Theoretical Predictions of Lactate and Hydrogen Ion Distributions in Tumours

High levels of lactate and H⁺-ions play an important role in the invasive and metastatic cascade of some tumours. We develop a mathematical model of cellular pH regulation focusing on the activity of the Na⁺/H⁺ exchanger (NHE) and the lactate/H⁺ symporter (MCT) to investigate the spatial correlations of extracellular lactate and H⁺-ions. We highlight a crucial role for blood vessel perfusion rates in determining the spatial correlation between these two cations. We also predict critical roles for blood lactate, the activity of the MCTs and NHEs on the direction of the cellular pH gradient in the tumour. We also incorporate experimentally determined heterogeneous distributions of the NHE and MCT transporters. We show that this can give rise to a higher intracellular pH and a lower intracellular lactate but does not affect the direction of the reversed cellular pH gradient or redistribution of protons away from the glycolytic source. On the other hand, including intercellular gap junction communication in our model can give rise to a reversed cellular pH gradient and can influence the levels of pH.     

Nitric oxide and pH modulation in gynaecological cancer

Nitric oxide plays several roles in cellular physiology, including control of the vascular tone and defence against pathogen infection. Neuronal, inducible and endothelial nitric oxide synthase (NOS) isoforms synthesize nitric oxide. Cells generate acid and base equivalents, whose physiological intracellular concentrations are kept due to membrane transport systems, including Na⁺/H⁺ exchangers and Na⁺/HCO₃^? transporters, thus maintaining a physiological pH at the intracellular (~7.0) and extracellular (~7.4) medium. In several pathologies, including cancer, cells are exposed to an extracellular acidic microenvironment, and the role for these membrane transport mechanisms in this phenomenon is likely. As altered NOS expression and activity is seen in cancer cells and because this gas promotes a glycolytic phenotype leading to extracellular acidosis in gynaecological cancer cells, a pro‐inflammatory microenvironment increasing inducible NOS expression in this cell type is feasible. However, whether abnormal control of intracellular and extracellular pH by cancer cells regards with their ability to synthesize or respond to nitric oxide is unknown. We, here, discuss a potential link between pH alterations, pH controlling membrane transport systems and NOS function. We propose a potential association between inducible NOS induction and Na⁺/H⁺ exchanger expression and activity in human ovary cancer. A potentiation between nitric oxide generation and the maintenance of a low extracellular pH (i.e. acidic) is proposed to establish a sequence of events in ovarian cancer cells, thus preserving a pro‐proliferative acidic tumour extracellular microenvironment. We suggest that pharmacological therapeutic targeting of Na⁺/H⁺ exchangers and inducible NOS may have benefits in human epithelial ovarian cancer.     

A Highly Temperature-sensitive Proton Current in Mouse Bone Marrow–derived Mast Cells

Proton (H⁺) conductive pathways are suggested to play roles in the regulation of intracellular pH. We characterized temperature-sensitive whole cell currents in mouse bone marrow–derived mast cells (BMMC), immature proliferating mast cells generated by in vitro culture. Heating from 24 to 36°C reversibly and repeatedly activated a voltage-dependent outward conductance with Q₁₀ of 9.9 ± 3.1 (mean ± SD) (n = 6). Either a decrease in intracellular pH or an increase in extracellular pH enhanced the amplitude and shifted the activation voltage to more negative potentials. With acidic intracellular solutions (pH 5.5), the outward current was detected in some cells at 24°C and Q₁₀ was 6.0 ± 2.6 (n = 9). The reversal potential was unaffected by changes in concentrations of major ionic constituents (K⁺, Cl⁻, and Na⁺), but depended on the pH gradient, suggesting that H⁺ (equivalents) is a major ion species carrying the current. The H⁺ current was featured by slow activation kinetics upon membrane depolarization, and the activation time course was accelerated by increases in depolarization, elevating temperature and extracellular alkalization. The current was recorded even when ATP was removed from the intracellular solution, but the mean amplitude was smaller than that in the presence of ATP. The H⁺ current was reversibly inhibited by Zn²⁺ but not by bafilomycin A₁, an inhibitor for a vacuolar type H⁺-ATPase. Macroscopic measurements of pH using a fluorescent dye (BCECF) revealed that a rapid recovery of intracellular pH from acid-load was attenuated by lowering temperature, addition of Zn²⁺, and depletion of extracellular K⁺, but not by bafilomycin A₁. These results suggest that the H⁺ conductive pathway contributes to intracellular pH homeostasis of BMMC and that the high activation energy may be involved in enhancement of the H⁺ conductance.     

