Physiology and Function of the Tight Junction

Anderson, Jm; Itallie, Van

doi:10.1101/cshperspect.a002584

Cited by 865 publications

(839 citation statements)

References 115 publications

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“…In contrast to the inhibition of miR‐155, its overexpression did not have a significant effect on the electrical resistance. The electrical resistance of the monolayer is mostly sensitive to the composition of claudins in the TJs 39. Therefore, we suppose that the electrical resistance in OGD/M and OGD/C control cells was similar because of the absence of CLDN1 on the cell membranes in both groups.…”

Section: Discussionmentioning

confidence: 91%

Inhibition of MicroRNA‐155 Supports Endothelial Tight Junction Integrity Following Oxygen‐Glucose Deprivation

Peña-Philippides

Gardiner

Caballero-Garrido

et al. 2018

JAHA

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BackgroundBrain microvascular endothelial cells form a highly selective blood brain barrier regulated by the endothelial tight junctions. Cerebral ischemia selectively targets tight junction protein complexes, which leads to significant damage to cerebral microvasculature. Short noncoding molecules called microRNAs are implicated in the regulation of various pathological states, including endothelial barrier dysfunction. In the present study, we investigated the influence of microRNA‐155 (miR‐155) on the barrier characteristics of human primary brain microvascular endothelial cells (HBMECs).Methods and ResultsOxygen‐glucose deprivation was used as an in vitro model of ischemic stroke. HBMECs were subjected to 3 hours of oxygen‐glucose deprivation, followed by transfections with miR‐155 inhibitor, mimic, or appropriate control oligonucleotides. Intact normoxia control HBMECs and 4 oxygen‐glucose deprivation–treated groups of cells transfected with appropriate nucleotide were subjected to endothelial monolayer electrical resistance and permeability assays, cell viability assay, assessment of NO and human cytokine/chemokine release, immunofluorescence microscopy, Western blot, and polymerase chain reaction analyses. Assessment of endothelial resistance and permeability demonstrated that miR‐155 inhibition improved HBMECs monolayer integrity. In addition, miR‐155 inhibition significantly increased the levels of major tight junction proteins claudin‐1 and zonula occludens protein‐1, while its overexpression reduced these levels. Immunoprecipitation and colocalization analyses detected that miR‐155 inhibition supported the association between zonula occludens protein‐1 and claudin‐1 and their stabilization at the HBMEC membrane. Luciferase reporter assay verified that claudin‐1 is directly targeted by miR‐155.ConclusionsBased on these results, we conclude that miR‐155 inhibition–induced strengthening of endothelial tight junctions after oxygen‐glucose deprivation is mediated via its direct target protein claudin‐1.

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Section: Discussionmentioning

confidence: 91%

Inhibition of MicroRNA‐155 Supports Endothelial Tight Junction Integrity Following Oxygen‐Glucose Deprivation

Peña-Philippides

Gardiner

Caballero-Garrido

et al. 2018

JAHA

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“…29 Overexpression of TMIGD1 in HEK-293 cells increased TEER (Figure 2A), whereas it reduced HEK-293 cell permeability as measured with fluorescently labeled dextran ( Figure 2B). Depleting TMIGD1 in primary human kidney epithelial cells (HK2) by shRNA significantly inhibited TEER ( Figure 2C).…”

Section: Tmigd1 Regulates Teer and Permeabilitymentioning

confidence: 95%

TMIGD1 Is a Novel Adhesion Molecule That Protects Epithelial Cells from Oxidative Cell Injury

Arafa

Bondzie

Rezazadeh

et al. 2015

The American Journal of Pathology

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Oxidative damage to renal tubular epithelial cells is a fundamental pathogenic mechanism implicated in both acute kidney injury and chronic kidney diseases. Because epithelial cell survival influences the outcome of acute kidney injury and chronic kidney diseases, identifying its molecular regulators could provide new insight into pathobiology and possible new therapeutic strategies for these diseases. We have identified transmembrane and immunoglobulin domain-containing 1 (TMIGD1) as a novel adhesion molecule, which is highly conserved in humans and other species. TMIGD1 is expressed in renal tubular epithelial cells and promotes cell survival. The extracellular domain of TMIGD1 contains two putative immunoglobulin domains and mediates self-dimerization. Our data suggest that TMIGD1 regulates transepithelial electric resistance and permeability of renal epithelial cells. TMIGD1 controls cell migration, cell morphology, and protects renal epithelial cells from oxidative-and nutrient-deprivationeinduced cell injury. Hydrogen peroxide-induced oxidative cell injury downregulates TMIGD1 expression and targets it for ubiquitination. Moreover, TMIGD1 expression is significantly affected in both acute kidney injury and in deoxy-corticosterone acetate and sodium chloride (deoxy-corticosterone acetate salt)-induced chronic hypertensive kidney disease mouse models. Taken together, we have identified TMIGD1 as a novel cell adhesion molecule expressed in kidney epithelial cells that protects kidney epithelial cells from oxidative cell injury to promote cell survival. (Am J Pathol 2015 http://dx

