Donna Ziemer

Effects of Muclin (Dmbt1) deficiency on the gastrointestinal system.

The Dmbt1 gene encodes alternatively spliced glycoproteins that are either membrane-associated or secreted epithelial products. Functions proposed for Dmbt1 include it being a tumor suppressor, having roles in innate immune defense and inflammation, and being a Golgi-sorting receptor in the exocrine pancreas. The heavily sulfated membrane glycoprotein mucin-like glycoprotein (Muclin) is a Dmbt1 product that is strongly expressed in organs of the gastrointestinal (GI) system. To explore Muclins functions in the GI system, the Dmbt1 gene was targeted to produce Muclin-deficient mice. Muclin-deficient mice have normal body weight gain and are fertile. The Muclin-deficient mice did not develop GI tumors, even when crossed with mice lacking the known tumor suppressor p53. When colitis was induced by dextran sulfate sodium, there was no significant difference in disease severity in Muclin-deficient mice. Also, when acute pancreatitis was induced with supraphysiological caerulein, there was no difference in disease severity in the Muclin-deficient mice. Exocrine pancreatic function was impaired, as measured by attenuated neurohormonal-stimulated amylase release from Muclin-deficient acinar cells. Also, by [(35)S]Met/Cys pulse-chase analysis, traffic of newly synthesized protein to the stimulus-releasable pool was significantly retarded in Muclin-deficient cells compared with wild type. Thus Muclin deficiency impairs trafficking of regulated proteins to a stimulus-releasable pool in the exocrine pancreas.

Decreased gastric bacterial killing and up-regulation of protective genes in small intestine in gastrin-deficient mouse.

Gastrin regulates gastric acid secretion, believed to be primarily responsible for killing ingested microbes. We examined gastric killing of gavaged E. coli in gastrin-deficient mice, which have decreased gastric acid production. Additionally, the expression of intestinal genes involved in epithelial protection were analyzed: the mucus layer glycoprotein muclin, the polymeric Ig receptor, trefoil factor 3, and small proline-rich protein 2a (sprr2a). Gastric pH was 2.5 pH units greater in gastrin-deficient mice, and E. coli survival was increased greater than 20-fold at 10 min after gavage compared to control. Muclin and sprr2a gene expression were significantly increased (2.0- and 2.6-fold) in the intestine, and antibiotic treatment reversed these effects. In conclusion, reduced gastric acid secretion results in increased survival of ingested microorganisms in gastrin-deficient mice. Bacterial survival is associated with increased expression of muclin and sprr2a in the intestine, indicating that these genes play protective roles in the intestine.

Processing of pro-Muclin and divergent trafficking of its products to zymogen granules and the apical plasma membrane of pancreatic acinar cells

Proteins are sorted and packaged into regulated secretory granules at the trans Golgi network but how such granules form is poorly understood. We are studying Muclin, the major sulfated protein of the mouse pancreatic acinar cell, and what its role may be in zymogen granule formation. Muclin behaves as a peripheral membrane protein localized to the lumen of the zymogen granule but the cDNA for this protein predicts it is a type I membrane protein with a short, 16-amino-acid, cytosolic tail (C-Tail). Using domain-specific antibodies, we demonstrate that Muclin is derived from a precursor, pro-Muclin, which is cleaved to produce Muclin and an approximately 80-kDa membrane glycoprotein (p80). Incubation of pulse-labeled cells at < or = 22 degrees C to block exit from the trans Golgi network also blocks cleavage of pro-Muclin but not sulfation, a trans Golgi network event, suggesting that cleavage occurs in a post-Golgi compartment. After cleavage the two products of pro-Muclin diverge with Muclin remaining in the regulated secretory pathway and p80 trafficking to the apical plasma membrane, presumably via the constitutive-like pathway. When transfected into exocrine AR42J cells, Muclin labeling is perinuclear and in large sub-plasma membrane puncta. Transiently transfected AR42J cells have greater immunolabeling for amylase than nontransfected cells, suggesting a role for Muclin in cargo accumulation in the regulated secretory pathway. A construct with the C-Tail deleted targets to small diffusely-distributed puncta and without the large sub-plasma membrane structures. Thus, the C-Tail is required for proper Muclin targeting. When transfected into neuroendocrine AtT-20 cells Muclin is not colocalized with ACTH in cell processes, and it appears to be constitutively trafficked to the plasma membrane, suggesting that Muclin has exocrine-specific information. We present a working model for pro-Muclin as a Golgi cargo receptor for exocrine secretory granule formation at the trans Golgi network.

Developmental expression of a mucinlike glycoprotein (MUCLIN) in pancreas and small intestine of CF mice

The mucinlike glycoprotein MUCLIN, one of two protein products of the CRP-ductin gene, was used to study changes in the expression of sulfated glycoconjugates during the pathogenesis of cystic fibrosis, using the cystic fibrosis transmembrane conductance regulator (CFTR) knockout mouse (CF mouse). We assessed the appearance of dilated lumina containing protein or mucus plugs in pancreatic acini and crypts of the small intestine and quantified MUCLIN protein and CRP-ductin mRNA during postnatal development. In CF mice, the pancreatic acinar lumen was dilated by postnatal day 16 (P16), but MUCLIN protein was first significantly increased by P23 and remained elevated through adulthood compared with normal mice. Similarly, intestinal crypts had CF-like mucus plugs by P16, but MUCLIN protein was first elevated by P23 and remained elevated through adulthood compared with normal mice. In both organs, MUCLIN labeling of the luminal surface was increased concomitantly with dilation and protein or mucus plugging but before upregulation of expression. The morphological changes were then followed by upregulation of MUCLIN protein and CRP-ductin mRNA expression. This is the first direct study of CF pathogenesis and the resultant increase in glycoconjugate gene expression. The data are consistent with CF pathogenesis progressing from an initial alteration in protein secretory dynamics (increased luminal MUCLIN and protein/mucus plugs) to an upregulation of glycoprotein/mucin gene expression, which is expected to exacerbate obstruction of the luminal spaces.The mucinlike glycoprotein MUCLIN, one of two protein products of the CRP-ductin gene, was used to study changes in the expression of sulfated glycoconjugates during the pathogenesis of cystic fibrosis, using the cystic fibrosis transmembrane conductance regulator (CFTR) knockout mouse (CF mouse). We assessed the appearance of dilated lumina containing protein or mucus plugs in pancreatic acini and crypts of the small intestine and quantified MUCLIN protein and CRP-ductin mRNA during postnatal development. In CF mice, the pancreatic acinar lumen was dilated by postnatal day 16( P16), but MUCLIN protein was first significantly increased by P23 and remained elevated through adulthood compared with normal mice. Similarly, intestinal crypts had CF-like mucus plugs by P16, but MUCLIN protein was first elevated by P23 and remained elevated through adulthood compared with normal mice. In both organs, MUCLIN labeling of the luminal surface was increased concomitantly with dilation and protein or mucus plugging but before upregulation of expression. The morphological changes were then followed by upregulation of MUCLIN protein and CRP-ductin mRNA expression. This is the first direct study of CF pathogenesis and the resultant increase in glycoconjugate gene expression. The data are consistent with CF pathogenesis progressing from an initial alteration in protein secretory dynamics (increased luminal MUCLIN and protein/mucus plugs) to an upregulation of glycoprotein/mucin gene expression, which is expected to exacerbate obstruction of the luminal spaces.