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Characterization of a novel brain barrier ex vivo insect‐based P‐glycoprotein screening model
Author(s) -
Andersson Olga,
Badisco Liesbeth,
Hansen Ane Håkansson,
Hansen Steen Honoré,
Hellman Karin,
Nielsen Peter Aadal,
Olsen Line Rørbæk,
Verdonck Rik,
Abbott N. Joan,
Vanden Broeck Jozef,
Andersson Gunnar
Publication year - 2014
Publication title -
pharmacology research and perspectives
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.975
H-Index - 27
ISSN - 2052-1707
DOI - 10.1002/prp2.50
Subject(s) - ex vivo , blood–brain barrier , p glycoprotein , medicine , computational biology , in vivo , neuroscience , pharmacology , biology , computer science , microbiology and biotechnology , drug resistance , central nervous system , multiple drug resistance
Abstract In earlier studies insects were proposed as suitable models for vertebrate blood–brain barrier ( BBB ) permeability prediction and useful in early drug discovery. Here we provide transcriptome and functional data demonstrating the presence of a P‐glycoprotein (Pgp) efflux transporter in the brain barrier of the desert locust ( Schistocerca gregaria ). In an in vivo study on the locust, we found an increased uptake of the two well‐known Pgp substrates, rhodamine 123 and loperamide after co‐administration with the Pgp inhibitors cyclosporine A or verapamil. Furthermore, ex vivo studies on isolated locust brains demonstrated differences in permeation of high and low permeability compounds. The vertebrate Pgp inhibitor verapamil did not affect the uptake of passively diffusing compounds but significantly increased the brain uptake of Pgp substrates in the ex vivo model. In addition, studies at 2°C and 30°C showed differences in brain uptake between Pgp‐effluxed and passively diffusing compounds. The transcriptome data show a high degree of sequence identity of the locust Pgp transporter protein sequences to the human Pgp sequence (37%), as well as the presence of conserved domains. As in vertebrates, the locust brain–barrier function is morphologically confined to one specific cell layer and by using a whole‐brain ex vivo drug exposure technique our locust model may retain the major cues that maintain and modulate the physiological function of the brain barrier. We show that the locust model has the potential to act as a robust and convenient model for assessing BBB permeability in early drug discovery.

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