Short-chain fatty acids enhance diffusional ca transport in the epithelium of the rat cecum and colon

We examined the effect of short-chain fatty acids (SCFAs) on Ca absorption from the large intestine in rats in vitro. An Ussing-type chamber technique was used to determine the net transport of Ca from the luminal side to the basolateral side of isolated epithelium in cecum and colon preparations. The concentration of Ca in the serosal and mucosal Tris buffer solution was 1.25 mM and 10 mM, respectively. Both solutions were warmed at 37 degrees C and bubbled with 95% O2 and 5% CO2. During and after the incubation period (30 min or 60 min), the Ca concentration in the serosal medium was determined and the net transepithelial Ca transport was evaluated. The addition of 80 mM acetic acid, 40 mM propionic acid and 10 mM butyric acid to the mucosal medium increased net Ca absorption (about 300%) in the cecum and colon. An individual application of acetic, propionic or butyric acid (0.01 to 100 mM) to the mucosal medium also increased net Ca absorption at doses of 10 mM and /or 100 mM in the cecum and colon. An increase in solute concentration in the mucosal medium by addition of glycerol or PGE400, or a decrease in pH (7.0-3.0) by addition of HCl did not affect transepithelial Ca transport. We concluded that SCFAs affect the epithelial tissue and promote Ca absorption from the large intestine in vitro. The enhancement of Ca transport induced by SCFAs might be involved in the paracellular transport mechanism.     

Difructose anhydride III and sodium caprate activate paracellular transport via different intracellular events in Caco-2 cells

A nondigestible disaccharide, difructose anhydride (DFA) III, is known to activate calcium transport via tight junctions (TJs); however, the characteristics of and mechanisms for the increase in paracellular transport induced by DFAIII have not been clarified. We compared the effect of DFAIII with that of sodium caprate (C10), a well-known enhancer of TJ permeability, on the changes in TJ proteins, transport of paracellular markers, and effects of nine cellular signaling blockers using Caco-2 monolayers. The addition of DFAIII (0-100mmol/L) and C10 (0-10mmol/L) to the apical medium of the Caco-2 monolayers dose-dependently decreased transepithelial electrical resistance (TER), which is an indicator of TJ permeability. The reduction with C10 was much faster than that with DFAIII. Transport of the paracellular markers of various molecular weights (182-43,200) was elevated by the addition of 100mmol/L DFAIII and 10mmol/L C10. The transport rates were much in the presence of C10 than of DFAIII, while the reduction in TER by two treatments was similar (from 1000 to 300Omega cm(2)). Treatment with DFAIII and C10 changed the distribution of actin filament and claudin-1, but not occludin, junctional adhesion molecule-1, or zonula occludens-1; however, alterations in the patterns of the TJ proteins differed according to treatment. An inhibitor of myosin light chain kinase and a chelator of intracellular calcium ion ([Ca(2+)](i)) attenuated the TER reduction by C10, but not by DFAIII. These data demonstrate that the increase in TJ permeability induced by DFAIII results from the alterations to actin and claudin-1 via [Ca(2+)](i)-independent mechanisms.     

Effect of Bacterial Contamination on Cecal Size and Cecal Contents of Gnotobiotic Rodents

In the present investigation the effect of various bacterial contaminations of gnotobiotic mice and rats on cecal size is presented. Of the species tested, Bacteroides oralis and Fusobacterium nucleatum did not establish in germ-free mice. Streptococcus mutans, Clostridium difficile, a Neisseria strain and two recent cecal isolates established, but failed to exert an effect upon the cecum of mice. A group K streptococcus and B. fragilis increased the cecal size apparently by increasing the levels of water-soluble protein, peptides, and carbohydrates in the cecal contents. Mixed ileal bacteria decreased the cecal size by preventing accumulation of soluble proteins and carbohydrates in the cecum. A Peptococcus strain caused a reduction by lowering the levels of insoluble material in the cecum. When this strain was combined with two Clostridium isolates and introduced into gnotobiotic rats, 50 to 65% cecal reduction was observed. This polycontamination did not decrease the per cent water of the cecal contents but caused lower levels of both soluble and insoluble material to accumulate in the cecum. No net nitrogen absorption from the distal small intestine occurred in either the germ-free or polycontaminated rats.     

