Novel fluorescence-based approaches for the study of biogenic amine transporter localization, activity, and regulation.

Pre-synaptic norepinephrine (NE) and dopamine (DA) transporters (NET and DAT) terminate catecholamine synaptic transmission through reuptake of released neurotransmitter. Recent studies reveal that NET and DAT are tightly regulated by receptor and second messenger-linked signaling pathways. Common approaches for studying these transporters involve use of radiolabeled substrates or antagonists, methods possessing limited spatial resolution and that bear limited opportunities for repeated monitoring of living preparations. To circumvent these issues, we have explored two novel assay platforms that permit temporally resolved quantitation of transport activity and transporter protein localization. To monitor the binding and transport function of NET and DAT in real-time, we have investigated the uptake of the fluorescent organic compound 4-(4-diethylaminostyryl)-N-methylpyridinium iodide (ASP+). We have extended our previous single cell level application of this substrate to monitor transport activity via high-throughput assay platforms. Compared to radiotracer uptake methods, acquisition of ASP+ fluorescence is non-isotopic and allows for continuous, repeated transport measurements on both transfected and native preparations. Secondly, we have extended our application of small-molecule-conjugated fluorescent CdSe/ZnS nanocrystals, or quantum dots (Qdots), to utilize antibody and peptide ligands that can identify surface expressed transporters, receptors and other membrane proteins in living cell systems. Unlike typical organic fluorophores, Qdots are highly resistant to bleaching and can be conjugated to multiple ligands. They can also be illuminated by conventional light sources, yet produce narrow, gaussian emission spectra compatible with multiple target visualization (multiplexing). Together, these approaches offer novel opportunities to investigate changes in transporter function and distribution in real-time with superior spatial and temporal resolution.

NMDA receptor subunit mRNA and protein expression in ethanol-withdrawal seizure-prone and -resistant mice.

BACKGROUND: Ethanol withdrawal seizure-prone (WSP) and -resistant (WSR) mice have been genetically selected for differences in handling-induced convulsion severity during withdrawal from chronic ethanol administration. Importantly, drug-naïve mice from these selected lines also differ in handling-induced convulsion severity. Different N-methyl-D-aspartate (NMDA) receptor subunit and splice variant associations confer varying sensitivities to ethanol, and may play a role in the different behavioral responses of the WSP and WSR mice. METHODS: In situ hybridization of riboprobes was used to characterize NMDA receptor subunit and splice variant mRNA expression in cortex and hippocampus from WSP and WSR mice. In addition, immunoblotting and immunohistochemistry were used to examine the expression of specific NMDA receptor subunits and splice variants in hippocampus and cortex from the selected mouse lines. RESULTS: In situ hybridization of riboprobes indicated that, in brain sections from both WSP and WSR mice, there was a differential regional distribution of mRNA for the mouse NR1, NR2A, NR2B, and NR2C NMDA receptor subunits. However, there were no differences between the selected lines in the hybridization of riboprobes to hippocampal subfields or cortical layers. In addition, hybridization of the probe for a 63-base N1-terminal cassette of ethanol-sensitive NR1 splice variants labeled both cortex and hippocampus. The level of hybridization did not differ across subfields of the hippocampus. Results from Western blot and immunohistochemical experiments also indicated that there were no differences between selected lines in NMDA receptor subunit protein expression. However, there was a correlation between mRNA and protein expression in hippocampus and cortex for each NMDA receptor subunit that was examined. CONCLUSIONS: The data suggest that at the level of both mRNA and protein, NMDA receptor subunit and splice variant expression can be uncoupled from convulsion severity in mice that have been selectively bred for symptoms of ethanol withdrawal.

Metabolism of catecholamines by catechol-O-methyltransferase in cells expressing recombinant catecholamine transporters.

To determine if catechol-O-methyltransferase (COMT) metabolizes catecholamines within cell lines used for heterologous expression of plasmalemmal transporters and alters the measured characteristics of 3H-substrate transport, the uptake of monoamine transporter substrates was assessed in three cell lines (C6 glioma, L-M fibroblast, and HEK293 cells) that had been transfected with the recombinant human transporters. Uptake and cellular retention of 3H-catecholamines was increased by up to fourfold by two COMT inhibitors, tropolone and Ro 41-0960, with potencies similar to those for inhibition of COMT activity, whereas the uptake of two transporter substrates that are not substrates for COMT, [3H]serotonin and [3H]MPP+, was unaffected. Direct measurement of monoamine substrates by HPLC confirmed that tropolone (1 mM) increased the retention of the catecholamines dopamine and norepinephrine, but not the retention of serotonin in HEK293 cells. Saturation analysis of the uptake of [3H]dopamine by C6 cells expressing the dopamine transporter demonstrated that tropolone (1 mM) decreased the apparent Km of transport from 0.61 microM to 0.34 microM without significantly altering the maximal velocity of transport. These data suggest that endogenous COMT activity in mammalian cells may alter neurotransmitter deposition and thus the apparent kinetic characteristics of transport.

Effects of subchronic clozapine and haloperidol on striatal glutamatergic synapses.

Subchronic treatment with haloperidol increases the number of asymmetric glutamate synapses associated with a perforated postsynaptic density in the striatum. To characterize these synaptic changes further, the effects of subchronic (28 days) administration of an atypical antipsychotic, clozapine (30 mg/kg, s.c.), or a typical antipsychotic, haloperidol (0.5 mg/kg, s.c.), on the binding of [3H] MK-801 to the NMDA receptor-linked ion channel complex and on the in situ hybridization of riboprobes for NMDAR2A and 2B subunits and splice variants of the NMDAR1 subunit were examined in striatal preparations from rats. The density of striatal glutamate immunogold labeling associated with nerve terminals of all asymmetric synapses and the immunoreactivity of those asymmetric synapses associated with a perforated postsynaptic density were also examined by electron microscopy. Subchronic neuroleptic administration had no effect on [3H] MK-801 binding to striatal membrane preparations. Both drugs increased glutamate immunogold labeling in nerve terminals of all asymmetric synapses, but only haloperidol increased the density of glutamate immunoreactivity within nerve terminals of asymmetric synapses containing a perforated postsynaptic density. Whereas subchronic administration of clozapine, but not haloperidol, resulted in a significant increase in the hybridization of a riboprobe that labels all splice variants of the NMDAR1 subunit, both drugs significantly decreased the abundance of NMDAR1 subunit mRNA containing a 63-base insert. Neither drug altered mRNA for the 2A subunit, but clozapine significantly increased hybridization of a probe for the 2B subunit. The data suggest that some neuroleptic effects may be mediated by glutamatergic systems and that typical and atypical antipsychotics can have varying effects on the density of glutamate in presynaptic terminals and on the expression of specific NMDA receptor splice variant mRNAs. Alternatively, NMDAR1 subunit splice variants may differentially respond to interactions with glutamate.