Rodney Tatum

Inflammation and Disruption of the Mucosal Architecture in Claudin-7–Deficient Mice

BACKGROUND & AIMS Integrity of the intestinal epithelium is required for nutrition absorption and defense against pathogens. Claudins are cell adhesion molecules that localize at tight junctions (TJs); many are expressed in the intestinal tract, but little is known about their functions. Claudin-7 is unique in that it has a stronger basolateral membrane distribution than other claudins, which localize primarily to apical TJs in the intestinal epithelium. We investigated the basolateral functions of claudin-7 and assessed the effects of disruption of Cldn7 in intestines of mice. METHODS We generated Cldn7(-/-) mice and examined their intestines by histology, molecular and cellular biology, and biochemistry approaches. We performed gene silencing experiments in epithelial cell lines using small interfering RNAs (siRNAs). RESULTS The Cldn7(-/-) mice had severe intestinal defects that included mucosal ulcerations, epithelial cell sloughing, and inflammation. Intestines of Cldn7(-/-) mice produced significantly higher levels of cytokines, the nuclear factor κB p65 subunit, and cyclooxygenase 2; they also up-regulated expression of matrix metalloproteinases (MMPs)-3 and -7. siRNA in epithelial cell lines showed that the increased expression of MMP-3 resulted directly from claudin-7 depletion, whereas that of MMP-7 resulted from inflammation. Electron microscopy analysis showed that intestines of Cldn7(-/-) mice had intercellular gaps below TJs and cell matrix loosening. Deletion of Cldn7 reduced expression and altered localization of the integrin α2 subunit in addition to disrupting formation of complexes of claudin-7, integrin α2, and claudin-1 that normally form in epithelial basolateral compartments of intestines. CONCLUSIONS In mice, claudin-7 has non-TJ functions, including maintenance of epithelial cell-matrix interactions and intestinal homeostasis.

Renal salt wasting and chronic dehydration in claudin-7-deficient mice

Claudin-7, a member of the claudin family, is highly expressed in distal nephrons of kidneys and has been reported to be involved in the regulation of paracellular Cl(-) permeability in cell cultures. To investigate the role of claudin-7 in vivo, we generated claudin-7 knockout mice (Cln7(-/-)) by the gene-targeting deletion method. Here we report that Cln7(-/-) mice were born viable, but died within 12 days after birth. Cln7(-/-) mice showed severe salt wasting, chronic dehydration, and growth retardation. We found that urine Na(+), Cl(-), and K(+) were significantly increased in Cln7(-/-) mice compared with that of Cln7(+/+) mice. Blood urea nitrogen and hematocrit were also significantly higher in Cln7(-/-) mice. The wrinkled skin was evident when Cln7(-/-) mice were approximately 1 wk old, indicating that they suffered from chronic fluid loss. Transepidermal water loss measurements showed no difference between Cln7(+/+) and Cln7(-/-) skin, suggesting that there was no transepidermal water barrier defect in Cln7(-/-) mice. Claudin-7 deletion resulted in the dramatic increase of aldosterone synthase mRNA level as early as 2 days after birth. The significant increases of epithelial Na(+) channel alpha, Na(+)-Cl(-) cotransporter, and aquaporin 2 mRNA levels revealed a compensatory response to the loss of electrolytes and fluid in Cln7(-/-) mice. Na(+)-K(+)-ATPase alpha(1) expression level was also greatly increased in distal convoluted tubules and collecting ducts where claudin-7 is normally expressed. Our study demonstrates that claudin-7 is essential for NaCl homeostasis in distal nephrons, and the paracellular ion transport pathway plays indispensable roles in keeping ionic balance in kidneys.

WNK4 phosphorylates ser206 of claudin‐7 and promotes paracellular Cl− permeability

Mutations in WNK4 have been linked to hypertension in PHAII. Paracellular ion transport has been reported to be involved in this disease process; however, the specific molecular target has not been identified. In this study, we found that TJ protein claudin‐7 and WNK4 were partially co‐localized in renal tubules of rat kidney and co‐immunoprecipitated in kidney epithelial cells. The wild‐type and PHAII‐causing mutant, but not the kinase‐dead mutant, phosphorylated claudin‐7. We have identified ser206 in the COOH‐terminus of claudin‐7 as a putative phosphorylation site for WNK4. More importantly, disease‐causing mutant enhanced claudin‐7 phosphorylation and significantly increased paracellular permeability to Cl−.

