Role of the unstirred layer in protecting the murine gastric mucosa from bile salt

Vibrio cholerae RND efflux systems: mediators of stress responses, colonization and pathogenesis

Resistance Nodulation Division (RND) efflux systems are ubiquitous transporters in gram-negative bacteria that provide protection against antimicrobial agents and thereby enhance survival in virtually all environments these prokaryotes inhabit. Vibrio cholerae is a dual lifestyle enteric pathogen that spends much of its existence in aquatic environments. An unwitting encounter with a human host can lead to V. cholerae intestinal colonization by strains that encode cholera toxin and toxin co-regulated pilus virulence factors leading to potentially fatal cholera diarrhea and dissemination in the environment. Adaptive response mechanisms to host factors encountered by these pathogens are therefore critical both to engage survival mechanisms such as RND-mediated transporters and to induce timely expression of virulence factors. Sensing of cues encountered in the host may therefore activate more than protective responses such as efflux systems, but also be coordinated to initiate expression of virulence factors. This review summarizes recent advances that contribute towards the understanding of RND efflux physiological functions and how the transport systems interface with the regulation of virulence factor production in V. cholerae.

Review article: lack of clinical significance of the interaction between H2-receptor antagonists and ethanol

It has been proposed that an appreciable fraction of ingested ethanol is metabolized in the gastric mucosa and that inhibition of this metabolism by H2-receptor antagonists produces clinically important increases in blood ethanol. This paper reviews available data concerning gastric metabolism of ethanol and the influence of H2-antagonists on ethanol metabolism. It concludes that very little, if any, metabolism of ethanol is likely to occur in the gastric mucosa, and the interaction between H2-antagonists and ethanol is clinically insignificant.

First-pass gastric mucosal metabolism of ethanol is negligible in the rat

Ethanol metabolism by gastric alcohol dehydrogenase (ADH) is thought to be an important determinant of peripheral ethanol time-concentration curves (AUCs) in rats and humans. We quantitated this metabolism in rats by measuring the gastric absorption of oral ethanol (0.25 g/kg) and the gastric venous-arterial (V-A) difference of ethanol versus ethanol metabolites (acetate, acetaldehyde, and bicarbonate). Over 1 h, approximately 20% of the ethanol was absorbed from the stomach and 70% was emptied into the duodenum. The gastric V-A difference of ethanol metabolites was less than 4% of that of ethanol. Thus, gastric metabolism accounted for less than 1% (less than 4% of 20% absorbed) of the dose. This negligible metabolism was predictable from the low affinity of gastric ADH for ethanol. In contrast, gastric ADH has a high affinity for octanol, and 66% of this compound was metabolized during gastric absorption. Evidence supporting gastric metabolism of ethanol largely derives from the lower AUCs observed after oral than after intravenous administration; however, we observed increasingly higher AUCs with increasingly rapid portal vein infusions of identical ethanol doses. We conclude that gastric metabolism of ethanol is negligible in the rat, and differences in AUCs ascribed to gastric metabolism may reflect differences in ethanol absorption.

The effects of sucralfate and luminal stasis on recovery of the chambered rat gastric mucosa from taurocholate-induced damage

We have previously shown, using a gastric chamber model, that both sucralfate and luminal stasis protected the rat gastric mucosa against the development of hemorrhagic erosions produced by subsequent exposure for 10 minutes to acidified (50 mM HCl) 80 mM sodium taurocholate (NaT). The protection afforded by sucralfate was abolished by inhibition of cyclooxygenase activity but restored by sucralfate. In this study we demonstrate that indomethacin pretreatment decreases both the depth (in microns) and magnitude (in pH units) of the juxtamucosal pH gradient, but that sucralfate restores these parameters to levels characteristic of normal mucosae. The cytoprotective effect of sucralfate is thus prostaglandin-independent and, at least in part, a consequence of sucralfate-induced increases in the thickness of the juxtamucosal pH gradient/unstirred layer. We have also examined the ability of sucralfate to prevent the otherwise inevitable development of hemorrhagic erosions when it was applied after the gastric mucosa was exposed to NaT. When 100 mg sucralfate in 50 mM HCl was applied for 10 minutes, without stirring, subsequent to a 10-minute exposure of the mucosa to NaT, the average lesion area was reduced from about 15% to less than 3%. Unlike its cytoprotective property, the ability of sucralfate to accelerate the recovery process after damage was abolished by indomethacin pretreatment. Studies using antimony microelectrodes revealed that indomethacin pretreatment resulted in reductions in both the depth and magnitude of the pH gradient that resulted from plasma efflux from the mucosa after exposure to the acidified bile salt. These studies demonstrate that sucralfate is capable not only of prevention or attenuation of acute damage when administered prior to damaging agents, but is also capable of arresting the sequence of events that produces hemorrhage in the previously inflamed or damaged stomach.

Alteration of gastric surface cell pH regulation by sodium taurocholate

Gastric mucosal cells from guinea pigs were grown in cell culture. Acridine orange fluorescence at 624 nm was used as an qualitative indicator of intracellular pH. The cultured cells were exposed to Hank's solution at pH 7.4, 6.0, 5.0, 4.0, 3.0, and 1.8 for 30 min. After removal of the acid, the cells were loaded with acridine orange for qualitative pH assessment. The cells developed alkaline shifts in the cytoplasmic pH in direct proportion to the acid load. This alkaline overcorrection after exposure to acid was blocked by amiloride and blunted by taurocholic acid in a dose-dependent fashion. These results suggest that gastric surface cells may regulate their cytoplasmic pH with a sodium-hydrogen antiporter. These results also suggest that this antiport system may be adversely affected by bile salts.