Impact of difructose anhydride III,raffinose, and fructooligosaccharides on energy intake,gut hormones,and cecal fermentation in rats fed a high-fat and high-sucrose diet

We investigated the effects of dietary supplementation of difructose anhydride III (DFA III), raffinose (Raf), and fructooligosaccharides (FOS) on diet-induced obesity development. Male rats were fed normal or high-fat and high-sucrose (HFS) diet, with or without supplementing (3%) DFA III, Raf, or FOS, for 8 or 5 weeks. Supplementing DFA III to the HFS diet decreased energy intake compared to the non-supplemented HFS diet. Accordingly, body weight gain and fat accumulation reduced in DFA III-fed rats. Cecal acetate production and plasma glucagon-like peptide-1 (GLP-1) and peptide-YY (PYY) were elevated in DFA III-fed rats, while Raf and FOS partially affected these parameters. These results demonstrate that DFA III has suppressive effect on excessive energy intake driven by the palatable obesogenic diet, possibly due to combined effects of increased anorexigenic factors such as cecal acetate production and GLP-1/PYY secretion.     

Effects of ingestion of difructose anhydride III (DFA III) and the DFA III-assimilating bacterium Ruminococcus productus on rat intestine

We have isolated a difructose anhydride III (DFA III)-assimilating bacterium, Ruminococcus productus AHU1760, from human. After an acclimation period of 1 week, male Sprague-Dawley rats (5 weeks old) were divided into four groups (control diet, R. productus diet, DFA III diet, and R. productus + DFA III diet; n = 8) and fed the assigned test diets for 2 weeks. The viable count of administered R. productus was 4.9 x 10(7) CFU/d in R. productus-fed rats and 4.7 x 10(7) CFU/d in R. productus + DFA III-fed rats. Survival in cecal content of this strain was confirmed by randomly amplified polymorphic DNA. The ratio of secondary bile acids in feces in R. productus + DFA III-fed rats decreased the same as that in rats fed only DFA III. The viable count of lactobacilli and bifidobacteria, known as beneficial bacteria, increased more in R. productus + DFA III-fed rats than in control or R. productus-fed rats. A combination of R. productus and DFA III might improve the balance of intestinal microbiota to a healthier condition.     

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.     

Lecture: New light on the role of claudins in the kidney

The physiology of paracellular permeation of ions and solutes in the kidney is pivotally important but poorly understood. Claudins are the key components of the paracellular pathway. Defects in claudin function result in a broad range of renal diseases, including hypomagnesemia, hypercalciuria and nephrolithiasis. This review describes recent findings on the physiological function of claudins underlying paracellular transport mechanisms with a focus on renal Ca ( 2+) handling. We have uncovered a molecular mechanism underlying paracellular Ca ( 2+) transport in the thick ascending limb of Henle (TAL) that involves the functional interplay of three important claudin genes: claudin-14, -16 and -19, all of which are associated with human kidney diseases with hypercalciuria, nephrolithiasis and bone mineral loss. The Ca ( 2+) sensing receptor (CaSR) signaling in the kidney has long been a mystery. By analyzing small non-coding RNA molecules in the kidney, we have uncovered a novel microRNA based signaling pathway downstream of CaSR that directly regulates claudin-14 gene expression and establishes the claudin-14 molecule as a key regulator for renal Ca ( 2+) homeostasis. The molecular cascade of CaSR-microRNAs-claudins forms a regulatory loop to maintain proper Ca ( 2+) homeostasis in the kidney.     

Absorption of 3-oxy-methyl-D-glucose by chicken cecum and jejunum in vivo

Jejunal and cecal 3-oxy-methyl-D-glucose (3-OMG) absorption was studied in 4- to 8-week-old chickens by an in vivo perfusion technique (perfusion rate 1.5 ml/min). Total and phloridzin-insensitive 3-OMG absorption was tested for lumenal substrate concentrations ranging from 1.25 to 20 mmol/l. The estimated apparent Michaelis constants in jejunum and cecum were 5.1 and 4.0 mmol/l (Lineweaver-Burk method) and 3.2 and 3.1 mmol/l (visual inspection method), respectively. Vmax were similar in both segments with either method, about 0.3 mumol/cm2 X 5 min. Passive permeability coefficients were the same in both regions (about 45 l/cm2 X 5 min X 10(3)). The transport properties of the cecal epithelium in vivo suggest a role of these intestinal segments in the absorption of nutrients originated from digestive processes.     

