Utilizing Voltage-gated Calcium Channels to Assess the Activity of Cathinone Derivatives at Human Monoamine Transporters

• Main Author: Ruiz, Brian A
• Format: Others
• Published: VCU Scholars Compass 2018
• Subjects: monoamine transporter; psychostimulant; cathinone; dopamine; serotonin; addiction; Cellular and Molecular Physiology
• Online Access: https://scholarscompass.vcu.edu/etd/5547; https://scholarscompass.vcu.edu/cgi/viewcontent.cgi?article=6633&context=etd

Cathinones are psychostimulant compounds heavily implicated as drugs of abuse. They exert their physiological actions at the monoamine transporters, which are responsible for maintaining synaptic neurotransmitter homeostasis. Monoamine transporters produce currents during transport and have been shown to depolarize cell membranes and activate voltage-gated calcium channels in mammalian expression systems. This phenomenon is harnessed in an assay which measures these induced calcium transients, allowing for quantification of pharmacodynamic effects of compounds at monoamine transporters. It is unknown if this electrical coupling occurs in neurons, but the implications if it does are significant. In the current work, fluorescent resonance energy transfer studies of HEK cells expressing hDAT suggest that a subpopulation of monoamine transporters and calcium channels may be interacting directly. Additionally, this work presents calcium assay data comparing several novel methcathinone analogs. Of the compounds tested, a single α-methyl substituent at the α-carbon yields the greatest potency at hDAT. The implications of these results shed light on future psychostimulant studies and further define the physiological relationship of the components of a system used to study these compounds.