Membrane transport parameters in frog corneal epithelium measured using impedance analysis techniques

Summary Active Cl^– transport in bullfrog corneal epithelium was studied using transepithelial impendance analysis methods, and direct-current (DC) measurements of membrane voltages and resistance ratios. The technique allows the estimation of the apical and basolateral membrane conductances, and the paracellular conductance, and does not rely on the use of membrane conductance-altering agents to obtain these measurements as was requisite in earlier DC equivalent-circuit analysis studies. In addition, the analysis results in estimates of the apical and basolateral membrane capacitances, and allows resolution of the paracellular conductance into properties of the tight junctions and lateral spaces. Membrane capacitances (proportional to areas) were used to estimate the specific conductances of the apical and basolateral membranes, as well as to evaluate coupling between the cell layers. We confirm results obtained from earlier studies: (1) apical membrane conductance is proportional to the rate of active Cl^– transport and is, highly Cl^– selective; (2) intracellular Cl^– activity is above electrochemical equilibrium, thereby providing a net driving force for apical membrane Cl^– exit; (3) the paracellular conductance is comparable to the transcellular conductance. We also found that: (1) the paracellular conductance is composed of the series combination of the junctional conductance and a nonnegligible lateral space resistance; (2) a small K⁺ conductance reported in the apical membrane may result from Cl^– channels possessing a finite permeability to K⁺; (3) the basolateral membrane areas is 36 times greater than the apical membrane area which is consistent with the notion of electrical coupling between the five to six cell layers of the epithelium; (4) the specific conductance of the basolateral membrane is many times lower than that of the apical membrane; (5) the net transport of Cl^– is modulated primarily by changes in the conductance of the apical membrane and not by changes in the net electrochemical gradient resulting from opposite changes in the electrical and chemical gradients; (6) the conductance of the basolateral membrane does not change with transport which implies that the net driving force for K⁺ exit increases with transport, possibly due to an increase in the intracellular K⁺ activity.     

Regulation of the paracellular Na+ and Cl- conductances by the NaCl-generated osmotic gradient in a manner dependent on the direction of osmotic gradients

In the present study, we investigated the effect of osmolality on the paracellular ion conductance (Gp) composed of the Na⁺ conductance (G_Na) and the Cl⁻ conductance (G_Cl). An osmotic gradient generated by NaCl with relatively apical hypertonicity (NaCl-absorption-direction) induced a large increase in the G_Na associated with a small increase in the G_Cl, whereas an osmotic gradient generated by NaCl with relatively basolateral hypertonicity (NaCl-secretion-direction) induced small increases in the G_Na and the G_Cl. These increases in the Gp caused by NaCl-generated osmotic gradients were diminished by the application of sucrose canceling the NaCl-generated osmotic gradient. The osmotic gradient generated by basolateral application of sucrose without any NaCl gradients had little effects on the Gp. However, this basolateral application of sucrose produced a precondition drastically quickening the time course of the action of the NaCl-generated osmotic gradient on the Gp. Further, we found that application of the basolateral hypotonicity generated by reduction of NaCl concentration shifted the localization of claudin-1 to the apical from the basolateral side. These results indicate that the osmotic gradient regulates the paracellular ion conductive pathway of tight junctions via a mechanism dependent on the direction of NaCl gradients associated with a shift of claudin-1 localization to the apical side in renal A6 epithelial cells.     

A microfluidic bioreactor with integrated transepithelial electrical resistance (TEER) measurement electrodes for evaluation of renal epithelial cells

We have developed a bilayer microfluidic system with integrated transepithelial electrical resistance (TEER) measurement electrodes to evaluate kidney epithelial cells under physiologically relevant fluid flow conditions. The bioreactor consists of apical and basolateral fluidic chambers connected via a transparent microporous membrane. The top chamber contains microfluidic channels to perfuse the apical surface of the cells. The bottom chamber acts as a reservoir for transport across the cell layer and provides support for the membrane. TEER electrodes were integrated into the device to monitor cell growth and evaluate cell–cell tight junction integrity. Immunofluorescence staining was performed within the microchannels for ZO‐1 tight junction protein and acetylated α‐tubulin (primary cilia) using human renal epithelial cells (HREC) and MDCK cells. HREC were stained for cytoskeletal F‐actin and exhibited disassembly of cytosolic F‐actin stress fibers when exposed to shear stress. TEER was monitored over time under normal culture conditions and after disruption of the tight junctions using low Ca²⁺ medium. The transport rate of a fluorescently labeled tracer molecule (FITC‐inulin) was measured before and after Ca²⁺ switch and a decrease in TEER corresponded with a large increase in paracellular inulin transport. This bioreactor design provides an instrumented platform with physiologically meaningful flow conditions to study various epithelial cell transport processes. Biotechnol. Bioeng. 2010;107:707–716. © 2010 Wiley Periodicals, Inc.     