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“…Permeability of tight junctions is controlled by claudins and occludins (28). To investigate whether the lack of B 0 AT1 had an impact on tight junction permeability, we measured the amount of the tight-junction markers claudin-2 (Cldn2) and occludin (Ocln) by SDS-PAGE Western blotting (Fig.…”

Section: Slc6a19-deficient Micementioning

confidence: 99%

Impaired Nutrient Signaling and Body Weight Control in a Na+ Neutral Amino Acid Cotransporter (Slc6a19)-deficient Mouse

Bröer

Juelich

Vanslambrouck

et al. 2011

Journal of Biological Chemistry

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Amino acid uptake in the intestine and kidney is mediated by a variety of amino acid transporters. To understand the role of epithelial neutral amino acid uptake in whole body homeostasis, we analyzed mice lacking the apical broad-spectrum neutral (0) amino acid transporter B 0 AT1 (Slc6a19). A general neutral aminoaciduria was observed similar to human Hartnup disorder which is caused by mutations in SLC6A19. Na ؉ -dependent uptake of neutral amino acids into the intestine and renal brushborder membrane vesicles was abolished. No compensatory increase of peptide transport or other neutral amino acid transporters was detected. Mice lacking B 0 AT1 showed a reduced body weight. When adapted to a standard 20% protein diet, B 0 AT1-deficient mice lost body weight rapidly on diets containing 6 or 40% protein. Secretion of insulin in response to food ingestion after fasting was blunted. In the intestine, amino acid signaling to the mammalian target of rapamycin (mTOR) pathway was reduced, whereas the GCN2/ATF4 stress response pathway was activated, indicating amino acid deprivation in epithelial cells. The results demonstrate that epithelial amino acid uptake is essential for optimal growth and body weight regulation.In a typical Western diet humans consume about 80 -100 g of protein per day. Proteins are hydrolyzed by the action of secreted and membrane-bound peptidases into individual amino acids, di-and tripeptides (1). Individual amino acids are taken up by a variety of amino acid transporters, whereas diand tripeptides are absorbed by the peptide transporter PepT1 (SLC15A1) (2). Together this digestive process makes 90 -95% of ingested proteins available to the body. Protein demand is particularly high during growth and development when new proteins are required to build up body mass. In the adult, protein recycling is quite efficient, and only 50 g of protein is needed per day to replace protein lost through urine and feces.The bulk of neutral amino acids is absorbed in the intestine by the neutral amino acid transporter B 0 AT1 (SLC6A19), which is also expressed in the kidney where it mediates reabsorption of neutral amino acids (3). Expression studies in heterologous systems have shown that B 0 AT1 accepts all neutral amino acids with a preference for large neutral amino acids such as branched-chain amino acids and methionine (4, 5). These amino acids are taken up with a K m of about 1 mM, whereas smaller amino acids are taken up with higher K m values. Glycine and proline are poor substrates of B 0 AT1. As a result additional transporters are involved in the uptake of imino acids and glycine, such as PAT1 (SLC36A1), PAT2 (SLC36A2), and IMINO (SLC6A20) (6). Additional transport systems for other neutral amino acids in the kidney and intestine have been proposed; these include a specific intestinal transporter for methionine and phenylalanine (7) and the amino acid antiporter ASCT2 (SLC1A5) as a mediator of small neutral amino acids and glutamine uptake in kidney and intestine (8).Efficient trafficking and sur...

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Physiology and Function of the Tight Junction

Cited by 865 publications

References 115 publications

Inhibition of MicroRNA‐155 Supports Endothelial Tight Junction Integrity Following Oxygen‐Glucose Deprivation

Inhibition of MicroRNA‐155 Supports Endothelial Tight Junction Integrity Following Oxygen‐Glucose Deprivation

TMIGD1 Is a Novel Adhesion Molecule That Protects Epithelial Cells from Oxidative Cell Injury

Impaired Nutrient Signaling and Body Weight Control in a Na+ Neutral Amino Acid Cotransporter (Slc6a19)-deficient Mouse

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