Arabidopsis plasma membrane H+-ATPase genes AHA2 and AHA7 have distinct and overlapping roles in the modulation of root tip H+ efflux in response to low-phosphorus stress

Phosphorus deficiency in soil is one of the major limiting factors for plant growth. Plasma membrane H+-ATPase (PM H+-ATPase) plays an important role in the plant response to low-phosphorus stress (LP). However, few details are known regarding the action of PM H+-ATPase in mediating root proton (H+) flux and root growth under LP. In this study, we investigated the involvement and function of different Arabidopsis PM H+-ATPase genes in root H+ flux in response to LP. First, we examined the expressions of all Arabidopsis PM H+-ATPase gene family members (AHA1-AHA11) under LP. Expression of AHA2 and AHA7 in roots was enhanced under this condition. When the two genes were deficient in their respective Arabidopsis mutant plants, root growth and responses of the mutants to LP were highly inhibited compared with the wild-type plant. AHA2-deficient plants exhibited reduced primary root elongation and lower H+ efflux in the root elongation zone. AHA7-deficient plants exhibited reduced root hair density and lower H+ efflux in the root hair zone. The modulation of H+ efflux by AHA2 or AHA7 was affected by the action of 14-3-3 proteins and/or auxin regulatory pathways in the context of root growth and response to LP. Our results suggest that under LP conditions, AHA2 acts mainly to modulate primary root elongation by mediating H+ efflux in the root elongation zone, whereas AHA7 plays an important role in root hair formation by mediating H+ efflux in the root hair zone.

Hierarchical spike clustering analysis for investigation of interneuron heterogeneity

Action potentials represent the output of a neuron. Especially interneurons display a variety of discharge patterns ranging from regular action potential firing to prominent spike clustering or stuttering. The mechanisms underlying this heterogeneity remain incompletely understood. We established hierarchical cluster analysis of spike trains as a measure of spike clustering. A clustering index was calculated from action potential trains recorded in the whole-cell patch clamp configuration from hippocampal (CA1, stratum radiatum) and entorhinal (medial entorhinal cortex, layer 2) interneurons in acute slices and simulated data. Prominent, region-dependent, but also variable spike clustering was detected using this measure. Further analysis revealed a strong positive correlation between spike clustering and membrane potentials oscillations but an inverse correlation with neuronal resonance. Furthermore, clustering was more pronounced when the balance between fast-activating K(+) currents, assessed by the spike repolarisation time, and hyperpolarization-activated currents, gauged by the size of the sag potential, was shifted in favour of fast K(+) currents. Simulations of spike clustering confirmed that variable ratios of fast K(+) and hyperpolarization-activated currents could underlie different degrees of spike clustering and could thus be crucial for temporally structuring interneuron spike output.

Hydrogen-rich water regulates cucumber adventitious root development in a heme oxygenase-1/carbon monoxide-dependent manner

Hydrogen gas (H2) is an endogenous gaseous molecule in plants. Although its reputation is as a "biologically inert gas", recent results suggested that H2 has therapeutic antioxidant properties in animals and plays fundamental roles in plant responses to environmental stresses. However, whether H2 regulates root morphological patterns is largely unknown. In this report, hydrogen-rich water (HRW) was used to characterize H2 physiological roles and possible signaling transduction pathways in the promotion of adventitious root (AR) formation in cucumber explants. Our results showed that a 50% concentration of HRW was able to mimic the effect of hemin, an inducer of a carbon monoxide (CO) synthetic enzyme, and heme oxygenase-1 (HO-1), in restoring AR formation in comparison with the inhibition effect conferred by auxin-depletion treatment alone. It was further shown that the inducible effect of HRW could be further blocked by the co-treatment with N-1-naphthylphtalamic acid (NPA; an auxin transport inhibitor). The HRW-induced response, at least partially, was HO-1-dependent. This conclusion was supported by the fact that the exposure of cucumber explants to HRW up-regulates cucumber HO-1 gene expression and its protein levels. HRW-mediated induction of representative target genes related to auxin signaling and AR formation, such as CsDNAJ-1, CsCDPK1/5, CsCDC6, CsAUX22B-like, and CsAUX22D-like, and thereafter AR formation (particularly in the AR length) was differentially sensitive to the HO-1 inhibitor zinc protoporphyrin IX (ZnPP). Above blocking actions were clearly reversed by CO, further confirming that the above response was HO-1/CO-specific. However, the addition of a well-known antioxidant, ascorbic acid (AsA), failed to influence AR formation triggered by HRW, thus ruling out the involvement of redox homeostasis in this process. Together, these results indicated that HRW-induced adventitious rooting is, at least partially, correlated with the HO-1/CO-mediated responses. We also suggested that exogenous HRW treatment on plants might be a good option to induce root organogenesis.

[Raman spectroscopy study of the effect of H+ on the oxygen affinity capacity of hemoglobin]

The hemoglobin was extracted from the blood which was provided by the healthy volunteers and the impact of the pH on hemoglobin oxygen binding capacity was studied with microscopic Raman spectroscopy. The results indicated that: under the excitation light of 514.5 nm, with the reducing of the oxygen partial pressure (PO2), the Raman peak intensity at 1 375, 1 562, 1 585 and 1 638 cm(-1) of the control hemoglobin (pH 7.4) reduced gradually, among which, the change of the 1 375 and 1 638 cm(-1) were the most significant and had a good relevance with the PO2. The curves were plotted by regarding the PO2 as the x-axis and the Raman absolute intensity as the y-axis, and the relationship between hemoglobin Raman absolute intensity of the 1 375 and 1 638 cm(-1) and their related PO2 levels when the pH was 5.7, 7.4 and 8.0 respectively were analyzed. The data was well linear fitted and the fitting equation was obtained. The relationship of the slope (Raman intensity/PO2 level) among them were K8.0 > K7.4 > K5.7, indicating that the lower the pH, the easier the release of the oxygen molecules. It was showed that the Raman spectroscopy technique could be used to detect the oxygen binding rate of hemoglobin quantitatively, and the effect of the PH on oxygen binding state of hemoglobin could be observed, which could provide a new method and make a foundation for the monitoring of the PO2 levels in the blood, as well as the research on the regulatory factors of the blood oxygen affinity, such as H+ and CO2.

Hydrogen tunneling links protein dynamics to enzyme catalysis

The relationship between protein dynamics and function is a subject of considerable contemporary interest. Although protein motions are frequently observed during ligand binding and release steps, the contribution of protein motions to the catalysis of bond making/breaking processes is more difficult to probe and verify. Here, we show how the quantum mechanical hydrogen tunneling associated with enzymatic C-H bond cleavage provides a unique window into the necessity of protein dynamics for achieving optimal catalysis. Experimental findings support a hierarchy of thermodynamically equilibrated motions that control the H-donor and -acceptor distance and active-site electrostatics, creating an ensemble of conformations suitable for H-tunneling. A possible extension of this view to methyl transfer and other catalyzed reactions is also presented. The impact of understanding these dynamics on the conceptual framework for enzyme activity, inhibitor/drug design, and biomimetic catalyst design is likely to be substantial.

The effects of temperature change on the circadian clock of Neurospora

The phase resetting of the circadian oscillatory system by pulses of increased temperature (zeitgebers) and the temperature compensation of its period length during longer exposures are major features of the system, but are not well understood in molecular terms. In Neurospora crassa, the effects of pulses of increased temperature on the circadian rhythm of conidiation were determined and possible inputs to the oscillatory system tested, including changes in cyclic 3',5'-adenosine monophosphate (cAMP), inositol 1,4,5-trisphosphate and H+ concentrations, as well as changes of phosphorylation, synthesis and degradation of proteins. Following the kinetics of these parameters during exposure to increased temperature showed transient changes. Experimental manipulation of cAMP, Ca2+ and H+ levels, and of the synthesis and, possibly, degradation of proteins, resulted in phase shifts of the oscillatory system. It is assumed that the temperature signal affects the oscillator(s) by multiple pathways and shifts the whole state of the oscillatory system. Second messenger levels, protein synthesis and protein degradation show adaptation to longer exposures to elevated temperature which may be involved in the temperature compensation of the period length. The temperature compensation is also proposed to involve a shift in the state of all or most oscillator variables.