NaCl flux between apical and basolateral side recruits claudin-1 to tight junction strands and regulates paracellular transport

In multicellular organisms, epithelia separate and divide the internal environment maintaining appropriate conditions in each compartment. To maintain homeostasis in these compartments, claudins, major cell adhesion molecules in tight junctions (TJs), regulate movements of several substances through the paracellular pathway (barrier function). In this study, we investigated effects of the flux of several substances between apical and basolateral side on paracellular transport and TJ protein localization. NaCl flux from apical to basolateral side increased paracellular conductance (Gp) and recruited claudin-1 from lateral cell membrane to the apical end with the colocalization with occludin, one of the TJ proteins concentrated at TJ strands. Oppositely-directed flux of sucrose against NaCl flux inhibited these reactions and same directional flux of sucrose with NaCl enhanced the increase of Gp, whereas 10-kDa dextran inhibited these reactions regardless of the side of administration. Our present findings indicated that TJ protein localization and barrier function are regulated depending on the environmental differences between apical and basolateral side.     

The Detailed Localization Pattern of Na+/K+/2Cl? Cotransporter Type 2 and Its Related Ion Transport System in the Rat Endolymphatic Sac

The endolymphatic sac (ES) is a part of the membranous labyrinth. ES is believed to perform endolymph absorption, which is dependent on several ion transporters, including Na⁺/K⁺/2Cl⁻ cotransporter type 2 (NKCC-2) and Na⁺/K⁺-ATPase. NKCC-2 is typically recognized as a kidney-specific ion transporter expressed in the apical membrane of the absorptive epithelium. NKCC-2 expression has been confirmed only in the rat and human ES other than the kidney, but the detailed localization features of NKCC-2 have not been investigated in the ES. Thus, we evaluated the specific site expressing NKCC-2 by immunohistochemical assessment. NKCC-2 expression was most frequently seen in the intermediate portion of the ES, where NKCC-2 is believed to play an important role in endolymph absorption. In addition, NKCC-2 expression was also observed on the apical membranes of ES epithelial cells, and Na⁺/K⁺-ATPase coexpression was observed on the basolateral membranes of ES epithelial cells. These results suggest that NKCC-2 performs an important role in endolymph absorption and that NKCC-2 in apical membranes and Na⁺/K⁺-ATPase in basolateral membranes work coordinately in the ES in a manner similar to that in renal tubules. (J Histochem Cytochem 58:759–763, 2010)     

Chloride transport activation by plasma osmolarity during rapid adaptation to high salinity of Fundulus heteroclitus

Transition from low salt water to sea water of the euryhaline fish, Fundulus heteroclitus, involves a rapid signal that induces salt secretion by the gill chloride cells. An increase of 65 mOsm in plasma osmolarity was found during the transition. The isolated, chloridecell-rich opercular epithelium of sea-water-adapted Fundulus exposed to 50 mOsm mannitol on the basolateral side showed a 100% increase in chloride secretion, which was inhibited by bumetanide 10^–4 m and 10^–4 m DPC (N-Phenylanthranilic acid). No effect of these drugs was found on apical side exposure. A Na⁺/H⁺ exchanger, demonstrated by NH₄Cl exposure, was inhibited by amiloride and its analogues and stimulated by IBMX, phorbol esters, and epithelial growth factor (EGF). Inhibition of the Na⁺/H⁺ exchanger blocks the chloride secretion increase due to basolateral hypertonicity. A Cl^–/HCO ₃ ^– exchanger was also found in the chloride cells, inhibited by 10^–4 m DIDS but not involved in the hyperosmotic response. Ca²⁺ concentration in the medium was critical for the stimulation of Cl^– secretion to occur. Chloride cell volume shrinks in response to hypertonicity of the basolateral side in sea-water-adapted operculi; no effect was found on the apical side. Freshwater-adapted fish chloride cells show increased water permeability of the apical side. It is concluded that the rapid signal for adaptation to higher salinities is an increased tonicity of the plasma that induces chloride cell shrinkage, increased chloride secretion with activation of the Na⁺K⁺2Cl^– cotransporter, the Na⁺/H⁺ exchanger and opening of Cl^– channels.The work was supported by the National Institutes of Health, Research Grant EYO1340 to J.A.Z. Part of this research was performed while Dr. Zadunaisky was a Scholar In Residence at the Fogarty International Center of The National Institutes of Health in Bethesda, Maryland. Ms. Dawn Roberts was a fellow of the Grass Foundation and Pew Foundation during this work. Grants from the National Science Foundation and the National Institutes of Health to the Mount Desert Island Biological Laboratory also provided assistance for this research.     

