Surface characteristics of carbonic-anhydrase-rich cells in turtle urinary bladder

The H+-ATPase (V-ATPase): from proton pump to signaling complex in health and disease

A primary function of the H⁺-ATPase (or V-ATPase) is to create an electrochemical proton gradient across eukaryotic cell membranes, which energizes fundamental cellular processes. Its activity allows for the acidification of intracellular vesicles and organelles, which is necessary for many essential cell biological events to occur. In addition, many specialized cell types in various organ systems such as the kidney, bone, male reproductive tract, inner ear, olfactory mucosa, and more, use plasma membrane V-ATPases to perform specific activities that depend on extracellular acidification. It is, however, increasingly apparent that V-ATPases are central players in many normal and pathophysiological processes that directly influence human health in many different and sometimes unexpected ways. These include cancer, neurodegenerative diseases, diabetes, and sensory perception, as well as energy and nutrient-sensing functions within cells. This review first covers the well-established role of the V-ATPase as a transmembrane proton pump in the plasma membrane and intracellular vesicles and outlines factors contributing to its physiological regulation in different cell types. This is followed by a discussion of the more recently emerging unconventional roles for the V-ATPase, such as its role as a protein interaction hub involved in cell signaling, and the (patho)physiological implications of these interactions. Finally, the central importance of endosomal acidification and V-ATPase activity on viral infection will be discussed in the context of the current COVID-19 pandemic.

Electrogenic proton transport by intercalated cells of tight urinary epithelia

Structure-function studies of the turtle bladder indicate that electrogenic proton secretion into the urinary compartment is accomplished by alpha-type intercalated cells which are rich in carbonic anhydrase. In the absence of electrochemical potential gradients (delta mu H = 0), the rate of H+ secretion (JH) is a function of the number of H+ pumps in position at the apical cell membrane, as judged from morphometric and freeze-fracture studies of apical membrane area characterized by a cytoplasmic coating with studs and by rod-shaped intramembrane particles (RSP). At a given pump population, JH is a sigmoid function of delta mu H, with delta pH and delta psi having equivalent effects on JH. The JH versus delta mu H relation reflects the intrinsic properties of the H+ pump and suggests a H+ pump model consisting of two components, a channel through the apical membrane across which delta mu H falls, and a catalytic unit located within the cytoplasm (outside of delta mu H). Each intramembrane RSP is associated with several cytoplasmic studs, but the precise relations between the two remain to be clarified.

Topographical distribution of cells in the rat submandibular gland duct system with special reference to dark cells and tuft cells

The duct system of the rat submandibular gland consists of the intercalated duct, the granular convoluted tubule, the striated duct, the excretory duct, the main excretory duct, and the salivary bladder. The duct system contains special cell types, such as dark cells and tuft cells, in addition to principal cells. However, little is known about cell distribution in the duct system. The purpose of the present study was to examine cell distribution and to perform a morphometric analysis of the duct system. Transmission and scanning electron microscopy were used to examine the duct system of the rat submandibular gland. Six regions in the duct system, the striated duct, the interlobular excretory duct, the 5-mm proximal excretory duct from the hilus, the main excretory duct at the hilus, the 10-mm distal main excretory duct from the hilus, and the salivary bladder, were investigated. Morphometric and statistical analyses of the data were then performed. The epithelium of the duct system consisted of a heterogeneous cell population. Dark cells and tuft cells were present throughout the duct system. The principal, dark, and tuft cells were distinguished by their different microvilli by using a scanning electron microscope. The frequency of these cells in the total epithelial cell population was as follows: The percentage of principal cells in the six regions of the duct system varied from 87.5% to 94.4%, that of dark cells varied from 4.1% to 7.2%, and that of tuft cells varied from 1.8% to 7.2%. The number of principal and tuft cells was significantly different between the striated duct and the main excretory duct at the hilus (P < 0.01). However, no significant difference in number of dark cells throughout the duct system was observed (P > 0.05). The abundance of the principal, dark, and tuft cells in the duct system of the rat submandibular gland was determined. Few tuft cells were distributed in the striated duct, and most were found at the hilus. Dark cells were distributed equally throughout the duct system.

