Our study revealed an increase of approximately 40-fold in the BCRP-mediated transport of PMX and MTX when the pH was decreased from 7.4 to 5.5. In contrast, only a 2-fold increase was observed for ES. These results indicate a mechanism of transport that is directly dependent on the effective ionization state of the substrates and BCRP. For ES, which retains a constant ionization state throughout the applied pH, the observed Navitoclax mild increase in activity is attributable to the overall changes in the effective ionization state and conformation of BCRP. For MTX and PMX, the marked increase in BCRP transport activity
was likely due to the change in ionization state of MTX and PMX at lowered pH and their intermolecular interactions with BCRP. To further rationalize the molecular basis of the pH dependence, molecular modeling and docking studies were carried out using a homology model of BCRP, which has previously been closely examined in structural and site-directed mutagenesis studies (Am J Physiol Cell Physiol 299: C1100-C1109, 2010). On the basis of docking studies, all model compounds were found to associate with arginine 482 (Arg482) by direct salt-bridge interactions via their negatively charged carboxylate or sulfate groups. However, at lower pH, protonated MTX and PMX formed an additional salt-bridge interaction between their positively charged moieties and the nearby negatively charged selleck products aspartic acid 477
(Asp477) carboxylate side chain. The formation of this “salt-bridge triad” is expected to increase the overall electrostatic interactions between MTX and PMX with BCRP, which can form a rational basis for the pH dependence of the observed enhanced binding selectivity and transport activity. Removal of Arg482 in site-directed mutagenesis studies eliminated this pH dependence, which lends further support to our binding model. These
results shed light on the importance of electrostatic interactions in transport activity and may have important implications in the design of ionizable chemotherapeutics selleck chemicals llc intended for tumors in the acidic microenvironment.”
“Bach1 is a stress-responsive transcriptional factor that is thought to control the expression levels of cytoprotective factors, including heme-oxygenase (HO)-1. In the present study, we investigated the roles of Bach1 in the development of left ventricular (LV) hypertrophy and remodeling induced by transverse aortic constriction (TAC) in vivo using Bach1 gene-deficient (Bach1(-/-)) mice. TAC for 3 weeks in wild-type control (Bach1(+/+)) mice produced LV hypertrophy and remodeling manifested by increased heart weight, histological findings showing increased myocyte cross-sectional area (CSA) and interstitial fibrosis (picro Sirius red staining), reexpressions of ANP, BNP, and beta MHC genes, and echocardiographic findings showing wall thickening, LV dilatation, and reduced LV contraction.