Tumour necrosis factor alpha and nuclear factor kappaB inhibit transcription of human TFF3 encoding a gastrointestinal healing peptide.

BACKGROUND: and aims: Tumour necrosis factor alpha (TNF-alpha) induction of nuclear factor kappaB (NFkappaB) activation plays a major role in the pathogenesis of inflammatory bowel disease (IBD). Trefoil factor family peptides TFF1, TFF2, and TFF3 exert protective, curative, and tumour suppressive functions in the gastrointestinal tract. In this study, we investigated effects of the TNF-alpha/NFkappaB regulatory pathway by TNF-alpha on expression of TFFs. METHODS: After TNF-alpha stimulation, expression of TFF genes was analysed by quantitative real time polymerase chain reaction and by reporter gene assays in the gastrointestinal tumour cell lines HT-29 and KATO III. Additionally, NFkappaB subunits and a constitutive repressive form of inhibitory factor kappaB (IkappaB) were transiently coexpressed. In vivo, morphological changes and expression of TFF3, mucins, and NFkappaB were monitored by immunohistochemistry in a rat model of 2,4,6-trinitrobenzene sulphonic acid induced colitis. RESULTS: TNF-alpha stimulation evoked up to 10-fold reduction of TFF3 expression in the colon tumour cell line HT-29. Downregulation of reporter gene transcription of TFF3 was observed with both TNF-alpha and NFkappaB, and was reversible by IkappaB. In vivo, the increase in epithelial expression of NFkappaB coincided with reduced TFF3 expression during the acute phase of experimental colitis. CONCLUSIONS: Downregulation of intestinal trefoil factor TFF3 is caused by repression of transcription through TNF-alpha and NFkappaB activation in vitro. In IBD, perpetual activation of NFkappaB activity may contribute to ulceration and decreased wound healing through reduced TFF3.

Functions of GI-GPx: lessons from selenium-dependent expression and intracellular localization.

Gastro intestinal glutathione peroxidase (GI-GPx) is one of the four distinct mammalian selenoperoxidases. It had been reported to be restricted to the gastrointestinal tract but has more recently been identified also in human liver and some tumor cell lines. GI-GPx ranks high in the hierarchy of selenoproteins. The GI-GPx mRNA rather increases than decreases in selenium deficiency. GI-GPx protein responds poorly to selenium deprivation and increases fast upon resupplementation. Putative biological roles of GI-GPx, e.g. protection against food-born hydroperoxides, redox-regulation of proliferation or apoptosis, and modulation of mucosal immunity, are discussed in the light of cellular and subcellular distribution, transcriptional regulation and observations with k.o. mice.

Cellular and subcellular localization of gastrointestinal glutathione peroxidase in normal and malignant human intestinal tissue.

The gastrointestinal glutathione peroxidase (GI-GPx) is believed to prevent absorption of hydroperoxides. GI-GPx is expressed in the intestine together with the other three glutathione peroxidase isoenzymes, raising the question of the physiological role of the different GPx types. We therefore studied the cellular and subcellular distribution of GI-GPx in normal and malignant tissue obtained from patients with colorectal cancer or familial polyposis by immunohistochemistry. In healthy ileum epithelium GI-GPx was preferentially enriched in Paneth cells. In unaffected crypts of colon and rectum, it decreased gradually from the ground to the luminal surface. In crypt ground, GI-GPx was uniformly distributed, whereas in cells at the luminal surface it was concentrated in structures capping the nuclei at the apical pole. In colorectal cancer, GI-GPx expression depended on the stage of malignant transformation. In early stages, GI-GPx was increased and pronouncedly associated with the vesicular structures. In progressed stages of malignancy, structures disintegrated and GI-GPx distribution became more diffuse. These observations support the hypothesis that GI-GPx, apart from being a barrier against hydroperoxide absorption, might be involved in cell growth and differentiation.

Gastrointestinal glutathione peroxidase prevents transport of lipid hydroperoxides in CaCo-2 cells.

BACKGROUND & AIMS: Gastrointestinal glutathione peroxidase (GI-GPx), 1 of the 4 types of selenium-dependent glutathione peroxidases, is expressed exclusively in the gastrointestinal system and has therefore been suggested to function as a barrier against the absorption of dietary hydroperoxides. METHODS: The selenium-dependent expression of GI-GPx and cytosolic GPx (cGPx) was analyzed by Western blotting. Transport of 13-hydroperoxy octadecadienoic acid (13-HPODE) was investigated in a CaCo-2 cell monolayer modulated in GI-GPx and cGPx by selenium restriction or repletion. Localization of GI-GPx in rat intestine was visualized by immunohistochemistry. RESULTS: Low but significant GI-GPx levels were detected in selenium-deficient CaCo-2 cells and in the gastrointestinal tract of selenium-deficient rats, whereas cGPx was completely absent. Selenium supplementation of CaCo-2 cells resulted in a 5-fold increase of GI-GPx protein, whereas total GPx activity increased by a factor of 13, with most of the GPx activity under selenium-adequate conditions being cGPx. Irrespective of the selenium status, 13-HPODE did not reach the basolateral side of an intact CaCo-2 cell monolayer. Depending on the selenium status, hydroperoxides damaged the monolayer as evidenced by loss of transepithelial resistance and paracellular diffusion of lucifer yellow. Only under these conditions was unmetabolized 13-HPODE detectable at the basolateral side. CONCLUSIONS: Low GI-GPx levels, as present in selenium deficiency, suffice to prevent transport of 13-HPODE. GI-GPx may thus function as a barrier against hydroperoxide absorption. cGPx contributes to balance major oxidative challenge.