Effects of Hydrostatic Pressure on Carcinogenic Properties of Epithelia

The relationship between chronic inflammation and cancer is well known. The inflammation increases the permeability of blood vessels and consequently elevates pressure in the interstitial tissues. However, there have been only a few reports on the effects of hydrostatic pressure on cultured cells, and the relationship between elevated hydrostatic pressure and cell properties related to malignant tumors is less well understood. Therefore, we investigated the effects of hydrostatic pressure on the cultured epithelial cells seeded on permeable filters. Surprisingly, hydrostatic pressure from basal to apical side induced epithelial stratification in Madin-Darby canine kidney (MDCK) I and Caco-2 cells, and cavities with microvilli and tight junctions around their surfaces were formed within the multi-layered epithelia. The hydrostatic pressure gradient also promoted cell proliferation, suppressed cell apoptosis, and increased transepithelial ion permeability. The inhibition of protein kinase A (PKA) promoted epithelial stratification by the hydrostatic pressure whereas the activation of PKA led to suppressed epithelial stratification. These results indicate the role of the hydrostatic pressure gradient in the regulation of various epithelial cell functions. The findings in this study may provide clues for the development of a novel strategy for the treatment of the carcinoma.     

Immunocytochemical characterization of two types of microvillar cells in rodent olfactory epithelium

Microvillar cells (MCs) have been identified in the olfactory epithelium of various mammalian species from rodents to humans. Studies on properties and functions of MCs to date have yielded partially controversial results, supporting alternatively an epithelial or a neuronal nature of these cells. In the present study, single and double immunolabeling investigations were carried out using antibodies against cytoskeletal and integral membrane proteins in order to further characterize MCs in rat and mouse olfactory epithelium. Application of antibodies against ankyrin (ANK), a protein that links integral membrane proteins to the submembrane cytoskeleton, led to intense labeling of the basolateral membranes of numerous cells with characteristic MC morphology. ANK-immunoreactive (ir) cells bore an apical tuft of -actin-ir microvilli, were filled with cytokeratin 18 (CK18)-ir filamentous network, and extended a basal process that appeared to end above the basal membrane. Immunoreactions for villin, an actin-crosslinking protein particularly prominently expressed in brush cells in the gastrointestinal and respiratory tract epithelia, and for the -subunit of sodium-potassium ATPase (Na⁺, K⁺-ATPase), revealed that ANK-ir MCs fall into two subpopulations. The less frequent type I MCs displayed villin immunoreactivity in their apical microvilli and underneath the basolateral membranes; the more numerous type II MCs were negative for villin but possessed intense basolateral immunoreactivity for Na⁺, K⁺-ATPase. Strong reactivity for the epithelial-type integral membrane protein of adherens junctions, E-Cadherin, was localized in basolateral membranes of both types of MCs. Our results support an epithelial nature of ANK-ir MCs in rat and mouse olfactory epithelium. Type I MCs strongly resemble brush cells in their immunocytochemical characteristics, namely, their ANK reactivity, CK18 reactivity, and villin reactivity. The intense Na⁺, K⁺-ATPase reactivity of type II MCs implicates these cells in transport processes.     

