverted inner membrane vesicles (Ki = 126 microM) and partially purified F1-ATPase (Ki = 177 microM). The smaller Ki for coupled mitochondria was accounted for by energy-dependent Rhodamine 123 uptake into the matrix. Above about 20 nmol/mg protein (10 microM), Rhodamine 123 caused rapid swelling of energized mitochondria. Effects on electron-transfer reactions and coupling were small or negligible even at the highest Rhodamine 123 concentrations employed. delta psi-dependent Rhodamine 123 uptake together with Rhodamine 123 binding account for the intense fluorescent staining of mitochondria in living cells. Inhibition of mitochondria ATPase likely accounts for the cytotoxicity of Rhodamine 123. At concentrations which do not inhibit mitochondrial function, Rhodamine 123 is a sensitive and specific probe of delta psi in isolated mitochondria.     

花生不同生育期小叶脉转移细胞形态变化和ATP酶活性定位的研究

迄今已在上千种高等植物中看到具有胞壁内突生长的转移细胞,认为它是一种输送溶质的细胞,在源库二端行使光合产物的垭距离运输。转移细胞质膜上具有较强的ATP酶活性,在发育成熟的转移细胞质膜上ATP酶活     

Asymmetrical, agonist-induced fluctuations in local extracellular [Ca(2+)] in intact polarized epithelia.

We recently proposed that extracellular Ca(2+) ions participate in a novel form of intercellular communication involving the extracellular Ca(2+)-sensing receptor (CaR). Here, using Ca(2+)-selective microelectrodes, we directly measured the profile of agonist-induced [Ca(2+)]ext changes in restricted domains near the basolateral or luminal membranes of polarized gastric acid-secreting cells. The Ca(2+)-mobilizing agonist carbachol elicited a transient, La(3+)-sensitive decrease in basolateral [Ca(2+)] (average approximately 250 microM, but as large as 530 microM). Conversely, carbachol evoked an HgCl2-sensitive increase in [Ca(2+)] (average approximately 400 microM, but as large as 520 microM) in the lumen of single gastric glands. Both responses were significantly reduced by pre-treatment with sarco-endoplasmic reticulum Ca(2+) ATPase (SERCA) pump inhibitors or with the intracellular Ca(2+) chelator BAPTA-AM. Immunofluorescence experiments demonstrated an asymmetric localization of plasma membrane Ca(2+) ATPase (PMCA), which appeared to be partially co-localized with CaR and the gastric H(+)/K(+)-ATPase in the apical membrane of the acid-secreting cells. Our data indicate that agonist stimulation results in local fluctuations in [Ca(2+)]ext that would be sufficient to modulate the activity of the CaR on neighboring cells.     

Arachidonic acid enhances intracellular [Ca2+]i increase and mitochondrial depolarization induced by glutamate in cerebellar granule cells

Maturation of primary neuronal cultures is accompanied by an increase in the proportion of cells that exhibit biphasic increase in free cytoplasmic Ca2+ ([Ca2+]i) followed by synchronic decrease in electrical potential difference across the inner mitochondrial membrane (DeltaPsim) in response to stimulation of glutamate receptors. In the present study we have examined whether the appearance of the second phase of [Ca2+]i change can be attributed to arachidonic acid (AA) release in response to the effect of glutamate (Glu) on neurons. Using primary culture of rat cerebellar granule cells we have investigated the effect of AA (1-20 microM) on [Ca2+]i, DeltaPsim, and [ATP] and changes in these parameters induced by neurotoxic concentrations of Glu (100 microM, 10-40 min). At =10 microM, AA caused insignificant decrease in DeltaPsim without any influence on [Ca2+]i. The mitochondrial ATPase inhibitor oligomycin enhanced AA-induced decrease in DeltaPsim; this suggests that AA may inhibit mitochondrial respiration. Addition of AA during the treatment with Glu resulted in more pronounced augmentation of [Ca2+]i and the decrease in DeltaPsim than the changes in these parameters observed during independent action of AA; removal of Glu did not abolish these changes. An inhibitor of the cyclooxygenase and lipoxygenase pathways of AA metabolism, 5,8,11,14-eicosatetraynoic acid, increased the proportion of neurons characterized by Glu-induced biphasic increase in [Ca2+]i and the decrease in DeltaPsim. Palmitic acid (30 microM) did not increase the percentage of neurons exhibiting biphasic response to Glu. Co-administration of AA and Glu caused 2-3 times more pronounced decrease in ATP concentrations than that observed during the independent effect of AA and Glu. The data suggest that AA may influence the functional state of mitochondria, and these changes may promote biphasic [Ca2+]i and DeltaPsim responses of neurons to the neurotoxic effect of Glu.     