Active proton and urea transport by amphibian skin

Proton secretion in frog skin is mediated by an electrogenic H+ pump. Pharmacological and immunocytological approaches have identified this pump as belonging to the V-ATPase class. The key role of this V-ATPase in proton secretion (acid-base balance) and as a membrane energizer of other solute transport from very dilute solutions is outlined. It is shown that the frog skin constitutes a model of a V-ATPase-dependent Na+ transport mechanism applicable to other freshwater animals. On the other hand, attempts to implicate the V-ATPase in the active urea transport that develops through the skin of salt-adapted frogs have failed; the nature of the different urea transporters located on apical and basal epithelial cell membranes and those responsible for active urea reabsorption remain to be identified.

Scales of urine acidification: apical membrane-associated particles in turtle bladder

Since the time of Smith, studies of urinary acidification have shifted their focus to ever smaller scales and have revealed iterative patterns or organization. For this review we focus on the organization of intra- and submembrane particles at the scale of the apical cell membrane of the H+ secreting, alpha intercalated cells. Particles were examined quantitatively by thin section and freeze-fracture (FF) electron microscopy. Ongoing studies in turtle bladder indicate that the density of submembrane particles (studs) per micron 2 is approximately the same as that of spherical units (SPUs) forming linear (rod-shaped) arrays on FF. This one-to-one relationship is observed in the presence or absence of CO2 and suggests that CO2-induced changes in H+ secretion do not involve dissociation of the intramembrane (channel) and cytoplasmic (catalytic) parts of the H-ATPase. Structure-function studies based on density estimates of the particles, morphometry of the H+ secreting cell population, and measurement of H+ transport rate prior to fixation permit functional correlation across scales of study.

Role of membrane trafficking in plasma membrane solute transport

Cells can rapidly and reversibly alter solute transport rates by changing the kinetics of transport proteins resident within the plasma membrane. Most notably, this can be brought about by reversible phosphorylation of the transporter. An additional mechanism for acute regulation of plasma membrane transport rates is by the regulated exocytic insertion of transport proteins from intracellular vesicles into the plasma membrane and their subsequent regulated endocytic retrieval. Over the past few years, the number of transporters undergoing this regulated trafficking has increased dramatically, such that what was once an interesting translocation of a few transporters has now become a widespread modality for regulating plasma membrane solute permeabilities. The aim of this article is to review the models proposed for the regulated trafficking of transport proteins and what lines of evidence should be obtained to document regulated exocytic insertion and endocytic retrieval of transport proteins. We highlight four transporters, the insulin-responsive glucose transporter, the antidiuretic hormone-responsive water channel, the urinary bladder H(+)-ATPase, and the cystic fibrosis transmembrane conductance regulator Cl- channel, and discuss the various approaches taken to document their regulated trafficking. Finally, we discuss areas of uncertainty that remain to be investigated concerning the molecular mechanisms involved in regulating the trafficking of proteins.

Localization of transport compartments in turtle urinary bladder

To characterize different transport compartments in the urinary bladder epithelium of postabsorptive turtles, the electrolyte composition of individual cells was determined using electron microprobe analysis. After blocking the transepithelial Na transport, the short-circuit current decreased from positive to negative values (from 26.5 +/- 17.7 to -3.9 +/- 2.9 after ouabain and from 25.4 +/- 17.2 to -8.0 +/- 5.1 microA/cm2 after amiloride). Whereas under control conditions the Na and K concentrations were similar in all cell types and the same was true for Cl in most of the cells, some cells exhibited very low Cl concentrations. The epithelial cells were subdivided according to their electrolyte composition into ouabain-sensitive and ouabain-insensitive ones. In the ouabain-sensitive cells, which made up the majority of epithelial cells and showed a relatively high Cl concentration (about 36 mmol/kg wet weight), the Na concentration increased after ouabain by about 90 mmol/kg wet weight and the K concentration decreased by a similar amount. Since these alterations could largely be prevented when amiloride was applied before ouabain, it is suggested that the granular and basal cells form a syncytial Na transport compartment similar to that in other multilayered epithelia. The ouabain-insensitive cells, in which almost no alteration in Na and K concentrations was observed after ouabain, were subdivided into a Cl-rich (34.6 +/- 7.6 mmol/kg wet weight) and a Cl-poor (12.0 +/- 5.6 mmol/kg wet weight) population. Since in these cells no large mucin granules were detectable, they are regarded as carbonic anhydrase-rich cells involved in H and HCO3 transport.

