Functional characteristics of the porcine colonic epithelium following transportation stress and Salmonella infection.

OBJECTIVE: Stressful life events and infections contribute to gut disorders such as irritable bowel syndrome (IBS) and inflammatory bowel disease (IBD). We used a pig model to analyse whether this could be linked to altered mediator sensitivity of the epithelial lining. MATERIAL AND METHODS: Uninfected control pigs or pigs with subclinical Salmonella (S.) typhimurium DT 104 infection were killed either without (ConRest, InfRest) or with prior 8-h transportation (ConTrans, InfTrans). Short-circuit current (I(sc)), tissue conductance (G(t)) and release of mast cell mediators were monitored in isolated colonic epithelia mounted in Ussing chambers. Epithelia were exposed to histamine (100 microM, mucosally), substance P (SP; 1 microM, serosally), calcimycin A23187 (1 microM, serosally) and theophylline (10 mM, bilaterally). Transepithelial flux of histamine and colonic activities of histamine N-methyltransferase (HMT) and diamine oxidase (DAO) were determined. RESULTS: S. infection decreased baseline I(sc), G(t) and histamine fluxes, while transportation had no effect on these values. Mucosal histamine increased I(sc) only in ConTrans pigs. This was not associated with increased mucosal-to-serosal flux of histamine but with a 2-fold increased DAO activity. Serosal SP increased I(sc) only in transported animals, but the increase was six times higher in ConTrans versus InfTrans pigs. Effectiveness of SP was not dependent on the release of histamine or prostaglandin D2. A23187 and theophylline elicited increases in I(sc) that were not different between treatments. CONCLUSIONS: Transportation stress facilitates secretory responses of the colonic epithelium to SP and luminal histamine. This is suppressed by subclinical S. infection. Effects of S. infection on porcine colon resemble, in part, the known effects of an oral S. endotoxin application.

Histamine inactivation in the colon of pigs in relationship to abundance of catabolic enzymes.

OBJECTIVE: Catabolism of histamine plays a crucial role in the intestine in preventing intoxication by luminal histamine. Two enzymes are involved, namely histamine N-methyltransferase (HMT) and diamine oxidase (DAO). The purpose of this study was to find a link between histamine catabolism and the activities of HMT and DAO. MATERIAL AND METHODS: Epithelia of porcine proximal colon were mounted in Ussing chambers. After mucosal addition of (3)H-histamine (100 micromol x l(-1)) and (14)C-mannitol, the appearance of non-catabolized histamine, (3)H-histamine label (hist-rad) and (14)C-mannitol label were measured in parallel on the serosal side. Activities of HMT and DAO were determined in the proximal colon and proximal jejunum. RESULTS: Differences between the fluxes of histamine and hist-rad indicated catabolic conversion of 81.4+/-1.6% histamine during epithelial transit. Fluxes of hist-rad and histamine increased linearly with increasing mannitol fluxes but the percentage of catabolized histamine was not related to either mannitol or hist-rad fluxes. However, the percentage of catabolized histamine rose with increasing DAO activity. Given a negative correlation between DAO and HMT activities, the fraction of catabolized histamine decreased with increasing HMT activity. HMT activity was comparable in the colon and jejunum, but DAO activity was approximately nine times higher in the jejunum. CONCLUSIONS: Permeation, but not the relative efficiency of catabolism, of histamine depends on epithelial/paracellular tightness. While previous studies have shown that colonic HMT essentially catabolizes the bulk of histamine during permeation, DAO activity seems to be more variable and limiting for the overall efficiency of the catabolic process.