Regulation of paracellular Na and Cl conductances by hydrostatic pressure

The effect of hydrostatic pressure on the paracellular ion conductance (Gp) composed of the Na⁺ conductance (G_Na) and the Cl⁻ conductance (G_Cl) has been Investigated. Gp, G_Na and G_Cl were time-dependently increased after applying an osmotic gradient generated by NaCl with basolateral hypotonicity. Hydrostatic pressure (1-4 cm H₂O) applied from the basolateral side enhanced the osmotic gradient-induced increase in Gp, G_Na and G_Cl in a magnitude-dependent manner, while the hydrostatic pressure applied from the apical side diminished the osmotic gradient-induced increase in Gp, G_Na and G_Cl. How the hydrostatic pressure influences Gp, G_Na and G_Cl under an isosmotic condition was also investigated. Gp, G_Na and G_Cl were stably constant under a condition with basolateral application of sucrose canceling the NaCl-generated osmotic gradient (an isotonic condition). Even under this stable condition, the basolaterally applied hydrostatic pressure drastically elevated Gp, G_Na and G_Cl, while apically applied hydrostatic pressure had little effect on Gp, G_Na or G_Cl. Taken together, these observations suggest that certain factors controlled by the basolateral osmolality and the basolaterally applied hydrostatic pressure mainly regulate the Gp, G_Na and G_Cl.     

Structural and functional membrane polarity in cultured monolayers of MDCK cells

Summary MDCK cells form monolayers which have many of the properties usually found in transporting epithelia. The present article is devoted to the study of the structural and functional polarization of MDCK cells, which is one of the central features of transporting epithelia. The results show: (i) that MDCK monolayers transport 2.6 mol hr^–1 cm^–2 of sodium in the apical to basolateral direction; (ii) the passive flux of this ion is relatively large (20.3 mole hr^–1 cm^–2), which is a characteristic of leaky epithelia; (iii) a large fraction of the penetration of sodium into the cells proceeds through an amiloride-sensitive channel, and the exit is operated mainly by a ouabain-sensitive pump; (iv) the net transport of sodium from the apical to the basolateral side agrees with the asymmetric labeling of the pumps with³H-ouabain; (v) this asymmetric labeling agrees, in turn, with a higher concentration of intramembrane particles (IMPs) in freeze-fracture replicas of the basolateral side of the plasma membrane; (vi) the structural polarization of confluent MDCK cells is also revealed by the location of microvilli, occluding junctions, and pinocytotic vesicles; and (vii) the presence of a continuous ring formed by actin microfilaments visualized by immunofluorescence under the lateral aspect of the plasma membrane that may be related to the distribution of the occluding junctions, which act as barriers separating apical from basolateral membrane components.     

Activation of Apical K<Superscript>+</Superscript> Conductances by Muscarinic Receptor Stimulation in Rat Distal Colon: Fast and Slow Components

In the epithelium of rat distal colon the acetylcholine analogue carbachol induces a transient increase of short-circuit current (I_sc) via stimulation of cellular K⁺ conductances. Inhibition of the turnover of inositol-1,4,5-trisphosphate (IP₃) by LiCl significantly reduced both the amplitude and the duration of this response. When the apical membrane was permeabilized with nystatin, LiCl nearly abolished the carbachol-induced activation of basolateral K⁺ conductances. In contrast, in epithelia, in which the basolateral membrane was bypassed by a basolateral depolarization, carbachol induced a biphasic increase in the K⁺ current across the apical membrane consisting of an early component carried by charybdotoxin- and tetraethylammonium-sensitive K⁺ channels followed by a sustained plateau carried by channels insensitive against these blockers. Only the latter was sensitive against LiCl or inhibition of protein kinases. In contrast, the stimulation of the early apical K⁺ conductance by carbachol proved to be resistant against inhibition of phospholipase C or protein kinases. However, apical dichlorobenzamil, an inhibitor of Na⁺/Ca²⁺ exchangers, or a Ca²⁺-free mucosal buffer solution significantly reduced the early component of the carbachol-induced apical K⁺ current. The presence of an apically localized Na⁺/Ca²⁺-exchanger was proven immunohistochemically. Taken together these experiments reveal divergent regulatory mechanisms for the stimulation of apical Ca²⁺-dependent K⁺ channels in this secretory epithelium, part of them being activated by an inflow of Ca²⁺ across the apical membrane.