Norepinephrine stimulation of lymphocyte ATPase by an alpha adrenergic receptor mechanism.

The effects of norepinephrine in interaction with adrenergic blocking compounds were studied on membrane adenosine triphosphatase (ATPase) activities of human lymphocytes and lymphoblasts. Sodium-potassium ion exchange pump activity was assayed by 86-Rb uptake and ATPase activity of membrane fractions was assayed by ADP and inorganic phosphate generation. The results of these studies indicate that norepinephrine acts by an alpha adrenergic mechanism to enhance membrane sodium-potassium ion exchange pump activity and ATPase activity. The pharmacologic and ionic dissection of the adrenergic sensitivity of ATPase activity indicates that this alpha adrenergic mechanism is related to membrane ATPase activities in addition to that associated with the ion exchange pump. Analysis of fractions obtained by sucrose gradients indicates that the action of norepinephrine is localized in the plasma membrane. Beta adrenergic stimulation was observed to inhibit ATPase activity. The complexity of adrenergic effects on membrane ATPase suggests interactions of hormone modulation of membrane nucleotide cyclases and transport-related ATPase enzymes.     

Volume regulation in Mycoplasma gallisepticum: evidence that Na+ is extruded via a primary Na+ pump.

The primary extrusion of Na+ from Mycoplasma gallisepticum cells was demonstrated by showing that when Na+-loaded cells were incubated with both glucose (10 mM) and the uncoupler SF6847 (0.4 microM), rapid acidification of the cell interior occurred, resulting in the quenching of acridine orange fluorescence. No acidification was obtained with Na+-depleted cells or with cells loaded with either KCl, RbCl, LiCl, or CsCl. Acidification was inhibited by dicyclohexylcarbodiimide (50 microM) and diethylstilbesterol (50 microM), but not by vanadate (100 microM). By collapsing delta chi with tetraphenylphosphonium (200 microM) or KCl (25 mM), the fluorescence was dequenched. The results are consistent with a delta chi-driven uncoupler-dependent proton gradient generated by an electrogenic ion pump specific for Na+. The ATPase activity of M. gallisepticum membranes was found to be Mg2+ dependent over the entire pH range tested (5.5 to 9.5). Na+ (greater than 10 mM) caused a threefold increase in the ATPase activity at pH 8.5, but had only a small effect at pH 5.5. In an Na+-free medium, the enzyme exhibited a pH optimum of 7.0 to 7.5, with a specific activity of 30 +/- 5 mumol of phosphate released per h per mg of membrane protein. In the presence of Na+, the optimum pH was between 8.5 and 9.0, with a specific activity of 52 +/- 6 mumol. The Na+-stimulated ATPase activity at pH 8.5 was much more stable to prolonged storage than the Na+-independent activity. Further evidence that two distinct ATPases exist was obtained by showing that M. gallisepticum membranes possess a 52-kilodalton (kDa) protein that reacts with antibodies raised against the beta-subunit of Escherichia coli ATPase as well as a 68-kDa protein that reacts with the anti-yeast plasma membrane ATPases antibodies. It is postulated that the Na+ -stimulated ATPases functions as the electrogenic Na+ pump.     

A vacuolar-type proton pump in a vesicle fraction enriched with potassium transporting plasma membranes from tobacco hornworm midgut

Mg-ATP dependent electrogenic proton transport, monitored with fluorescent acridine orange, 9-aminoacridine, and oxonol V, was investigated in a fraction enriched with potassium transporting goblet cell apical membranes of Manduca sexta larval midgut. Proton transport and the ATPase activity from the goblet cell apical membrane exhibited similar substrate specificity and inhibitor sensitivity. ATP and GTP were far better substrates than UTP, CTP, ADP, and AMP. Azide and vanadate did not inhibit proton transport, whereas 100 microM N,N'-dicyclohexylcarbodiimide and 30 microM N-ethylmaleimide were inhibitors. The pH gradient generated by ATP and limiting its hydrolysis was 2-3 pH units. Unlike the ATPase activity, proton transport was not stimulated by KCl. In the presence of 20 mM KCl, a proton gradient could not be developed or was dissipated. Monovalent cations counteracted the proton gradient in an order of efficacy like that for stimulation of the membrane-bound ATPase activity: K+ = Rb+ much greater than Li+ greater than Na+ greater than choline (chloride salts). Like proton transport, the generation of an ATP dependent and azide- and vanadate-insensitive membrane potential (vesicle interior positive) was prevented largely by 100 microM N,N'-dicyclohexylcarbodiimide and 30 microM N-ethylmaleimide. Unlike proton transport, the membrane potential was not affected by 20 mM KCl. In the presence of 150 mM choline chloride, the generation of a membrane potential was suppressed, whereas the pH gradient increased 40%, indicating an anion conductance in the vesicle membrane. Altogether, the results led to the following new hypothesis of electrogenic potassium transport in the lepidopteran midgut. A vacuolar-type electrogenic ATPase pumps protons across the apical membrane of the goblet cell, thus energizing electroneutral proton/potassium antiport. The result is a net active and electrogenic potassium flux.     