Hydrogen symbioses in evolution and disease

Hydrogen is the source of energy that unites the metabolisms and fuels the innovative potentials of all living organisms. Autotrophs use hydrogen emitted into hydrothermal vents, where symbiotic communities that share hydrogen thrive. On the surface, life developed using photons to cleave water, releasing hydrogen carried into a reverse Krebs cycle to produce carbohydrates, from which hydrogen and its constituent electron and proton are extracted. Fluctuant electrogenic power is harnessed by extensive exchanges and symbiotic sharing schemes of hydrogen sources and carriers. These communicate with electrostatic nuclear centres, forming a positive feedback loop. If the proton-motive circuitry fails from loss of Redox potential, premature ageing and all-category disease can result.

Oppositely directed H+ gradient functions as a driving force of rat H+/organic cation antiporter MATE1

Recently, we have isolated the rat (r) H+/organic cation antiporter multidrug and toxin extrusion 1 (MATE1) and reported its tissue distribution and transport characteristics. Functional characterization suggested that an oppositely directed H+ gradient serves as a driving force for the transport of a prototypical organic cation, tetraethylammonium, by MATE1, but there is no direct evidence to prove this. In the present study, therefore, we elucidated the driving force of tetraethylammonium transport via rMATE1 using plasma membrane vesicles isolated from HEK293 cells stably expressing rMATE1 (HEK-rMATE1 cells). A 70-kDa rMATE1 protein was confirmed to exist in HEK-rMATE1 cells, and the transport of various organic cations including [14C]tetraethylammonium was stimulated in intracellular acidified HEK-rMATE1 cells but not mock cells. The transport of [14C]tetraethylammonium in membrane vesicles from HEK-rMATE1 cells exhibited the overshoot phenomenon only when there was an outwardly directed H+ gradient, as observed in rat renal brush-border membrane vesicles. The overshoot phenomenon was not observed in the vesicles from mock cells. The stimulated [14C]tetraethylammonium uptake by an H+ gradient [intravesicular H+ concentration ([H+]in) > extravesicular H+ concentration ([H+]out)] was significantly reduced in the presence of a protonophore, carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). [14C]tetraethylammonium uptake was not changed in the presence of valinomycin-induced membrane potential. These findings definitively indicate that an oppositely directed H+ gradient serves as a driving force of tetraethylammonium transport via rMATE1, and this is the first demonstration to identify the driving force of the MATE family. The present experimental strategy is very useful in identifying the driving force of cloned transporters whose driving force has not been evaluated.

The surface energy of water; molecular biology of the working mechanisms

The surface tension and surface energy of water, have been studied for two centuries. The ability to do physical chemical work dates from the decades at the close of the nineteenth century and opening of the twentieth. Teaching and research popularity dropped in the post-war years, and today is practically unique. Before 1846, Laplace, the French scientist, found that pressure was needed to force water, or other liquid, through small holes. The pressure needed was greater for smaller holes, and the relationship depended upon the surface tension of the liquid under test, and the inverse of the radius of the holes. The Laplace formula still appears in Physiological textbooks. The importance in the small air tubes of respiratory physiology, and in the capillary circulation generally, is still studied. The use of surface energy for protein conformational changes has received little attention. A proposed scheme for the human erythrocyte glucose transporter, although shown to be experimentally consistent, has been disregarded. A possible reason is the difficulty of comprehending how surface energy can actually perform mechanical work. Therefore, studies with molecular models, which increase the understanding of how mechanical work is done are described in more detail here.

Mechanism of acid-induced bone resorption

PURPOSE OF REVIEW

This review presents our current understanding of the way metabolic acidosis induces calcium efflux from bone, and in the process, buffers additional systemic hydrogen ions associated with acidosis.

RECENT FINDINGS

Acid-induced changes in bone mineral are consistent with a role for bone as a proton buffer. In response to metabolic acidosis in an in-vitro bone organ culture system, we observed a fall in mineral sodium, potassium, carbonate and phosphate, which each buffer protons and in vivo should increase systemic pH towards the physiologic normal. Initially, metabolic acidosis stimulates physicochemical mineral dissolution and subsequently cell-mediated bone resorption. Acidosis suppresses the activity of bone-resorbing cells, osteoblasts, decreasing gene expression of specific matrix proteins and alkaline phosphatase activity. There is concomitant acid stimulation of prostaglandin production by osteoblasts, which acting in a paracrine manner increases synthesis of the osteoblastic receptor activator of nuclear factor kappa B ligand (RANKL). The acid induction of RANKL then stimulates osteoclastic activity and recruitment of new osteoclasts to promote bone resorption and buffering of the proton load. Both the regulation of RANKL and acid-induced calcium efflux from bone are mediated by prostaglandins.

SUMMARY

Metabolic acidosis, which occurs during renal failure, renal insufficiency or renal tubular acidosis, results in decreased systemic pH and is associated with an increase in urine calcium excretion. The apparent protective function of bone to help maintain systemic pH, which has a clear survival advantage for mammals, will come partly at the expense of its mineral stores.

A carrier-mediated mechanism for pyridoxine uptake by human intestinal epithelial Caco-2 cells: regulation by a PKA-mediated pathway

Vitamin B6 is essential for cellular functions and growth due to its involvement in important metabolic reactions. Humans and other mammals cannot synthesize vitamin B6 and thus must obtain this micronutrient from exogenous sources via intestinal absorption. The intestine, therefore, plays a central role in maintaining and regulating normal vitamin B6 homeostasis. Due to the water-soluble nature of vitamin B6 and the demonstration that transport of other water-soluble vitamins in intestinal epithelial cells involves specialized carrier-mediated mechanisms, we hypothesized that transport of vitamin B6 in these cells is also carrier mediated in nature. To test this hypothesis, we examined pyridoxine transport in a model system for human enterocytes, the human-derived intestinal epithelial Caco-2 cells. The results showed pyridoxine uptake to be 1) linear with time for up to 10 min of incubation and to occur with minimal metabolic alteration in the transported substrate, 2) temperature and energy dependent but Na+ independent, 3) pH dependent with higher uptake at acidic compared with alkaline pHs, 4) saturable as a function of concentration (at buffer pH 5.5 but not 7.4) with an apparent Michaelis-Menten constant (Km) of 11.99 +/- 1.41 microM and a maximal velocity (Vmax) of 67.63 +/- 3.87 pmol. mg protein-1. 3 min-1, 5) inhibited by pyridoxine structural analogs (at buffer pH 5.5 but not 7.4) but not by unrelated compounds, and 6) inhibited in a competitive manner by amiloride with an apparent inhibitor constant (Ki) of 0.39 mM. We also examined the possible regulation of pyridoxine uptake by specific intracellular regulatory pathways. The results showed that whereas modulators of PKC, Ca+2/calmodulin (CaM), and nitric oxide (NO)-mediated pathways had no effect on pyridoxine uptake, modulators of PKA-mediated pathway were found to cause significant reduction in pyridoxine uptake. This reduction was mediated via a significant inhibition in the Vmax, but not the apparent Km, of the pyridoxine uptake process. These results demonstrate, for the first time, the involvement of a specialized carrier-mediated mechanism for pyridoxine uptake by intestinal epithelial cells. This system is pH dependent and amiloride sensitive and appears to be under the regulation of an intracellular PKA-mediated pathway.

Role of luminal anion and pH in distal tubule potassium secretion

Potassium secretory flux (J(K)) by the distal nephron is regulated by systemic and luminal factors. In the present investigation, J(K) was measured with a double-barreled K(+) electrode during paired microperfusion of superficial segments of the rat distal nephron. We used control solutions (100 mM NaCl, pH 7.0) and experimental solutions in which Cl(-) had been replaced with a less permeant anion and/or pH had been increased to 8.0. J(K) increased when Cl(-) was replaced by either acetate ( approximately 37%), sulfate ( approximately 32%), or bicarbonate ( approximately 62%), and also when the pH of the control perfusate was increased ( approximately 26%). The majority (80%) of acetate-stimulated J(K) was Ba(2+) sensitive, but furosemide (1 mM) further reduced secretion ( approximately 10% of total), suggesting that K(+)-Cl(-) cotransport was operative. Progressive reduction in luminal Cl(-) concentration from 100 to 20 to 2 mM caused increments in J(K) that were abolished by inhibitors of K(+)-Cl(-) cortransport, i.e., furosemide and [(dihydroindenyl)oxy]alkanoic acid. Increasing the pH of the luminal perfusion fluid also increased J(K) even in the presence of Ba(2+), suggesting that this effect cannot be accounted for only by K(+) channel modulation of K(+) secretion in the distal nephron of the rat. Collectively, these data suggest a role for K(+)-Cl(-) cotransport in distal nephron K(+) secretion.