The effect of conjugated linoleic acid on transepithelial calcium transport and mediators of paracellular permeability in human intestinal-like Caco-2 cells

Conjugated linoleic acid (CLA) increases paracellular permeability across human intestinal-like Caco-2 cell monolayers, which transport Ca predominantly by the transcellular route. In vivo, however, paracellular Ca transport is the predominant route of Ca transport. Therefore, the objective of this study was to investigate the effect of CLA on transepithelial Ca transport in Caco-2 cells transporting Ca predominantly by the paracellular route. Cells were seeded onto permeable transport membranes and allowed to differentiate, over 14 d, into intestinal-like cell monolayers. Monolayers (n=9/treatment) were exposed to 0 (control) or 80 microM- 18:2, -cis-9, trans-11 CLA or -trans-10, cis-12 CLA for 14 d prior to Ca transport studies. Overall transepithelial Ca transport as well as transcellular and parcellular Ca transport was significantly increased (P<0.001) by exposure of Caco-2 cells to both isomers of CLA, an effect which appeared to be related to altered localization of zona occludens 1 (a tight junction protein).     

Effects of DFA IV in rats: calcium absorption and metabolism of DFA IV by intestinal microorganisms.

Di-D-fructose-2,6':6,2'-dianhydride (DFA IV) is a disaccharide consisting of two fructose residues that can be prepared from levan by levan fructotransferase from Arthrobacter nicotinovorans GS-9, and it can be expected to have novel physiological functions from its unique structure. In this study, the effects of DFA IV on calcium absorption and the metabolism of DFA IV by intestinal microorganisms were studied in rats to examine the physiological functions of DFA IV. The apparent calcium absorption in rats fed with DFA IV was significantly higher than that in the control rats, and it seems that calcium absorption had almost been completed at the end of the small intestine. DFA IV also increased the calcium absorption in in vitro experiments, using everted jejunal and ileal sacs, and this result supports the finding obtained in the in vivo experiments. These results indicate that DFA IV may have a function for increasing the calcium absorption in the small intestine of rats. However, the effect in the large intestine could not be clearly observed because of the lack of calcium that reached there. The results of analyses of organic acids in the cecal and colonic contents and of DFA IV in the fecal, cecal, and colonic contents showed that the metabolism of DFA IV by microorganisms in the large intestine progressed gradually, and that DFA IV was converted mainly to acetate, butyrate, and lactate.     

Increased Ca++ or mg++ concentration reduces relative tight-junction permeability to Na+ in the cortical thick ascending limb of Henle's loop of rabbit kidney

We have tested whether increased Ca++ and Mg++ concentrations have an effect on transepithelial voltage (PDte) and transepithelial resistance (Rte) in isolated perfused cortical thick ascending limbs (cTAL) of rabbit kidney. The divalent cations added at 2.5, 5.0 and 10.0 mmol.l-1 to the lumen or peritubular bath perfusate led to a concentration-dependent increase in Rte. The maximal response in Rte was observed between 5 and 10 mmol.l-1. No significant change in active transepithelial potential difference (PDte) was observed. The increase in Rte still occurred when the transcellular current was reduced by Ba++ (3 mmol.l-1) added to the lumen perfusate. This suggests that the increase in Rte caused by Ca++ and Mg++ is due to a modification of the paracellular shunt pathway. In the absence of active transport, i.e. when furosemide (5.10(-5) mol.l-1) was added to the lumen perfusate. Ca++ and Mg++ reduced the transepithelial diffusion potential generated by a NaCl gradient established across the epithelium, and thus produced a reduction of the relative permeability for Na+ over Cl- (PNa+/PCl-) of the paracellular shunt pathway. This indicates that divalent cations increase Rte by reducing the sodium permeability of the tight junctions. The observed Ca++ and Mg++ induced reduction of the sodium permeability of the paracellular pathway corresponds to a decrease in net Na+ reabsorption by 5-10%. Since it has been demonstrated that peptide hormones such as parathyrin (PTH) modulate divalent cation and NaCl reabsorptions, in a second series of experiments we tested the effects of PTH (2-20 USP.l-1) and dbcAMP (10(-3) mol.l-1) on PDte and Rte of isolated perfused cTAL segments of rabbit nephron. Neither Rte nor PDte were affected by PTH or dbcAMP.     

