Protamine reversibly decreases paracellular cation permeability in Necturus gallbladder

Impedance Spectroscopy as a Tool for Monitoring Performance in 3D Models of Epithelial Tissues

In contrast to traditional 2D cell cultures, both 3D models and organ-on-a-chip devices allow the study of the physiological responses of human cells. These models reconstruct human tissues in conditions closely resembling the body. Translation of these techniques into practice is hindered by associated labor costs, a need which may be remedied by automation. Impedance spectroscopy (IS) is a promising, automation-compatible label-free technology allowing to carry out a wide range of measurements both in real-time and as endpoints. IS has been applied to both the barrier cultures and the 3D constructs. Here we provide an overview of the impedance-based analysis in different setups and discuss its utility for organ-on-a-chip devices. Most attractive features of impedance-based assays are their compatibility with high-throughput format and supports for the measurements in real time with high temporal resolution, which allow tracing of the kinetics. As of now, IS-based techniques are not free of limitations, including imperfect understanding of the parameters that have their effects on the impedance, especially in 3D cell models, and relatively high cost of the consumables. Moreover, as the theory of IS stems from electromagnetic theory and is quite complex, work on popularization and explanation of the method for experimental biologists is required. It is expected that overcoming these limitations will lead to eventual establishing IS based systems as a standard for automated management of cell-based experiments in both academic and industry environments.

Zinc strengthens the jejunal barrier by reversibly tightening the paracellular route

During the postweaning period, piglets are prone to gastrointestinal infections. The resulting impairment of intestinal barrier function may cause diarrhea associated with growth retardation or even death of piglets. Orally applied Zn is commonly used to prevent and treat diarrhea, but its mode of action still needs to be elucidated. To analyze the molecular mechanism whereby Zn acts on porcine intestinal barrier function, ex vivo studies on piglet jejunum and accompanying in vitro studies on a porcine jejunal epithelial cell line, IPEC-J2/PS, were performed with electrophysiological tools. Feeding pharmacological Zn doses exerted no significant electrophysiologically ascertainable short- and long-term effects on jejunal barrier function ex vivo. However, in IPEC-J2/PS, basolateral Zn was cytotoxic since its application caused a release of lactate dehydrogenase and an irreversible breakdown of the epithelial barrier. In contrast, apical Zn application caused an immediate increase in paracellular resistance and a decrease in permeability to the paracellular marker fluorescein, reflecting overall barrier strengthening in vitro. Apical effects were fully reversible upon washout. This indicates that Zn supplemented to feed was completely washed out during ex vivo jejunum preparation. We conclude that there is no evidence for long-term barrier effects through prophylactic Zn supplementation and that extracellular Zn acts acutely and reversibly from the apical side via tightening the paracellular route, thus counteracting leak-flux diarrhea.NEW & NOTEWORTHY Therapeutically administered Zn successfully treats diarrhea in veterinary and human medicine. Here we present data that Zn strengthens the porcine jejunal epithelial barrier by reversibly tightening the paracellular route for inorganic ions and small solutes. Acute or long-lasting Zn effects on transcellular transport (Cl^- secretion) were not detected. We therefore conclude that Zn is useful for acutely treating leak-flux diarrhea rather than secretory diarrhea. Suitability as prophylactic feed supplement, however, is questionable.

Physiological roles of claudins in kidney tubule paracellular transport

The paracellular pathways in renal tubular epithelia such as the proximal tubules, which reabsorb the largest fraction of filtered solutes and water and are leaky epithelia, are important routes for transepithelial transport of solutes and water. Movement occurs passively via an extracellular route through the tight junction between cells. The characteristics of paracellular transport vary among different nephron segments with leaky or tighter epithelia. Claudins expressed at tight junctions form pores and barriers for paracellular transport. Claudins are from a multigene family, comprising at least 27 members in mammals. Multiple claudins are expressed at tight junctions of individual nephron segments in a nephron segment-specific manner. Over the last decade, there have been advances in our understanding of the structure and functions of claudins. This paper is a review of our current knowledge of claudins, with special emphasis on their physiological roles in proximal tubule paracellular solute and water transport.

High-dose dietary zinc oxide mitigates infection with transmissible gastroenteritis virus in piglets

BACKGROUND

Zinc (Zn) supplementation has been shown to reduce the incidence of diarrhea and to protect animals from intestinal diseases, but the mechanisms of this protective effect against virus infection in vivo have not yet been elucidated. Transmissible gastroenteritis virus (TGEV) causes diarrhea in piglets with an age-dependent decrease of severity.

RESULTS

We used 60 weaned piglets that were divided into three groups to evaluate the effect of different Zn levels added to a conventional diet (50 mg Zn/kg diet, Znlow, control group). The other groups received the diet supplemented with ZnO at final concentrations of 150 mg Zn/kg diet (Znmed), or 2,500 mg/kg diet (Znhigh). Oral challenge infection with TGEV was performed when the pigs had been fed for 1 week with the respective diet. Half of the piglets of each group were sacrificed at day 1 and 18 after challenge infection. Fecal consistency was improved and body weights increased in the Znhigh group when compared to the other groups, but no direct effect of Zn concentrations in the diet on fecal TGEV shedding and mucosal immune responses was detectable. However, in the Znhigh group, we found a prevention of villus atrophy and decreased caspase-3-mediated apoptosis of jejunal epithelium. Furthermore, pigs receiving high Zn diet showed a down-regulation of interferon (IFN)-α, oligoadenylate synthetase (OAS), Zn transporter SLC39A4 (ZIP4), but up-regulation of metallothionein-1 (MT1), as well as the Zn transporters SLC30A1 (ZnT1) and SLC30A5 (ZnT5). In addition, forskolin-induced chloride secretion and epithelial resistance were controlled at a physiological level in the Znhigh but not the other groups. Finally, in the Znhigh group, we documented an earlier and higher systemic TGEV-specific serum antibody response.