Alveolar hypercapnia augments pulmonary C-fiber responses to chemical stimulants: role of hydrogen ion

To determine whether the excitabilities of pulmonary C fibers to chemical and mechanical stimuli are altered by CO(2)-induced acidosis, single-unit pulmonary C-fiber activity was recorded in anesthetized, open-chest rats. Transient alveolar hypercapnia (HPC) was induced by administering CO(2)-enriched gas mixture (15% CO(2), balance air) via the respirator inlet for 30 s, which rapidly lowered the arterial blood pH from a baseline of 7.40 +/- 0.01 to 7.17 +/- 0.02. Alveolar HPC markedly increased the responses of these C-fiber afferents to several chemical stimulants. For example, the C-fiber response to right atrial injection of the same dose of capsaicin (0.25-1.0 microg/kg) was significantly increased from 3.07 +/- 0.70 impulses/s at control to 8.48 +/- 1.52 impulses/s during HPC (n = 27; P < 0.05), and this enhanced response returned to control within approximately 10 min after termination of HPC. Similarly, alveolar HPC also induced significant increases in the C-fiber responses to right atrial injections of phenylbiguanide (4-8 microg/kg) and adenosine (0.2 mg/kg). In contrast, HPC did not change the response of pulmonary C fibers to lung inflation. Furthermore, the peak response of these C fibers to capsaicin during HPC was greatly attenuated when the HPC-induced acidosis was buffered by infusion of bicarbonate (1.36-1.82 mmol. kg(-1). min(-1) for 35 s). In conclusion, alveolar HPC augments the responses of these afferents to various chemical stimulants, and this potentiating effect of CO(2) is mediated through the action of hydrogen ions on the C-fiber sensory terminals.

Arachidonic acid-induced H+ and Ca2+ increases in both the cytoplasm and nucleoplasm of rat cerebellar granule cells

1. Arachidonic acid (AA) exerts multiple physiological and pathophysiological effects in the brain. By continuously measuring the intracellular pH (pH(i)) and Ca2+ levels ([Ca2+]i) in primary cultured rat cerebellar granule cells, we have found, for the first time, that 20 min treatment with 10 microM AA resulted in marked increases in Ca2+ and H+ levels in both the cytosol and nucleus. 2. A much higher concentration (40 mM) of another weak acid, propionic acid, was needed to induce a similar change in pH(i). The [Ca2+]i increase was probably caused by AA-induced activation of Ni2+-sensitive cationic channels, but did not involve NMDA channels or the Na+-Ca2+ exchanger. 3. AA-induced acidosis occurs by a different mechanism involving predominantly the passive diffusion of the un-ionized form of AA, rather than a protein carrier, as proposed by Kamp & Hamilton for fatty acids (FAs) in artificial phospholipid bilayers (the 'flip-flop' model). The following results, which are similar to those observed in lipid bilayers, support this conclusion: (1) FAs containing a -COOH group (AA, linoleic acid, alpha-linolenic acid, and docosahexaenoic acid) induced intracellular acidosis, whereas a FA with a -COOCH3 group (AA methyl ester) had little effect on pH(i), (2) a FA amine, tetradecylamine, induced intracellular alkalosis, and (3) the AA-/FA-induced pH(i) changes were reversed by bovine serum albumin. 4. Further evidence in support of a passive diffusion model, rather than a membrane protein carrier, is that: (1) there was a linear relationship between the initial rate of acid flux and the concentration of AA (2-100 microM), (2) acidosis was not inhibited by 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid, a potent inhibitor of the plasma membrane FA carrier protein, and (3) the involvement of most known H+-related membrane carriers and H+ conductance has been ruled out. 5. Since AA can be released under both physiological and pathophysiological conditions, the possible significance of the AA-evoked increases in H+ and Ca2+ in both the cytoplasm and nucleoplasm is discussed.

Experimental determination of hydrogen bandwidth for the ion parametric resonance model

The ion parametric resonance (IPR) model predicts that distinct patterns of field-induced biological responses will occur at particular magnetic field combinations which establish ion resonances. An important characteristic of resonance is the bandwidth response of the system, in part because it determines the required tolerances of the test system. Initial development of the IPR model used literature data to estimate the bandwidth for any ion resonance to be -/+10% of its exact resonance. Because the charge-to-mass ratio of hydrogen is much larger than any other biologically significant ion, hydrogen resonance provides a unique test case by which a single ionic bandwidth can be clearly measured. Of particular relevance is work by Trillo et al. that demonstrated a hydrogen-only, resonance-based IPR response of neurite outgrowth in PC-12 cells. The work reported here considers the response of nerve-growth-factor-stimulated PC-12 cells exposed to magnetic fields tuned at or near hydrogen resonance. This work was designed to test directly the IPR model hypothesis of a -/+10% ionic bandwidth. Consistent with the work of Trillo et al., resonance conditions were established using a 2.97 microT static magnetic field, and the AC frequency and field strength were varied to prove different aspects of the resonance. With this static field 45 Hz was the resonance frequency identified for hydrogen, 42.5 and 47.5 Hz were near-resonance frequencies, and 40 and 50 Hz bounded the assumed -/+10% hydrogen resonance bandwidth. We repeated each test three times. The cell responses at 45 Hz exposures agreed with the IPR model predictions and replicated results obtained by Trillo et al. Cells exposed to 42.5 and 47.5 Hz (near resonance) magnetic fields responded in the same general pattern as those exposed to 45 Hz fields, but neurite outgrowth was less than that observed at resonance. Measured results for cells exposed to either 40 Hz or 50 Hz fields were indistinguishable from off-resonance responses, consistent with the hypothesized bandwidth. These results confirm that the response bandwidth for the hydrogen ion is no greater than -/+10%, and give further support to the resonance-based predictions of the IPR model.

Interactions between Ca(2+) and H(+) and functional consequences in vascular smooth muscle

Ca(2+) and H(+) ions can profoundly alter vascular tone. In many physiological and pathological processes, changes in the concentration of both ions occur. Thus, to understand the processes and mechanisms that modify force, it is necessary to understand what changes occur in these ions and, importantly, how they interact with each other. In this minireview, we highlight the quantitatively important mechanisms involved in the contractile responses of vascular tissues to pH change and discuss the cellular and molecular reasons underlying these responses.

Effects on parameters of glucose homeostasis in healthy humans from ingestion of leguminous versus maize starches

BACKGROUND

Due to their lower glycaemic index, leguminous seeds affect human carbohydrate metabolism lesser than do cereals. Problems, however, could arise from side effects, e.g., increasing flatulence.

AIM OF THE STUDY AND METHODS

In 26 healthy subjects, metabolic and symptomatic responses following acute ingestion of equivalent amounts of pure pea starch (NASTAR (Cosucra BV, Rosendaal/The Netherlands), crude yellow pea flour (CPC Deutschland, Germany), and modified and unmodified cornstarches (SNOWFLAKE and SIRONA, Cerestar/Germany) were assessed, i.e., plasma glucose, serum insulin, C-peptide, hydrogen exhalation, and flatulence.

RESULTS

Pure pea starch elicited less hyperglycaemia (minus 47 %), hyperinsulinaemia (minus 54 %), and C-peptide secretion (minus 37 %) as compared to cornstarch (p<0.05), while the responses to modified versus unmodified corn starch were similar (8 subjects, n.s.). Pure pea and corn starches were equally well tolerated, while flatulence and breath hydrogen concentration were increased only after the intake of crude pea flour. Maldigestion of pea flour was calculated to be around 10 % (reference lactulose).

CONCLUSIONS

The well-known metabolic advantages of pea starch over cornstarch were confirmed. Tolerability of pure pea starch was excellent, but not of crude pea flour. Provided it has the same technical characteristics, pure pea starch as a "prebiotic" could replace cornstarch in industrial food production.