The effect of short-term fluctuations in pH on NO−3 uptake and intracellular constituents in Skeletonemacostatum (Grev.) Cleve

Measurements of uptake rates, intracellular nitrogen pools, and other key intracellular constituents were made during exponential growth in Skeletonema costatum (Grev.) Cleve under varying pH levels. An understanding of the overall effects of extracellular pH on the above mentioned cellular parameters is crucial in order to ascertain the degree to which pH must be regulated and monitored in laboratory experiments with marine phytoplankton.It was found that uptake rates and intracellular pool sizes of NO^?₃ were directly influenced by the extracellular pH level, whereas, other cellular compounds remained relatively unchanged. Therefore, nitrogen uptake and intracellular nitrogen storage are dependent on key H⁺ and OH_? ion transport mechanisms that are associated with phytoplankton metabolism. These findings reiterate the fact that investigators examining nitrogen uptake and assimilatory mechanisms in marine phytoplankton must be conscious of cellular H ⁺ and OH^? fluxes that contribute to intracellular pH regulation and changes in extracellular pH levels, both of which interact to affect phytoplankton metabolic processes.     

Intracellular control of proton extrusion inSaccharomyces cerevisiae

Wild-type and mutant (glucosephosphate isomerase, pyruvate kinase and respiratory deficientrho) strains were used to determine the kinetics of substrate-induced H⁺ efflux in dilute suspensions, glucose-induced production of titratable acidity in intact cells and cell-free extracts, and kinetics of extracellular titratable acidity production (pH-stat). The results indicate that (1) initial phases of H⁺ efflux proceed at the expense of preexisting cell acidity reserves while subsequent efflux is supported by de novo formed acidity, (2) apart from regulation by pH_out the H⁺ efflux is subject to intracellular control, (3) intracellular acidity level is controlled separately from H⁺ efflux. Tentative scheme is proposed for the regulation of H⁺ fluxes inS. cerevisiae.     

Buffered diffusion around a spherical proton pumping cell: a theoretical analysis

H⁺ ions are a substrate of many active and passive membrane transporters in all cells. Absolute proton fluxes are often quantified using intracellular pH sensitive microelectrodes or pH sensitive dyes. These measurements, however, rely on a priori estimates of the intracellular buffer capacity and on the assumption of diffusive equilibrium inside the cell. Here, assuming local equilibrium of protons with a single mobile buffer, we model the diffusion of H⁺ in the extracellular medium around an H⁺ pumping cell to estimate the expected pH changes as a function of time, distance from the cell, extracellular buffer capacity, and the absolute proton flux across the membrane. In particular, using accurate numerical simulation, we gauge the range of validity of an explicit, analytical solution of the linearized, nonstationary diffusion equation. Our results provide a framework to quantify the absolute membrane proton flux, if spatiotemporal information about the extracellular pH change is available, e.g., using imaging of pH dependent fluorescent dyes.     

Regulation of intracellular pH in LLC-PK1 cells by Na+/H+ exchange

Summary Suspensions of LLC-PK₁ cells (a continuous epitheliod cell line with renal characteristics) are examined for mechanisms of intracellular pH regulation using the fluorescent probe BCECF. Initial experiments determine suitable calibration procedures for use of the BCECF fluorescent signal. They also determine that the cell suspension contains cells which (after 4 hr in suspension) have Na⁺ and K⁺ gradients comparable to those of cells in monolayer culture. The steady-state intracellular pH (7.05±0.01,n=5) of cells which have recovered in (pH 7.4) Na⁺-containing medium is not affected over several minutes by addition of 100 M amiloride or removal of extracellular Na⁺ (Na _o ⁺ /H _i ⁺ and Na _i ⁺ /H _o ⁺ exchange reactions are functionally inactive (compared to cellular buffering capacity). In contrast, Na _o ⁺ /H _i ⁺ exchange is activated by an increased cellular acid load. This activation may be observed directly either as a stimulation of net H⁺ efflux or net Na⁺ influx with decreasing intracellular pH. The extrapolation of this latter data suggests a set point of Na⁺/H⁺ exchange of approximately pH 7.0, consistent with the observed resting intracellular pH of approximately 7.05.     

