KLF4 regulation in intestinal epithelial cell maturation.

The Krüppel-like factor 4 (KLF4) transcription factor suppresses tumorigenesis in gastrointestinal epithelium. Thus, its expression is decreased in gastric and colon cancers. Moreover, KLF4 regulates both differentiation and growth that is likely fundamental to its tumor suppressor activity. We dissected the expression of Klf4 in the normal mouse intestinal epithelium along the crypt-villus and cephalo-caudal axes. Klf4 reached its highest level in differentiated cells of the villus, with levels in the duodenum>jejunum>ileum, in inverse relation to the representation of goblet cells in these regions, the lineage previously linked to KLF4. In parallel, in vitro studies using HT29cl.16E and Caco2 colon cancer cell lines clarified that KLF4 increased coincident with differentiation along both the goblet and absorptive cell lineages, respectively, and that KLF4 levels also increased during differentiation induced by the short chain fatty acid butyrate, independently of cell fate. Moreover, we determined that lower levels of KLF4 expression in the proliferative compartment of the intestinal epithelium are regulated by the transcription factors TCF4 and SOX9, an effector and a target, respectively, of beta-catenin/Tcf signaling, and independently of CDX2. Thus, reduced levels of KLF4 tumor suppressor activity in colon tumors may be driven by elevated beta-catenin/Tcf signaling.

Oxyntomodulin and glicentin: brain-gut peptides in the rat.

Glucagon-like materials and glucagon have been identified by immunoassay and immunocytochemistry in the mammalian central nervous system. However, the molecular forms relevant to brain glucagon-like immunoreactivity (GLI) have not been precisely defined. In the rat small intestine, more than 90% of GLI is constituted by two peptides: oxyntomodulin (OXM) and glicentin. This work was initiated to characterize and determine the concentrations of these two peptides and glucagon in the rat central nervous system and to compare their relative proportions with those found in the gut. Different regions from the adult rat brain were analyzed by HPLC in association with RIA, using a central glucagon antiserum and an antibody directed toward the C-terminal end of OXM and glicentin. The elution profiles of hypothalamus extracts were constituted by two main peaks, both detected by the two antibodies used and displaying the same retention times as glicentin and OXM, respectively. A third small peak, which coeluted with glucagon, was constantly recorded with the central glucagon antiserum. The percentages of glicentin, OXM, and glucagon in 10 hypothalami were 37 +/- 1%, 55 +/- 1%, and 8 +/- 2%, respectively (n = 8). This distribution was quite similar to that in small intestinal extracts (38 +/- 1%, 59 +/- 1%, and 1.3 +/- 0.1%, respectively; n = 7); however, the peptide concentrations were almost 50-fold greater in intestine than in hypothalamus. In the medulla oblongata, the same peptide ratio was observed, with 10-fold lower concentrations compared to those in hypothalamus. In olfactory bulb, cerebellum, and cortex the concentrations were close the the detection limit, whereas they could be not detected in the pituitary. The combination of HPLC and specific RIAs allowed us to unambiguously characterize OXM and glicentin as the major components of GLI in the rat hypothalamus and medulla oblongata. The same proportion of these two peptides in the central nervous system and the gut indicates that a similar posttranslational processing exists in these rat tissues, another example of the brain-gut axis.

Distribution of oxyntomodulin and glucagon in the gastrointestinal tract and the plasma of the rat.