Intracellular H+ regulates the alpha-subunit of ENaC, the epithelial Na+ channel

Protons regulate electrogenic sodium absorption in a variety of epithelia, including the cortical collecting duct, frog skin, and urinary bladder. Recently, three subunits (alpha, beta, gamma) coding for the epithelial sodium channel (ENaC) were cloned. However, it is not known whether pH regulates Na+ channels directly by interacting with one of the three ENaC subunits or indirectly by interacting with a regulatory protein. As a first step to identifying the molecular mechanisms of proton-mediated regulation of apical membrane Na+ permeability in epithelia, we examined the effect of pH on the biophysical properties of ENaC. To this end, we expressed various combinations of alpha-, beta-, and gamma-subunits of ENaC in Xenopus oocytes and studied ENaC currents by the two-electrode voltage-clamp and patch-clamp techniques. In addition, the effect of pH on the alpha-ENaC subunit was examined in planar lipid bilayers. We report that alpha,beta,gamma-ENaC currents were regulated by changes in intracellular pH (pHi) but not by changes in extracellular pH (pHo). Acidification reduced and alkalization increased channel activity by a voltage-independent mechanism. Moreover, a reduction of pHi reduced single-channel open probability, reduced single-channel open time, and increased single-channel closed time without altering single-channel conductance. Acidification of the cytoplasmic solution also inhibited alpha, beta-ENaC, alpha,gamma-ENaC, and alpha-ENaC currents. We conclude that pHi but not pHo regulates ENaC and that the alpha-ENaC subunit is regulated directly by pHi.

Gap junction change in supporting cells of the organ of Corti with ryanodine and caffeine

It has been demonstrated that the gap junctions of the supporting cells of the organ of Corti are controlled by H+ and Ca2+. Inside these cells there is a tubular structure. It is supposed that this network is endoplasmic reticulum. Calcium release from inside the cells, and the effect of calcium on the gap junctions of these cells, were investigated under whole cell clamping application of ryanodine and caffeine. Membrane capacitance and membrane resistance were calculated, with corrections for changes in whole cell parameters. Ryanodine-treated cells (1 microM-10 mM), caffeine-treated cells (5 mM 500 nM) and A23187-treated cells were uncoupled at their gap junctions. Therefore, Ca2+ plays a role in the uncoupling of the gap junctions in supporting cells of the organ of Corti from inside the cells.

Isolation and characterization of Methanobacterium thermoautotrophicum DeltaH mutants unable to grow under hydrogen-deprived conditions

By using random mutagenesis and enrichment by chemostat culturing, we have developed mutants of Methanobacterium thermoautotrophicum that were unable to grow under hydrogen-deprived conditions. Physiological characterization showed that these mutants had poorer growth rates and growth yields than the wild-type strain. The mRNA levels of several key enzymes were lower than those in the wild-type strain. A fed-batch study showed that the expression levels were related to the hydrogen supply. In one mutant strain, expression of both methyl coenzyme M reductase isoenzyme I and coenzyme F420-dependent 5,10-methylenetetrahydromethanopterin dehydrogenase was impaired. The strain was also unable to form factor F390, lending support to the hypothesis that the factor functions in regulation of methanogenesis in response to changes in the availability of hydrogen.

Methionine and 2-hydroxy-4-methylthiobutanoic acid are transported by distinct Na(+)-dependent and H(+)-dependent systems in the brush border membrane of the chick intestinal epithelium

The pathways that facilitate the uptake of L-methionine (L-Met), D-methionine (D-Met) and L-2-hydroxy-4-methylthiobutanoic acid (L-HMB) were characterized in chick intestinal brush border membrane vesicles. A model of high affinity transport (Km approximating 0.1 mmol/L) converged to the data obtained for 35S-L-Met uptake under Na(+)-gradient and Na(+)-free conditions. The maximal velocity of 35S-L-Met transport was almost threefold greater in the presence of a Na(+)-gradient. Concentrations (100 mmol/L) of D-Met, the L-isomers of neutral amino acids and 2-aminobicyclo[2.2.1]heptane-2-carboxylic acid completely inhibited 35S-L-Met transport. A model of low affinity competitive inhibition (Ki approximately 17 mmol/L) described D-Met inhibition of 35S-L-Met transport. These data indicate that L- and D-Met are transported by a broad specificity system B type transporter. Maximal rates of 3H-L-HMB uptake were obtained under conditions of an internally directed H(+)-gradient (pHin = 7.5, pHout = 5.5). A model of intermediate affinity transport (Km approximately 1 mmol/L) described H(+)-dependent 3H-L-HMB uptake across the vesicles. The data from this and other studies indicate that a H(+)-dependent, nonstereo-specific system facilitates the uptake of the hydroxy analogues of linear amino acids, including HMB.

Effect of pH on potassium and proton conductance in renal proximal tubule

The effect of intracellular and extracellular pH on potassium conductance (GK) was examined in isolated amphibian (Rana pipiens) proximal tubule cells under whole cell voltage clamp conditions. Internal perfusion of the patch pipette was used to precisely control intracellular pH. In the region of normal resting potential (-51 +/- 3 mV), raising cell pH from 6.5 to 8.0 did not significantly increase GK (1.1 +/- 0.3 vs. 1.3 +/- 0.3 nS; P > 0.08, n = 8). Similar elevations in external (bath) pH had even less of an effect on GK. In contrast, when cells were voltage clamped to 30 mV more negative than the resting potential, raising internal pH from 6.5 to 8.0 did increase GK from 1.05 +/- 0.3 to 1.8 +/- 0.5 nS (P < 0.04; n = 8). These results suggest that modest changes in pH have little effect on GK, except at large negative potentials. In the process of examining the pH dependence of GK, a slowly activating, voltage-dependent conductance of 7.5 +/- 1 nS (n = 20; for 20 microns cells) was observed during cell depolarization. Although the instantaneous current-voltage relation of this conductance was linear, its marked voltage dependence produced an apparent steady-state rectification, with Gm = 0.5 +/- 0.2 nS and Gout = 9.0 +/- 1 nS (n = 11). Outward current was reversibly blocked by 3 mM Cu, Cd, or Co. In the absence of Na, K, and Ca (and only trace amounts of Cl), rapid changes in bath pH from 6.5 to 8.0 shifted the steady-state reversal potential (Erev) by -37 +/- 4 mV (n = 9) and the instantaneous Erev by -56 +/- 4 mV (n = 9). These shifts in Erev were consistent with a hydrogen ion conductance (GH), similar to what has been reported for snail neuron, neutrophils, alveolar epithelial cells, and phagocytes. Since the magnitude of this GH would be insignificant at resting cell pH and membrane potential, its role in renal proximal tubule under normal conditions is somewhat obscure. Nonetheless, in pathological situations, GH could function to prevent acid overload during any process that depolarizes the cell, such as low temperature or metabolic inhibition.

Does counterperfusion supersaturation cause gas cysts in pneumatosis cystoides coli, and can breathing heliox reduce them?

The pathogenesis of pneumatosis cystoides coli remains obscure in the absence of an explanation for why pockets of gas should form in the first place and why they should be maintained in the wall and mesentery of the colon. Counterperfusion supersaturation could explain the formation and location of the gas cysts, which occur mostly near blood vessels on the mesenteric border of the colon, and the absence of methane gas in them. The hypothesis can be tested by treating patients with pneumatosis cystoides coli with heliox.

Intracellular H+ inhibits a cloned rat kidney outer medulla K+ channel expressed in Xenopus oocytes

The pH sensitivity of a cloned rat kidney K+ channel, ROMK1, was examined after expression in Xenopus oocytes. Membrane currents and intracellular pH (pHi) were concomitantly monitored by the two-microelectrode voltage-clamp technique and a pH-sensitive microelectrode. Oocytes injected with ROMK1 cRNA developed a hyperpolarized resting potential of -98.7 +/- 0.98 mV and a slightly inwardly rectifying Ba(2+)-sensitive K+ current. Lowering external pH from 7.4 to 6.7 using membrane-permeable acetate buffer reduced measured pHi from 7.2 to 6.6 and reduced the ROMK1 current by 80%. The H+ blockade of ROMK1 currents was voltage independent. The relationship between ROMK1 slope conductance and pHi fitted to a titration curve suggested binding of four H+ to a site with a pK of 6.79. Extracellular acidification from pH 7.4 to 6.0 using membrane-impermeable biphthalate buffer had no effect on the ROMK1 current. The pH sensitivity of the ROMK1 channel is similar to that reported for a small-conductance native kidney K+ channel.

