Guinea pig hippocampal 5-HT1E receptors: a tool for selective drug development

Recent studies have indicated that the serotonin [5-hydroxytryptamine (5-HT)] 1E receptor, originally discovered in human brain tissue, is not expressed in rat or mouse brain. Thus, there have been few reports on 5-HT_1E receptor drug development. However, expression of 5-HT_1E receptor mRNA has been shown in guinea pig brain. To establish this species as an animal model for 5-HT_1E drug development, we identified brain regions that exhibit 5-carboxyamidotryptamine, ritanserin, and LY344864 – insensitive [³H]5-HT binding (characteristic of the 5-HT_1E receptor). In hippocampal homogenates, where 5-HT_1E receptor density was sufficiently high for radioligand binding analysis, 100 nM 5-carboxyamidotryptamine, 30 nM ritanserin, and 100 nM LY344864 were used to mask [³H]5-HT binding at non-5-HT_1E receptors. The K _d of [³H]5-HT was 5.7 ± 0.7 nM and is indistinguishable from the cloned receptor K _d of 6.5 ± 0.6 nM. The affinities of 16 drugs for the cloned and hippocampal-expressed guinea pig 5-HT_1E receptors are essentially identical ( R ² = 0.97). These findings indicate that using these conditions autoradiographical distribution and signal transduction studies of the 5-HT_1E receptor in guinea pig brain are feasible. Using the guinea pig as an animal model should provide important insights into possible functions of this receptor and the therapeutic potential of selective human 5-HT_1E drugs.     

Two Amino Acid Differences in the Sixth Transmembrane Domain Are Partially Responsible for the Pharmacological Differences Between the 5-HT1Dβ and 5-HT1E 5-Hydroxytryptamine Receptors

Abstract: 5-Hydroxytryptamine elicits its physiological effects by interacting with a diverse group of receptors. Two of these receptors, the 5-HT_1Dβ and the 5-HT_1E receptors, are ∼60% identical in the transmembrane domains that presumably form the ligand binding site yet have very different pharmacological properties. Analysis of the pharmacological properties of a series of chimeric 5-HT_1Dβ/5-HT_1E receptors indicates that sequences in the sixth and seventh transmembrane domains are responsible for the differential affinity of 5-carboxamidotryptamine for these two receptors. More detailed analysis shows that two amino acid differences in the sixth transmembrane domain (Ile³³³ and Ser³³⁴ in the 5-HT_1Dβ receptor, corresponding to Lys³¹⁰ and Glu³¹¹ in the 5-HT_1E receptor) are largely responsible for the differential affinities of some, but not all, ligands for the 5-HT_1Dβ and 5-HT_1E receptors. It is likely that these two amino acids subtly determine the overall three-dimensional structure of the receptor rather than interact directly with individual ligands.     

The GRIP domain is a specific targeting sequence for a population of trans-Golgi network derived tubulo-vesicular carriers

Vesicular carriers for intracellular transport associate with unique sets of accessory molecules that dictate budding and docking on specific membrane domains. Although many of these accessory molecules are peripheral membrane proteins, in most cases the targeting sequences responsible for their membrane recruitment have yet to be identified. We have previously defined a novel Golgi targeting domain (GRIP) shared by a family of coiled-coil peripheral membrane Golgi proteins implicated in membrane trafficking. We show here that the docking site for the GRIP motif of p230 is a specific domain of Golgi membranes. By immuno-electron microscopy of HeLa cells stably expressing a green fluorescent protein (GFP)-p230_GRIP fusion protein, we show binding specifically to a subset of membranes of the trans -Golgi network (TGN). Real-time imaging of live HeLa cells revealed that the GFP-p230_GRIP was associated with highly dynamic tubular extensions of the TGN, which have the appearance and behaviour of transport carriers. To further define the nature of the GRIP membrane binding site, in vitro budding assays were performed using purified rat liver Golgi membranes and cytosol from GFP-p230_GRIP-transfected cells. Analysis of Golgi-derived vesicles by sucrose gradient fractionation demonstrated that GFP-p230_GRIP binds to a specific population of vesicles distinct from those labelled for β-COP or γ-adaptin. The GFP-p230_GRIP fusion protein is recruited to the same vesicle population as full-length p230, demonstrating that the GRIP domain is solely proficient as a targeting signal for membrane binding of the native molecule. Therefore, p230 GRIP is a targeting signal for recruitment to a highly selective membrane attachment site on a specific population of trans -Golgi network tubulo-vesicular carriers.