CONCLUSIONS

These results suggest that high dietary Zn could provide enhanced protection in the intestinal tract and stimulate the systemic humoral immune response against TGEV infection.

Improved cell line IPEC-J2, characterized as a model for porcine jejunal epithelium

Cell lines matching the source epithelium are indispensable for investigating porcine intestinal transport and barrier properties on a subcellular or molecular level and furthermore help to reduce animal usage. The porcine jejunal cell line IPEC-J2 is established as an in vitro model for porcine infection studies but exhibits atypically high transepithelial resistances (TER) and only low active transport rates so that the effect of nutritional factors cannot be reliably investigated. This study aimed to properly remodel IPEC-J2 and then to re-characterize these cells regarding epithelial architecture, expression of barrier-relevant tight junction (TJ) proteins, adequate TER and transport function, and reaction to secretagogues. For this, IPEC-J2 monolayers were cultured on permeable supports, either under conventional (fetal bovine serum, FBS) or species-specific (porcine serum, PS) conditions. Porcine jejunal mucosa was analyzed for comparison. Main results were that under PS conditions (IPEC-J2/PS), compared to conventional FBS culture (IPEC-J2/FBS), the cell height increased 6-fold while the cell diameter was reduced by 50%. The apical cell membrane of IPEC-J2/PS exhibited typical microvilli. Most importantly, PS caused a one order of magnitude reduction of TER and of trans- and paracellular resistance, and a 2-fold increase in secretory response to forskolin when compared to FBS condition. TJ ultrastructure and appearance of TJ proteins changed dramatically in IPEC-J2/PS. Most parameters measured under PS conditions were much closer to those of typical pig jejunocytes than ever reported since the cell line’s initial establishment in 1989. In conclusion, IPEC-J2, if cultured under defined species-specific conditions, forms a suitable model for investigating porcine paracellular intestinal barrier function.

Discerning apical and basolateral properties of HT-29/B6 and IPEC-J2 cell layers by impedance spectroscopy, mathematical modeling and machine learning

Quantifying changes in partial resistances of epithelial barriers in vitro is a challenging and time-consuming task in physiology and pathophysiology. Here, we demonstrate that electrical properties of epithelial barriers can be estimated reliably by combining impedance spectroscopy measurements, mathematical modeling and machine learning algorithms. Conventional impedance spectroscopy is often used to estimate epithelial capacitance as well as epithelial and subepithelial resistance. Based on this, the more refined two-path impedance spectroscopy makes it possible to further distinguish transcellular and paracellular resistances. In a next step, transcellular properties may be further divided into their apical and basolateral components. The accuracy of these derived values, however, strongly depends on the accuracy of the initial estimates. To obtain adequate accuracy in estimating subepithelial and epithelial resistance, artificial neural networks were trained to estimate these parameters from model impedance spectra. Spectra that reflect behavior of either HT-29/B6 or IPEC-J2 cells as well as the data scatter intrinsic to the used experimental setup were created computationally. To prove the proposed approach, reliability of the estimations was assessed with both modeled and measured impedance spectra. Transcellular and paracellular resistances obtained by such neural network-enhanced two-path impedance spectroscopy are shown to be sufficiently reliable to derive the underlying apical and basolateral resistances and capacitances. As an exemplary perturbation of pathophysiological importance, the effect of forskolin on the apical resistance of HT-29/B6 cells was quantified.

Calcium inhibits paracellular sodium conductance through claudin-2 by competitive binding

Claudins form paracellular pores at the tight junction in epithelial cells. Profound depletion of extracellular calcium is well known to cause loosening of the tight junction with loss of transepithelial resistance. However, moderate variations in calcium concentrations within the physiological range can also regulate transepithelial permeability. To investigate the underlying molecular mechanisms, we studied the effects of calcium on the permeability of claudin-2, expressed in an inducible MDCK I cell line. We found that in the physiological range, calcium acts as a reversible inhibitor of the total conductance and Na(+) permeability of claudin-2, without causing changes in tight junction structure. The effect of calcium is enhanced at low Na(+) concentrations, consistent with a competitive effect. Furthermore, mutation of an intrapore negatively charged binding site, Asp-65, to asparagine partially abrogated the inhibitory effect of calcium. This suggests that calcium competes with Na(+) for binding to Asp-65. Other polyvalent cations had similar effects, including La(3+), which caused severe and irreversible inhibition of conductance. Brownian dynamics simulations demonstrated that such inhibition can be explained if Asp-65 has a relatively high charge density, thus favoring binding of Ca(2+) over that of Na(+), reducing Ca(2+) permeation by inhibiting its dissociation from this site, and decreasing Na(+) conductance through repulsive electrostatic interaction with Ca(2+). These findings may explain why hypercalcemia inhibits Na(+) reabsorption in the proximal tubule of the kidney.