Pneumatosis cystoides intestinalis and high breath H2 excretion: insights into the role of H2 in this condition

Patients with pneumatosis cystoides intestinalis have been reported to excrete excessive H2 because of a lack of H2-consuming intestinal bacteria. This study describes a patient with bacterial overgrowth and pneumatosis of the small intestine whose colonic flora avidly consumed H2 but whose small bowel flora produced but did not consume H2. There is no commonly accepted mechanism whereby excessive luminal H2 causes intramural gas. An explanation is proposed in which an initial, transitory source of intramural gas is distinguished from the mechanism that results in the persistence of the gas. Independent of the initial source of gas, rapid diffusion of H2 from the lumen into an intramural gas bubble would cause N2, O2, and CO2 to diffuse from the blood into the bubble. As a result, the bubble would expand and then persist indefinitely as long as H2 continued to diffuse from the lumen to the intramural gas collection.

Extracellular H+ modulates acetylcholine-activated nonselective cation channels in guinea pig ileum

The effects of external H+ on the acetylcholine-induced inward current (nonselective cationic current; InsACh) in guinea pig ileal smooth muscle were investigated using the conventional whole cell patch-clamp technique. When the external pH (pHo) was lowered, the amplitude of InsACh was increased, with no significant change in the reversal potential or no detectable induction of other ionic permeabilities. The dose-response curve for this effect was best described by a Hill-type equation with an apparent pKa value of 7.4 and a Hill coefficient of approximately 1. The effect of pHo was associated with a shift of the steady-state activation curve for InsACh; the half-maximum activation potential became more negative on lowering pHo. Similar results were obtained when InsACh was activated by intracellularly applied guanosine 5'-O-(3-thiotriphosphate). These results indicate that the external H+ activity is an efficient regulator of InsACh channel, and this may have a physiological importance for controlling the muscarinic receptor-mediated contractions in this muscle.

Developmental blockage of mouse embryos caused by fatty acids

PURPOSE

It has been shown that lipid peroxides derived from polyunsaturated fatty acids (PUFAs) inhibit the proliferation of various cells. In the meantime, it has been suggested that oxidative stress is closely related to the developmental blockage of mammalian embryos cultured in vitro. In this study, we investigated the effects by various fatty acids on mouse embryo development in vitro, and the reversal of these effects by various antioxidants such as superoxide dismutase, ascorbic acid, alpha-tocopherol, uric acid, and ethylenediaminetetraacetic acid.

METHODS

Pronuclear and two-cell stage mouse (ICR) embryos were cultured in Biggers-Whitten-Whittingham medium with 0.3% bovine serum albumin alone or complexed with one of the following fatty acids: palmitic, stearic, oleic, linoleic, linolenic, or arachidonic acid. We also measured the fluorescence emission of embryos in media containing various fatty acids in order to investigate the involvement of H2O2 or lipid peroxidation in embryo development.

RESULTS

Palmitic acid and PUFAs including linoleic acid inhibited the embryo development. The inhibitory effect of PUFAs was attenuated by adding antioxidants into the media, while the inhibitory effect of palmitic acid was not. Both pronuclear and two-cell stage embryos with PUFAs showed markedly more intensive emissions than those under other conditions.

CONCLUSIONS

These results suggest that lipid radicals can easily be generated in early stage embryos and that blastomeres are among the cells vulnerable to the damage by lipid peroxidation.

Hydrogen and potassium regulation of (pro)renin processing and secretion

H and K ions play central roles in prorenin processing and secretion, and prorenin is abnormally expressed in H and K disorders. At the surface membrane of juxtaglomerular (JG) cells, K is sensed and regulated by K channels (coupled to Cl channels and activated by excess Ca), Na-K-adenosinetriphosphatase, and a KCl/H exchange transporter (regulated by Ca). In JG cell granular membrane, K flux is regulated by K channels and a KCl/H exchange transporter (activated by Ca). H channels and a H pump reside in the granular membrane, which maintain H concentration in the granular matrix at least two orders of magnitude greater than in cytosol. The H pump may also be responsible for maintaining the acidic matrix required for maximal prorenin processing to renin by prohormone convertase for human renin (PCren), the prorenin convertase. These molecules form the core of a chemiosmotic system, which appears to regulate both prorenin processing and renin secretion. Renin secretion and prorenin processing appear to be of more than causal significance in clinical disorders characterized by chemiosmotic imbalance. A critical review of the literature supports the following general conclusions. First, hyperrenin state defines the initial phase in the pathogenesis of heart disease, diabetes mellitus, and hypertension. Second, low-renin syndrome defines the transition-to-establish phase in the pathogenesis of heart disease, diabetes mellitus, and hypertension in which the key feature is renin secretory hyporesponsivity. Third, renin disorders are usually associated with other endocrine disorders (polyendocrinopathies types I, II, and III), suggesting that renin may be an important molecule in the processing of chemiosmotic forces. The key chemiosmotic molecules (K and H) are also important in the processing and export of most (if not all) hormones. Thus, by regulating K and H homeostasis, renin may regulate the endocrine system.

The Ca(2+)-extruding ATPase of the human platelet creates and responds to cytoplasmic pH changes, consistent with a 2 Ca2+/nH+ exchange mechanism

The Ca(2+)-extruding ATPase pump of the human platelet was studied in situ by measuring Ca2+ extrusion from quin2-overloaded platelets (Johansson, J.S., Haynes, D.H. 1988. J. Membrane Biol. 104:147-163). Cytoplasmic pH (pHcyt) was measured by BCECF fluorescence in parallel experiments. The pump was studied by raising the cytoplasmic free Ca2+ to 2.5 microM and monitoring active Ca2+ extrusion into a Ca(2+)-free medium. The pump was shown to perturb pHcyt, to not respond to changes in membrane potential and to respond to imposed changes in pHcyt in a manner consistent with the Ca2+ pump acting as a 2 Ca2+/nH+ exchanger. (i) Raising the external pH (pHext) from 7.40 to 7.60 lowers the Vmax of the pump in basal condition (Vmax,1) from 110 +/- 18 to 73 +/- 12 microM/min (= mumol/liter cell volume/min). (ii) Lowering pHext to 7.13 raised Vmax,1 to 150 +/- 15 microM/min. (iii) In an N-methyl-D-glucamine (NMDG+) medium, the pump operation against high [Ca2+]cyt acidifies the cytoplasm by -0.36 +/- 0.10 pH units, and the pump becomes self-inhibited. (iv) Use of nigericin to drive pHcyt down to 6.23 reduces the Vmax,1 to 18 +/- 11 microM/min. (v) Alkalinization of the cytoplasm by monensin in the presence of Na+ raises the Vmax,1 (basal state with Km,1 = 80 nM) to 136 +/- 24 microM/min, but also activates the pump fourfold (Vmax,2 = 280 +/- 28 microM/min; Km,2 = 502 +/- 36 nM). (vi) Transient elevation of pHcyt by NH4Cl at high [Ca2+]cyt activates the pump eightfold (Vmax,2 > or = 671 +/- 350 microM/min). The large activation by alkaline pHcyt at high [Ca2+]cyt can be explained by Ca(2+)-calmodulin activation of the pump (Valant, P.A., Adjei, P.N., Haynes, D.H. 1992. J. Membrane Biol. 130:63-82) and by increased Ca2+ affinity of calmodulin at high pH.

