Abstract
Voltage-gated L-type Ca(2+) -channels (LTCCs) are the target of Ca(2+) -channel blockers (CCBs), which are in clinical use for the evidence-based treatment of hypertension and angina. Their cardiovascular effects are largely mediated by the Ca(v) 1.2-subtype. However, based on our current understanding of their physiological and pathophysiological roles, Ca(v) 1.3 LTCCs also appear as attractive drug targets for the therapy of various diseases, including treatment-resistant hypertension, spasticity after spinal cord injury and neuroprotection in Parkinson's disease. Since CCBs inhibit both Ca(v) 1.2 and Ca(v) 1.3, Ca(v) 1.3-selective inhibitors would be valuable tools to validate the therapeutic potential of Ca(v) 1.3 channel inhibition in preclinical models. Despite a number of publications reporting the discovery of Ca(v) 1.3-selective blockers, their selectivity remains controversial. We conclude that at present no pharmacological tools exist that are suitable to confirm or refute a role of Ca(v) 1.3 channels in cellular responses. We also suggest essential criteria for a small molecule to be considered Ca(v) 1.3-selective.