Two-path impedance spectroscopy for measuring paracellular and transcellular epithelial resistance

Solutes are transported across epithelial cell layers via transcellular and paracellular pathways. The transcellular pathway leads across the apical and basolateral cell membrane, whereas the paracellular pathway is directed through the tight junction. Tight junction proteins (claudins, occludin, tricellulin) can not only form barriers but also paracellular channels that are--in concert with membrane channels and transporters--regulated in a wide range in health and disease states. Thus, it is desirable to determine para- and transcellular resistance (R(para), R(trans)) separately. This cannot be achieved by conventional transepithelial resistance (TER) measurements. We present an impedance spectroscopic approach that is optimized for differentiation between these two pathways. The method is based on a transepithelial impedance measurement in specialized Ussing chambers, combined with a Ca(2+)-dependent modulation of R(para) through EGTA and flux measurements of a nonradioactive paracellular marker, fluorescein. The prerequisites are a paracellular marker that varies in parallel to 1/R(para), an experimental regime that alters R(para) without affecting R(trans), and exact knowledge of the resistance of subepithelial components. The underlying prerequisites and the applicability as a routine method were verified on cell lines of different tightness including HT-29/B6 colon cells and Madin-Darby canine kidney tubule cells C7 and C11.

Function and regulation of claudins in the thick ascending limb of Henle

The thick ascending limb (TAL) of Henle mediates transcellular reabsorption of NaCl while generating a lumen-positive voltage that drives passive paracellular reabsorption of divalent cations. Disturbance of paracellular reabsorption leads to Ca(2+) and Mg(2+) wasting in patients with the rare inherited disorder of familial hypercalciuric hypomagnesemia with nephrocalcinosis (FHHNC). Recent work has shown that the claudin family of tight junction proteins form paracellular pores and determine the ion selectivity of paracellular permeability. Importantly, FHHNC has been found to be caused by mutations in two of these genes, claudin-16 and claudin-19, and mice with knockdown of claudin-16 reproduce many of the features of FHHNC. Here, we review the physiology of TAL ion transport, present the current view of the role and mechanism of claudins in determining paracellular permeability, and discuss the possible pathogenic mechanisms responsible for FHHNC.

Protamine-Induced Epithelial Barrier Disruption Involves Rearrangement of Cytoskeleton and Decreased Tight Junction-Associated Protein Expression in Cultured MDCK Strains

Natural and synthetic polycationic proteins, such as protamine, have been used to reproduce the tissue injury and changes in epithelial permeability caused by positively charged substances released by polymorphonuclear cells during inflammation. Protamine has diverse and often conflicting effects on epithelial permeability. The effects of this polycation on the distribution and expression of tight junction (TJ)-associated proteins have not yet been investigated. In this work, we examined the influence of protamine on paracellular barrier function and TJ structure using two strains of the epithelial Madin-Darby canine kidney (MDCK) cell line that differed in their TJ properties ("tight" TJ-strain I and "leaky" TJ-strain II). Protamine induced concentration-, time- and strain-dependent alterations in transepithelial electrical resistance (Rt) only when applied to apical or apical+basolateral monolayer surfaces, indicating a polarity of action. In MDCK II cells, protamine (50 microg/ml) caused a significant increase in Rt that returned to control values after 2 h. However, the treatment of this MDCK strain with a higher concentration of protamine (250 microg/ml) significantly decreased the Rt after 30 min. In contrast, treated MDCK I monolayers showed a significant decrease in Rt after apical treatment with protamine at both concentrations. The protamine-induced decrease in Rt was paralleled by an increase in the phenol red basal-to-apical flux in both MDCK strains, suggesting disruption of the paracellular barrier. Marked changes in cytoskeletal F-actin distribution/polymerization and a significant reduction in the junctional expression of the tight junctional proteins occludin and claudin-1 but subtle alterations in ZO-1 were observed following protamine-elicited paracellular barrier disruption. In conclusion, protamine induces alterations in the epithelial barrier function of MDCK monolayers that may involve the cytoskeleton and TJ-associated proteins. The various actions of protamine on epithelial function may reflect different degrees of interaction of protamine with the plasma membrane and different intracellular processes triggered by this polycation.

Intestinal microcirculation and gut permeability in acute pancreatitis: early changes and therapeutic implications