The key role of the mitochondria-rich cell in Na+ and H+ transport across the frog skin epithelium

We have investigated the possibility that the mitochondria-rich (MR) cells participate in sodium and proton transport, when the frog skin epithelium is bathed on its apical side with solutions of low Na+ concentration, by comparing transport rates with morphological observations (MR cell number and MR cell pit surface area). Frogs were adapted to various salinities or the isolated skins were treated with the following hormones, deoxycorticosterone acetate (DOCA), arginine vasotocin (AVT) and oxytocin in order to modify the transport of sodium and hydrogen ions. Adaptation of the frogs (either 3-4 days or 7-10 days) to distilled water, NaCl (50 mmol/l), KCl (50 mmol/l) or Na2SO4 (25 mmol/l) solutions modified the Na+ transport rate and the morphology of the epithelium. The highest Na+ transport rates were found for the animals adapted to the Na+ free solutions and were correlated with an increase in the total MR cell pit surface area (number of MR cells x individual cell pit-surface area). The KCl adaptated group showed the largest increase in sodium and proton transport and also presented a metabolic acidosis as reflected by plasma acidification (pCO2 increase and HCO3- decrease). Proton secretion and sodium absorption were also found to be stimulated by either serosal DOCA addition (10(-6) M) or during acidification of the epithelium by serosally applied CO2. Na+ transport was enhanced by AVT (10(-6) M) or oxytocin (100 mU/ml) when the skin was bathed on its apical side with a high Na+ containing solution (115 mmol/l), whereas these hormones did not exert any effect on Na+ transport when the apical solution was low in Na+ (0.5 mmol/l).(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructure of the kidney of a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona). II. Distal tubule, connecting tubule, collecting duct and Wolffian duct

The ultrastructure of the distal nephron, the collecting duct and the Wolffian duct was studied in a South American caecilian, Typhlonectes compressicaudus (Amphibia, Gymnophiona) by transmission and scanning electron microscopy (TEM, SEM). The distal tubule (DT) is made up of one type of cell that has a well-developed membrane labyrinth established both by interdigitating processes and by interlocking ramifications. The processes contain large mitochondria, the ramifications do not. The tight junction is shallow and elongated by a meandering course. The connecting tubule (CNT) is composed of CNT cells proper and intercalated cells, both of which are cuboidal in shape. The CNT cells are characterized by many lateral interlocking folds. The intercalated cells have a dark cytoplasm densely filled with mitochondria. Their apical cell membrane is typically amplified by microplicae beneath which a layer of globular particles (studs) is found. The collecting duct (CD) is composed of principal cells and intercalated cells, again both cuboidal in shape. The CD epithelium is characterized by dilated intercellular spaces, which are often filled with lateral microfolds projecting from adjacent principal cells. The apical membrane is covered by a prominent glycocalyx. The intercalated cells in the CD are similar to those in the CNT. The Wolffian duct (WD) has a tall pseudostratified epithelium established by WD cells proper, intercalated cells and basal cells. The WD cells contain irregular-shaped dense granules located beneath the apical cell membrane. The intercalated cells of the WD have a dark cytoplasm with many mitochondria; their nuclei display a dense chromatin pattern.