Oxyntomodulin (OXM), an intestinal glucagon-containing peptide extended at its C-terminal end by an octa-peptide, is one of the gut glucagon-like immunoreactants (GLI) or enteroglucagon. The distribution of OXM and glucagon was determined in the gastrointestinal tract and in the plasma of the rat. Reversed-phase HPLC, associated with RRA or RIA, performed with an N-terminally directed glucagon antiserum (GOL), was used. HPLC of intestinal extracts or plasma separated the GOL immunoreactivity into three peaks: two major peaks coeluting with a preparation of rat glicentin (peak I, partially purified from rat intestine) and porcine or rat OXM, respectively, and a smaller peak coeluting with glucagon. The behavior of the three peaks in the analytical systems matched that of glicentin, OXM, and glucagon, respectively, allowing their identification. The concentrations of OXM picomoles per g of tissue) gradually increased from the duodenum (9 +/- 1) to ileum (93 +/- 4), thereafter decreasing in cecum and colon (22 +/- 3). In the gut, OXM, glucagon, and peak I averaged 40%, 1%, and 59% of the total GLI, respectively. OXM was present in significant amounts in the pancreas (18% of GLI) and stomach (27% of GLI), two tissues in which it accounted, together with glucagon, for almost the totality of GLI. In 24 h-fasted rats, plasma concentrations of OXM, glucagon, and peak I, determined after HPLC with GOL antiserum, were 15.1 pM, 8.6 pM, and 12.3 pM, respectively. Two hours after refeeding, both OXM and peak I were significantly increased (P less than 0.05 and P less than 0.02) by a similar factor (2-fold), while glucagon remained unchanged. When the HPLC results were compared with RIA measurement of GLI (GOL antiserum) and glucagon (with a C-terminal glucagon antiserum) in plasma, enteroglucagon (GOL--C-terminal glucagon antiserum immunoreactivities) correlated well with the sum of OXM plus peak I. The combination of HPLC and RRA or RIA allows the unambiguous determination of OXM, glucagon, and glicentin (peak I) in tissues and plasma. In the rat intestine and in the plasma, OXM and glicentin appear roughly in the same ratio and seem to be the major components, if not the totality, of enteroglucagon.

Oxyntomodulin-like immunoreactivity: diurnal profile of a new potential enterogastrone.

The biological specificity of oxyntomodulin toward the gastric mucosa results from its C-terminal octapeptide. A RIA using a specific antibody raised against this region permitted quantification of the whole set of proglucagon-derived peptides that interact with the oxyntomodulin recognition systems, corresponding to the new concept of oxyntomodulin-like-immunoreactivity (OLI). The present report describes the physiological 24-h OLI profile in human plasma (eight men and eight women; mean age, 45 yr; range, 20-77 yr). Blood was withdrawn every hour from 0700-1900 h and every 2 h from 2100-0500 h. A meal-dependent profile was found for circulating OLI, with basal values (60 +/- 7 ng/L) at 0500 h and rises elicited by each food intake. The highest value (136 +/- 21 ng/L) was obtained at 2100 h. Plasma concentrations and diurnal variations of OLI were similar to those of the other intestinal peptides known to exert an endocrine function. The mean circulating OLI values increased with age, whereas no change was noticed according to sex. The inhibitory effect exerted by the peptides of the OLI family on gastric acid secretion, the meal dependence of their plasma concentrations, and the observed synchronism of their diurnal profile with that previously described for somatostatin make them candidates for an enterogastrone action.

Immunological detection of prohormone convertases in two different proglucagon processing cell lines.

The distribution of the prohormone convertases, PC1/3, PC2 and PC5/6, was determined by immunoblotting in two cell lines. In alpha TC1-6 cells, the proglucagon processing occurred according to the pancreatic A-cell type. In STC-1 cells, proglucagon was processed in a manner reminiscent of the intestinal L-cell type. PC1/3 was undetectable in both proglucagon processing cell lines whereas PC2 displayed a strong immunostaining in the alpha TC1-6 cells and was barely detectable in the STC-1 cells. PC5/6 was detected as a 70 kDa protein in both cell lines. These results suggest a possible role of PC2 in the processing of proglucagon into glucagon in the A-cells, whereas in L-cells it would require still undetermined endoproteases.

Miniglucagon production from glucagon: an extracellular processing of a hormone used as a prohormone.

Glucagon is secondarily processed into its C-terminal (19-29) fragment, referred to as 'miniglucagon', which modulates the glucagon action. This extracellular processing, occurring at the level of of the glucagon target cells, is due to the presence at the cell surface of a new 100-kDa processing enzyme with characteristics of both thiol- and metalloprotease.

Miniglucagon: a local regulator of islet physiology.