Translocation of bacteria from the intestine causes local and systemic infection in severe acute pancreatitis. Increased intestinal permeability is considered a promoter of bacterial translocation. The mechanism leading to increased gut permeability may involve impaired intestinal capillary blood flow. The aim of this study was to evaluate and correlate early changes in capillary blood flow and permeability of the colon in acute rodent pancreatitis of graded severity. Edematous pancreatitis was induced by intravenous cerulein; necrotizing pancreatitis by intravenous cerulein and intraductal glycodeoxycholic acid. Six hours after induction of pancreatitis, the permeability of the ascending colon was assessed by the Ussing chamber technique; capillary perfusion of the pancreas and colon (mucosal and subserosal) was determined by intravital microscopy. In mild pancreatitis, pancreatic capillary perfusion remained unchanged (2.13 c 0.06 vs. 1.98 +/-0.04 nl x min(-1) x cap(-1) [control]; P = NS), whereas mucosal (1.59 +/-0.03 vs. 2.28 +/-0.03 nl x min(-1) x cap((-1))[control]; P <0.01) and subserosal (2.47 +/-0.04 vs. 3.74 +/-0.05 nl x min(-1) x cap((-1))[control]; P <0.01) colonic capillary blood flow was significantly reduced. Severe pancreatitis was associated with a marked reduction in both pancreatic (1.06 +/-0.03 vs. 1.98 +/-0.04 nl x min(-1) x cap(-1) [control]; P <0. 01) and colonic (mucosal: 0.59 +/-0.01 vs. 2.28 +/-0.03 nl x min(-1) x cap((-1))[control], P <0.01; subserosal: 1.96 +/-0.05 vs. 3.74 +/-0.05 nl x min(-1) x cap(-1) [control], P <0.01) capillary perfusion. Colon permeability tended to increase with the severity of the disease (control: 147 +/-19 nmol x thr(-1) x cm(-2); mild pancreatitis: 158 +/-23 nmol x hr(-1) x cm(-2); severe pancreatitis: 181 +/-33 nmol x hr(-1) x cm(-2); P = NS). Impairment of colonic capillary perfusion correlates with the severity of pancreatitis. A decrease in capillary blood flow in the colon, even in mild pancreatitis not associated with significant protease activation and acinar cell necrosis or impairment of pancreatic capillary perfusion, suggests that colonic microcirculation is especially susceptible to inflammatory injury. There was no significant change in intestinal permeability in the early stage of pancreatitis, suggesting a window of opportunity for therapeutic interventions to prevent the later-observed increase in gut permeability, which could result in improved intestinal microcirculation.

Impedance analysis for the determination of epithelial and subepithelial resistance in intestinal tissues

The barrier function of the intestinal wall plays a key role in body homeostasis and defense against noxious agents. Conventional Ussing chamber techniques determine the overall transmural resistance but do not differentiate epithelial and subepithelial tissues. The barrier function, however, resides in the epithelial cell layer only. Transmural impedance analysis can solve this problem, if adequate models are applied. We show that: (i) epithelial and subepithelial impedances are additive, (ii) the epithelium proper can be represented by a very general electrical model, which demonstrates short-circuiting at high frequencies (due to cell membrane capacitances), and (iii) the reactance of subepithelial tissue can be described phenomenologically. Using an empirical expression for description of the subepithelial impedance, the present method allows the determination of the epithelial and the subepithelial resistance. This was exemplified in rat ileum, which defied adequate impedance analysis so far. Of the transmural DC resistance of 61 +/- 5 omega.cm2 (n = 8) the subepithelial contribution was 28 +/- 2 omega.cm2 and the epithelial resistance was 33 +/- 4 omega.cm2.

Ussing chamber for high-frequency transmural impedance analysis of epithelial tissues

An Ussing chamber was designed for impedance analysis of epithelial tissue and optimized for the use of high-frequency alternating current stimuli. Shielded voltage electrodes, located axially within the electric field of the Ussing chamber, minimized the reactive properties of the set-up. By vectorial subtraction, the small reactive contribution of the optimized Ussing chamber was completely compensated for. This method allowed for transmural impedance measurements in a frequency range of 1-65 kHz. For the first time, Nyquist plots of cultured intestinal cell monolayers (HT-29/B6) are presented. The epithelial monolayers in different stages of confluence showed the impedance locus as a semicircle, with the high frequency end close to the origin. These epithelial monolayers could be modeled by a simple RC-parallel circuit without a series resistance.

Paracellular transport of water and carbohydrates during intestinal perfusion of protamine in the rat

With these experiments, the authors' purpose was to determine whether the intestinal perfusion of protamine would successfully block paracellular transport without causing significant change in cardiovascular function. In anesthetized (50 mg x kg-1 sodium pentobarbital) rats (n=12), heart rate and mean arterial blood pressure were measured during perfusion (0.5 mL x min-1) of a carbohydrate-electrolyte solution through the small intestine. The carbohydrate-electrolyte solution contained 150 mM glucose, 150 mM fructose, 10 mM lactulose, 17 mEq sodium, 3 mEq potassium, and either 0.0, 0.1, 1.0, or 10 mg x mL-1 protamine. Osmolality of the 4 solutions ranged from 363 +/- 2 to 365 +/- 3 mOsm x kg-1. Core temperature was maintained at 37 degrees C in an environmental chamber. Heart rate and mean arterial blood pressure were constant during all intestinal perfusions. Forty-one percent of the perfused lactulose was absorbed. Absorption of glucose, fructose, and lactulose was significantly inhibited by 0.1 mg x mL-1 protamine, while water absorption was decreased 41 percent by 1.0 mg x mL-1 protamine. Water and lactulose absorption fell 75% with protamine, and glucose and fructose absorption fell 50%. Lactulose and fructose absorption did not decrease further when protamine dose rose to 10 mg x mL-1. These results indicate that 1) perfusion of protamine into the small intestine in doses that significantly affect intestinal transport does not significantly affect heart rate and mean arterial blood pressure; and 2) if the primary effect of protamine is to block paracellular movement of water and solute, the greater protamine inhibition of water and lactulose absorption is consistent with a greater paracellular transport of water and lactulose than for glucose and fructose.