[Prevalence of lactose malabsorption in Roman school children. A H2 breath test study using a cow's milk]

The aim of this study was to evaluate the prevalence of lactose malabsorption in a population of 75 (43 males, 32 females) apparently healthy school-children using the H2 breath test with cow's milk. The children, ranging in age from 8 years and 6 months to 15 years and 2 months (mean: 11 years, 7 months) were divided into 2 age groups: Group I (no. = 26): age < 11 years and Group II (no. = 49): age > 11 years. After on overnight fasting, lasting at least 8 hours, samples of expired air were collected at 0 time and at 30-min intervals following the administration of 250 ml cow's milk for a total time of 3 hours. The H2 breath concentration was then measured by gas chromatography (Micro-Lyzer Quintron Instruments Company mod. 12). A net rise of more than 20 ppm H2 was considered as lactose malabsorption. Subjects with symptoms such as excessive flatulence, abdominal pain, or diarrhoea, were considered as lactose intolerant. Two-hundred and 50 ml of cow's milk (12 g of lactose) was considered a more physiological vehicle than the traditional lactose aqueous solution. The examined children, all on free diet, showed a fasting alveolar from 0 to 43 ppm (mean +/- SD = 7.9 +/- 7.6). Sixty-six children out of 70 (93.3%), who completed the test had a total absorption of lactose. Two out of 4 children with lactose malabsorption originated from areas (East Africa and Central America), where a high incidence of this metabolic disorder is a characteristic findings.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism by which histamine increases gastric mucosal blood flow in the rat. Role of luminal H+

The mechanism by which histamine increases gastric mucosal blood flow (GMBF) was investigated in the anesthetized rat. The experiment was performed in the presence of tripelennamine, an H1 antagonist, to focus on the relationship between acid secretion (H2-receptor-mediated response) and GMBF. The stomach was mounted on a Lucite chamber, perfused with saline, and GMBF was measured by laser Doppler flowmetry simultaneously with acid secretion. Under these conditions, histamine at the submaximal dose significantly increased GMBF as well as acid secretion, and this increase of GMBF was completely blocked when acid secretion was inhibited by cimetidine or omeprazole. The elevation of GMBF caused by histamine was also significantly attenuated when luminal H+ was removed by intraluminal perfusion with NaHCO3 or glycine. Glycine by itself did not affect the increase of acid secretion induced by histamine and the increase of GMBF caused by isoproterenol, yet significantly inhibited the GMBF response induced by pentagastrin. Intraluminal perfusion with HCl also produced an increase of GMBF in a concentration-related manner, even in the presence of omeprazole during histamine infusion. Pretreatment of the animals with indomethacin significantly blocked the GMBF responses induced by either histamine or luminal HCl. These results suggest that the increase of GMBF during acid secretion induced by histamine may be caused by luminal H+ and involve endogenous prostaglandins in its mechanism.

Induction of protein phosphorylation, protein synthesis, immediate-early-gene expression and cellular proliferation by intracellular pH modulation. Implications for the role of hydrogen ions in signal transduction

In Syrian hamster embryo cells, intracellular acidification (but not alkalization) results in proliferation, immediate-early-gene expression and tyrosine phosphorylation. In addition, both intracellular acidification and alkalization result in serine/threonine phosphorylation and de novo protein synthesis of specific proteins. Calcium is not mobilized in response to either intracellular alkalization or acidification. Neither intracellular acidification nor alkalization altered the serum proliferative signal while intracellular alkalization (but not acidification) reduced the epidermal-growth-factor-induced proliferative signal, tyrosine phosphorylation and immediate-early-gene expression. Finally, intracellular acidification (but not alkalization) could induce immediate-early-gene expression in cells growing in the presence of serum, indicating that the pH signalling pathway is not down modulated by the serum signalling pathway. These results, while indirect, indicate that hydrogen ions may play an important role in mitogen-signal transduction in Syrian hamster embryo cells.

[Fructose malabsorption and dysfunctional gastrointestinal manifestations]

BACKGROUND

Individuals with impaired intestinal absorption of fructose may exhibit recurrent abdominal discomfort after the ingestion of fructose-containing foods. We report on patients with this disorder in whom the diagnosis was made by the fructose hydrogen breath test.

METHODS

We investigated 293 patients with recurrent abdominal pain, meteorism or diarrhea in connection with the ingestion of fruits, apple juice or soft drinks. Mixed expired air was collected before and at 30 minute intervals after a fructose load and analysed thereafter by a hydrogen sensitive electrochemical cell. Incomplete absorption of fructose was defined as a peak rise in breath hydrogen of > 20 ppm.

RESULTS

108 out of 293 patients showed an abnormal peak rise after fructose (mean 71.8 ppm, SD 31.4). This malabsorption of fructose was associated with clinical symptoms in 79 of them. Sensitivity and specificity of the fructose hydrogen breath test were 98 or 86 per cent respectively. 19 patients with an abnormal breath test and symptoms following fructose were reexamined after a load with equimolar concentrations of glucose and fructose. Hydrogen breath test was normal in all of them, none developed abdominal discomfort.

CONCLUSION

A considerable number of individuals suffer from dysfunctional gastrointestinal problems due to fructose malabsorption. The fructose hydrogen breath test is a simple, sensitive and noninvasive method for the diagnosis for this disorder. Possible means of treatment are dietary fructose restriction or a modification of the diet in which fructose-containing foods are exchanged for those with equal concentrations of glucose and fructose.

Electrogenic H(+)-regulated sulfate-chloride exchange in lobster hepatopancreatic brush-border membrane vesicles

Transport of [35S]sulfate by brush-border membrane vesicles (BBMV) of lobster (Homarus americanus) hepatopancreas was stimulated by an outwardly directed chloride gradient. In contrast, sulfate uptake was not enhanced by inwardly directed Na+ or K+ transmembrane gradients. An inside-positive membrane potential (valinomycin and K+) stimulated SO4(2-)-Cl- exchange, whereas an inside-negative membrane potential was inhibitory. Sulfate-sulfate exchange was not affected by alterations of transmembrane potential. An inwardly directed proton gradient, or the presence of low bilateral pH, enhanced SO4(2-)-Cl- exchange, but the H+ gradient alone did not stimulate sulfate uptake in chloride-equilibrated BBMV or in vesicles lacking internal Cl-. The stilbenes 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS) and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) strongly inhibited SO4(2-)-Cl- exchange. Sulfate influx occurred by a combination of carrier-mediated transfer, exhibiting Michaelis-Menten kinetics, and nonsaturable "apparent diffusion." 36Cl- influx into sulfate-loaded BBMV was stimulated by an inside-negative transmembrane potential compared with short-circuited vesicles. These results suggest that sulfate-chloride exchange in hepatopancreatic BBMV occurred by an electrogenic carrier mechanism exhibiting a 1:1 flux ratio that was modulated by internal and external H(+)-sensitive regulatory sites. The role of this antiport process in anion secretion is discussed.

Common cis-acting region responsible for transcriptional regulation of Bradyrhizobium japonicum hydrogenase by nickel, oxygen, and hydrogen

Bradyrhizobium japonicum expresses hydrogenase in microaerophilic free-living conditions in the presence of nickel. Plasmid-borne hup-lacZ transcriptional fusion constructs were used to study the regulation of the hydrogenase gene. The hydrogenase gene was transcriptionally induced under microaerobic conditions (0.1 to 3.0% partial pressure O2). The hydrogenase gene was not transcribed or was poorly transcribed in strictly anaerobic conditions or conditions above 3.0% O2. Hydrogen gas at levels as low as 0.1% partial pressure induced hydrogenase transcription, and a high level of transcription was maintained up to at least 10% H2 concentration. No transcription was observed in the absence of H2. Hydrogenase was regulated by H2, O2, and Ni when the 5'-upstream sequence was pared down to include base number -168. However, when the upstream sequence was pared down to base number -118, the regulatory response to O2, H2, and Ni levels was negated. Thus, a common cis-acting regulatory region localized within 50 bp is critical for the regulation of hydrogenase by hydrogen, oxygen, and nickel. As a control, the B. japonicum hemA gene which codes for delta-aminolevulinic acid synthase was also fused to the promoterless lacZ gene, and its regulation was tested in the presence of various concentrations of O2 and H2. hemA-lacZ transcription was not dependent on levels of Ni, O2, or H2. Two different hup-lacZ fusions were tested in a Hup- background, strain JH47; these hup-lacZ constructs in JH47 demonstrated dependency on nickel, O2, and H2, indicating that the hydrogenase protein itself is not a sensor for regulation by O2, H2, or nickel.