Band 3 is the basolateral anion exchanger of dark epithelial cells of turtle urinary bladder

The turtle urinary bladder serves as a model for collecting duct functions in the mammalian kidney. The epithelium of both the turtle bladder and the mammalian collecting duct can generate a steep gradient for H+ ions between blood and urine. Secretion of H+ into the urine is coupled to a basolateral efflux of HCO-3 that appears to be exchanged mainly against Cl-. Here we show that approximately 80% of the dark cells of the bladder contain a 110,000 relative molecular weight (Mr) analogue of the turtle erythrocyte anion exchanger, band 3. The band 3 analogue is confined to the basolateral cell surface and is absent from the apical membrane. A minor population of the dark cells (approximately 20%), which have been previously suggested to represent reverse cells that are involved in HCO-3 secretion rather than absorption, appears not to express a band 3-like anion exchanger, at either the apical or the basolateral membrane. The bladder band 3 protein is colocalized with actin and isoforms of ankyrin (200,000 Mr) and spectrin (230,000 Mr) along the basolateral membrane. Linkage of band 3 via ankyrin to the spectrin-actin lattice may restrict this anion exchanger to the basolateral membrane surface. In view of our previous observation of a band 3-like anion exchanger in the collecting duct epithelium of the rat kidney, these findings point to a common molecular basis for acid-base transport in the mammalian collecting duct and the reptilian urinary bladder.

Vasoactive intestinal peptide stimulates alkali excretion in turtle urinary bladder

The turtle urinary bladder possesses an active transport mechanism for the electrogenic secretion of alkali. This process is independent of exogenous Cl and Na, induced by cyclic AMP (cAMP), and potentiated in bladders from NaHCO3-loaded (alkalotic) turtles. In the present study, it is shown that the serosal addition of vasoactive intestinal peptide (VIP) induces rapidly developing parallel increases in alkali secretion and in the short-circuiting current carried by this secretion. The VIP-induced increment in alkali secretion is greater in the presence than in the absence of an exogenously added phosphodiesterase inhibitor. Additions of a cAMP analog subsequent to the VIP-induced alkali secretion fail to induce any further increase in alkalinization. These results provide evidence for the action of VIP as a hormonal up regulator of alkali excretion in the turtle urinary bladder.

Proton transport and membrane shuttling in turtle bladder epithelium

Proton secretion in the urinary bladder of the fresh-water turtle is mediated by proton pumps located in the apical membrane of carbonic-anhydrase (CA)-rich cells. It has been proposed that the rate of proton transport is regulated by endocytotic and exocytotic fusion processes which alter the apical membrane area, and hence number of exposed pumps. Three techniques were used to study this process. Analyses of transepithelial impedance provided estimates of transport-associated changes in net membrane area, as well as other electrical parameters. Electron microscopy allowed visualization of the endocytotic vesicles thought to be involved in the process. Finally, uptake of a fluorescent fluid-phase marker provided measurements of the rates of endocytosis. We report the following: endocytotic and exocytotic processes occur primarily in the CA-rich cells; inhibition of proton transport resulting from 0.5 mM acetazolamide (AZ) results in a decrease in the apical membrane area of approximately 0.47 cm2/cm2 tissue; the apical membrane specific conductance of the CA-rich cells is approximately 220 microS/microF, and possibly represents a Cl- conductance that may function in counter-ion flow; the decline in transport following AZ is not directly proportional to the decline in apical membrane area, suggesting that changes in pump kinetics are also involved in the regulation of transport; the CA-rich cells exhibit a high rate of constitutive pinocytosis, and hence membrane shuttling, which appears to be independent of the rate of transport; AZ induces a transient increase in the rates of endocytosis and shuttling; and the transport-associated changes in apical membrane area may reflect an effect of AZ on a regulated endocytotic pathway which is distinct from the pinocytotic process.

Mechanisms of renal tubular acidification

Both bicarbonate retrieval from the filtrate as well as the net excretion of acid depend upon hydrogen ion secretion by the tubular epithelium. Hydrogen ion secretion is mediated either by sodium-hydrogen exchange, an electroneutral and secondary active process, or by hydrogen ion secretion, a directly electrogenic and primary active process. Extrusion of hydrogen ions across the apical cell membrane is accompanied by electrogenic bicarbonate transfer across the basolateral cell membrane. Both luminal and peritubular pH exert a strong influence upon acidification by altering the gradient against which hydrogen transport or base exit occur. In the distal nephron, both hydrogen ion secretion and bicarbonate secretion may occur. These transport operations have been shown to be mediated by subgroups of intercalated cells in which hydrogen pumps and bicarbonate-chloride exchange processes are located either in the apical or basolateral cell membranes. Regulation of acidification involves several factors: the rate of luminal buffer delivery, sodium and chloride delivery, the luminal and peritubular pH and pCO2, the electrical potential, mineralocorticoids and the state of the potassium balance.

