Abstract
The blood-brain barrier (BBB) hinders CNS chemotherapy entry for malignant glioma treatment. It is predominantly composed of brain endothelium linked by bicellular (BJ) and tricellular (TJ) tight junctions. Previous studies demonstrated,angubindin-1 inhibited TJ angulin-1 to increase brain and CSF targeted therapy in rodent lung cancer models. We hypothesize angubindin-1 can transiently decrease BBB junctional integrity to increase chemotherapy permeability and prolong rodent glioma model survival. Rat brain endothelial cells were treated with TJ and BJ inhibitors against angulin-1 (angubindin-1 600µg/mL), claudin-3 (C-CPE 200µg/mL) or claudin-5 (C-CPE-MT 200µg/mL). Endothelial integrity was assessed by immunoblotting and cell-cell electrical impedance. Effects of angubindin-1 on efflux transporter P-glycoprotein (PGP) and migration were studied using rat and human derived glioma cells. Rat glioma models were treated with doxil (3 mg/kg), angubindin-1 (10 mg/kg or 30 mg/kg), or combination therapy for assessments on tumor volume, BBB permeability and survival. We observed decreased angulin-1 expression 5 hours after angubindin-1 treatment, with return to baseline by 24 hours (p<0.05). Angubindin-1, CCPE, and CCPE-mt globally reduced endothelial cell-cell integrity, maximally at 4 hours with a return to baseline by 12 hours; with angubindin-1 demonstrating the largest decreased cell-adhesion (angubindin-1 vs control, p< 0.0001). Angubindin-1 also decreased PGP efflux of rhodamine in both endothelial and glioma cells, along with demonstrating a pro-migratory dose-dependent effect on rat glioma cells. Combined angubindin-1 and doxil increased survival in rat glioma models compared with doxil alone (24 days vs. 18 days, p < 0.0001). Day 14 tumor volume was significantly decreased with angubindin-1 and combination treatment respectively (77.5 % vs 81.6 %, p<0.05). Ongoing studies are exploring, angubindin-1’s effect on large CNS drug permeability, TJ localization post BBB disruption and additional combinational treatments in glioma models. Collectively, these findings pose a unique opportunity to disrupt BBB integrity and improve malignant glioma treatment options.