Ca2+ and pH regulation of K+ channels in membrane vesicles of rabbit proximal tubule

The effect of Ca2+ and pH on the renal epithelial K+ channel was investigated by measuring the Ba2(+)-sensitive 86Rb+ fluxes in membrane vesicles from pars convoluta of rabbit proximal tubule. It was found that the presence of nanomolar concentrations of Ca2+ in the internal compartment (cytoplasmic) of the vesicles ([Ca2+]i) substantially lowered the channel-mediated flux. Ba2(+)-sensitive 86Rb+ uptake was completely blocked by 10 microM [Ca2+]i. This inhibitory effect of Ca2+ was strongly dependent on pH. Thus 0.1 microM [Ca2+]i produced a maximal inhibition of 86Rb+ uptake at pH greater than 7.4 but had no effect at pH less than 7.0. The tracer fluxes measured in the absence of Ca2+ were pH independent over this range. The data are compatible with the model that Ca2+ blocks K+ channels by binding to a site composed of one or several deprotonated groups. The protonation of any one of these groups prevents Ca2+ from binding to this site but does not by itself block transport.

Proton-induced sodium current in frog isolated dorsal root ganglion cells

1. The proton-induced current was examined in isolated frog dorsal root ganglion (DRG) cells by the use of the "concentration-clamp" technique, which allows intracellular perfusion and rapid change of external solution with various pH (pHo) within 2 ms under single-electrode voltage-clamp condition. 2. Over one-half of the examined neurons showed no response for a "step" reduction of pHo even in a Ca2(+)-free external solution. In smaller neurons having a diameter less than 20 microns, the persistent and reliable proton-induced responses were obtained, though the current amplitude and the activation and inactivation varied considerably for each cell. 3. The decrease of external Na+ concentration ([Na+]o) reduced the proton response. The proton response reversed the direction and the Na+ equilibrium potential (ENa). 4. With decreasing pHo from 7.4, proton response increased in a sigmoidal fashion. The threshold was around pH 7.0 and the maximum response appeared at pH 5.2, whereas pKa and Hill coefficient were 6.0 and 1.97, respectively. 5. The activation and inactivation phases of the proton-induced current behaved as a single exponential function. The time constants of activation (tau a) and inactivation (tau i) were not affected by changing either the holding membrane potential (VH) or the low external Ca2+ concentration [( Ca2+]o) between 10(-6) and 5 X 10(-3) M. But the decrease of pHo up to 5.2 decreased both tau a and tau i in a saturable manner. 6. In the inactivation curve of proton-induced current obtained by decreasing pHo from various conditioning pHo to 5.5, half inactivation occurred at pHo 7.45.(ABSTRACT TRUNCATED AT 250 WORDS)

Stimulation of H+ secretion by CO2 in turtle bladder: role of intracellular pH, exocytosis, and calcium

We studied the interaction of intracellular pH, exocytosis, and cell calcium on the stimulation of H+ secretion by CO2 in turtle bladder. Intracellular pH was continuously monitored by the fluorescent dye 6-carboxyfluorescein and exocytosis was monitored by the release of mucosal fluorescein dextran. The initial stimulation of H+ secretion by 1 or 5% CO2 added to the serosal solution was accompanied by a similar and temporally related increase in exocytosis. Furthermore, a decrease in intracellular pH seems necessary for the early increase in H+ secretion and exocytosis. Because calcium plays an important role in exocytosis, we measured intracellular calcium in isolated cells with the fluorescent dye quin2. An increase in intracellular calcium (from 50 to 100 nM) was observed in isolated turtle bladder epithelial cells gassed with 5% CO2. To further evaluate the role of intracellular calcium on H+ secretion and exocytosis we utilized agents that alter cell calcium such as trifluoperazine and lanthanum. In the presence of CO2 these agents blocked partially the increase in H+ secretion and exocytosis but did not affect the decrease in intracellular H+. In conclusion, exocytosis, intracellular pH, and intracellular calcium play a key role in mediating CO2-stimulated H+ secretion in the turtle bladder.

Mode of action of angiotensin II and vasopressin on their target cells

In this short review, the cellular mode of action of angiotensin II and arginine-vasopressin is described with emphasis on the transmembrane signalling system. Two target cells are considered: the zona glomerulosa cell of the adrenal gland and the vascular smooth muscle cell. The information provided should help practitioners in endocrinology and hypertension to understand the physiological concepts which are expected to form the basis for future therapeutic developments.

The novel dihydronaphthyridine Ca2+ channel blocker CI-951 improves CBF, brain pHi, and EEG recovery in focal cerebral ischemia

The effects of the novel dihydronaphthyridine Ca2+ antagonist CI-951 on focal cerebral ischemia were assessed during MCA occlusion in 30 white New Zealand rabbits under 1.0% halothane anesthesia. In vivo brain pHi and focal CBF were measured with umbelliferone fluorescence. Baseline normocapnic brain pHi and CBF were 7.02 +/- 0.02 and 48.4 +/- 2.9 ml/100 g/min, respectively. In the severe ischemic regions, 15 min postocclusion brain pHi and CBF were 6.62 +/- 0.04 and 14.4 +/- 0.7 ml/100 g/min in controls vs. 6.60 +/- 0.02 and 12.9 +/- 2.3 ml/100 g/min, respectively, in animals destined to receive CI-951. Twenty minutes after MCA occlusion, CI-951 was administered at 0.5 microgram/kg/min and brain pHi and CBF were determined in both regions of severe and moderate ischemia for 4 h postocclusion. Control severe ischemic sites demonstrated no significant improvement in brain pHi and only mild increases in CBF over the next 4 h. CI-951 caused significant improvement in both of these parameters. Postocclusion 4 h brain pHi and CBF measured 6.69 +/- 0.04 and 18.5 +/- 3.2 ml/100 g/min in controls vs. 7.01 +/- 0.04 and 41.7 +/- 5.3 ml/100 g/min, respectively, in CI-951 animals (p less than 0.001). Similar improvements were observed in moderate ischemic sites. In animals that demonstrated postocclusion EEG attenuation, 75% of CI-951 animals had EEG recovery as compared to 18% in controls. CI-951 may be a useful therapeutic agent for focal cerebral ischemia if histological and outcome studies verify these data.

Repeated noninvasive measurement of gastrointestinal transit in rats

A technique for repeated and noninvasive measurement of oro-cecal transit time in rats and other small animals is described. It is based on the incomplete digestion of carbohydrates such as lactose fed orally to the animals. Since the activity of the enzyme lactase is low in almost all species, lactose is fermented by colonic bacteria after it arrived in the cecum, thus producing hydrogen. Hydrogen is delivered to the lungs via the circulation and exhaled by the animal. An increase in breath hydrogen measured by means of an electrochemical cell or a gas-chromatograph indicates the arrival of the nutrient bolus in the cecum. The method can be used repeatedly in individual animals under various experimental conditions such as investigations of stress effects on gastrointestinal transit.

Contractile shortening response of ventricular cells to extracellular acidosis. Evidence for two-site control of H+-Ca2+ interaction

The effect of extracellular acidosis on contraction of single isolated ventricular cells from rabbit was measured in a system in which pHo could be changed in less than 200 msec. The contractile response to acidotic levels was complete within 25 seconds. The response was measured 30 seconds after pHo was decreased to 7.0, 6.5, 6.0, and 5.5 at each of 8 [Ca]o levels (0.125-4.0 mM). Cell shortening versus [Ca]o was plotted to construct a curve for each pHo level, with each point relative to shortening at pH 7.5, [Ca]o = 1 mM (100% value). Calcium current (1 mM [Ca]o) was also measured 30 seconds after pHo was decreased from 7.5 to 6.5 with single-cell patch clamp technique. The contractile response to extracellular acidosis is accurately predicted by assuming two (probably sarcolemmal) sites at which H+ ions affect calcium binding and/or flux: (equation; see text) The first factor represents a set of sites that are proposed to control access, dependent on the degree of their ionization, to sites represented by the second factor. The latter sites are proposed to accept calcium according to mass-action law. The response of calcium channel current to extracellular acidosis was also complete and reversible within 25 seconds. The current response indicates that the two-site model could be predictive for the effect of extracellular acidosis on calcium current in ventricular cells.

