Literature DB >> 17392177

Hypoxia disrupts the barrier function of neural blood vessels through changes in the expression of claudin-5 in endothelial cells.

Takashi Koto1, Keiyo Takubo, Susumu Ishida, Hajime Shinoda, Makoto Inoue, Kazuo Tsubota, Yasunori Okada, Eiji Ikeda.   

Abstract

The mechanisms underlying the hypoxia-induced disruption of the barrier function of neural vasculature were analyzed with reference to the expression of claudin-5, a component of tight junctions between neural endothelial cells. The movement of claudin-5 from the cytoplasm to the plasma membrane of cultured confluent brain-derived endothelial (bEND.3) cells was closely correlated with the increase in the transendothelial electrical resistance. Inhibition of the expression of claudin-5 by RNAi resulted in a reduction of transendothelial electrical resistance, indicating a critical role of claudin-5 in the barrier property. Hypoxia (1% O(2)) altered the location of claudin-5 in the plasma membrane and the level of claudin-5 protein in bEND.3 cells, and these changes were accompanied by a decrease in the transendothelial electrical resistance. In vivo the claudin-5 molecules were expressed under normoxia in the plasma membrane of retinal microvascular endothelial cells but were significantly reduced under hypoxic conditions. Tracer experiments revealed that the barrier function of hypoxic retinal vasculature with depressed claudin-5 expression was selectively disrupted against small molecules, which is very similar to the phenotype of claudin-5-deficient mice. These in vitro and in vivo data indicate that claudin-5 is a target molecule of hypoxia leading to the disruption of the barrier function of neural vasculature.

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Year:  2007        PMID: 17392177      PMCID: PMC1829471          DOI: 10.2353/ajpath.2007.060693

Source DB:  PubMed          Journal:  Am J Pathol        ISSN: 0002-9440            Impact factor:   4.307


  44 in total

Review 1.  Multifunctional strands in tight junctions.

Authors:  S Tsukita; M Furuse; M Itoh
Journal:  Nat Rev Mol Cell Biol       Date:  2001-04       Impact factor: 94.444

Review 2.  Tight junction proteins.

Authors:  L González-Mariscal; A Betanzos; P Nava; B E Jaramillo
Journal:  Prog Biophys Mol Biol       Date:  2003-01       Impact factor: 3.667

3.  Protection against hypoxia-induced increase in blood-brain barrier permeability: role of tight junction proteins and NFkappaB.

Authors:  Rachel C Brown; Karen S Mark; Richard D Egleton; Jason D Huber; Amanda R Burroughs; Thomas P Davis
Journal:  J Cell Sci       Date:  2003-02-15       Impact factor: 5.285

4.  Complex phenotype of mice lacking occludin, a component of tight junction strands.

Authors:  M Saitou; M Furuse; H Sasaki; J D Schulzke; M Fromm; H Takano; T Noda; S Tsukita
Journal:  Mol Biol Cell       Date:  2000-12       Impact factor: 4.138

5.  The tight junction-specific protein occludin is a functional target of the E3 ubiquitin-protein ligase itch.

Authors:  Andreas Traweger; Deyu Fang; Yun-Cai Liu; Wolfgang Stelzhammer; Istvan A Krizbai; Fritz Fresser; Hans-Christian Bauer; Hannelore Bauer
Journal:  J Biol Chem       Date:  2002-01-08       Impact factor: 5.157

6.  Matrix metalloproteinase-mediated disruption of tight junction proteins in cerebral vessels is reversed by synthetic matrix metalloproteinase inhibitor in focal ischemia in rat.

Authors:  Yi Yang; Eduardo Y Estrada; Jeffrey F Thompson; Wenlan Liu; Gary A Rosenberg
Journal:  J Cereb Blood Flow Metab       Date:  2006-07-19       Impact factor: 6.200

7.  Production and activation of matrix metalloproteinase-2 in proliferative diabetic retinopathy.

Authors:  Kousuke Noda; Susumu Ishida; Makoto Inoue; Ken-ichi Obata; Yoshihisa Oguchi; Yasunori Okada; Eiji Ikeda
Journal:  Invest Ophthalmol Vis Sci       Date:  2003-05       Impact factor: 4.799

8.  Cerebral microvascular changes in permeability and tight junctions induced by hypoxia-reoxygenation.

Authors:  Karen S Mark; Thomas P Davis
Journal:  Am J Physiol Heart Circ Physiol       Date:  2002-04       Impact factor: 4.733

9.  Localization of claudin-3 in tight junctions of the blood-brain barrier is selectively lost during experimental autoimmune encephalomyelitis and human glioblastoma multiforme.

