miR-146a regulates the crosstalk between intestinal epithelial cells, microbial components and inflammatory stimuli.

Regulation of miR-146a abundance and its role in intestinal inflammation and particularly in intestinal epithelial cells (IECs) has been poorly studied. Here we study the relationship between bacterial antigens and inflammatory stimuli, and miR-146a expression using IEC lines and models of colitis (trinitrobenzenesulfonic acid (TNBS), dextran sulfate sodium (DSS) and the CD4 + CD62L + T cell transfer model). Specific bacterial antigens and cytokines (LPS, flagelin and IL-1ß/TNF) stimulate miR-146a expression, while peptidoglycan, muramyldipeptide and CpG DNA have no effect. Overexpression of miR-146a by LPS depends on the activation of the TLR4/MyD88/NF-kB and Akt pathways. Accordingly, the induction of miR-146a is lower in TLR4, but not in TLR2 knock out mice in both basal and colitic conditions. miR-146a overexpression in IECs induces immune tolerance, inhibiting cytokine production (MCP-1 and GROα/IL-8) in response to LPS (IEC18) or IL-1ß (Caco-2). Intestinal inflammation induced by chemical damage to the epithelium (DSS and TNBS models) induces miR-146a, but no effect is observed in the lymphocyte transfer model. Finally, we found that miR-146a expression is upregulated in purified IECs from villi vs. crypts. Our results indicate that miR-146a is a key molecule in the interaction among IECs, inflammatory stimuli and the microbiota.

Tissue Non-specific Alkaline Phosphatase Expression is Needed for the Full Stimulation of T Cells and T Cell-Dependent Colitis.

BACKGROUND AND AIMS: Two alkaline phosphatase isoforms, intestinal [IAP] and tissue non-specific alkaline phosphatase [TNAP], are coexpressed in mouse colon, with the latter predominating in colitis. We aimed to examine the role of TNAP in T lymphocytes, using heterozygous TNAP+/- mice [as TNAP-/- mice are non-viable]. METHODS: In vitro primary cultures and in vivo T cell models using TNAP+/- mice were used. RESULTS: Stimulated splenocytes [lipopolysaccharide and concanavalin A] and T lymphocytes [concanavalin A and a-CD3/a-CD28] showed a decreased cytokine production and expression when compared with wild-type [WT] cells. Decreased T cell activation was reproduced by the TNAP inhibitors levamisole, theophylline, and phenylalanine in WT cells. Intraperitoneal administration of anti-CD3 in vivo resulted in reduced plasma cytokine levels, and decreased activation of splenocytes and T cells ex vivo in TNAP+/- mice. We further tested the hypothesis that TNAP expressed in T lymphocytes is involved in T cell activation and inflammation, using the lymphocyte transfer model of colitis. Rag1-/- mice were transferred with T naïve cells [CD4+ CD62L+] from TNAP+/- or WT mice and developed colitis, which was attenuated in the group receiving TNAP+/- cells. Compared with WT, T cells from TNAP+/- mice showed a decreased capacity for proliferation, with no change in differentiation. CONCLUSIONS: Our results offer clear evidence that TNAP modulates T lymphocyte function and specifically T cell-dependent colitis. This was associated with distinct changes in the type of TNAP expressed, probably because of changes in glycosylation.

Dose-dependent antiinflammatory effect of ursodeoxycholic acid in experimental colitis.

The denomination of inflammatory bowel disease comprises a group of chronic inflammatory diseases of the digestive tract, ulcerative colitis and Crohn's disease being the most important conditions. Bile acids may play a role both in etiology and pharmacology of this disease. Thus, although deoxycholic acid is regarded as a proinflammatory agent ursodeoxycholic acid, which is currently being used to treat certain types of cholestasis and primary biliary cirrhosis, because of their choleretic, cytoprotective and immunomodulatory effects, it has been reported to exert an anti-inflammatory activity. We aim to confirm and characterize the intestinal antiinflammatory activity of ursodeoxycholic acid. The experimental model trinitrobenzenesulfonic acid (TNBS)-induced colitis in rats has been used. Animal status was characterized by a number of macroscopic and biochemical parameters. Oral administration of ursodeoxycholic acid was able to ameliorate experimental colonic inflammation. This occurred only at a relatively high dose (50 mg/kg day), whereas ursodeoxycholic acid was without significant effect at doses of 10 and 25 mg/kg day. The therapeutic effect was evidenced, among others, by a higher body weight recovery, a diminished affected to total mucosal area and lower alkaline phosphatase activity in treated vs. control (TNBS treated) animals. These results indicate that, at the appropriate dose, ursodeoxycholic acid is a potentially useful drug to reduce intestinal inflammation and could be envisaged to be incorporated in the treatment of inflammatory bowel diseases.

Tissue-nonspecific alkaline phosphatase is activated in enterocytes by oxidative stress via changes in glycosylation.

BACKGROUND: Intestinal inflammation produces an induction of alkaline phosphatase (AP) activity that is attributable in part to augmented expression, accompanied by a change in isoform, in epithelial cells. METHODS: This study focuses on induction of AP in intestinal epithelial cells in vitro. RESULTS: Treatment with the oxidants H2O2, monochloramine, or tButOOH increases AP activity in vitro in Caco-2, HT29, and IEC18 cells. We selected IEC18 cells for further testing. Basal AP activity in IEC18 cells is of the tissue-nonspecific (bone-liver-kidney) type, as indicated by Northern and Western blot analysis. Oxidative stress augments AP activity and the sensitivity of the enzyme to levamisole, homoarginine, and heat in IEC18 cells. Increased immunoreactivity to tissue-nonspecific AP antibodies suggests an isoform shift from liver to either kidney or bone type. This effect occurs without changes at the mRNA level and is sensitive to tunicamycin, an inhibitor of N-glycosylation, and neuraminidase digestion. Saponin and deoxycholate produce similar effects to oxidants. Butyrate but not proinflammatory cytokines or LPS can induce a similar effect but without toxicity. The AP increase is not prevented by modulators of the MAPK, NF-κB, calcium, and cyclic adenosine monophosphate (cAMP) pathways, and is actually enhanced by actinomycin D via higher cell stress. CONCLUSIONS: Oxidative stress causes a distinct increase in enterocyte AP activity together with cell toxicity via changes in the glycosylation of the enzyme that correspond to a shift in isotype within the tissue-nonspecific paradigm. We speculate that this may have physiological implication for gut defense.

Reversible Ponceau staining as a loading control alternative to actin in Western blots.

It is becoming standard practice to measure a housekeeping gene, typically actin, in Western blots, as it is the rule in RNA blots. We have applied reversible Ponceau staining to check equal loading of gels and measured actin in parallel under different conditions. Our results show that densitometric analysis is comparable with both techniques. Therefore, routine quantitation of Ponceau staining before antibody probing is validated as an alternative to actin blotting.