Necrotizing Enterocolitis in a mouse model leads to widespread renal inflammation, acute kidney injury and disruption of renal tight junction proteins

Background:Necrotizing enterocolitis (NEC) is a devastating condition affecting premature infants and leads to high mortality and chronic morbidity. Severe form of NEC is associated with acute renal failure, fluid imbalance, hyponatremia, and acidosis. We investigated the effect of NEC on tight junction (TJ) proteins in kidneys using a NEC mouse model to investigate the basis for the observed renal dysfunction.Methods:NEC was induced in C57BL/6 mice by formula feeding and subjecting them to periods of hypoxia and cold stress. NEC was confirmed by gross and histological examination. We studied various markers of inflammation in kidneys and investigated changes in expression of several TJ proteins and AQP2 using immunofluorecent staining and western blotting.Results:We found markedly increased expression of NFκB, TGFβ, and ERK1/2 along with claudin-1, -2, -3, -4, -8, and AQP-2 in NEC kidneys. The membrane localization of claudin-2 was altered in the NEC kidneys and its immunostaining signal at TJ was disrupted.Conclusion:NEC led to a severe inflammatory response not only in the gut but also in the kidneys. NEC increased expression of several TJ proteins and caused disruption of claudin-2 in renal tubules. These observed changes can help explain some of the clinical findings observed in NEC.

Detection of Tight Junction Barrier Function In Vivo by Biotin

Tight junctions (TJs) are the most apical component of the junctional complexes in mammalian epithelial cells and form selective paracellular barriers restricting the passage of solutes and ions across the epithelial sheets. Claudins, a TJ integral membrane protein family, play a critical role in regulating paracellular barrier permeability. In the in vitro cell culture system, transepithelial electrical resistance (TER) measurement and the flux of radioisotope or fluorescent labeled molecules with different sizes have been widely used to determine the TJ barrier function. In the in vivo system, the tracer molecule Sulfo-NHS-Biotin was initially used in Xenopus embryo system and subsequently was successfully applied to a number of animal tissues in situ and in different organisms under the experimental conditions to examine the functional integrity of TJs by several laboratories. In this chapter, we will describe the detailed procedures of applying biotin as a paracellular tracer molecule to different in vivo systems to assay TJ barrier function.

Analysis of Claudin Genes in Pediatric Patients with Bartter’s Syndrome

Bartters syndrome is a constellation of symptoms characterized by hyper‐reninemic hypokalemia, metabolic alkalosis, elevated renin and aldosterone, low or normal blood pressure, and hyperplasia of the juxtaglomerular apparatus. So far, five gene mutations in proteins regulating the sodium chloride transport in the thick ascending limb of Henles loop have been described. However, the molecular mechanisms underlying the presentation of hypomagnesemia in some of these patients remains unclear. Claudins are a family of transmembranous proteins within the tight junctions that have been shown to be important for the paracellular movement of ions. Mutations in claudin‐16 have been identified in patients with familial hypomagnesemia with hypercalciuria and nephrocalcinosis. To test the hypothesis that mutations in claudin genes may be involved in the altered magnesium and calcium transport in Bartters syndrome, we began to examine the genes of claudins known to be present in renal tubules in four pediatric patients with Bartters syndrome. All four patients were African Americans with hypomagnesemia and hypercalciuria. In this study, we did not find any mutation in the coding regions of claudin‐2, ‐3, ‐4, ‐7, ‐8, ‐10, ‐11, or ‐16 genes in these patients. However, all patients had a single nucleotide substitution of C for T at the position of 451 of claudin‐8 gene sequence that changes amino acid residue from serine to proline at the position of 151 in the second extracellular domain of claudin‐8 protein. The significance of this known single nucleotide polymorphism remains to be determined.