The regulation of renal acid secretion: new observations from studies of distal nephron segments

In this review we have attempted to present for the general reader the new information on renal acidification that has emerged from the study of discrete segments of the distal nephron. We have structured our presentation in the context of the cation exchange hypothesis which has strongly influenced modern thinking of acid-base regulation. We have shown that distal nephron acidification is active and can proceed even in the absence of sodium. We have also shown beyond doubt, that pH or the determinants of pH can influence the rate of proton secretion in probably all of the distal nephron segments. We have drawn attention to an exciting new means by which chloride (or its substitution) could alter the rate of net bicarbonate transport. A possible role for bicarbonate secretory activity in the mammalian distal nephron has been discussed as has the influence of mineralocorticoids on acid secretion. There is no question that all of this new information has created the need for a reassessment of the validity of the cation exchange hypothesis. After all, this is a view which specifically denies that renal acid excretion is modulated by pH of the blood, and affirms that it is intrarenal sodium handling that is the "driving force", so to speak, behind acidification responses. However, it seems inappropriate at this time to insist that current data do not allow for a component of sodium transport by the distal nephron to modulate the rate of acid secretion. It is also possible, as we have suggested, that an important effect of chloride gradients, independent of blood pH, could alter bicarbonate retrieval. Most importantly, we wish to stress that much of the in vitro perfusion data does not derive from animals subjected to the chronic acid-base derangements which were precisely those situations to which the cation exchange hypothesis was directed. Simply put, the whole animal studies of Schwartz and his colleagues provided no experimental observations on intrarenal sodium handling or acidification mechanisms, just as the microperfusion studies, both in vivo and in vitro, provide insufficient data that can be applied to whole animals subjected to chronic disturbances.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence for separate cellular origins of sodium and acid-base transport in the turtle bladder

Transmembrane electrical parameters of the epithelial cells in short-circuited turtle bladders were measured to determine whether those cells participating in Na reabsorption also participate in electrogenic transepithelial acidification and alkalinization. Amiloride-induced increases in intracellular potential (Vsca), apical fractional resistance (FRa), and concomitant decreases in short-circuit current (Isc) denote the participation of the impaled cells in Na reabsorption. In bladders from postabsorptive turtles, amiloride increased Vsca by -45 mV, increased FRa by 37%, and decreased Isc from 36 to -10 microA/cm2. In bladders from NaHCO3-loaded turtles, amiloride increased Vsca by -21 mV, FRa by 21%, and decreased Isc from 22 to 0 microA/cm2. Neither the subsequent inhibition of the negative acidification current in postabsorptive bladders, nor stimulation of positive alkalinization current in bladders from NaHCO3-loaded turtles was associated with any transmembrane electrical change that could be attributed to changes in those transport processes. It is concluded that the electrogenic luminal acidification and alkalinization processes of the turtle bladder are not produced by, or electrically coupled to, those cells that are involved in Na reabsorption.

Membrane electrical parameters in turtle bladder measured using impedance-analysis techniques

Equivalent-circuit impedance analysis experiments were performed on the urinary bladders of freshwater turtles in order to quantify membrane ionic conductances and areas, and to investigate how changes in these parameters are associated with changes in the rate of proton secretion in this tissue. In all experiments, sodium reabsorption was inhibited thereby unmasking the electrogenic proton secretion process. We report the following: transepithelial impedance is represented exceptionally well by a simple equivalent-circuit model, which results in estimates of the apical and basolateral membrane ionic conductances and capacitances; when sodium transport is inhibited with mucosal amiloride and serosal ouabain, the apical and basolateral membrane conductances and capacitances exhibit a continual decline with time; this decline in the membrane parameters is most likely caused by subtle time-dependent changes in cell volume, resulting in changes in the areas of the apical and basolateral membranes; stable membrane parameters are obtained if the tissue is not treated with ouabain, and if the oncotic pressure of the serosal solution is increased by the addition of 2% albumin; inhibition of proton secretion using acetazolamide in CO2 and HCO3- -free bathing solutions results in a decrease in the area of the apical membrane, with no significant change in its specific conductance; stimulation of proton transport with CO2 and HCO3- -containing serosal solution results in an increase in the apical membrane area and specific conductance. These results show that our methods can be used to measure changes in the membrane electrophysiological parameters that are related to changes in the rate of proton transport. Notably, they can be used to quantify in the live tissue, changes in membrane area resulting from changes in the net rates of endocytosis and exocytosis which are postulated to be intimately involved in the regulation of proton transport.