Epithelial barrier and ion transport in coeliac sprue: electrical measurements on intestinal aspiration biopsy specimens

Epithelial barrier function and ion transport was studied in coeliac sprue using a miniaturised Ussing device for measurements on diagnostic aspiration biopsy specimens from the jejunum of untreated or gluten free nourished sprue patients, or from healthy controls. Pure epithelial resistance (Re) indicating epithelial barrier function was determined by transmural alternating current impedance analysis. It was reduced by 56% in acute sprue mean (SEM) (9 (1) omega.cm2) compared with controls (20(2) omega.cm2). In gluten free nourished sprue patients Re was only partly recovered (15 (1) omega.cm2). Subepithelial resistance (Rsub) was also changed from 28 (1) omega.cm2- in control to 17 (1) omega.cm2 in acute sprue because of the change in mucosal architecture, but was unchanged in gluten free nourished sprue patients (29 (4) omega.cm2). In acute sprue, unidirectional Na+ and Cl- fluxes were increased in both directions as a consequence of the decreased resistance. However, short circuit current (ISC) as well as Na+ and Cl- net fluxes were not significantly different from control. Subsequently, the electrogenic Cl- secretory system was investigated. After maximal stimulation with theophylline and prostaglandin E1, a Cl(-)-dependent increase in ISC was obtained in the sprue mucosa and control jejunum. It showed saturation characteristics and was blockable by serosal bumetanide. When compared with control, neither Km nor Vmax of this electrogenic Cl- secretion was significantly changed in coeliac sprue. In conclusion, a miniaturised Ussing device was used for transport measurements on intestinal biopsy specimens. In acute coeliac disease, the epithelial barrier of the jejunum was seriously disturbed. The active electrogenic Cl- secretory transport system was present in the sprue mucosa, but was not activated in the Ussing chamber in vitro when compared with control jejunum.

Cholangiocytes express the aquaporin CHIP and transport water via a channel-mediated mechanism

Cholangiocytes line the intrahepatic bile ducts and regulate salt and water secretion during bile formation, but the mechanism(s) regulating ductal water movement remains obscure. A water-selective channel, the aquaporin CHIP, was recently described in several epithelia, so we tested the hypothesis that osmotic water movement by cholangiocytes is mediated by CHIP. Isolated rodent cholangiocytes showed a rapid increase in volume in the presence of hypotonic extracellular buffers; the ratio of osmotic to diffusional permeability coefficients was > 10. The osmotically induced increase in cholangiocyte volume was inversely proportional to buffer osmolality, independent of temperature, and reversibly blocked by HgCl2. Also, the luminal area of isolated, enclosed bile duct units increased after exposure to hypotonic buffer and was reversibly inhibited by HgCl2. RNase protection assays, anti-CHIP immunoblots, and immunocytochemistry confirmed that CHIP transcript and protein were present in isolated cholangiocytes but not in hepatocytes. These results demonstrate that (i) isolated cholangiocytes and intact, polarized bile duct units manifest rapid, mercury-sensitive increases in cell size and luminal area, respectively, in response to osmotic gradients and (ii) isolated cholangiocytes express aquaporin CHIP at both the mRNA and the protein level. The data implicate aquaporin water channels in the transcellular movement of water across cholangiocytes lining intrahepatic bile ducts and provide a plausible molecular explanation for ductal water secretion.

Effect of acute Yersinia enterocolitica infection on intestinal barrier function in the mouse

BACKGROUND

Yersinia enterocolitica is an important cause of diarrhea, but little is known about the underlying mechanisms. We therefore studied the impact of acute Y. enterocolitica infection on intestinal barrier function in a mouse model.

METHODS

For this purpose CD-1 mice were infected with Y. enterocolitica (serotype 08; 6 x 10(7) viable bacteria), and alternating current impedance analysis was performed on days 1, 2, 3, 5, and 8 after infection.

RESULTS

The infection resulted in a decrease in epithelial resistance from 18.0 +/- 0.9 omega.cm2 (controls) to 12.1 +/- 0.5 omega.cm2 (day 1, p < 0.001), from which the animals recovered by day 5. To locate this loss in barrier function, the horizontal distribution of local conductances was measured by voltage scanning, yielding two results. First, conductance was homogeneously distributed across the chamber area, excluding erosions or ulcers among the gross surface area and favoring tight junction opening as the source of barrier dysfunction. Second, the conductance of villus tips was compared with that of the intervillus region (consisting of lateral villus walls plus crypts). On day 1 the former was increased by 74% and the latter by 18%. Then, two other mechanisms of diarrhea were tested, namely malabsorption and secretion. First, the increase in ISC after the addition of 3-O-methylglucose, representing Na(+)-glucose cotransport, was shown not to be impaired. Second, bumetanide-inhibitable ISC, representing electrogenic Cl- secretion, also did not differ between controls and infected animals.

CONCLUSIONS

Our data show that epithelial barrier dysfunction plays a role in Y. enterocolitica infection, while Na(+)-glucose cotransport and electrogenic Cl- secretion are unaltered.

Polycation-induced enhancement of epithelial paracellular permeability is independent of tight junctional characteristics

The nature of polycation-induced change in transepithelial permeability was investigated in strains I (tight) and II (leaky) MDCK epithelial monolayers. Apical exposure to poly(L-lysine) (PLL, mol. wt. (MW) approximately 20,000) induced a dose-dependent increase in transepithelial conductance (GT) in both strains which correlated with increasing transepithelial flux of extracellular markers (thiourea/inulin) indicating that PLL enhanced paracellular permeability in these epithelia. Coincident with the increase in GT, PLL also induced an inward short circuit current (Isc) which was associated with the early phase of the increase in GT and may be responsible for part of it. Morphological studies showed that immunofluorescent staining of the tight junction protein, ZO-1, was abolished following PLL exposure. In addition, F-actin staining in monolayers challenged with PLL demonstrated breaks in the zonulae occludentes at the apical surface. PLL had similar effects on monolayers of T84 and HCT-8 human intestinal cells indicating that polycation action may be general for a range of epithelial types. We conclude that epithelial exposure to polycations results in opening of the paracellular route by mechanisms which are independent of tight junction characteristics.

