Core 1- and core 3-derived mucin-type O-glycans are primary components of the mucus layer in the colon. Reduced mucus thickness and impaired O-glycosylation are observed in human ulcerative colitis. However, how both types of O-glycans maintain mucus barrier function in the colon is unclear. We found that C1galt1 expression, which synthesizes core 1 O-glycans, was detected throughout the colon, whereas C3GnT, which controls core 3 O-glycan formation, was most highly expressed in the proximal colon. Consistent with this, mice lacking intestinal core 1-derived O-glycans (IEC C1galt1−/−) developed spontaneous colitis primarily in the distal colon, whereas mice lacking both intestinal core 1- and core 3-derived O-glycans (DKO) developed spontaneous colitis in both distal and proximal colon. DKO mice showed an early onset and more severe colitis than IEC C1galt1−/− mice. Antibiotic treatment restored the mucus layer and attenuated colitis in DKO mice. Mucins from DKO mice were more susceptible to proteolysis than WT mucins. This study indicates that core 1- and 3-derived O-glycans collectively contribute to the mucus barrier by protecting it from bacterial protease degradation and suggests new therapeutic targets to promote mucus barrier function in colitis patients.
BACKGROUND & AIMS Core 1- and 3-derived mucin-type O-linked oligosaccharides (O-glycans) are major components of the colonic mucus layer. Defective forms of colonic O-glycans, such as Tn antigen, are frequently observed in patients with ulcerative colitis and colorectal cancer, but it is not clear if they contribute to pathogenesis. We investigated whether and how impaired O-glycosylation contributes to development of colitis-associated colorectal cancer using mice lacking intestinal core 1- and 3-derived O-glycans. METHODS We generated mice that lack the core 1- and 3-derived intestinal O-glycans (DKO mice) and analyzed them, along with mice that lack the intestinal epithelial core 1 O-glycans (IEC C1galt1−/− mice) or mice that lack core 3 O-glycans (C3Gnt−/− mice). Intestinal tissues were collected at different time points and analyzed for levels of mucin and Tn antigen, development of colitis, and tumor formation using imaging, quantitative PCR, immunoblot, and ELISA techniques. We also used cellular and genetic approaches, as well as intestinal microbiota depletion, to identify inflammatory mediators and pathways that contribute to disease in DKO and wild-type littermates (controls). RESULTS Intestinal tissues from DKO mice contained higher levels of Tn antigen and had more severe spontaneous chronic colitis than tissues from IEC C1galt1−/− mice, whereas spontaneous colitis was absent in C3GnT−/− and control mice. IEC C1galt1−/− mice and DKO mice developed spontaneous colorectal tumors, although the onset of tumors in the DKO mice was earlier (age 8–9 months) than that in IEC C1galt1−/− mice (around age 12 months). Antibiotic depletion of the microbiota did not cause loss of Tn antigen but did reduce the development of colitis and cancer formation in DKO mice. Colon tissues from DKO mice, but not control mice, contained active forms of caspase-1 and increased caspase-11, which were reduced after antibiotic administration. Supernatants from colon tissues of DKO mice contained increased levels of interleukin-1β and interleukin-18, compared to those from control mice. Disruption of the caspase 1 and caspase 11 genes in DKO mice (DKO/Casp1/11−/− mice) decreased development of colitis, characterized by reduced colonic thickening, hyperplasia, and inflammatory infiltrate, compared with DKO mice. CONCLUSIONS Impaired expression of O-glycans causes colonic mucus barrier breach and subsequent microbiota-mediated activation of caspase 1-dependent inflammasomes in colonic epithelial cells of mice. These processes could contribute to colitis-associated colon cancer in humans.
PURPOSE. This study seeks to characterize corneal functions and complications in a streptozocin (STZ)-induced rat model of type I diabetes mellitus (DM) and to understand the pathogenesis of diabetic keratopathy. METHODS. DM was induced via STZ injection in Sprague-Dawley rats. Body weight, length, and corneal size were measured and compared with the age-matched normal controls. Corneal morphology and histology were evaluated with slit lamp, digital confocal microscopy and hematoxylin and eosin staining. Tear secretion was measured with cotton threads, and corneal sensitivity was determined with an esthesiometer. Protein expression and distribution were assessed with Western blotting and immunohistochemistry. Wound healing was determined using an in vivo corneal epithelial debridement model. RESULTS. Compared with the normal control rats, STZ rats had reduced body weight, and body length, but minimally affected corneal size. No significant changes in ocular surface regularity, corneal thickness, and morphology were noted in diabetic corneas. STZ rats showed stronger Rose Bengal staining, decreased tear secretion, slightly attenuated sensitivity, less innervation, delayed epithelial wound healing, and impaired epidermal growth factor receptor signaling in their corneas. While the expression of adherens junction protein β-catenin, and tight junction proteins occludin and ZO-1 was unchanged, the formation of these junctions after wound closure was delayed. CONCLUSIONS. Pathogenesis of diabetic keratopathy involves multiple tissues and/or cell types and several events including reduced tear secretion, impaired innervation, weakened cell junction, and altered wound responses. These insights may prove useful for the clinical translation of evolving strategies for the management and treatment of diabetic corneal complications.
