EXPANDING MONOAMINE TRANSPORTERS PHARMACOLOGY USING CALCIUM CHANNELS

Ruchala, Iwona

01 January 2017

Research in drug development meets many challenges including lengthy, complex and costly procedures to identify novel pharmacotherapies. In our lab, we developed a method for fast screening of small molecules that interact with monoamine transports – dopamine and serotonin (DAT, SERT). These membrane proteins play important roles in brain neurotransmission responsible for cognition, motion and pleasure. Dysfunction in dopaminergic and serotonergic systems result in neurological disorders such as depression, Attention Deficit Hyperactivity Disorder (ADHD), schizophrenia and addiction. DAT and SERT are responsible for uptake of dopamine (DA) or serotonin (5HT) into the synapse and they limit neurotransmitter signaling. Drugs that mimic or antagonize actions of endogenous neurotransmitters (DA and 5HT) increase the concentrations of DA and/or 5HT either by blocking the transporter (blockers) or by competing uptake with neurotransmitter (substrate). The uptake of substrates is associated to an inward current that depolarizes the cell membrane. Voltage-gated calcium channels (CaV) can respond to small changes in membrane potential. In our method, we combined permanent cell line expressing the human dopamine transporter (hDAT) or the human serotonin transporter (hSERT) (FlpIn TREx expression system) with transient transfection of CaV. This system works as a tightly electrically coupled system. Cells challenged with substrate of the transports produce detectable Ca2+ signal while monoamine transporter blockers can inhibit these Ca2+ signals. The novelty of this method relies on the ability to discriminate between substrate and blockers of monoamine transporters. Preliminary experiments measuring our optimized cell system in a Flex Station 3 plate reader suggest that the co-expression of a voltage-gated Ca2+ channel, a monoamine transporter and a genetically encoded Ca2+ sensor constitute a rapid screening biosensor to identify active drugs at monoamine transporters. Our novel methodology can rapidly assess drug-effect profile on monoamine transporters and benefit development of new psychotherapeutics for treatment of mental illnesses. It can also be used to characterize mechanism of action of emerging drug of abuse, as well as to discover small molecules with novel drug-effect profile useful in basic neuroscience research.

monoamine transporters

drugs of abuse

amphetamine

HTS

calcium assay

The pharmacology of the sigma-1 receptor

Brimson, James M.

January 2010

The sigma-1 receptor, although originally classified as an opioid receptor is now thought of as distinct receptor class, sharing no homology with any other known mammalian protein. The receptor has been implicated with a number of diseases including cancer and depression. Modulation of the receptors activity with agonists has potential antidepressant activity whereas antagonists lead to death of cancer cells. Using radioligand binding assays, utilizing the cancer cell line MDA-MB-468, which highly expresses the sigma-1 receptor, a series of novel specific, high affinity, sigma-1 receptor ligands have been characterised. These ligands differed from any previous sigma- 1 receptor ligand in that they are very simple ammonium salts, containing a single nitrogen atom and either straight or branched carbon chains. The binding studies revealed that the straight-chain ammonium salts gave nH values of 1 whereas the branched-chain ammonium salts had statistically significant lower nH values. The ammonium salts were tested for sigma-1 receptor activity in vitro using ratiometric Fura-2 calcium assays and the MTS cell proliferation assay. Branched-chain ammonium salts appeared to have sigma-1 receptor antagonist like effects on cytoplasmic calcium and cell proliferation, whereas the straight-chain ammonium salts behaved as sigma-1 receptor agonists. Three ammonium salts stood out as potential effective sigma-1 receptor drugs, the straight-chain ammonium salt dipentylammonium, and two branched-chain ammonium salts, bis(2-ethylhexyl)ammonium and triisopentylammonium. The ammonium salts were then tested in vivo. Dipentylammonium showed significant antidepressant properties when tested in behavioural models for depression and bis(2-ethylhexyl)ammonium and triisopentylammonium were able to significantly inhibit the growth of tumours implanted in mice. Finally I looked at the coupling of the sigma-1 receptor with G-proteins and show that sigma-1 receptor antagonists dose dependently reduce G-protein activity and inhibition of G-proteins enhanced the sigma-1 antagonists' effects of calcium signalling.

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