Ion transport in the experimental short bowel syndrome of the rat

The adaptational changes of epithelial ion transport in the short bowel syndrome were studied. Ileal remnants of rats were investigated 8 weeks after 70% proximal small intestinal resection. Pure epithelial resistance measured by impedance analysis decreased from 27 +/- 1 to 21 +/- 1 omega.cm2, and polyethylene glycol 4000 fluxes increased from 2.5 +/- 0.3 to 3.6 +/- 0.3 nmol.h-1.cm-2, indicating increased permeability of the short bowel. Unidirectional flux measurements in control ileum showed absorptive net fluxes of Na+ and Cl- that were assigned to electroneutral NaCl absorption and a short-circuit current that was accounted for by the residual flux (HCO3- secretion). Neither NaCl absorption nor HCO3- secretion were altered in the short bowel. Also, electrogenic Cl- secretion, defined after maximal stimulation by theophylline and prostaglandin E1 was not changed in the short bowel. In contrast, electrogenic Na+/glucose cotransport increased in Vmax from 2.0 +/- 0.3 in controls to 5.0 +/- 1.0 mumol.h-1.cm-2 in the short bowel. Tight junction structure was studied by freeze-fracture electron microscopy. The number of horizontal strands was unchanged, whereas tight junction depth was slightly increased in the short bowel. Microvillus area of short bowels was increased by 20% in villus regions. Under the light microscope, villus height was increased by 30%. In conclusion, the short bowel mucosa undergoes adaptive responses to reduced overall absorptive area by increasing glucose-dependent electrogenic Na+ absorption to 250%, which is partly caused by increased villus and microvillus surface area. Electrogenic Cl- and HCO3- secretion and electroneutral NaCl absorption remained unchanged. The decreased epithelial resistance is caused by mucosal surface amplification.

Uncoupled basal sodium absorption and chloride secretion in prairie dog (Cynomys ludovicianus) gallbladder

1. Prairie dog gallbladders mounted in a Ussing-type chamber and bathed with symmetrical Ringer's solutions exhibited a transepithelial resistance (Rt) of 51 +/- 5 omega cm2, a lumen negative potential difference (Vms) of 11.5 +/- 0.7 mV and a short-circuit current (Isc) of 6.9 +/- 0.3 microEq/hr/cm2. 2. Radioisotopic ion flux experiments revealed that the basal Isc of 6.9 +/- 0.3 microEq/hr/cm2 was mostly accounted for by net Na+ absorption of 3.2 +/- 0.5 microEq/hr/cm2 and net Cl- secretion of 2.9 +/- 0.3 microEq/hr/cm2. 3. In HCO3- free Ringer's, net Na+ flux was virtually abolished, net Cl- flux decreased by 50% and Isc was reduced by 77%. 4. 10(-3) M mucosal amiloride and DIDS reduced Isc by 28 and 24%, respectively. 5. Mucosal NaCl diffusion potentials indicated that the paracellular pathway was cation selective. 6. Thin section electron micrographs showed a single cell population in this epithelium suggesting that net Na+ absorption and Cl- secretion may emerge from the same cells. 7. We conclude that prairie dog gallbladder epithelium is an electrogenic tissue and, in contrast to gallbladders of most other species, simultaneously but independently absorbs Na+ and secretes Cl-.

Transepithelial resistance of ciliary epithelial cells in culture: functional modification by protamine and extracellular calcium

1. Bovine pigmented and human non-pigmented ciliary epithelial cells were cultured on porous filter supports to obtain measurements of transepithelial electrical parameters. 2. The non-pigmented cells showed maximal transepithelial resistance of 15-30 omega cm2 from the third to seventh day in culture. 3. The pigmented ciliary cells reached maximal resistances of 9-20 omega cm2 after the fourth day in culture. 4. The transepithelial resistances of the cultured epithelia were functionally increased by protamine. This effect could be reversed by heparin. 5. We conclude that the range of resistances in cultured ciliary epithelial cells is the same as in whole ciliary preparations. Thus, cultured ciliary epithelial cells can be used for studies on transepithelial transport.

Tight junction regulation during impaired ion transport in blind loops of rat jejunum

Epithelial cell tight junction structure in self-filling blind loops of rat jejunum, a model for blind loop syndrome in humans, was analyzed morphometrically along the crypt-villus axis. In control jejunum, the number of strands and junctional depth, including meshwork depth, decreased from crypt to villus tip. In the blind loop, aberrant strands appeared below the meshwork, particularly in crypt cells. Consequently, total junctional depth was greater than in controls. Furthermore, strand number and junctional meshwork depth were increased in blind loops at the villus tip. It is that site along the crypt-villus axis which showed the most shallow junction in control jejunum. This structural change is paralleled by a three-fold increase in epithelial resistance as previously measured by alternating current impedance analysis. Relative Na over Cl permeability (PNa:Cl) was obtained from dilution potential measurements. PNa:Cl was 1.50:1 in control jejunum and 1.35:1 in the blind loop (n.s.). Considering the cation selectivity of the tight junction, the increase in epithelial resistance in blind loops cannot be attributed to a collapse of the lateral intercellular space but is due to changes in tight junctional permeability resulting from structural alteration. The blind loop syndrome represents a further example of diminished epithelial ion transport and concomitant decrease in tight junction permeability, thus supporting the general concept of regulation of the tight junction in response to active transport activity.