Intracellular pH transients of mammalian astrocytes

Intracellular pH (pHi) is an important physiologic variable that both reflects and influences cell function. Glial cells are known to alter their functional state in response to a variety of stimuli and accordingly may be expected to display corresponding shifts in pHi. We used fine-tipped, double-barreled, pH-sensitive microelectrodes to continuously monitor pHi in glial cells in vivo from rat frontal cortex. Cells were identified as glia by a high membrane potential and lack of injury discharge or synaptic potentials. Continuous, stable recordings of pHi from astrocytes were obtained for up to 80 min but typically lasted for approximately 10 min. Resting pHi was 7.04 +/- 0.02 with a membrane potential of 73 +/- 0.9 mV (mean +/- SEM; n = 51). With cortical stimulation, glia depolarized and became more alkaline by 0.05-0.40 pH (n = 50). During spreading depression (SD), glia shifted more alkaline by 0.11-0.78 pH (n = 26). After stimulation or SD, glia repolarized and pHi became more acidic than at resting levels. Superfusion of the cortical surface with 0.5-2 mM Ba2+ caused glia to hyperpolarize during stimulation and completely abolished the intracellular alkaline response. The predominant pH response of the interstitial space during stimulation or SD was a slow acidification. With superfusion of Ba2+ an early stimulus-evoked interstitial alkaline shift was revealed. The mechanism of the intracellular alkaline shift is likely to involve active extrusion of acid. However, internal consumption of protons cannot be excluded. The sensitivity of the response to Ba2+ suggests that it is triggered by membrane depolarization. These results suggest that glial pHi is normally modulated by the level of local neuronal activity.

Regulation of cytoplasmic pH of cultured bovine corneal endothelial cells in the absence and presence of bicarbonate

Intracellular pH (pHi) in confluent monolayers of cultured bovine corneal endothelial cells was determined using the pH-dependent absorbance of intracellularly trapped 5(and 6)carboxy-4',5'-dimethylfluorescein. Steady-state pH was 7.05 +/- 0.1 in the nominal absence of bicarbonate, and 7.15 +/- 0.1 in the presence of 28 mM HCO3-/5% CO2. Following an acid load imposed by a NH4Cl prepulse, pHi was regulated in the absence of HCO3- by a Na+-dependent process inhibitable to a large extent by 1 mM amiloride and 0.1 mM dimethylamiloride. In the presence of 28 mM HCO3-/5% CO2, this regulation was still dependent on Na+, but the inhibitory potency of amiloride was less. DIDS (1 mM) partially inhibited this regulation in the presence, but not in the absence of bicarbonate. With cells pretreated with DIDS, amiloride was as effective in inhibiting recovery from acid load as in the absence of HCO3-. The presence of intracellular Cl- did not appreciably affect this recovery, which was still sensitive to DIDS in the absence of Cl-. Removal of extracellular Na+ led to a fall of pHi, which was greatly attenuated in the absence of HCO3-. This acidification was largely reduced by 1 mM DIDS, but not by amiloride. Cl removal led to an intracellular alkalinization in the presence of HCO3-. The presence of a Cl-/HCO3- exchanger was supported by demonstrating DIDS-sensitive 36Cl- uptake into confluent cell monolayers. Thus, bovine corneal endothelial cells express three processes involved in intracellular pH regulation: an amiloride-sensitive Na+/H+ antiport, a Na+-HCO3- symport and a Cl-/HCO3- exchange, the latter two being DIDS sensitive.

Transmembrane outward hydrogen current in intracellularly perfused neurones of the snail Helix pomatia

The ionic nature and pharmacological properties of the outward current activated by membrane depolarization were studied on isolated neurones of the snail Helix pomatia, placed in Na+- and Ca2+-free extracellular solutions and intracellularly perfused with K+-free solution ("nonspecific outward current"). It was shown that the amplitude and reversal potential of this current (estimated from instantaneous current-voltage characteristics) are determined mainly by the transmembrane gradient for H+ ions. Lowering of pHi induced an increase in the current amplitude and a shift of the reversal potential to more negative values; the shift magnitude was comparable with that predicted for the hydrogen electrode. Raising pHi, as well as lowering pHo, induced a decrease in the current amplitude and a displacement of the current activation curve to more positive potentials. Addition of EGTA (8 mmol/l) to the intracellular perfusate did not affect the current amplitude. Extracellular 4-aminopyridine (10 mmol/l), verapamil (0.25 mmol/l) or Cd2+ (0.5 mmol/l) blocked the current. It is concluded that the current studied is carried mainly by H+ ions. In the same neurones the nature of the fast decay of the calcium inward current was also studied (in the presence of extracellular Ca2+ ions). This decay considerably slowed when pHi was raised or pHo was lowered, and it became less pronounced upon extracellular application of 4-aminopyridine or upon intracellular introduction of phenobarbital (4 mmol/l) and tolbutamide (3 mmol/l). It is suggested that the fast decay of the calcium inward current is due to activation of a Ca-sensitive component of the hydrogen current which depends on accumulation of Ca2+ ions. The possible physiological role of the transmembrane hydrogen currents is discussed.

The plasma membrane sodium-hydrogen exchanger and its role in physiological and pathophysiological processes

The plasma membranes of most if not all vertebrate cells contain a transport system that mediates the transmembrane exchange of sodium for hydrogen. The kinetic properties of this transport system include a 1:1 stoichiometry, affinity for lithium and ammonium ion in addition to sodium and hydrogen, the ability to function in multiple 1:1 exchange modes involving these four cations, sensitivity to inhibition by amiloride and its analogues, and allosteric regulation by intracellular protons. The plasma membrane sodium-hydrogen exchanger plays a physiological role in the regulation of intracellular pH, the control of cell growth and proliferation, stimulus-response coupling in white cells and platelets, the metabolic response to hormones such as insulin and glucocorticoids, the regulation of cell volume, and the transepithelial absorption and secretion of sodium, hydrogen, bicarbonate and chloride ions, and organic anions. Preliminary evidence raises the possibility that the sodium-hydrogen exchanger may play a pathophysiological role in such diverse conditions as renal acid-base disorders, essential hypertension, cancer, and tissue or organ hypertrophy. Thus, future research on cellular acid-base homeostasis in general, and on plasma membrane sodium-hydrogen exchange in particular, will enhance our understanding of a great variety of physiological and pathophysiological processes.

Proton-coupled transport of organic solutes in animal cell membranes and its relation to Na+ transport

Recent studies on proton-coupled transport of organic solutes in animal cell membranes were reviewed. In the intestinal and renal brush border membranes, transport of intact small peptides (di- or tri-peptides) has been established to be cotransported with H+. The peptide transport is Na+-independent, dependent on a pH gradient, electrogenic as revealed by transport-associated membrane depolarization and conductance increase, and reveals a marked overshoot uptake when a sufficiently large proton gradient is imposed across the membrane. Similar properties are found for L-lysine transport by the brush border membrane vesicles from mullet kidney and for L-leucine transport in some cultured cells. Partial involvement of H+ in Na+-dependent transport has also been reported for some organic acids, L-glutamate, and citrate. The physiological meanings of these purely H+-dependent and partially H+-dependent transports have been discussed based on available data.

Ca2+- and H+-dependent effects of crude bacterial phospholipase C on the hydroosmotic response of toad urinary bladder to serosal hypertonicity

Phospholipase C (EC 3.1.4.3.) from Clostridium perfringens (crude extracts) was used to study the role of phospholipids in the osmotic permeability of the urinary bladder of the toad. When added to the serosal bath (430 mU/ml) it inhibited the effects of antidiurectic hormone (ADH) and exogenous cyclic AMP. Under the same conditions the increase in osmotic flow produced by serosal hypertonicity (SH) was slightly enhanced by the lipase. The hydroosmotic effect of SH was greatly potentiated by the lipase by decreasing 10-fold the Ca2+ concentration. The SH-induced flow was inhibited by the lipase if the Ca2+ or the H+ concentration was increased 10-fold, but not if the increase in positive charges was produced by a concentration of Mg2+. Phospholipase C had no effect on the action of either ADH or SH if added to the mucosal bath. Serosal neuraminidase or phospholipase A2 could not mimic the effect of phospholipase C on SH. The effect of phospholipase C on the response to SH was not modified if fatty acid-free bovine serum albumin was added to the bath. Therefore, the release of products of lipolysis into the bath do not seem to be responsible for the effects of phospholipase C on SH-induced water flow. The results suggest that the effects of the enzyme on the composition and rearrangement of lipids at the basolateral membrane produce modifications of the water flow. Ca2+ and H+ may modify the enzyme-substrate interaction, suggesting that different phospholipids may be differentially involved in the control of water permeability of the basolateral membrane.(ABSTRACT TRUNCATED AT 250 WORDS)