Miniglucagon, or glucagon-[19-29], is partially processed from glucagon in its target tissues where it modulates the glucagon action. In the islets of Langerhans, the glucagon-producing A cells contain miniglucagon at a significant level (2-5% of the glucagon content). We studied a possible control of insulin release by miniglucagon using as a model the MIN6 cell line. Miniglucagon, in the 10(-14) to 10(-9) M range, inhibited insulin release induced by glucose, glucagon, tGLP-1, or glibenclamide by 85-100% with an IC50 close to 1 pM. While no change in the cyclic AMP content was noted, Ca2+ influx was reduced in parallel with the inhibition of insulin release. Use of pharmacological modulators of L-type voltage-sensitive Ca2+ channels and bacterial toxins indicates that miniglucagon blocks insulin release by closing this type of channel via a pertussis toxin-sensitive G protein. Miniglucagon is a novel, possibly physiologically relevant, local regulator of islet function.

Metabolic clearance rates of oxyntomodulin and glucagon in the rat: contribution of the kidney.

The half-life (t1/2) and metabolic clearance rate (MCR) of exogenous natural porcine oxyntomodulin (porcine OXM) and the synthetic analog of rat oxyntomodulin, [Nle27]-OXM (rat OXM), were compared with that of glucagon in control, sham-operated and acutely nephrectomized rats using the primed-continuous infusion technique. The half-disappearance times for porcine OXM (8.2 +/- 0.5 min) and rat OXM (6.4 +/- 0.5 min) were 3-fold slower than that of glucagon (1.9 +/- 0.1 min). Acute bilateral nephrectomy significantly prolonged the half-disappearance time of rat OXM (8.2 +/- 0.7 min) and glucagon (3.6 +/- 0.4 min) compared with that of sham-operated animals (6.5 +/- 0.8 min and 2.5 +/- 0.2 min, respectively). The mean MCRs were similar for porcine and rat OXM (11.3 +/- 0.7 and 11.9 +/- 0.5 ml.kg-1.min-1) but were 3 times lower than that measured with glucagon (36 +/- 5 ml.kg-1.min-1). Bilateral nephrectomy reduced the MCR of OXM and glucagon by 38% and 34%, respectively. No significant increase in C-terminal glucagon immunoreactivity was noticed during infusion of either porcine or rat OXM, measured directly in plasma, with a specific C-terminal glucagon antiserum or after HPLC. In the course of the glucagon infusion, blood glucose was increased 2-fold, while the same dose of porcine OXM or of rat OXM induced only a small increase over the values in phosphate buffer-infused rats. 10 times higher doses of rat OXM were necessary to obtain a similar hyperglycemic effect. These results indicate that: (1) the metabolism of OXM is 3-fold slower than that of glucagon, (2) renal clearance contributed close to 35% of the overall metabolic plasma extraction for OXM and glucagon and (3) OXM, although effective at a higher dose, when compared with glucagon, displays a hyperglycemic effect probably through the glucagon receptors.

[Oxyntomodulin, a new hormonal marker of intestinal malabsorption syndromes]. / L'oxyntomoduline, nouveau marqueur hormonal des syndromes de malabsorption intestinale.

Plasma oxyntomodulin-like immunoreactivity (OLI) concentrations were found to be significantly elevated in 6 patients with coeliac disease when compared with those observed in 38 healthy subjects. Furthermore, OLI hypersecretion is related to the degree of malabsorption. This marker could be used as a test for detection and follow-up of patients with malabsorptive disorders.

MiniSOX9, a dominant-negative variant in colon cancer cells.

Inherited and acquired changes in pre-mRNA processing have significant roles in human diseases, especially cancer. Characterization of aberrantly spliced mRNAs may thus contribute to understand malignant transformation. We recently reported an anti-oncogenic potential for the SOX9 transcription factor in the colon. For instance, the Sox9 gene knock out in the mouse intestine results in an excess of proliferation with appearance of hyperplasia. SOX9 is expressed in colon cancer cells but its endogenous activity is weak. We looked for SOX9 variants that may impair SOX9 activity in colon cancer cells and we discovered MiniSOX9, a truncated version of SOX9 devoid of transactivation domain as a result of retention of the second intron. A significant overexpression of MiniSOX9 mRNA in human tumor samples compared with their matched normal tissues was observed by real-time reverse transcriptase-PCR. Immunohistochemistry revealed that MiniSOX9 is expressed at high levels in human colon cancer samples whereas it is undetectable in the surrounding healthy tissues. Finally, we discovered that MiniSOX9 behaves as a SOX9 inhibitor, inhibits protein kinase Cα promoter activity and stimulates the canonical Wnt pathway. This potential oncogenic activity of the SOX9 locus gives new insights on its role in colon cancer.

