In support, collapse of the vesicular pH gradient using folimycin only increased synaptopHluorin fluorescence by 50% (Tischbirek et al., 2012). Similarly, the displacement of LTR by APDs was taken as evidence of drug accumulation in SVs. However it is unclear why LTR would
be displaced if the pH gradient is unaffected. One future test to confirm that APDs have no effect on neurotransmitter uptake into SVs would be to utilize recently developed fluorescent false neurotransmitters (Gubernator et al., 2009) to determine any modulation of their uptake and release BMS 354825 by these drugs during KCl-evoked SV turnover. The central hypothesis of the work outlined by Tischbirek et al. (2012) is that APDs are released during SV fusion to inhibit presynaptic sodium channels. However, do APDs remain in the synaptic cleft at micromolar concentrations for a sufficient time to exert their effect? Glutamate is stored in SVs at high millimolar levels. Extensive modeling studies have revealed that released glutamate only remains at such see more concentrations within 100 nm of the release site and even then dissipates to micromolar levels within less than 100 microseconds, a dilution of approximately 100-fold (Diamond and Jahr, 1997 and Raghavachari and Lisman, 2004). If these parameters
were recapitulated for APDs, it would confound their proposed mechanism of action, since drug would be diluted below its IC50 for channel antagonism. However, glutamate is a charged, hydrophilic molecule whose synaptic concentration is controlled by both diffusion and reuptake by transport proteins, whereas APDs are lipophilic molecules with no known transport targets. These factors may retard the exit of APDs from the tight, membrane-delimited synaptic cleft. Importantly, Tischbirek et al. (2012) also demonstrated that sodium channels are inhibited by APDs with far greater potency (two orders of magnitude) when they are in their inactivated all state, suggesting
they may exert a biological effect even after their dilution in the cleft. It will therefore be critical for future studies to determine the APD concentration in the synapse, while considering the clinically relevant circulating free concentration of drug. Finally this study reiterates the extraordinary fact that SVs recycle perfectly well with an altered luminal cargo or indeed no cargo at all (Cousin and Nicholls, 1997). The demonstration by Tischbirek et al. (2012) that key psychoactive drugs are accumulated inside SVs and delivered with high precision provides a potentially useful strategy for designing compounds with an activity-dependent mode of action. By altering the pKa of lead compounds, novel drugs could be designed that are accumulated inside SVs.