Correlation between apical intramembrane particles and H+ secretion rates during CO2 stimulation in turtle bladder

To correlate the prevalence of rod-shaped intramembrane particles (RSP) in the apical membranes of carbonic anhydrase-rich (CA) cells and the H+ transport rate in turtle urinary bladder, we carried out morphometric studies by means of scanning and freeze-fracture electron microscopy of the alpha and beta subpopulations of CA cells. Correlations were made between the apical membrane areas of alpha cells and H+ transport rate at 0 and 5% ambient CO2. Exposure to CO2 more than doubled the planar area of the luminal surface of alpha cells and increased the degree of folding (amplification) of the apical cell membrane from 2.8 +/- 0.3 to 3.8 +/- 0.3. The actual apical membrane area of alpha cells increased from 176 mm2 to 693 mm2 per 8 cm2 epithelial area. The RSP density also appeared to be increased by about 40%. The total CO2-induced increase in RSPs in position at the luminal surface was 5 fold while the increase in H+ transport was 9-fold. We conclude that stimulation of H+ transport by CO2 involves recruitment of RSP to the apical cell membrane of alpha-type CA cells and that RSPs are associated with active H+ transport. They may represent linear arrays of transmembrane components of H+ pumps.

Effect of furosemide on ion transport in the turtle bladder: evidence for direct inhibition of active acid-base transport

The diuretic furosemide inhibits acid-base transport in the short-circuited turtle bladder. It inhibits luminal acidification when present in either mucosal or serosal bathing fluids, but decreases alkalinization only from the serosal side of the tissue. The inhibition of both acid-base transport processes is independent of ambient Cl-; and the disulfonic stilbene, SITS, an inhibitor of Cl--HCO3- exchange, fails to prevent the furosemide-elicited inhibition of alkalinization. These results preclude an absolute requirement of a furosemide-sensitive Cl--HCO3- exchange by these transport processes. The drug also interferes with the CO2-induced stimulation of acidification and alkalinization. The inhibition of the residual acidification in acetazolamide-treated, acidotic bladders, however, suggests an action at sites other than cytosolic carbonic anhydrase. Although active Na+ and Cl- reabsorption and tissue oxygen uptake are also decreased by furosemide, the rate of oxygen consumption uncoupled by 2,4-dinitrophenol is not diminished, indicating a primary inhibition of the various ion transport processes, not of metabolism. It is proposed that inhibition of transepithelial acid-base transport by furosemide in the turtle bladder includes inhibition of the acid-base pumps.

Chloride-induced increment in short-circuiting current of the turtle bladder. Effects of in-vivo acid-base state

Evidence for the participation of conductive and non-conductive (exchange) transmembrane anion pathways in the luminal acidification, alkalinization, and chloride-reabsorptive functions of the turtle bladder is provided from the pattern of Cl- -induced changes in transepithelial electrical parameters of isolated urinary bladders from three groups of donor turtles: control or post-absorptive turtles (those killed 5 days after feeding); acidotic turtles (NH4Cl-loaded); and alkalotic turtles (NaHCO3-loaded). The predominance of each of the three aforementioned transport functions as well as the response to Cl- -addition is altered by the in-vivo electrolyte balance of the turtle. In post-absorptive bladders, which are poised for acidification and Cl- reabsorption, the mucosal and serosal addition of Cl- to Na+-free, (HCO3- + CO2)-containing media increases the negative short-circuiting current (Isc). In acidotic bladders, which are poised for acidification but not Cl- reabsorption, mucosal Cl- addition has no effect on this Isc whereas serosal Cl- addition increases the negative Isc in a manner identical to that observed in the post-absorptive bladders. Alkalotic bladders do not possess an acidification function but instead are poised for Cl- reabsorption and cAMP-dependent electrogenic alkali secretion (positive Isc). In these bladders, serosal Cl- addition is without effect while mucosal Cl- addition produces transient changes in this positive Isc. It is found that these results can be replicated by a model of the turtle bladder in which transmembrane Cl- and HCO3- conductive and exchange paths mediate transepithelial acidification, alkalinization and Cl- reabsorption.