pH dependence of protamine action on apical membrane permeability in Necturus gallbladder epithelium

Protamine reversibly decreases cation permeability and alters the structure of Necturus gallbladder tight junctions. Conflicting results, however, have been published whether or not it also affects apical cell membrane permeability. We investigated this issue more systematically by measuring voltage (psi mc) and fractional resistance (fRa) of the apical membrane at varying concentrations of protamine, K+, and H+ in the bathing solution. At pH 7.6 and [K+] 2.5 mM, (Poler, M.S. and Reuss, L. (1987) Am. J. Physiol. 253, C662) 6 microM protamine caused psi mc to depolarize from -58 to -51 mV and fRa to decrease from 0.74 to 0.67. If we increased pH to 8.1 these effects were even more pronounced. At [K+] 2.5 mM, but not 4.5 mM, psi mc transiently hyperpolarized for about 5 min after adding protamine. Most importantly, if [K+] was 4.5 mM and pH was adjusted to 7.1 (Bentzel et al. (1987) J. Membr. Biol. 95, 9) no significant changes of psi mc and fRa occurred. In any case, at a supramaximal concentration of 200 microM, protamine did not further increase the paracellular response but produced decreasing psi mc and fRa. We conclude that 6 microM protamine decreases K+ conductance of the apical membrane, if it is already tuned high by high pH. At low control K+ conductance as observed at lower pH, protamine action is restricted to the paracellular pathway. Thus, conflicting results were due to different experimental conditions. At a solution pH of 7.1, 6 microM protamine fulfills criteria of a selective tool for reversibly altering structure and function of the tight junction in Necturus gallbladder.

Protamine alters apical membrane K+ and Cl- permeability in gallbladder epithelium

Protamine addition to the solution bathing the mucosal side of Necturus gallbladder epithelium (25-100 mg/l) caused depolarization of both cell membranes, a mucosa-negative change in transepithelial voltage, an increase in the apical membrane resistance (Ra) followed by a decrease, and a monotonic increase in transepithelial resistance (Rt). In protamine (25 mg/l), the change in apical membrane voltage elicited by elevating mucosal solution [K+] from 2.5 to 92.5 mM was reduced from 66 +/-2 to 38 +/- 5 mV (P less than 0.001). The K+-induced fall in Ra was also reduced in protamine. These effects could also be elicited by elevating mucosal solution [K+] simultaneously with the addition of protamine and by transient addition of protamine during exposure to the high K+ medium. The effect of protamine on the electrodiffusive Cl- permeability of the apical membrane (PCl) was studied both in control and forskolin-treated tissues. In the absence of forskolin, the hyperpolarization of Vmc produced by lowering mucosal [Cl-] to 10 mM was reversed to a small depolarization; in forskolin, the initial depolarization produced by lowering [Cl-] was significantly increased. Finally, exposure to protamine in the absence of forskolin produced an initial fall in intracellular Cl- activity. Our results indicate that protamine decreases apical membrane K+ permeability and increases apical membrane PCl. The time course of the effects of protamine suggests the possibility of an initial effect on surface potential, followed by secondary actions mediated by intracellular events.

Impaired intestinal sodium and chloride transport in the blind loop syndrome of the rat

Self-filling blind loops of rat jejunum were used as a model for the blind loop syndrome in humans. Electrical resistance, short circuit current, and unidirectional sodium and chloride fluxes were measured using the Ussing technique. Whereas net fluxes for sodium and chloride did not differ significantly from zero in the blind loop or in the control, unidirectional fluxes of either direction were decreased and electrical resistance was increased, indicating an increase in the tightness of the intestinal wall. Measurements of alternating current impedance and micropuncture experiments revealed that this was due to an increase in epithelial resistance from 9 +/- 1 omega X cm2 (n = 15, results of both methods) to 27 +/- 4 omega X cm2 (n = 15) and in subepithelial resistance from 40 +/- 2 omega X cm2 (n = 15) to 76 +/- 7 omega X cm2 (n = 15). As the ratio of epithelial to subepithelial resistance was similar in the blind loop and in the control, lower transport rates in the blind loop are indicative of impaired epithelial transport function. Subsequently, two different transport systems were characterized. First, the 3-o-methyl-glucose-induced, phlorizin-reversible increase in short circuit current, representing glucose-coupled sodium absorption, showed a 77% decrease in maximum velocity in the blind loop and no change in Km. Second, the chloride-induced, bumetanide-reversible increase in short circuit current in tissues stimulated simultaneously by prostaglandin E1 and theophylline, representing rheogenic chloride secretion, also showed a decrease in maximum velocity (of 83%) and no change in Km. A morphometric analysis revealed that the crypt surface area increased by 100% in the blind loop, whereas the villous surface area was not significantly different between blind loops and controls. We conclude that the jejunal self-filling blind loop is characterized by impaired active ion transport processes and an increase in epithelial and subepithelial resistance.