The corneal epithelium consists of stratified epithelial cells, sparsely interspersed with dendritic cells (DCs) and a dense layer of sensory axons. We sought to assess the structural and functional correlation of DCs and sensory nerves. Two morphologically different DCs, dendriform and round-shaped, were detected in the corneal epithelium. The dendriform DCs were located at the sub-basal space where the nerve plexus resides, with DC dendrites crossing several nerve endings. The round-shaped DCs were closely associated with nerve fiber branching points, penetrating the basement membrane and reaching into the stroma. Phenotypically, the round-shaped DCs were CD86 positive. Trigeminal denervation resulted in epithelial defects with or without total tarsorrhaphy, decreased tear secretion, and the loss of dendriform DCs at the ocular surface. Local DC depletion resulted in a significant decrease in corneal sensitivity, an increase in epithelial defects, and a reduced density of nerve endings at the center of the cornea. Post-wound nerve regeneration was also delayed in the DC-depleted corneas. Taken together, our data show that DCs and sensory nerves are located in close proximity. DCs may play a role in epithelium innervation by accompanying the sensory nerve fibers in crossing the basement membrane and branching into nerve endings.
Material Supplementary 9.DC1http://www.jimmunol.org/content/suppl/2010/06/18/jimmunol.100050
The functions of intraepithelial dendritic cells (DCs) are critical for mucosal innate and adaptive immunity, but little is known about the role of tissue-specific DCs in epithelial homeostasis and tissue repair. By using the epithelial debridement wound model and CD11c-diphtheria toxin receptor mice that express a CD11c promoter-driven diphtheria toxin receptor, we showed that DCs migrate along with the epithelial sheet to cover the wound and that local depletion of DCs resulted in a significant delay in epithelial wound closure. In response to wounding, migratory epithelia produce CXCL10, thymic stromal lymphopoietin, and IL-1 and its antagonist soluble IL-1 receptor antagonist (sIL-1Ra); depletion of corneal DCs reversed their elevated expressions to a different extent, suggesting a DC-mediated positive feedback loop in epithelial gene expression. Furthermore, both CXCL10 and thymic stromal lymphopoietin were localized in migratory epithelia, suggesting that epithelial cells play a key role in DC infiltration and activation in injured corneas. On the other hand, DC depletion resulted in suppressed epithelial AKT activation, increased cell apoptosis, and decreased polymorphonuclear leukocyte infiltration in the healing cornea. These results indicate that DCs and epithelium form a functional entity at mucosal surfaces for maintaining corneal homeostasis and for tissue repair.
NF-B is an inducible transcriptional factor for the expression of multiple genes involved in immunoinflammatory responses, cell proliferation, and survival, thus playing crucial roles in the pathogenesis of many diseases, including cancer, leukemia, and autoimmune diseases (1-4). NF-B primarily exists as the heterodimer consisting of p65 and p50 in the cytoplasm and is sequestered by binding to its inhibitory protein IB (5). Upon signaling, such as by tumor necrosis factor ␣ (TNF␣), IB is phosphorylated and is followed by proteasomemediated degradation, which liberates NF-B to the nucleus thereby activating the target genes.PKA exists in the cytoplasm as an inactivated tetramer holoenzyme composed of dimer catalytic subunits and dimer regulatory subunits, which dissociate upon elevation of cAMP (6 -10). PKAc is also predominantly involved in the IB-NF-B complex in the cytoplasm, and IB sequesters PKAc by masking its catalytic domain (11). Following a variety of extracellular stimuli such as TNF␣, IB is phosphorylated by IKK 2 and degraded by the 26 S proteasome (12, 13). As a consequence, the p65/p50 heterodimer complex is liberated, and the catalytic center of PKAc is exposed, enabling activated PKAc to phosphorylate p65 at 15). This PKA-dependent phosphorylation of p65 facilitates the recruitment of transcription coactivator CBP and DNA binding activity of p65; therefore, activation of PKA augments NF-B-dependent gene expression, and PKAc signaling is considered to up-regulate . With regard to the role of PKAc in NF-B signaling, some claimed that cAMP-dependent PKA activation down-regulated NF-B-dependent transcription by changing its DNA binding ability (18,19), modifying the transactivation domain of p65 (20), or blocking the degradation of IB proteins (21,22).In our previous report, we identified AKIP1 as a novel p65-interacting protein (23). AKIP1 was initially found in breast cancer cells (24) in which it facilitated the nuclear translocation of PKAc (25). We found that AKIP1 appears to serve as a molecular bridge between p65 and PKAc, promoting their interaction and subsequent p65 phosphorylation at Ser-276, thus enhancing NF-B signaling (23). Because NF-B is constitutively activated in some breast cancer cells, endowing them with resistance to apoptosis (26 -28), we hypothesized that the effect of PKA in NF-B cascade is associated with AKIP1 and could be modulated by AKIP1 in a cell type-dependent fashion.In this study, we further investigate the role of PKA in regulating NF-B-dependent transcription in various cell lines with different expression levels of endogenous AKIP1. We provide evidence that in minimal AKIP1-expressing cell lines, elevation of cAMP decreased p65-PKA binding and p65 phosphorylation at Ser-276, which eventually leads to down-regulation of the NF-B-dependent transcription. In contrast, in breast cancer cell lines MDA-MB231 and MCF7 with high AKIP1 expression, the PKA-activating agents increased p65-PKA binding and its phosphorylation and up-regulated the NF-B-dependent transcriptio...
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