Flow cytometric analysis of intracellular pH in cultured opossum kidney (OK) cells

Summary Suspensions of OK cells (a continuous renal epithelial cell line originating from the opossum kidney) were examined by flow cytometry. Three parameters were evaluated simultaneously; cell integrity as assayed by propidium iodide fluorescence, cell size as measured by time-of-flight, and intracellular pH as measured by fluorescence of 2,7-bis-(2-carboxyethyl)-5,6 carboxyfluorescein (BCECF). The suspension was shown to be composed of both intact singlets and doublets of cells, and no difference was noted in the behavior of these two populations with respect to the resting intracellular pH, or of the response of intracellular BCECF to changes in pH. Evidence suggests that using NH₄ prepulses to create an acid load broadens the intracellular pH distribution. The population of OK cells demonstrates a recovery from this acid load which is very homogeneous with respect to its sensitivity to Na⁺ removal or EIPA (ethylisopropyl-amiloride), suggesting that virtually all cells utilize Na⁺/H⁺ exchange for this recovery. The data also suggest heterogeneity in the cellular pH recovery from an acid load with respect to the observed rates of Na⁺/H⁺ exchange. Despite this heterogeneity, the Na⁺/H⁺ exchanger is observed to focus the resting intracellular pH of the population to approximately pH 7.4–7.5. The response of the population to PTH suggests that the majority of cells respond to the hormone, and that the total Na⁺/H⁺ exchange in individual cells is only partially inhibited even in the presence of saturating PTH concentrations.     

pH: Signal and Messenger in Plant Cells

Abstract: Since water spontaneously ionizes, protons cannot be removed from the medium: their free concentration in cells must be regulated through actively controlling H⁺‐related transport across membranes, by active and passive buffering, and by setting a certain pH within the metabolic network. Whereas these are the basic tools that provide effective H⁺ homeostasis, cellular compartmentation serves as an intermediate store into which protons can be shifted temporarily and from which protons can be regained when required. On the other hand, intracellular compartments can also serve as a final proton sink. pH regulation is not confined to intracellular spaces, but also comprises the apoplast. Whereas the pH of the cytosol is kept slightly alkaline at 7.2 to 7.5, with an average buffer capacity of 20 to 80 mM H⁺ per pH unit, the apoplastic pH may vary among tissues but is always acidic, with values between pH 5 and 6 and with a buffer capacity in the lower millimolar range per pH unit. pH can be a signal and/or a messenger, a distinction not always clearly made. Here, “signal” should be understood as information about an ongoing or preceding process, whereas “messenger” would be the carrying of certain information that will lead to a change of state. As such, pH would signal light intensity changes, drought, lack of oxygen and the presence of symbiotic partners or microbial attackers. On the other hand, pH would be a messenger in situations where pH changes are preconditions for certain processes, e.g., the gravity response or for activation of certain transporters in stomatal movements, and possibly for growth. The function of pH as a cellular messenger raises the question of whether pH should be understood as a “second messenger” in the way this is done for Ca²⁺. In an effort to give a comprehensive answer to this problem, the different roles of Ca²⁺ and H⁺ in cellular signalling are discussed and a number of Ca²⁺/pH interactions are presented.     