Lack of correlation between transepithelial transport capacity and paracellular pathway ultrastructure in Alcian blue-treated rabbit gallbladders

The effects of mucosal application of 1 mg% Alcian blue (a trivalent cationic phthalocyanine dye) on functional and ultrastructural parameters of the isolated rabbit gallbladder have been studied. Apart from minor changes in the shape of the group of central microvilli observed in thin-section electron microscopy and scanning electron microscopy, the major ultrastructural change induced by Alcian blue was an almost complete collapse of intercellular spaces in the region above the tight junctions up to the bases of the marginal microvilli as revealed by thin-section electron microscopy. Freeze-fracture electron microscopy demonstrated a complete disappearance of intramembrane particles of neighboring cell membranes corresponding to the region of interspace collapse. Transepithelial electrical resistance (RT) increased from 44.5 to 58.7 ohm . cm2 upon treatment with Alcian blue. This increase could be well accounted for by the observed structural changes in the paracellular pathway if this pathway determines the low resistance of the rabbit gallbladder epithelium. Despite the increase in RT, net mucosa-to-serosa fluid transport and the spontaneous mucosa- positive potential difference of 3 mV were unaltered by Alcian blue treatment, supporting the hypothesis that the transepithelial transport mechanism per se is electroneutral. A calculation of the maximal paracellular mucosa-to-serosa waterflow in response to a lateral intercellular space hypertonicity of 20 mosM demonstrates that in the Alcian blue-treated gallbladder the resulting figure is about three orders of magnitude too low to keep up with the unaltered spontaneous transepithelial net fluid transport. It is therefore concluded that the tight junction pathway in rabbit gallbladders does not serve as a route for net fluid transport.     

Role of the Paracellular Pathway in Isotonic Fluid Movement Across the Renal Tubule

Evidence for a highly permeable paracellular shunt in the proximal tubule is reviewed. The paracellular pathway is described as a crucial site for the regulation of net absorption and for solute-solvent interaction. Available models for the coupling of salt and water transport are assessed with respect to the problem of isotonic water movement. Two new models are proposed taking into account that the tight junctions are permeable to salt and water and that active transport sites for sodium are distributed uniformly along the lateral cell membrane. The first model (continuous model) is a modification of Diamond and Bossert''s proposal using different assumptions and boundary conditions. No appreciable standing gradients are predicted by this model. The second model (compartmental model) is an expansion of Curran''s double membrane model by including additional compartments and driving forces. Both models predict a reabsorbate which is not isosmotic. For the particular case of the proximal tubule it is shown that in the presence of a leaky epithelium these deviations from isotonicity might have escaped experimental observation.     

Effects of metabolic inhibition on ion transport by dog bronchial epithelium

Mammalian bronchial epithelium absorbs Na+ under basal conditions, but Cl- secretion can be induced. We studied the effects of several modes of metabolic inhibition on the bioelectric properties and solute permeability of dog bronchial epithelium mounted in Ussing chambers. Net Na+ absorption and short-circuit current were inhibited by approximately 75% by hypoxia or by 10(-3) M NaCN. The reduced net Na+ absorption was characterized by a decrease in absorptive flux and an increase in backflux. The latter change was proportional to an increase in permeability to [14C]mannitol, implying that solute flow through a paracellular shunt was increased. In contrast, the reduction of conductance expected from exposure to amiloride (0.94 +/- 0.15 ms/cm2 or 12%) was abolished by NaCN pretreatment. Metabolic inhibition also decreased epithelial conductance and unidirectional Cl- fluxes by approximately 25%. NaCN rapidly and reversibly inhibited the hyperpolarization of potential difference (PD) induced by low luminal bath [Cl-]. This effect was mimicked by the Cl- channel blocker, 5-nitro-2-(3-phenylpropylamino) benzoic acid. Because the transepithelial Cl- diffusion PD reflects, in part, the depolarization of the Cl- -conductive apical cell membrane, metabolic inhibition appears to affect this path. We conclude that metabolic inhibition not only decreased net ion transport by dog bronchial epithelium but also inhibited cellular Na+- and Cl- -conductive pathways and increased paracellular permeability.     

The MDCK cell line is made up of populations of cells with diverse resistive and transport properties

The MDCK cell line has been used as a model for the renal distal tubule. When grown on permeable supports, the cells form tight junctions and transport sodium and calcium. Widely different values have, however, been obtained for resistance and transports by different investigators. Since the MDCK cell line is genetically heterogeneous, one potential reason for observed differences is the use of different populations of cells. Dilutional techniques have been used to obtain eleven MDCK cell clones. The clones exhibit a range of values for resistance (300-4000 ohms cm2), net Ca2+ transport (3.2-81 pmol/cm2/min) and net Na+ transport (0.4-6.0 nmol/cm2/min). To determine if the characteristics of clonal cell lines changed with increasing passage number, resistance was measured at relatively early and late passage number. Resistance increased with increasing passage number in two of six lines and decreased in one. These studies demonstrate that differences between previous studies may be due to differences in cell population, length of time since passage, and passage number. Clonal cell lines should provide a useful tool to investigate ion transport and mechanisms of regulation of transport in this model of renal distal tubule.     