Authors:  Hartwig Wolburg; Karen Wolburg-Buchholz; Jörg Kraus; Gesa Rascher-Eggstein; Stefan Liebner; Stefan Hamm; Frank Duffner; Ernst-H Grote; Werner Risau; Britta Engelhardt
Journal:  Acta Neuropathol       Date:  2003-02-25       Impact factor: 17.088

10.  Cyclic AMP induces phosphorylation of claudin-5 immunoprecipitates and expression of claudin-5 gene in blood-brain-barrier endothelial cells via protein kinase A-dependent and -independent pathways.

Authors:  Tsutomu Ishizaki; Hideki Chiba; Takashi Kojima; Masato Fujibe; Tamotsu Soma; Hideaki Miyajima; Kunihiko Nagasawa; Ikuo Wada; Norimasa Sawada
Journal:  Exp Cell Res       Date:  2003-11-01       Impact factor: 3.905
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  83 in total

Review 1.  Tight junction in blood-brain barrier: an overview of structure, regulation, and regulator substances.

Authors:  Wei-Ye Liu; Zhi-Bin Wang; Li-Chao Zhang; Xin Wei; Ling Li
Journal:  CNS Neurosci Ther       Date:  2012-06-12       Impact factor: 5.243

2.  Participation of the second extracellular loop of claudin-5 in paracellular tightening against ions, small and large molecules.

Authors:  Christian Piehl; Jörg Piontek; Jimmi Cording; Hartwig Wolburg; Ingolf E Blasig
Journal:  Cell Mol Life Sci       Date:  2010-03-24       Impact factor: 9.261

3.  Paracellular tightness and claudin-5 expression is increased in the BCEC/astrocyte blood-brain barrier model by increasing media buffer capacity during growth.

Authors:  Hans Christian Helms; Helle Sønderby Waagepetersen; Carsten Uhd Nielsen; Birger Brodin
Journal:  AAPS J       Date:  2010-10-22       Impact factor: 4.009

4.  Fabrication of two-layered channel system with embedded electrodes to measure resistance across epithelial and endothelial barriers.

Authors:  Nicholas J Douville; Yi-Chung Tung; Ran Li; Jack D Wang; Mohamed E H El-Sayed; Shuichi Takayama
Journal:  Anal Chem       Date:  2010-03-15       Impact factor: 6.986

5.  Differential effects of hydrocortisone and TNFalpha on tight junction proteins in an in vitro model of the human blood-brain barrier.

Authors:  Carola Förster; Malgorzata Burek; Ignacio A Romero; Babette Weksler; Pierre-Olivier Couraud; Detlev Drenckhahn
Journal:  J Physiol       Date:  2008-02-07       Impact factor: 5.182

6.  Phosphorylation of claudin-5 and occludin by rho kinase in brain endothelial cells.

Authors:  Masaru Yamamoto; Servio H Ramirez; Shinji Sato; Tomomi Kiyota; Ronald L Cerny; Kozo Kaibuchi; Yuri Persidsky; Tsuneya Ikezu
Journal:  Am J Pathol       Date:  2008-01-10       Impact factor: 4.307

7.  Interaction between pericytes and endothelial cells leads to formation of tight junction in hyaloid vessels.

Authors:  Dong Hyun Jo; Jin Hyoung Kim; Jong-Ik Heo; Jeong Hun Kim; Chung-Hyun Cho
Journal:  Mol Cells       Date:  2013-11-08       Impact factor: 5.034

8.  Nerve growth factor-induced protection of brain capillary endothelial cells exposed to oxygen-glucose deprivation involves attenuation of Erk phosphorylation.

Authors:  Shimon Lecht; Hadar Arien-Zakay; Cezary Marcinkiewicz; Peter I Lelkes; Philip Lazarovici
Journal:  J Mol Neurosci       Date:  2009-12-10       Impact factor: 3.444

9.  An experimental platform for systemic drug delivery to the retina.

Authors:  Matthew Campbell; Anh T H Nguyen; Anna-Sophia Kiang; Lawrence C S Tam; Oliviero L Gobbo; Christian Kerskens; Sorcha Ni Dhubhghaill; Marian M Humphries; G-Jane Farrar; Paul F Kenna; Peter Humphries
Journal:  Proc Natl Acad Sci U S A       Date:  2009-10-12       Impact factor: 11.205

10.  Cilostazol strengthens barrier integrity in brain endothelial cells.

Authors:  Shoji Horai; Shinsuke Nakagawa; Kunihiko Tanaka; Yoichi Morofuji; Pierre-Oliver Couraud; Maria A Deli; Masaki Ozawa; Masami Niwa
Journal:  Cell Mol Neurobiol       Date:  2012-12-07       Impact factor: 5.046
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