pH regulation in the stomatogastric ganglion of the crab Cancer pagurus

The regulation of intracellular neuronal pH and pH from the extracellular space was studied in the isolated stomatogastric ganglion of the crab Cancer pagurus. Intracellular neuronal pH was found to be 0.3–0.4 pH units more acidic than the standard bath pH of 7.4 and surprisingly, the extracellular space pH was found to be around 0.1 pH units more alkaline than the bath pH. Extracellular space pH shifts in response to bath pH changes decreased as a function of the depth of the recording site within the ganglion, suggesting the existence of restrictions in the free diffusion of H⁺. The amplitude of these pH_e shifts increased in Na⁺-free saline or with amiloride, suggesting Na⁺-dependent regulation of the extracellular space pH. In Na⁺ free saline or in the presence of amiloride, intracellular pH recovery from an NH₄Cl induced acidosis was reduced, and the H⁺ muffling capacity (cf. Thomas et al. 1991) of the extracellular space was markedly reduced. Changes of bath pH had only small effects on the rhythm generating properties of one of the central pattern generators of the stomatogastric ganglion, while NH₄Cl-induced intraganglionic pH changes markedly altered this rhythm.Abbreviations CPG central pattern generator - ECS extracellular space - LP lateral pyloric neuron - NMDG N-methyl-D-glucamine - PD pyloric dilator neuron - pH_e extracellular space pH - pH_i intracellular pH - pH_o bath pH - STG stomatogastric ganglion - V_ref reference potential     

Potassium Transport and Regulation of Intracellular pH in Elodea densa Leaves

The effects of extracellular K⁺ concentration ([K⁺]_o) on the pH of cell sap, “bulk cytoplasm” and vacuole have been investigated in Elodea densa leaves under conditions of either low or high activity of the plasmalemma electrogenic H⁺ pump. Cell sap pH was evaluated directly in the cell sap expressed after freezing and thawing. Cytoplasmic and vacuolar pH were calculated by the weak base and weak acid distribution method, DMO and benzylamine appearing to be a suitable acid and base, respectively, for this purpose in this material. When added to the basal medium (no rapidly permeating ions present), 5 mM K⁺ induced an increase in intracellular pH, larger for the cell sap and the vacuole (about 0.2 units), and smaller but still significant for the cytoplasm (0.07 units). This alkalinizing effect of K⁺ was thus associated with a significant decrease in the pH difference across the tonoplast. The alkalinizing effect of K⁺ was markedly and synergistically enhanced by the presence of fusicoccin, a condition inducing a marked activation of H⁺ extrusion and of K⁺ uptake. The correlation between these effects of [K⁺]_o on intracellular pH and those on H⁺ extrusion indicates that changes in extracellular K⁺ concentration, and thus in K⁺ influx, can influence cytoplasmic and vacuolar pH by modulating the rate of H⁺ extrusion by the plasmalemma H⁺ pump.     

Measuring and modeling chloride-hydroxyl exchange in the Guinea-pig ventricular myocyte

Protons are powerful modulators of cardiac function. Their intracellular concentration is regulated by sarcolemmal ion transporters that export or import H⁺-ions (or their ionic equivalent: ). One such transporter, which imports H⁺-equivalents, is a putative Cl⁻/OH⁻ exchanger (CHE). A strong candidate for CHE is SLC26A6 protein, a product of the SLC26A gene family of anion transporters, which has been detected in murine heart. SLC26A6 protein is suggested to be an electrogenic ) exchanger. Unfortunately, there is insufficient characterization of cardiac CHE against which the properties of heterologously expressed SLC26A6 can be matched. We therefore investigated the proton, Cl⁻, and voltage dependence of CHE activity in guinea-pig ventricular myocytes, using voltage-clamp, intracellular pH fluorescence, and mathematical modeling techniques. We find that CHE activity is tightly regulated by intracellular and extracellular pH, is voltage-insensitive over a wide range (±80 mV), and displays substrate dependence suggestive of electroneutral 1Cl⁻/1OH⁻ exchange. These properties exclude electrogenic SLC26A6 as sole contributor to CHE. Either the SLC26A6 product in heart is electroneutral, or CHE comprises at least two transporters with oppositely balanced voltage sensitivity. Alternatively, CHE may comprise an H⁺-Cl⁻ coinflux system, which cannot be distinguished kinetically from an exchanger. Irrespective of ionic mechanism, CHE's pH sensitivity helps to define resting intracellular pH, and hence basal function in the heart.     