Localization of ionic pathways in the teleost opercular membrane by extracellular recording with a vibrating probe

We have adapted the vibrating probe extracellular recording technique to use on an epithelium under voltage clamp in an Ussing chamber. The vibrating probe allows very low drift measurements of current density immediately over the epithelial surface. These measurements allowed sites of electrogenic transport in the epithelium to be localized with a spatial resolution of 5 micrometers. The technique was applied to the opercular membrane of the teleost fish, the tilapia, Sarotherodon mossambicus. The mitochondrion-rich "chloride cells" were shown to be the only sites of electrogenic ion transport in this heterogeneous epithelium. Cell sampling experiments demonstrated variable negative short-circuit currents associated with nearly all of approximately 300 chloride cells examined, which appeared to account for all of the tissue short-circuit current. Current-voltage relations for individual cells were also measured. Conductance associated with chloride cells (i.e. cellular and junctional pathways) accounted for all but 0.5 mS/cm2 of the tissue conductance, with the balance apparently accounted for by leak pathways near the edge of the tissue. Current and conductance associated with other cell types was at least 50-fold smaller than for the chloride cell. Chloride-free solutions reduced chloride cell current and conductance by 98 and 95%, respectively.

Basic mechanisms of urinary acidification

This article has examined the process of urinary acidification from the perspective of events occurring at the cellular and single nephron level. Accordingly, the reabsorption of filtered HCO3- and the titration of urine buffers can be ascribed to the fundamental process of H+ secretion. The precise mechanism of H+ secretion by the tubule cells, the rate by which this occurs, and the factors regulating transport differ between nephron segments. Despite these differences, the cellular process of urinary acidification can be viewed as the extrusion of H+ against an electrochemical gradient across the luminal cell membrane and the movement of an HCO3- equivalent across the basolateral cell membrane. In the proximal tubule (convoluted and straight portions) approximately 90 per cent of the filtered load of HCO3- is reabsorbed. This occurs without the development of large lumen-to-blood pH gradients. The secretion of H+ across the luminal membrane occurs primarily via an electrically neutral Na-H exchange mechanism. Since it is the lumen-to-cell Na+ gradient which provides the energy, the secretion of H+ is a "secondary active" process dependent on the function of the Na-K-ATPase located in the basolateral cell membrane. During the elaboration of an acid urine, the distal nephron (distal convoluted tubule and collecting duct) reabsorbs that portion of the filtered HCO3- escaping proximal reabsorption, titrates luminal buffers, and lowers urine pH. The secretion of H+ occurs by a "primary active" mechanism, which involves the extrusion of H+ across the luminal cell membrane by an electrogenic H+ pump driven by the hydrolysis of ATP. The rate at which H+ is secreted depends on the electrochemical gradient for H+ across the luminal membrane. Thus, changes in both lumen pH and potential will effect H+ secretion, with low lumen pH inhibiting transport and large lumen-negative potentials stimulating transport. In some animals, depending on their homeostatic needs, secretion of HCO3- by the distal nephron can also occur. This process is localized to the distal convoluted tubule and the cortical collecting duct and appears to represent a transport system distinct from that responsible for H+ secretion.

