Botryllamide G is an ABCG2 Inhibitor That Improves Lapatinib Delivery in Mouse Brain

Overview

Journal Cancer Biol Ther

Specialties Oncology
Pharmacology

Date 2019 Nov 12

PMID 31709896

Citations 6

Authors

Jonathan D Strope

Cody J Peer

Tristan M Sissung

O Morgan Hall

Phoebe A Huang

Emily M Harris

Kirk R Gustafson

Curtis J Henrich

Dina M Sigano

Gary T Pauly

Joel P Schneider

Susan E Bates

William D Figg

Affiliations

Soon will be listed here.

Abstract

: Transporters comprising the blood-brain barrier complicate delivery of many therapeutics to the central nervous system. The present study ascertained whether the natural product botryllamide G is viable for inhibition of ABCG2 using lapatinib as a probe for ABCB1 and ABCG2-mediated efflux from the brain. : Wild-type and (-/-) mice were treated with botryllamide G and lapatinib ("doublet therapy"), and while a separate cohort of wild-type mice was treated with botryllamide, tariquidar and lapatinib ("triplet therapy"). : Botryllamide G demonstrates biphasic elimination with a rapid distribution, decreasing below the IC of 6.9 µM within minutes, yet with a relatively slower terminal half-life (4.6 h). In (-/-) mice, doublet therapy resulted in a significant increase in brain lapatinib AUC at 8 h (2058 h*ng/mL vs 4007 h*ng/mL; = .031), but not plasma exposure ( = .15). No significant differences were observed after 24 h. Lapatinib brain exposure was greater through 1 h when wild-type mice were administered triplet therapy (298 h*pg/mg vs 120 h*pg/mg; < .001), but the triplet decreased brain AUC through 24 h vs. mice administered lapatinib alone (2878 h*pg/mg vs 4461hr*ng/mL; < .001) and did not alter the brain:plasma ratio. : In summary, the ABCG2 inhibitor, botryllamide G, increases brain exposure to lapatinib in mice lacking , although the combination of botryllamide G and tariquidar increases brain exposure in wild-type mice only briefly (1 h). Additional research is needed to find analogs of this compound that have better pharmacokinetics and pharmacodynamic effects on ABCG2 inhibition.

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