Activation of AMP-activated Protein Kinase Regulates Hippocampal Neuronal pH by Recruiting Na+/H+ Exchanger NHE5 to the Cell Surface

Strict regulation of intra- and extracellular pH is an important determinant of nervous system function as many voltage-, ligand-, and H⁺-gated cationic channels are exquisitely sensitive to transient fluctuations in pH elicited by neural activity and pathophysiologic events such as hypoxia-ischemia and seizures. Multiple Na⁺/H⁺ exchangers (NHEs) are implicated in maintenance of neural pH homeostasis. However, aside from the ubiquitous NHE1 isoform, their relative contributions are poorly understood. NHE5 is of particular interest as it is preferentially expressed in brain relative to other tissues. In hippocampal neurons, NHE5 regulates steady-state cytoplasmic pH, but intriguingly the bulk of the transporter is stored in intracellular vesicles. Here, we show that NHE5 is a direct target for phosphorylation by the AMP-activated protein kinase (AMPK), a key sensor and regulator of cellular energy homeostasis in response to metabolic stresses. In NHE5-transfected non-neuronal cells, activation of AMPK by the AMP mimetic AICAR or by antimycin A, which blocks aerobic respiration and causes acidification, increased cell surface accumulation and activity of NHE5, and elevated intracellular pH. These effects were effectively blocked by the AMPK antagonist compound C, the NHE inhibitor HOE694, and mutation of a predicted AMPK recognition motif in the NHE5 C terminus. This regulatory pathway was also functional in primary hippocampal neurons, where AMPK activation of NHE5 protected the cells from sustained antimycin A-induced acidification. These data reveal a unique role for AMPK and NHE5 in regulating the pH homeostasis of hippocampal neurons during metabolic stress.     

Evaluation of ion gradient-dependent H+ transport systems in isolated enterocytes from the chick

Summary The experiments reported here evaluate the capability of isolated intestinal epithelial cells to accomplish net H⁺ transport in response to imposed ion gradients. In most cases, the membrane potential was kept constant by means of a K⁺ plus valinomycin voltage clamp in order to prevent electrical coupling of ion fluxes. Net H⁺ flux across the cellular membrane was examined at pH 6.0 (the physiological lumenal pH) and at pH 7.4 using methylamine distribution or recordings of changes in media pH. Results from both techniques suggest that the cells have an Na⁺/H⁺ exchange system in the plasma membrane that is capable of rapid and sustained changes in intracellular pH in response to an imposed Na⁺ gradient. The kinetics of the Na⁺/H⁺ exchange reaction at pH 6.0 [K _t for Na⁺=57mm,V _max=42 mmol H⁺/liter 3OMG (3-O-methylglucose) space/min] are dramatically different from those at pH 7.4 (K _t for Na⁺=15mm,V _max=1.7 mmol H⁺/liter 3OMG space/min). Experiments involving imposed K⁺ gradients suggest that these cells have negligible K⁺/H⁺ exchange capability. They exhibit limited but measurable H⁺ conductance. Anion exchange for base equivalents was not detected in experiments performed in media nominally free of bicarbonate.     

Extent of intracellular pH changes during H+ extrusion by maize root-tip cells

³¹P-Nuclear-magnetic-resonance spectra of maize (Zea mays L.) root tips, that had been induced to extrude large amounts of H⁺ in response to fusicoccin (FC) in the presence of potassium salts, indicate that the cytoplasmic pH does not become higher than that of controls. In fact, the cytoplasmic pH may become slightly (approx. 0.1 pH unit) lower in cells extruding H⁺. Estimations of the buffer capacity of the cells show that without active intracellular pH regulation, H⁺ extrusion caused by FC would cause the intracellular pH to rise by at least 0.6 pH unit h^-1. Our results indicate that intracellular pH is tightly regulated even during extreme rates of acid extrusion, and that a rise in cytoplasmic pH is not the signal linking H⁺ extrusion with enhanced organic-acid synthesis or other intracellular responses to H⁺ pumping.Abbreviations FC fusicoccin - P_i inorganic phosphate - NMR nuclear magnetic resonance - chemical shift - MDP methylene diphosphonic acid     

Generation and characterization of the first inhibitory antibody targeting tumour-associated carbonic anhydrase XII