Deficiency of epithelial basement membrane laminin in ulcerative colitis affected human colonic mucosa.

Imbalances in epithelium-matrix interactions have been discussed as a pathomechanism in ulcerative colitis, causing a colonic mucosal barrier dysfunction. Laminin, the major noncollagenous component of the basement membrane, plays a role in epithelial basal lamina formation and promotes differentiation of human enterocytes. We therefore investigated the distribution of laminin in ulcerative colitis affected colonic tissues. Tissue specimens from both affected and nonaffected colonic regions were obtained from ten patients with ulcerative colitis during colonoscopies or operations. Healthy tissue from five patients with colorectal cancer was used as control. After histological classification, the localization and distribution of the basement membrane associated extracellular matrix proteins were determined by immunohistochemistry. Paraffin-embedded sections were incubated with antibodies against laminin and type IV and V collagen. No positive immunoreactivity against laminin was found in most of the epithelial basement membranes surrounding the crypts in affected colonic tissues, without involvement of the subendothelial structures. In contrast, a type IV and V collagen accumulation occurred in all these tissue samples. The lack of laminin in combination with an overexpression of type IV and V collagen, as reported for the first time in this paper, leads to changes in basement membrane structure. These findings indicate that the three-dimensional network of the colonic epithelial basement membrane and its function are seriously disturbed in exacerbating ulcerative colitis. This provides new insights into the importance of cell-matrix interactions for physiological and pathological mechanisms in the etiology of ulcerative colitis.

Dietary resistant starch and chronic inflammatory bowel diseases.

These studies were performed to test the benefit of resistant starch on ulcerative colitis via prebiotic and butyrate effects. Butyrate, propionate, and acetate are produced in the colon of mammals as a result of microbial fermentation of resistant starch and other dietary fibers. Butyrate plays an important role in the colonic mucosal growth and epithelial proliferation. A reduction in the colonic butyrate level induces chronic mucosal atrophy. Short-chain fatty acid enemas increase mucosal generation, crypt length, and DNA content of the colonocytes. They also ameliorate symptoms of ulcerative colitis in human patients and rats injected with trinitrobenzene sulfonic acid (TNBS). Butyrate, and also to a lesser degree propionate, are substrates for the aerobic energy metabolism, and trophic factors of the colonocytes. Adverse butyrate effects occur in normal and neoplastic colonic cells. In normal cells, butyrate induces proliferation at the crypt base, while inhibiting proliferation at the crypt surface. In neoplastic cells, butyrate inhibits DNA synthesis and arrests cell growth in the G1 phase of the cell cycle. The improvement of the TNBS-induced colonic inflammation occurred earlier in the resistant starch (RS)-fed rats than in the RS-free group. This benefit coincided with activation of colonic epithelial cell proliferation and the subsequent restoration of apoptosis. The noncollagenous basement membrane protein laminin was regenerated initially in the RS-fed group, demonstrating what could be a considered lower damage to the intestinal barrier function. The calculation of intestinal short-chain fatty acid absorption confirmed this conclusion. The uptake of short-chain fatty acids in the colon is strongly inhibited in the RS-free group, but only slightly reduced in the animals fed with RS. Additionally, RS enhanced the growth of intestinal bacteria assumed to promote health. Further studies involving patients suffering from ulcerative colitis are necessary to determine the importance of RS in the therapy of a number of intestinal diseases and the maintenance of health.

[COX-2 associated loss of apoptosis activity in intestinal neoplams in Apc gene knock-out mice]. / COX-2-assoziierter Verlust der Apoptoseaktivität in intestinalen Neoplasien Apc-Gen-defekter Mäuse.

The aim of the study was to characterize both apoptotic and proliferating cells histologically and to analyze localisation and distribution of various apoptosis-associated proteins in tumours of different stages of degeneration in the animal model of Apc-gene defect mice. Such animals show clinical symptoms similar to those of patients suffering from Familial Adenomatous Polyposis (FAP) but develop the neoplasm's mainly in the small intestine. Tumours from all parts of the gut of 90 days old non-treated MIN-mice were classified as adenocarcinomas, histologically. The apoptosis-associated proteins bax, bcl-2, p53 and the COX-2 enzyme were investigated immunohistochemically. Additionally the localisation and distribution of proliferating (BrdU-labeling) and apoptotic (KLENOW, TUNEL) cells were analysed. In the summary we point out: 1. The activity of apoptosis increases in early stage of neoplasm as a defensive mechanism of mucosa. 2. A decrease in apoptosis rate occurs during carcinogenesis. 3. The inversely correlating, clear COX-2 accumulation accompanying carcinoma development supplies evidence for cyclooxygenase-inhibitor treatment is a promising therapeutic attempt in early stage of FAP.