CEACAM1, a SOX9 direct transcriptional target identified in the colon epithelium.

A deletion of the transcription factor SOX9 gene in the mice intestine affects the morphology of the colon epithelium and leads to hyperplasia. Nevertheless, direct transcriptional targets of SOX9 in this tissue are still unknown. A microarray analysis identified the tumor suppressor carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) as a possible SOX9 target gene and we demonstrate here that SOX9 upregulates CEACAM1 in human colonic cells. Moreover, CEACAM1 expression is reduced in colon of SOX9-deficient mouse, suggesting an important function for SOX9 in the transcriptional activation of the CEACAM1 gene. We further identified SOX9-binding sequences in the human and rat CEACAM1 promoters, and an electrophoretic mobility shift together with a chromatin immunoprecipitation provided an additional evidence of the SOX9 binding to the human promoter. In addition, we established that histone acyl-transferase p300 behaves as an SOX9 co-activator of the rat and human CEACAM1promoters. These results highlight CEACAM1 as the first direct target of SOX9 identified in the colon epithelium.

Development of an oxyntomodulin/glicentin C-terminal radioimmunoassay using a "thiol-maleoyl" coupling method for preparing the immunogen.

Oxyntomodulin (OXM) and glicentin, two peptides processed from proglucagon, both contain the glucagon sequence and a C-terminal basic octapeptide, KRNRNNIA extension. A method to produce antibodies, directed specifically toward the C-terminal extension of these two peptides, was developed; it consisted of the use of thioled bovine serum albumin conjugated with the synthetic N-maleoyl C-terminal octapeptide as the immunogen. Three rabbits (FAN, LEG, and PIP) generated antisera with affinity constants close to 5 X 10(10) M-1. In the radioimmunoassay system, these antisera showed a 100% cross-reactivity with OXM, partially purified rat and human glicentin, and the C-terminal 19-37 OXM fragment. They displayed no cross-reactivity toward the glucagon molecule. The cross-reactivity of C-terminal fragments of OXM demonstrated that the epitope involves the C-terminal hexapeptide and that the two last amino acid residues are essential for the binding. The high-performance liquid chromatography elution profiles of human jejunum or rat intestinal extracts obtained by radioimmunoassay with LEG antiserum showed two major peaks which had the same retention times as OXM and glicentin markers. Thus, the major end products in the human and rat small intestine are OXM and glicentin. In human or rat pancreas, the two main peaks detected were glucagon and the C-terminal hexapeptide of OXM/glicentin. Small amounts of OXM were also found in pancreas, whereas no significant quantities of glicentin could be detected. The "thiol-maleoyl" coupling method described here, and applied to produce C-terminal OXM/glicentin specific antisera, might be of general use to obtain antibodies against a well-defined epitope.

Cloning and tissue distribution of a new rat olfactory receptor-like (OL2).

Polymerase chain reaction (PCR) was used to clone an intronless cDNA encoding a new member (named OL2) of the G protein-coupled receptor superfamily. The coding region of the rat OL2 receptor gene predicts a seven transmembrane domain receptor of 315 amino acids. OL2 has 46.4 percent amino acid identity with OL1, an olfactory receptor expressed in the developing rat heart, and slightly lower percent indentities with several other olfactory receptors. PCR analysis reveals that the transcript is present mainly in the rat spleen and in a mouse insulin-secreting cell line (MIN6). No correlation was found between the tissue distribution of OL2 and that of the olfaction-related GTP-binding protein Golf alpha subunit. These findings suggest a role for this new hypothetical G-protein coupled receptor and for its still unknown ligand in the spleen and in the insulin-secreting beta cells.

Molecular cloning and tissue distribution of rat sarcosine dehydrogenase.