Effects of antidiuretic hormone on cellular conductive pathways in mouse medullary thick ascending limbs of Henle: I. ADH increases transcellular conductance pathways

Summary This paper reports experiments designed to assess the relations between net salt absorption and transcellular routes for ion conductance in single mouse medullary thick ascending limbs of Henle microperfusedin vitro. The experimental data indicate that ADH significantly increased the transepithelial electrical conductance, and that this conductance increase could be rationalized in terms of transcellular conductance changes. A minimal estimate (G _c ^min ) of the transcellular conductance, estimated from Ba⁺⁺ blockade of apical membrane K⁺ channels, indicated thatG _c ^min was approximately 30–40% of the measured transepithelial conductance. In apical membranes, K⁺ was the major conductive species; and ADH increased the magnitude of a Ba⁺⁺-sensitive K⁺ conductance under conditions where net Cl^– absorption was nearly abolished. In basolateral membranes, ADH increased the magnitude of a Cl^– conductance; this ADH-dependent increase in basal Cl^– conductance depended on a simultaneous hormone-dependent increase in the rate of net Cl^– absorption. Cl^– removal from luminal solutions had no detectable effect onG _e , and net Cl^– absorption was reduced at luminal K⁺ concentrations less than 5mm; thus apical Cl^– entry may have been a Na⁺,K⁺,2Cl^– cotransport process having a negligible conductance. The net rate of K⁺ secretion was approximately 10% of the net rate of Cl^– absorption, while the chemical rate of net Cl^– absorption was virtually equal to the equivalent short-circuit current. Thus net Cl^– absorption was rheogenic; and approximately half of net Na⁺ absorption could be rationalized in terms of dissipative flux through the paracellular pathway. These findings, coupled with the observation that K⁺ was the principal conductive species in apical plasma membranes, support the view that the majority of K⁺ efflux from cell to lumen through the Ba⁺⁺-sensitive apical K⁺ conductance pathway was recycled into cells by Na⁺,K⁺,2Cl^– cotransport.     

Leucine transport by the larval midgut of the parasitoid Aphidius ervi (Hymenoptera)

The larval midgut of the hymenopteran parasitoid Aphidius ervi accomplishes a large transport of nutrients from the lumen to the haemocoel, providing most of the organic molecules necessary for rapid insect development. l-amino acids in general, and leucine in particular, are efficiently accumulated in the larval body. We show here that the intact midgut of early 3rd instar larvae incubated in vitro can take up [³H]l-leucine from the basolateral side of the epithelium by transporters insensitive to the presence of monovalent cations. When the midgut is opened and the apical membrane of the absorbing epithelial cells is exposed to the medium containing radiolabelled leucine, a sodium-dependent uptake of the amino acid becomes apparent, disclosing the presence of a symport mechanism. Inhibition experiments of leucine uptake by a 100-fold excess of different amino acids, selected according to the properties of their side chain, revealed that this apical sodium-dependent mechanism is a broad spectrum transport system with a specialization for the absorption of aliphatic amino acids, that can also transfer glutamine and proline, but not phenylalanine, lysine and arginine. Altogether the experimental results obtained with intact- and open-gut preparations suggest that leucine transport across the basolateral membrane is mediated by both an uniporter and an obligatory amino acid exchange mechanism.     

CFTR–SLC26 transporter interactions in epithelia

Transport mechanisms that mediate the movements of anions must be coordinated tightly in order to respond appropriately to physiological stimuli. This process is of paramount importance in the function of diverse epithelial tissues of the body, such as, for example, the exocrine pancreatic duct and the airway epithelia. Disruption of any of the finely tuned components underlying the transport of anions such as Cl⁻, HCO₃ ⁻, SCN⁻, and I⁻ may contribute to a plethora of disease conditions. In many anion-secreting epithelia, the interactions between the cystic fibrosis transmembrane conductance regulator (CFTR) and solute carrier family 26 (SLC26) transporters determine the final exit of anions across the apical membrane and into the luminal compartment. The molecular identification of CFTR and many SLC26 members has enabled the acquisition of progressively more detailed structural information about these transport molecules. Studies employing a vast array of increasingly sophisticated approaches have culminated in a current working model which places these key players within an interactive complex, thereby setting the stage for future work.     

Functional analysis of tight junctions

Epithelial and endothelial cells are joined to each other via a set of intercellular junctions that differ in their morphological appearance, composition, and function. The tight junction or zonula occludens is the intercellular junction that regulates diffusion between cells and therefore allows endothelia and epithelia to form cellular barriers that separate compartments of different composition. This intercellular gate formed by tight junctions is not only highly regulated but is size- and ion-selective and, hence, represents a semipermeable diffusion barrier. In epithelia, tight junctions form a morphological and functional border between the apical and basolateral cell surface domains. They directly contribute to the maintenance of cell surface polarity by forming a fence that prevents apical/basolateral diffusion of lipids in the outer leaflet of the plasma membrane. Here we describe a set of assays that allow the analysis of tight junctions to determine their integrity and functional state.     

