Calcium-Dependent Regulation of the Neuronal Glycine Transporter GlyT2 by M2 Muscarinic Acetylcholine Receptors.

The neuronal glycine transporter GlyT2 modulates inhibitory glycinergic neurotransmission and plays a key role in regulating nociceptive signal progression. The cholinergic system acting through muscarinic acetylcholine receptors (mAChRs) also mediates important regulations of nociceptive transmission being the M2 subtype the most abundantly expressed in the spinal cord. Here we studied the effect of M2 mAChRs stimulation on GlyT2 function co-expressed in a heterologous system with negligible levels of muscarinic receptor activity. We found GlyT2 is down-regulated by carbachol in a calcium-dependent manner. Different components involved in cell calcium homeostasis were analysed to establish a role in the mechanism of GlyT2 inhibition. GlyT2 down-regulation by carbachol was increased by thapsigargin and reduced by internal store depletion, although calcium release from endoplasmic reticulum or mitochondria had a minor role on GlyT2 inhibition. Our results are consistent with a GlyT2 sensitivity to intracellular calcium mobilized by M2 mAChRs in the subcortical area of the plasma membrane. A crucial role of the plasma membrane sodium calcium exchanger NCX is proposed.

Trafficking properties and activity regulation of the neuronal glycine transporter GLYT2 by protein kinase C.

The neuronal glycine transporter GLYT2 controls the availability of the neurotransmitter in glycinergic synapses, and the modulation of its function may influence synaptic transmission. The active transporter is located in membrane rafts and reaches the cell surface through intracellular trafficking. In the present study we prove that GLYT2 constitutively recycles between the cell interior and the plasma membrane by means of a monensin-sensitive trafficking pathway. Also, a regulated trafficking can be triggered by PMA. We demonstrate that PMA inhibits GLYT2 transport by causing net accumulation of the protein in internal compartments through an increase of the internalization rate. In addition, a small increase of plasma membrane delivery and a redistribution of the transporter to non-raft domains is triggered by PMA. A previously identified phorbol-ester-resistant mutant (K422E) displaying an acidic substitution in a regulatory site, exhibits constitutive traffic but, in contrast with the wild-type, fails to show glycine uptake inhibition, membrane raft redistribution and trafficking modulation by PMA. We prove that the action of PMA on GLYT2 involves PKC (protein kinase C)-dependent and -independent pathways, although an important fraction of the effects are PKC-mediated. We show the additional participation of signalling pathways triggered by the small GTPase Rac1 on PMA action. GLYT2 inhibition by PMA and monensin also take place in brainstem primary neurons and synaptosomes, pointing to a GLYT2 trafficking regulation in the central nervous system.

The neuronal glycine transporter GLYT2 associates with membrane rafts: functional modulation by lipid environment.

The neuronal glycine transporter GLYT2 is a plasma membrane protein that removes the neurotransmitter glycine from the synaptic cleft, thereby aiding the pre-synaptic terminal reloading and the termination of the glycinergic signal. Missense mutations in the gene encoding GLYT2 (SLC6A5) cause hyperekplexia in humans. The activity of GLYT2 seems to be highly regulated. In this report, we demonstrate that GLYT2 is associated with membrane rafts in the plasma membrane of brainstem terminals and neurons. The transporter is localized to Triton X-100-insoluble light synaptosomal membranes together with flotillin-1, a marker protein for membrane rafts, in a methyl-beta-cyclodextrin (MbetaCD)-sensitive manner. In brainstem primary neurons, the GLYT2 punctuate pattern visualized by confocal microscopy was modified by cholesterol depletion with MbetaCD, unlike other non-raft neuronal markers. GLYT2-associated gold particles were observed by electron microscopy on purified rafts from brainstem synaptosomes. Furthermore, either in brainstem terminals and cultured neurons, the pharmacological reduction of the levels of raft components, cholesterol and sphingomyelin, impairs both the association of GLYT2 with membrane rafts and its transport activity. Thus, GLYT2 may require membrane raft location for optimal function, and therefore the lipid environment may constitute a new mechanism to modulate GLYT2.

The second intracellular loop of the glycine transporter 2 contains crucial residues for glycine transport and phorbol ester-induced regulation.

Na+ and Cl(-)-coupled glycine transporters control the availability of glycine neurotransmitter in the synaptic cleft of inhibitory glycinergic pathways. In this report, we have investigated the involvement of the second intracellular loop of the neuronal glycine transporter 2 (GLYT2) on the protein conformational equilibrium and the regulation by 4alpha-phorbol 12 myristate 13-acetate (PMA). By substituting several charged (Lys-415, Lys-418, and Lys-422) and polar (Thr-419 and Ser-420) residues for different amino acids and monitoring plasma membrane expression and kinetic behavior, we found that residue Lys-422 is crucial for glycine transport. The introduction of a negative charge in 422, and to a lower extent in neighboring N-terminal residues, dramatically increases transporter voltage dependence as assessed by response to high potassium depolarizing conditions. In addition, [2-(trimethylammonium)ethyl] methanethiosulfonate accessibility revealed a conformational connection between Lys-422 and the glycine binding/permeation site. Finally, we show that the mutation of positions Thr-419, Ser-420, and mainly Lys-422 to acidic residues abolishes the PMA-induced inhibition of transport activity and the plasma membrane transporter internalization. Our results establish a new structural basis for the action of PMA on GLYT2 and suggest a complex nature of the PMA action on this glycine transporter.