Histochemical and biochemical studies of carbonic anhydrase activity in the opercular epithelium of the euryhaline teleost, Fundulus heteroclitus

Carbonic anhydrase (CAH) activity was biochemically measured and histochemically localized (at both the light and electron microscope levels) in isolated opercular membranes from teleost fish, Fundulus heteroclitus, adapted to freshwater (FW), seawater (SW), and double-strength seawater (2 x SW). The normal morphology of this membrane showed that its epithelial portion consisted of five cell types: (1) chloride cells, which have been previously implicated as responsible for the active chloride transport across the epithelium; (2) mucous cells; (3) pavement cells, which formed the major portion of the free epithelial surface; (4) supportive cells, which had an abundance of intermediate (10 nm)-type filaments suggesting a structural role for these cells; and (5) vesicular cells, which were characterized by various types of membrane-bound vesicles, including lysosomes, and numerous free ribosomes. Vesicular cells may be stem cells and/or endocrine cells. Hansson's histochemical method for CAH revealed cobalt sulfide reaction product confined to the following structures in fish from each environment: (1) chloride cells: throughout the cytoplasm and some nuclear staining; (2) mucous cells: throughout the cytoplasm, some nuclear staining, and some in mucous granules; (3) vesicular cells: confined to lysosomes, some of the vesicles, and nucleoli; (4) a small portion of the intracellular space between adjacent vesicular cells and supportive cells; and (5) supportive cells: in nucleoli and occasionally in larger membrane-bound lysosomelike structures. Acetazolamide (10(-5) M) and potassium cyanate (KCNO) (10(-1) M) in Hansson's incubation medium completely inhibited the formation of reaction product. Biochemical determination of CAH activity on vascularly perfused, isolated opercular membranes showed no statistically significant difference in enzyme activity between environmental groups. The following units of activity/mg opercular membrane protein were measured: FW: 0.63 +/- 0.02; SW: 0.43 +/- 0.08; 2 x SW: 0.64 +/- 0.09.

Electrogenic proton transport in epithelial membranes

Certain polar epithelial cells have strong transport capacities for protons and can be examined in vitro as part of an intact epithelial preparation. Recent studies in the isolated turtle bladder and other tight urinary epithelial indicate that the apical membranes of the carbonic anhydrase-containing cell population of these tissues contain an electrogenic proton pump which has the characteristics of a proton-translocating ATPase. The translocation of protons is tightly coupled to the energy of ATP hydrolysis. Since the pump translocates protons without coupling to the movement of other ions, it may be regarded as an "ideal" electrogenic pump. The apparent simplicity of the functional properties has led to extensive studies of the characteristics of this pump and of the cellular organization of the secondary acid-base flows in the turtle bladder. Over a rather wide range of electrochemical potential gradients, for protons (delta approximately microH) across the epithelium, the rate of H+ transport is nearly linear with delta approximately microH. The formalisms of equivalent circuit analysis and nonequilibrium thermodynamics have been useful in describing the behavior of the pump, but these approaches have obvious limitations. We have attempted to overcome some of these limitations by developing a more detailed set of assumptions about each of the transport step across the pump complex and to formulate a working model for proton transport in the turtle bladder than can account for several otherwise unexplained experimental results. The model suggests that the real pump is neither a simple electromotive force nor a constant current source. Depending on the conditions, it may behave as one or the other.

Exocytosis regulates urinary acidification in turtle bladder by rapid insertion of H+ pumps into the luminal membrane

Urinary acidification by the turtle bladder is due to a H+-ATPase that is located in the luminal membrane. The rate of H+ transport is stimulated by an increase in the ambient CO2. Using the fluorescent dye acridine orange, we showed that the mitochondria-rich cell of this equilibrium contains vesicles whose internal pH is acidic. We measured the pH of these vesicles by using endocytosed fluorescein isothiocyanate-labeled dextran and found it to be near 5.0. The pH increased after treatment with protonophores or metabolic inhibitors, suggesting that it was due to a H+ pump rather than to a Donnan effect. In bladders preloaded with fluorescent dextran, CO2 stimulated exocytosis and H+ transport measured simultaneously in the same bladder. The increase in the H+ current correlated well with the extent of exocytosis, and both were inhibited by pretreatment with colchicine. We conclude that the turtle bladder contains an intracellular reserve of vesicles containing H+ pumps and CO2 stimulates rapid fusion of these vesicles with the luminal membrane with consequent insertion of H+ pumps, thereby stimulating H+ secretion across the whole epithelium.