Effects of anions on cellular volume and transepithelial Na+ transport across toad urinary bladder

Summary The effects of complete substitution of gluconate for mucosal and/or serosal medium Cl^– on transepithelial Na⁺ transport have been studied using toad urinary bladder. With mucosal gluconate, transepithelial potential difference (V _T) decreased rapidly, transepithelial resistance (R _T) increased, and calculated short-circuit current (I _sc) decreased. CalculatedE _Na was unaffected, indicating that the inhibition of Na⁺ transport was a consequence of a decreased apical membrane Na⁺ conductance. This conclusion was supported by the finding that a higher amiloride concentration was required to inhibit the residual transport. With serosal gluconateV _T decreased,R _T increased andI _sc fell to a new steady-state value following an initial and variable transient increase in transport. Epithelial cells were shrunken markedly as judged histologically. CalculatedE _Na fell substantially (from 130 to 68 mV on average). Ba²⁺ (3mm) reduced calculatedE _Na in Cl^– Ringer's but not in gluconate Ringer's. With replacement of serosal Cl^– by acetate, transepithelial transport was stimulated, the decrease in cellular volume was prevented andE _Na did not fall. Replacement of serosal isosmotic Cl^– medium by a hypo-osmotic gluconate medium (one-half normal) also prevented cell shrinkage and did not result in inhibition of Na⁺ transport. Thus the inhibition of Na⁺ transport can be correlated with changes in cell volume rather than with the change in Cl^– per se. Nystatin virtually abolished the resistance of the apical plasma membrane as judged by measurement of tissue capacitance. With K⁺ gluconate mucosa, Na⁺ gluconate serosa, calculated basolateral membrane resistance was much greater, estimated basolateral emf was much lower, and the Na⁺/K⁺ basolateral permeability ratio was much higher than with acetate media. It is concluded the decrease in cellular volume associated with substitution of serosal gluconate for Cl^– results in a loss of highly specific Ba²⁺-sensitive K⁺ conductance channels from the basolateral plasma membrane. It is possible that the number of Na⁺ pump sites in this membrane is also decreased.     

Immunolocalization of Na/K–ATPase and Na/K/2Cl cotransporter in the tubular epithelia of sea snake salt glands

The sublingual salt gland is the primary site of salt excretion in sea snakes; however, little is known about the mechanisms mediating ion excretion. Na⁺/K⁺–ATPase (NKA) and Na⁺/K⁺/2Cl⁻ cotransporter (NKCC) are two proteins known to regulate membrane potential and drive salt secretion in most vertebrate secretory cells. We hypothesized that NKA and NKCC would localize to the basolateral membranes of the principal cells comprising the tubular epithelia of sea snake salt glands. Although there is evidence of NKA activity in salt glands from several species of sea snake, the localization of NKA and NKCC and other potential ion transporters remains unstudied. Using histology and immunohistochemistry, we localized NKA and NKCC in salt glands from three species of laticaudine sea snake: Laticauda semifasciata, L. laticaudata, and L. colubrina. Antibody specificity was confirmed using Western blots. The compound tubular glands of all three species were found to be composed of serous secretory epithelia, and NKA and NKCC were abundant in the basolateral membranes. These results are consistent with the morphology of secretory epithelia found in the rectal salt glands of marine elasmobranchs, the nasal glands of marine birds and the gills of teleost fishes, suggesting a similar function in regulating ion secretion.     

