Levels of tight junction protein CLDND1 are regulated by microRNA-124 in the cerebellum of stroke-prone spontaneously hypertensive rats.

The claudin family shows organ- and tissue-specific expression of individual members. Deficiency or aberrant expression of distinct claudins has been reported to be associated with severe pathophysiological consequences. Claudin domain-containing 1 (CLDND1), also known as claudin-25, shows homology to this family of proteins. Furthermore, serum CLDND1-derived peptide antibody levels are elevated in patients with cerebral infarction, as compared with healthy controls. We previously reported that, in the adult murine brain, CLDND1 is abundantly expressed in the cerebellum in common sites of intracerebral hemorrhage, and CLDND1 levels are transiently decreased after hemorrhagic insult. However, regulation of CLDND1 expression levels in cerebrovascular disease is poorly studied, and most regulatory microRNAs remain to be defined. We assessed its expression level, according to the presence of early signs of cerebrovascular disease, in the brain of stroke-prone spontaneously hypertensive rats (SHRSPs) and investigated the microRNA regulation of Cldnd1 mRNA. We investigated the post-transcriptional regulation of Cldnd1 by examining the subcellular distribution of its mRNA and evaluating its translational regulation by microRNA in human brain endothelial cells (HBECs) and in the brain of SHRSPs. Using bioinformatics, we identified a conserved microRNA-124 (miR-124)-binding site in the 3'-untranslated region of Cldnd1 and demonstrated that miR-124 regulates the translation of Cldnd1 mRNA reporters in a sequence-specific manner in luciferase assays. HBECs transfected with an miR-124 mimic showed decreased levels of CLDND1 mRNA in reverse transcription quantitative PCR. miR-124 levels were markedly lower in SHRSP than in Wister Kyoto rat brains, whereas Cldnd1 mRNA and protein levels were significantly higher. In SHRSP brains, Cldnd1 mRNA levels increased with a decrease in miR-124. Therefore, by interacting with Cldnd1 mRNA, miR-124 influences CLDNL1 levels in the brain, thus playing a role in the development of cerebrovascular disease in SHRSPs.

Claudin domain containing 1 contributing to endothelial cell adhesion decreases in presence of cerebellar hemorrhage.

The claudin family comprises four-pass transmembrane proteins involved in the formation of tight junctions (TJs). Relatively recently, claudin domain containing (CLDND) 1, also known as claudin-25, was identified as a novel member of the claudin family. In the present study, we revealed that in the adult murine brain, CLDND1 is abundant in the cerebellum among common sites of intracerebral hemorrhage. Thus, the dynamics of CLDND1 after cerebellar hemorrhage were examined. Both CLDND1 mRNA and protein levels transiently decreased at 24 hr after hemorrhagic insult. For immunostaining, an anti-CLDND1 antibody that recognizes the specific epitope in the extracellular first loop was prepared. Dual immunohistochemical staining with CD31 using coronal cryosections of intact murine cerebellum tissue revealed that CLDND1 is expressed on endothelial cells. We therefore performed an in vitro permeability test using a human brain endothelial cell (HBEC) line to reveal whether CLDND1 contributes to cell adhesion like other claudins. CLDND1 was expressed on HBECs as well as in murine cerebellum tissue, and a strong signal was observed at TJs. RNA interference against CLDND1 decreased both the mRNA and protein levels without cytotoxicity. The permeability to small molecules, but not to large ones, across confluent HBECs increased on CLDND1 knockdown compared with mock-treated cells. These results suggest that the transient decrease of CLDND1 after cerebellar hemorrhage is responsible for low-molecular-weight selective vascular hyperpermeability. © 2017 Wiley Periodicals, Inc.

The retinoic acid receptor-related orphan receptor α positively regulates tight junction protein claudin domain-containing 1 mRNA expression in human brain endothelial cells.

Members of the claudin family play important roles in the formation of tight junctions (TJs) in several tissues. Claudin domain containing 1 (CLDND1) is homologous to this family and localizes to TJs and the cytoplasm when exogenously expressed in cultured epithelial cell lines. Furthermore, serum antibody levels of CLDND1-derived peptides are elevated in patients with cerebral infection, cardiovascular disease or diabetes mellitus as compared to healthy controls. However, CLDND1 transcriptional regulation remains poorly analyzed and most regional transcription factor binding sites remain to be defined. Notably, the CLDND1 promoter contains a putative response element for retinoic acid receptor-related orphan receptor α (RORα), which is involved in the above-mentioned disorders. In this study, we found that Cldnd1 and Rora mRNA levels are correlated in rat tissues and that RORα overexpression in human brain endothelial cells enhanced CLDND1 transcript expression. In addition, siRNA-mediated knockdown of RORα significantly decreased CLDND1 transcription. An electrophoresis mobility shift assay indicated that RORα binds to the identified response element in a sequence-specific manner. Furthermore, luciferase reporter assays confirmed that RORα interacts with the CLDND1 promoter to enhance transcription. Taken together, our findings strongly suggest that CLDND1 is a direct RORα target.