The carbonic anhydrases (CAs) constitute a family of almost ubiquitous enzymes of significant importance for many physiological and pathological processes. CAs reversely catalyse the conversion of CO₂ + H₂O to HCO₃ ⁻ and H⁺, thereby contributing to the regulation of intracellular pH. Above all, CAs are of key importance for cells that perform glycolysis that inevitably leads to the intracellular accumulation of lactate. CA XII is a plasma membrane-associated isoform of the enzyme, which is induced by hypoxia and oestrogen and, consequently, expressed at high levels on various types of cancer and, intriguingly, on cancer stem cells. The enzyme is directly involved in tumour progression, and its inhibition has an anti-tumour effect. Apart from its role in carcinogenesis, the enzyme contributes to various other diseases like glaucoma and arteriosclerotic plaques, among others. CA XII is therefore regarded as promising target for specific therapies. We have now generated the first monoclonal antibody (6A10) that binds to the catalytic domain of CA XII on vital tumour cells and inhibits CA XII enzyme activity at nanomolar concentrations and thus much more effective than acetazolamide. In vitro results demonstrate that inhibition of CA XII by 6A10 inhibits the growth of tumour cells in 3-dimensional structures. In conclusion, we generated the first specific and efficient biological inhibitor of tumour-associated CA XII. This antibody may serve as a valuable tool for in vivo diagnosis and adjuvant treatment of different types of cancer.     

Studies on the kinetics of Na+/H+ exchange in OK cells: Introduction of a new device for the analysis of polarized transport in cultured epithelia

Summary The present study describes a new perfusion technique—based on the use of a routine spectrofluorometer—which enables fluorometric evaluation of polarity, regulation and kinetics of Na⁺/H⁺ exchange at the level of an intact monolayer. Na⁺/ H⁺ exchange was evaluated in bicarbonate-free solutions in OK (opossum kidney) cells, a renal epithelial cell line. Na⁺/H⁺ exchange activity was measured by monitoring changes in intracellular pH (pH _i ) after an acid load, using the pH-sensitive dye 27-bis (carboxyethyl) 5–6-carboxy-fluorescein (BCECF). Initial experiments indicated that OK cells grown on a permeable support had access to apical and basolateral perfusion media. They also demonstrate that OK cells express an apical pH _i , recovery mechanism, which is Na⁺ dependent, ethylisopropylamiloride (EIPA) sensitive and regulated by PTH. Compared to resting conditions (pH _i =7.68; pH _o =7.4) where Na⁺/H⁺ exchange is not detectable, transport rate increased as pH _i decreased. A positive cooperativity characterized the interaction of internal H⁺ with the exchanger, and suggests multiple H⁺ binding sites. In contrast, extracellular [Na⁺] increased transport with simple Michaelis-Menten kinetics. The apparent affinity of the exchanger for Na⁺ was 19mM at an intracellular pH of 7.1 and 60mM at an intracellular pH of 6.6. Inhibition of Na⁺/H⁺ exchange activity by EIPA was competitive with respect to extracellular [Na⁺] and theK _i was 3.4 M. In conclusion, the technique used in the present study is well suited for determination of mechanisms involved in control of epithelial cell pH _i and processes associated with their polarized expression and regulation.     

NO3 ?-induced pH Changes in Mammalian Cells : Evidence for an NO3?-H+ Cotransporter