Bile salt-induced increases in duodenal brush-border membrane proton permeability, fluidity, and fragility

Rabbit duodenal brush-border membrane vesicles were treated in vitro with deoxycholate, glycodeoxycholate, or taurodeoxycholate. Intravesicular [14C]glucose space at equilibrium, 0.54 microliters/mg protein, was reduced by exposure to the three bile salts in a concentration (0.1-5.0 mM)-dependent manner, equatable with increased membrane fragility. Net proton permeability (Pnet), determined by acridine orange fluorescence quenching, was increased from 6.3 x 10(-4) cm/sec in untreated vesicles, by approximately 120, 150, and 170%, by treatment with bile salts at 0.1, 0.5 and 1.0 mM, respectively. The three bile salts were equipotent. The increases in membrane fragility and Pnet were not accompanied by significant increases in membrane fluidity, as assessed from steady-state and time-resolved diphenylhexatriene fluorescence anisotropy. The data demonstrate direct effects of bile salts on duodenal apical membrane fragility and proton permeability that are likely to be early events in bile salt-induced mucosal damage.

Protection of rat gastric mucosa by sucralfate. Effects of luminal stasis and of inhibition of prostaglandins synthesis

Studies using a gastric chamber model demonstrated that sucralfate protected the rat gastric mucosa against hemorrhagic erosions induced by 40 percent ethanol and by acidified 80 mM sodium taurocholate. Protection required continuous contact of sucralfate with the gastric mucosa but it occurred without the production, by sucralfate alone, of significant damage to the luminal epithelium. Ultrastructural examination indicated that sucralfate stimulated mucus secretion by surface epithelial cells. Furthermore, sucralfate was "cytoprotective" in that, in addition to its anti-ulcer effects, it significantly reduced the damaging effects of luminal ethanol on the surface epithelium. Luminal stasis also significantly reduced the extent of hemorrhagic erosions produced by both ethanol and sodium taurocholate, but the most effective reduction in erosions occurred when sucralfate and luminal stasis were combined. Pretreatment with indomethacin abolished the protection provided by luminal stasis, but this protection was restored by sucralfate. Thus, these studies suggest that protection of the gastric mucosa by sucralfate results in part from effects on the unstirred layer. Sucralfate or its products also interact with the epithelial cells and stimulate mucus release and synthesis or release of inflammatory mediators.

Stimulation of bile acid active transport related to increased mucosal cyclic AMP content in rat ileum in vitro

The regulation of bile acid transport in rat ileum was studied in vitro using the adenylate cyclase stimulator forskolin, or 3-isobutyl-1-methylxanthine (IBMX), a phosphodiesterase inhibitor. Forskolin 20 microM as well as 100 microM IBMX enhanced mucosal cyclic AMP to 3-fold the control levels. As a physiological response, net fluid absorption in everted ileal sacs was reduced. Taurocholate (10-500 microM) transfer in everted perfused segments of rat ileum was measured using a three compartment dual label method suitable for measuring active transport. Transport asymmetry with absorption exceeding its counterflux by 26-fold, was measured at 500 microM taurocholate. Forskolin increased absorption of taurocholate still further, by 68%, and reduced the serosal to mucosal flux. Enhanced intracellular accumulation of taurocholate indicated a stimulatory action of forskolin on active transport at the mucosal brush-border membrane. In uptake studies, accumulation of taurocholate was enhanced by 100 microM IBMX also. Forskolin-induced uptake stimulation could also be shown for chenodeoxycholate and cholate. In the presence of the neuronal blocker tetrodotoxin, uptake stimulation was still effective. Results indicate that the ileal bile acid transporter is included within the group of sodium-dependent cotransporters of the rat small intestine which are subject to a cyclic AMP-related stimulation at the mucosal cellular level.

The pathophysiological and pharmacological basis of peptic ulcer therapy

Both genetic and nongenetic factors predispose to ulcer diathesis. At the mucosal level ulcers result from an imbalance between aggressive factors and mucosal defense. Ulcer therapy reduces aggressive forces, bolsters defense, or both. Gastric acid, the major aggressive factor, may have its secretion inhibited or it may be partially neutralized by antacids. H2 receptor antagonists competitively block histamine occupancy of H2 receptors on parietal cells, thereby preventing stimulation of adenylate cyclase, cAMP rises, and activation of protein kinase and H+/K+ATPase. Prostaglandins inhibit acid secretion largely by preventing histamine-induced cAMP rises. Proton pump inhibitors bind H+/K+ATPase. Antimuscarinics inhibit acetylcholine receptors on the parietal cell, thereby blocking Ca2+ entry and subsequent activation of protein kinase and the proton pump. Mucosal defense is enhanced by certain prostaglandins, colloidal bismuth subcitrate and sucralfate. Prostaglandins stimulate secretion of bicarbonate and mucus, among other effects. Colloidal bismuth and sucralfate bind to proteins in the ulcer base and stimulate bicarbonate and mucus secretion, partially, in the case of sucralfate, by increasing endogenous prostanoid synthesis. Sucralfate also binds pepsin and bile acids. Colloidal bismuth temporarily eradicates mucosal colonization by Campylobacter pylori, another putative agent in ulcer diathesis.