Sarcosine dehydrogenase (SarDH) is a mitochondrial flavoenzyme involved in the oxidative degradation of choline to glycine. The absence of SarDH activity in humans is genetically transmitted and is the cause of an amino acid metabolism disorder called sarcosinemia. Tryptic fragments of the purified enzyme from rat liver were subjected to Edman degradation and the sequences obtained were used to clone the cDNA encoding the full length protein. The deduced amino acid sequence of SarDH shares an overall similarity of 47% with dimethylglycine dehydrogenase (Me2GlyDH), another flavoenzyme involved in the mitochondrial choline catabolism with a similar FAD-binding domain. Covalent binding of FAD to SarDH was demonstrated by the observation of strong fluorescence at 530 nm under excitation at 450 nm of the enzyme immunoprecipitated under denaturing conditions from liver extracts. The localization of SarDH immunoreactivity in the mitochondrial matrix was confirmed by Western-blot analysis of purified mitochondrial fractions. Finally, the tissue distribution of SarDH was investigated by Northern-blot analysis of total RNA and Western-blot analysis of total protein from several rat tissues. A strong expression in the liver, but also in the lung, pancreas, kidney, thymus, and oviduct was observed. We therefore suggest that the enzymes of the choline catabolism pathway are important also for metabolism in nonhepatic tissues.

alpha-Endosulfine, a new entity in the control of insulin secretion.

ATP-dependent potassium (K ATP) channels occupy a key position in the control of insulin release from the pancreatic beta cell since they couple cell polarity to metabolism. These channels close when more ATP is produced via glucose metabolism. They are also controlled by sulfonylureas, a class of drugs used in type 2 diabetic patients for triggering insulin secretion from beta cells that have lost part of their sensitivity to glucose. We have demonstrated the existence of endogenous counterparts to sulfonylureas which we have called 'endosulfines.' In this review, we describe the discovery, isolation, cloning, and biological features of the high-molecular-mass form, alpha-endosulfine, and discuss its possible role in the physiology of the beta cell as well as in pathology.

Diurnal profile of oxyntomodulin-like immunoreactivity in duodenal ulcer patients.

Plasma concentrations of oxyntomodulin-like immunoreactivity, a group of intestinal peptides capable of mediating an enterogastrone signal, were measured during a 24-h period in 6 duodenal ulcer patients and compared with those of 16 age-matched controls. Each subject was submitted to 18 oxyntomodulin-like immunoreactivity determinations. Four standardized meals were given during the test. Furthermore, each patient was evaluated for peak acid output after pentagastrin stimulation. The values of the duodenal ulcer subjects were predominantly within normal acid secretion limits. Fasting levels, meal-induced variations, and nocturnal production of oxyntomodulin-like immunoreactivity were similar in the two groups. A negative correlation was observed between peak acid output and oxyntomodulin-like immunoreactivity evaluated either as nocturnal production or as maximum nyctohemeral concentration. We conclude that, taken as a whole, duodenal ulcer disease is not caused by a defect in oxyntomodulin-like immunoreactivity secretion. However, this study does not rule out the possibility of a selective deficiency of these peptides in some duodenal ulcer subgroups such as hypersecretory patients.

Characterization of low-affinity binding sites for glibenclamide on the Kir6.2 subunit of the beta-cell KATP channel.

The ATP-sensitive K+ channel, an octameric complex of two structurally unrelated types of subunits, SUR1 and Kir6.2, plays a central role in the physiological regulation of insulin secretion. The sulfonylurea glibenclamide, which trigger insulin secretion by blocking the ATP-sensitive K+ channel, interacts with both high and low affinity binding sites present on beta-cells. The high affinity binding site has been localized on SUR1 but the molecular nature of the low affinity site is still uncertain. In this study, we analyzed the pharmacology of glibenclamide in a transformed COS-7 cell line expressing the rat Kir6.2 cDNA and compared with that of the MIN6 beta cell line expressing natively both the Kir6.2 and the SUR1 subunits. Binding studies and Scatchard analysis revealed the presence of a single class of low affinity binding sites for glibenclamide on the COS/Kir6.2 cells with characteristics similar to that observed for the low affinity site of the MIN6 beta cells.