Histochemical Evidence for the Occurrence of Oligomycin-sensitive Plasmalemma ATPase in Corn Roots

A cytochemical study has been made on the localization of ATPase activity in corn (Zea mays L.) roots. Light microscopy shows washing for 4 hours to increase the general ATPase activity in the peripheral layers of the root cortex; oligomycin and N,N-dicyclohexylcarbodiimide inhibit this activity, oligomycin being more effective. Ultrastructural studies of ATPase location show oligomycin treatment to inhibit both mitochondrial and plasmalemma ATPase, but only in the epidermis and outer cortex. Studies with lipid-soluble dyes indicate that oligomycin might not penetrate very deeply into root tissue in the time span of these experiments. It is suggested that the strong inhibition of ion absorption by oligomycin without a corresponding decline in ATP content is probably due to inhibition of ion absorption in the peripheral cell layers, thus limiting the supply of ion for symplastic transport to the uninhibited tissues.     

Membrane-bound ATPase contributes to hop resistance of Lactobacillus brevis

The activity of the membrane-bound H+-ATPase of the beer spoilage bacterium Lactobacillus brevis ABBC45 increased upon adaptation to bacteriostatic hop compounds. The ATPase activity was optimal around pH 5.6 and increased up to fourfold when L. brevis was exposed to 666 microM hop compounds. The extent of activation depended on the concentration of hop compounds and was maximal at the highest concentration tested. The ATPase activity was strongly inhibited by N,N'-dicyclohexylcarbodiimide, a known inhibitor of FoF1-ATPase. Western blots of membrane proteins of L. brevis with antisera raised against the alpha- and beta-subunits of FoF1-ATPase from Enterococcus hirae showed that there was increased expression of the ATPase after hop adaptation. The expression levels, as well as the ATPase activity, decreased to the initial nonadapted levels when the hop-adapted cells were cultured further without hop compounds. These observations strongly indicate that proton pumping by the membrane-bound ATPase contributes considerably to the resistance of L. brevis to hop compounds.     

Kaempferol induced inhibition of HL-60 cell growth results from a heterogeneous response, dominated by cell cycle alterations

Dietary flavonoids may be exploitable as chemotherapeutics and preventatives for critical health conditions, including cancer. Antiproliferative effects are commonly ascribed to such compounds but ambiguity exists as to the principal mechanism of action and the universal benefit of exposure, particularly at high concentrations. Here, we identify heterogeneous responses within HL-60 promyelocytic leukaemia cells that explain contradictions in the reported origin of the antiproliferative action of kaempferol, a dietary abundant flavonoid. At > or =10 microM, kaempferol exposure is predominantly characterised by cell cycle alterations, notably a significant increase in S-phase and a progressive accumulation in G2-M with 10 and > or =20 microM kaempferol, respectively. However, a limited but consistent membrane damage is observed across the 1-100 microM exposure and at 1 microM occurs devoid from indices of apoptosis which are only consistently observed with > or =10 microM kaempferol treatment. At the most cytotoxic exposures, multiparametric flow cytometric analysis revealed distinct sub populations of cells. Cells with decreased size, typical of apoptosis and necrosis, possessed heightened caspase-3 activity, decreased anti-apoptotic Bcl-2 expression and changes to membrane asymmetry and integrity. The remaining population had elevated active caspase-3 but no change or a moderate increase in Bcl-2 expression and no plasma membrane alterations. Differentiation was not a significant factor in HL-60 growth inhibition. In conclusion, kaempferol-induced growth inhibition is dominated by cell cycle changes but involves a limited cytotoxicity, which we propose results from a membrane damage centred as well as an apoptotic process. This heterogeneity of response may confound the disease-preventative role and pharmacological application of this flavonoid.