Solute carrier (SLC) transporters are a large and diverse class of relatively understudied transmembrane proteins. Due to their critical role in cellular homeostasis, physiological processes and... Show moreSolute carrier (SLC) transporters are a large and diverse class of relatively understudied transmembrane proteins. Due to their critical role in cellular homeostasis, physiological processes and disease development, there is a great number of SLCs that have the potential to be viable drug targets for the treatment of disease. Robust assays are required to identify and characterize potential drugs for SLCs, which are often screened in vitro using cell-based or cell-free systems. Conventional assays either require the use of chemical labels, which i) can be invasive and compromise a cell’s physiology, ii) are based on end-point measurements, iii) use cell preparations and/or iv) do not allow screening of a large number of compounds. This thesis presents the development and application of novel label-free assays based on electrical impedance that allow the assessment of functional activity for three human SLCs: the dopamine transporter (DAT, SLC6A3), norepinephrine transporter (NET, SLC6A2) and excitatory amino acid transporters (EAAT, SLC1 family). With the ability to screen and characterize SLC inhibitors, these assays are a new addition to the ever-expanding toolbox for SLC transporters and could prove valuable in drug discovery programs for a wide range of diseases. Show less
Doornbos, M.L.J.; Linden, I. van der; Vereyken, L.; Tresadern, G.; IJzerman, A.P.; Lavreysen, H.; Heitman, L.H. 2018
Label-free cellular assays using a biosensor provide new opportunities for studying G protein-coupled receptor (GPCR) signaling. As opposed to conventional in vitro assays, integrated receptor... Show more Label-free cellular assays using a biosensor provide new opportunities for studying G protein-coupled receptor (GPCR) signaling. As opposed to conventional in vitro assays, integrated receptor-mediated cellular responses are determined in real-time rather than a single downstream signaling pathway. In this study, we examined the potential of a label-free whole cell impedance-based biosensor system (i.e. xCELLigence) to study the pharmacology of one GPCR in particular, the mGlu2 receptor. This receptor is a target for the treatment of several psychiatric diseases such as schizophrenia and depression. After optimization of assay conditions to prevent interference of endogenous glutamate in the culture medium, detailed pharmacological assessments were performed. Concentration-response curves showed a concentration-dependent increase in impedance for agonists and positive allosteric modulators, whereas receptor inhibition by an antagonist or negative allosteric modulator resulted in a concentration-dependent decrease in cellular impedance. Interestingly, constitutive receptor activity was observed that was decreased by LY341495, which therefore behaved as an inverse agonist here, a property that was heretofore unappreciated. This was confirmed by concentration-dependent modulation of LY341495 potency and efficacy by a allosteric modulators. In summary, the use of the xCELLigence system to study mGlu2 receptor pharmacology was validated. This is the first class C GPCR to be characterized extensively by such method, opening new avenues to study receptor pharmacology including inverse agonism and demonstrating its value for future drug discovery efforts of mGlu receptors as well as other GPCRs. Show less