Arachidonic acid cascade and epithelial barrier function during Caco-2 cell differentiation

The small intestinal epithelium is a highly dynamic system continuously renewed by a process involving cell proliferation and differentiation. The intestinal epithelium constitutes a permeability barrier regulating the vectorial transport of ions, water, and solutes. Morphological changes during cell differentiation, as well as changes in the activity of brush-border enzymes and the expression of transport proteins, are well established. However, little is known about the arachidonic acid (AA) cascade underlying epithelial cell differentiation or its role in the development of epithelial barrier function. The main purpose of this study was to examine the activity of the high-molecular-weight phospholipases A(2) (PLA(2)) and cyclooxygenase (COX) pathway during differentiation, with particular emphasis on paracellular permeability. PLA(2) activity, AA release, COX-2 expression, prostaglandin E(2) (PGE(2)) production, and paracellular permeability were studied in preconfluent, confluent, and differentiated Caco-2 cell cultures. Our results show that Caco-2 differentiation induces a decrease in both calcium-independent PLA(2) activity and COX-2 expression and, consequently, a decrease in AA release and PGE(2) synthesis in parallel with a reduction in paracellular permeability. Moreover, the addition of PGE(2) to differentiated cells, at concentrations similar to those detected in nondifferentiated cultures, induces the disruption of epithelial barrier function. These results suggest that AA release by calcium-independent PLA(2), COX-2 expression, and subsequent PGE(2) release are important for the maintenance of paracellular permeability in differentiated Caco-2 cells.     

Eimeria tenella: anticoccidial action of drugs in birds with surgically closed ceca.

Surgical ligation of chick ceca was used to study the role of absorption and extraintestinal transport in the action of anticoccidial drugs. The administration of drugs in the feed was started after ligation of one of the paried ceca. Birds were inoculated orally with oocysts of Eimeria tenella before cecal ligation or were given bilateral cecal injections of sporozoites after ligation. Cecal lesions caused by the coccidia were evaluated and compared on day 6 postinoculation. Lesions in ligated and unligated ceca were reduced by feeding robenidine (33 ppm), arprinocid (70 ppm), zoalene (125 ppm), aklomide (250 ppm), clopidol (125 ppm), nicarbazin (125 ppm), monensin (120 ppm), salinomycin (60 ppm), and lasalocid (75 ppm). The lesions were more severe in the ligated cecum than in the intact cecum, whether in nonmedicated or medicated birds, but the differences were statistically significant only upon treatment with amprolium, aklomide, robenidine, and clopidol. Generally, however, all drugs except amprolium, significantly reduced the lesions in the ligated cecum in comparison with the control, nonmedicated ligated cecum. Therefore, we concluded that the systemic absorption of most anticoccidial drugs contributes significantly to their efficacy against coccidia in the intestinal mucosa.     

Claudin-3 acts as a sealing component of the tight junction for ions of either charge and uncharged solutes

The paracellular barrier of epithelia and endothelia is established by several tight junction proteins including claudin-3. Although claudin-3 is present in many epithelia including skin, lung, kidney, and intestine and in endothelia, its function is unresolved as yet. We therefore characterized claudin-3 by stable transfection of MDCK II kidney tubule cells with human claudin-3 cDNA. Two clone systems were analyzed, exhibiting high or low claudin-2 expression, respectively. Expression of other claudins was unchanged. Ultrastructurally, tight junction strands were changed toward uninterrupted and rounded meshwork loops. Functionally, the paracellular resistance of claudin-3-transfected monolayers was strongly elevated, causing an increase in transepithelial resistance compared to vector controls. Permeabilities for mono- and divalent cations and for anions were decreased. In the high-claudin-2 system, claudin-3 reduced claudin-2-induced cation selectivity, while in the low-claudin-2 system no charge preference was observed, the latter thus reflecting the "intrinsic" action of claudin-3. Furthermore, the passage of the paracellular tracers fluorescein (332 Da) and FD-4 (4 kDa) was decreased, whereas the permeability to water was not affected. We demonstrate that claudin-3 alters the tight junction meshwork and seals the paracellular pathway against the passage of small ions of either charge and uncharged solutes. Thus, in a kidney model epithelium, claudin-3 acts as a general barrier-forming protein.