The effect of NO₃ ⁻ on intracellular pH (pH_i) was assessed microfluorimetrically in mammalian cells in culture. In cells of human, hamster, and murine origin addition of extracellular NO₃ ⁻ induced an intracellular acidification. This acidification was eliminated when the cytosolic pH was clamped using ionophores or by perfusing the cytosol with highly buffered solutions using patch-pipettes, ruling out spectroscopic artifacts. The NO₃ ⁻- induced pH change was not due to modulation of Na⁺/H⁺ exchange, since it was also observed in Na⁺/H⁺ antiport-deficient mutants. Though NO₃ ⁻ is known to inhibit vacuolar-type (V) H⁺-ATPases, this effect was not responsible for the acidification since it persisted in the presence of the potent V-ATPase inhibitor bafilomycin A₁. NO₃ ⁻/HCO₃ ⁻ exchange as the underlying mechanism was ruled out because acidification occurred despite nominal removal of HCO₃ ⁻, despite inhibition of the anion exchanger with disulfonic stilbenes and in HEK 293 cells, which seemingly lack anion exchangers (Lee, B.S., R.B. Gunn, and R.R. Kopito. 1991. J. Biol. Chem. 266:11448– 11454). Accumulation of intracellular NO₃ ⁻, measured by the Greiss method after reduction to NO₂ ⁻, indicated that the anion is translocated into the cells along with the movement of acid equivalents. The simplest model to explain these observations is the cotransport of NO₃ ⁻ with H⁺ (or the equivalent counter-transport of NO₃ ⁻ for OH⁻). The transporter appears to be bi-directional, operating in the forward as well as reverse directions. A rough estimate of the fluxes of NO₃ ⁻ and acid equivalents suggests a one-to-one stoichiometry. Accordingly, the rate of transport was unaffected by sizable changes in transmembrane potential. The cytosolic acidification was a saturable function of the extracellular concentration of NO₃ ⁻ and was accentuated by acidification of the extracellular space. The putative NO₃ ⁻-H⁺ cotransport was inhibited markedly by ethacrynic acid and by α-cyano-4-hydroxycinnamate, but only marginally by 4,4′-diisothiocyanostilbene-2,2′ disulfonate or by p-chloromercuribenzene sulfonate. The transporter responsible for NO₃ ⁻-induced pH changes in mammalian cells may be related, though not identical, to the NO₃ ⁻-H⁺ cotransporter described in Arabidopsis and Aspergillus. The mammalian cotransporter may be important in eliminating the products of NO metabolism, particularly in cells that generate vast amounts of this messenger. By cotransporting NO₃ ⁻ with H⁺ the cells would additionally eliminate acid equivalents from activated cells that are metabolizing actively, without added energetic investment and with minimal disruption of the transmembrane potential, inasmuch as the cotransporter is likely electroneutral.     

Plasmalemmal vacuolar-type H+-ATPase in cancer biology

Vacuolar-type H⁺-adenosine triphosphatase (V-ATPase) is one of the most fundamental enzymes in nature. V-ATPases are responsible for the regulation of proton concentration in the intracellular acidic compartments. It has similar structure with the mitochondrial F₀F₁-ATP synthase (F-ATPase).^† The V-ATPases are composed of multiple subunits and have various physiological functions, including membrane and organelle protein sorting, neurotransmitter uptake, cellular degradative processes, and cytosolic pH regulation. The V-ATPases have been involved in multidrug resistance. Recently, plasma membrane V-ATPases have been involved in regulation of extracellular acidity, essential for cellular invasiveness and proliferation in tumor metastasis. The current knowledge regarding the structure and function of V-ATPase and its role in cancer biology is discussed. F in F₀F₁ ATPase is the coupling energy factor.     

The acid-base transport proteins NHE1 and NBCn1 regulate cell cycle progression in human breast cancer cells

Precise acid-base homeostasis is essential for maintaining normal cell proliferation and growth. Conversely, dysregulated acid-base homeostasis, with increased acid extrusion and marked extracellular acidification, is an enabling feature of solid tumors, yet the mechanisms through which intra- and extracellular pH (pH_i, pH_e) impact proliferation and growth are incompletely understood. The aim of this study was to determine the impact of pH, and specifically of the Na⁺/H⁺ exchanger NHE1 and Na⁺, HCO₃^? transporter NBCn1, on cell cycle progression and its regulators in human breast cancer cells. Reduction of pH_e to 6.5, a common condition in tumors, significantly delayed cell cycle progression in MCF-7 human breast cancer cells. The NHE1 protein level peaked in S phase and that of NBCn1 in G2/M. Steady state pH_i changed through the cell cycle, from 7.1 in early S phase to 6.8 in G2, recovering again in M phase. This pattern, as well as net acid extrusion capacity, was dependent on NHE1 and NBCn1. Accordingly, knockdown of either NHE1 or NBCn1 reduced proliferation, prolonged cell cycle progression in a manner involving S phase prolongation and delayed G2/M transition, and altered the expression pattern and phosphorylation of cell cycle regulatory proteins. Our work demonstrates, for the first time, that both NHE1 and NBCn1 regulate cell cycle progression in breast cancer cells, and we propose that this involves cell cycle phase-specific pH_i regulation by the two transporters.