Apical sodium entry in split frog skin: Current-voltage relationship

Summary Apical Na⁺ entry into frog skin epithelium is widely presumed to be electrodiffusive in nature, as for other tight epithelia. However, in contrast to rabbit descending colon andNecturus urinary bladder, the constant field equation has been reported to fit the apical sodium current (N _Na)-membrane potential (^mc) relationship over only a narrow range of apical membrane potentials or to be inapplicable altogether. We have re-examined this issue by impaling split frog skins across the basolateral membrane and examining the current-voltage relationships at extremely early endpoints in time after initiating pulses of constant transepithelial voltage. In this study, the rapid transient responses in ^mc were completed within 0.5 to 3.5 msec. Using endpoints to 1 to 25 msec, the Goldman equation provided excellent fits of the data over large ranges in apical potential of 300 to 420 mV, from approximately –200 to about +145 mV (cell relative to mucosa). Split skins were also studied when superfused with high serosal K⁺ in order to determine whether theI _Na-^mc relationship could be generated purely by transepithelial measurements. Under these conditions, the basolateral membrane potential was found to be –10±3 mV (cell relative to serosa, mean±se), the basolateral fractional resistance was greater than zero, and the transepithelial current was markedly and reversibly reduced. For these reasons, use of high serosal K⁺ is considered inadvisable for determining theI _Na-^mc relationship, at least in those tissues (such as frog skin) where more direct measurements are technically feasible. Analysis of theI _Na-^mc relationships under baseline conditions provided estimates of intracellular Na⁺ concentration and of apical Na⁺ permeability of 9 to 14mm and of 3 × 10^–7 cm · sec^–1, respectively, in reasonable agreement with estimates obtained by different techniques.     

Vaccinia virus entry, exit, and interaction with differentiated human airway epithelia

Variola virus, the causative agent of smallpox, enters and exits the host via the respiratory route. To better understand the pathogenesis of poxvirus infection and its interaction with respiratory epithelia, we used vaccinia virus and examined its interaction with primary cultures of well-differentiated human airway epithelia. We found that vaccinia virus preferentially infected the epithelia through the basolateral membrane and released viral progeny across the apical membrane. Despite infection and virus production, epithelia retained tight junctions, transepithelial electrical conductance, and a steep transepithelial concentration gradient of virus, indicating integrity of the epithelial barrier. In fact, during the first four days of infection, epithelial height and cell number increased. These morphological changes and maintenance of epithelial integrity required vaccinia virus growth factor, which was released basolaterally, where it activated epidermal growth factor 1 receptors. These data suggest a complex interaction between the virus and differentiated airway epithelia; the virus preferentially enters the cells basolaterally, exits apically, and maintains epithelial integrity by stimulating growth factor receptors.     

Electrophysiological studies of forskolin-induced changes in ion transport in the human colon carcinoma cell line HT-29 cl.19A: Lack of evidence for a cAMP-activated basolateral K+ conductance

Summary Forskolin (i.e, cAMP)-modulation of ion transport pathways in filter-grown monolayers of the Cl^–-secreting subclone (19A) of the human colon carcinoma cell line HT29 was studied by combined Ussing chamber and microimpalement experiments.Changes in electrophysiological parameters provoked by serosal addition of 10^–5 m forskolin included: (i) a sustained increase in the transepithelial potential difference (3.9±0.4 mV). (ii) a transient decrease in transepithelial resistance with 26±3 · cm² from a mean value of 138±13 · cm² before forskolin addition, (iii) a depolarization of the cell membrane potential by 24±1 mV from a resting value of –50±1 mV and (iv) a decrease in the fractional resistance of the apical membrane from 0.80±0.02 to 0.22±0.01. Both, the changes in cell potential and the fractional resistance, persisted for at least 10 min and were dependent on the presence of Cl^– in the medium. Subsequent addition of bumetanide (10^–4 m), an inhibitor of Na/K/2Cl cotransport, reduced the transepithelial potential, induced a repolarization of the cell potential and provoked a small increase of the transepithelial resistance and fractional apical resistance. Serosal Ba²⁺ (1mm), a known inhibitor of basolateral K⁺ conductance, strongly reduced the electrical effects of forskolin. No evidence was found for a forskolin (cAMP)-induced modulation of basolateral K⁺ conductance.The results suggest that forskolin-induced Cl^– secretion in the HT-29 cl.19A colonic cell line results mainly from a cAMP-provoked increase in the Cl^– conductance of the apical membrane but does not affect K⁺ or Cl^– conductance pathways at the basolateral pole of the cell. The sustained potential changes indicate that the capacity of the basolateral transport mechanism for Cl^– and the basal Ba²⁺-sensitive K⁺ conductance are sufficiently large to maintain the Cl^– efflux across the apical membrane. Furthermore, evidence is presented for an anomalous inhibitory action of the putative Cl^– channel blockers NPPB and DPC on basolateral conductance rather than apical Cl^– conductance.