Protamine alters structure and conductance of Necturus gallbladder tight junctions without major electrical effects on the apical cell membrane

Protamine is a naturally occurring basic protein (pI; 9.7 to 12.0). We have recently reported that protamine dissolved in the mucosal bath (2 to 20 microM), induces about a twofold increase in transepithelial resistance in Necturus gallbladder within 10 min. Conductance decreased concomitantly with cation selectivity. In this leaky epithelium, where greater than 90% of an applied current passes between cells, an increment in resistance of this magnitude suggests a paracellular action a priori. To confirm this, ionic conductance across the apical cell membrane was studied with microelectrodes. Protamine increased transepithelial resistance without changing apical cell membrane voltage or fractional membrane resistance. Variation in extracellular K concentration (6 to 50 mM) caused changes in apical membrane voltage not different from control. To determine if protamine-induced resistance changes were associated with structural alteration of tight junctions, gallbladders were fixed in situ at peak response and analyzed by freeze-fracture electron microscopy. According to a morphometrical analysis, the tight junctional intramembranous domain expands vertically due to incorporation of new strands (fibrils) into the main compact fibrillar meshwork. Since morphologic changes are complete within 10 min, strands are probably recycled into and out of the tight junctional membrane domain possibly by the cytoskeleton either from cytoplasmic vesicles or from intramembranous precursors. Regulation of tight junctional permeability by protamine and other perturbations may constitute a common mechanism by which leaky epithelia regulate transport, and protamine, in concentrations employed in this study, seems reasonably specific for the tight junction.

Adaptation of the jejunal mucosa in the experimental blind loop syndrome: changes in paracellular conductance and tight junction structure

Self-filling blind loops of rat jejunum exhibit hyperregenerative transformation of the mucosa. We used this experimental model to characterise mechanisms, which may occur under similar conditions in man (stagnant loop syndrome). Epithelial and subepithelial resistance were measured in the Ussing-chamber by voltage divider ratio measurements after positioning a microelectrode between epithelium and subepithelial tissue layers. In the blind loop, epithelial resistance increased from 8 +/- 1 to 23 +/- 1 omega cm2 and subepithelial resistance from 39 +/- 4 to 86 +/- 8 omega cm2 as compared with control jejunum. The increase in the subepithelial resistance was paralleled anatomically by an increase in the thickness of the subepithelial tissue layers from 63 +/- 4 microns to 177 +/- 19 microns. Ultrastructural analysis of the tight junction area by freeze fracture electron microscopy revealed an increase in the total junctional 'depth' in the crypts from 243 +/- 9 nm in control jejunum to 396 +/- 17 nm in the blind loop, while the number of horizontally oriented 'strands' remained unchanged. Villus tight junctions did not differ between blind loop and control. We interpret the alterations in the self-filling blind loop as an adaptive response of the epithelium which reduces backleakage of already absorbed electrolytes across the tight junction into the intestinal lumen. This mechanism is suitable to support the intestine in maintaining body electrolyte and water contents during cellular electrolyte malabsorption.

Epithelial and subepithelial resistance of rat large intestine: segmental differences, effect of stripping, time course, and action of aldosterone

Epithelial and subepithelial electrical resistances of rat large intestine were measured by means of a 4-electrode AC impedance technique in three segments, colon ascendens, colon descendens and rectum. Epithelial resistance of colon ascendens and colon descendens was about 35 omega X cm2 and not different between these two segments. It was, however, about 3 times higher in rectum (99 omega X cm2). This finding is in accord with our previous observation of about 3-fold higher net fluxes of ions and water in colon ascendens and colon descendens than in rectum. It confirms the concept of a main functional difference between the terminal part of the large intestine (rectum) and the more proximal segments (colon). The acutely (within hours) varied level of aldosterone by keeping the rats for 7 h in anaesthesia caused in the rectum a more than 10-fold increase in short circuit current (Isc) and transepithelial voltage but no significant decrease in resistance. Similarly, the decline in Isc, as regularly observed in the early phase of in vitro measurements on partially stripped large intestine, was paralleled by voltage changes but not by changes in resistance. We conclude that the wide range of resistance values published so far was caused to a great extent by including various portions of colon or rectum. By comparing intact (not stripped) and partially stripped preparations (muscularis propria removed) of the rectum it was shown that partial stripping did not alter the epithelial resistance but reduced the subepithelial resistance in this segment from 26 to 8 omega X cm2, or by 68%.(ABSTRACT TRUNCATED AT 250 WORDS)

Epithelial and subepithelial contributions to transmural electrical resistance of intact rat jejunum, in vitro

Epithelial and subepithelial resistance of rat jejunum was measured in vitro by two independent methods. (i) Transepithelial AC impedance data were interpreted in terms of a simple parallel RpCp element (representing the epithelial cell layer) in series with an ohmic resistor RS (representing the subepithelial layers). (ii) In separate experiments, the tip of a microelectrode was positioned between epithelium and subepithelial layers and the respective resistances were obtained from DC-pulse voltage divider ratios between both structures. The total tissue resistance as measured in conventional Ussing-chamber experiments (49 +/- 4 Ohm X cm2, mean of both methods) was formed to 81 +/- 6% (40 +/- 3 Ohm X cm2) by subepithelial layers and to only 19 +/- 3% (9 +/- 1 Ohm X cm2) by the epithelial cell line. We conclude that rat jejunum is more conductive than assumed so far. In in vitro flux studies on intact jejunal sheets a pronounced back-diffusion of absorbed substances will lead to an underestimation of the true net transport capacity of this structure. This error averages about fivefold and will be found likewise in conventional short-circuit measurements.