We have investigated the organization, on the plasma membrane and in detergent-insoluble membrane vesicles, of two neuronal glycosylphosphatidylinositolanchored (GPI) proteins: Thy-1, a negative regulator of transmembrane signalling; and prion protein, whose rapid endocytosis and Cu 2ϩ binding suggest that it functions in metal ion uptake. Prion protein occurred on the neuronal surface at high density in domains, located primarily at the cell body, which were relatively soluble in detergent. Thy-1, although much more abundantly expressed on neurons, occurred at lower density over much of the surface of neurites (and in lower abundance at the cell body) in domains that were highly resistant to detergent solubilization. Detergentinsoluble membrane vesicles contained Thy-1 at a density similar to that on the neuronal surface. Vesicles containing each protein could be separated by immunoaffinity isolation; lectin binding showed that they were enriched in different glycoproteins. Our results demonstrate a structural diversity of the domains occupied by functionally different GPI proteins.
Glycosylphosphatidylinositol-anchored prion protein and Thy-1, found in adjacent microdomains or "rafts" on the neuronal surface, traffic very differently and show distinctive differences in their resistance to detergent solubilization. Monovalent immunogold labeling showed that the two proteins were largely clustered in separate domains on the neuronal surface: 86% of prion protein was clustered in domains containing no Thy-1, although 40% of Thy-1 had a few molecules of prion protein associated with it. Only 1% of all clusters contained appreciable levels of both proteins (>3 immunogold label for both). In keeping with this distribution, immunoaffinity isolation of detergent-resistant membranes (DRMs) using the non-ionic detergent Brij 96 yielded prion protein DRMs with little Thy-1, whereas Thy-1 DRMs contained ϳ20% of prion protein. The lipid content of prion protein and Thy-1 DRMs was measured by quantitative nano-electrospray ionization tandem mass spectrometry. In four independent preparations, the lipid content was highly reproducible, with Thy-1 and prion protein DRMs differing markedly from each other and from the total DRM pool from which they were immunoprecipitated. Prion protein DRMs contained significantly more unsaturated, longer chain lipids than Thy-1 DRMs and had 5-fold higher levels of hexosylceramide. The different lipid compositions are in keeping with the different trafficking dynamics and solubility of the two proteins and show that, under the conditions used, DRMs can isolate individual membrane microenvironments. These results further identify unsaturation and glycosylation of lipids as major sources of diversity of raft structure.The separation of membrane lipids into different phases creates diverse microenvironments within a biological membrane (1, 2). In particular, cholesterol is believed to condense with saturated phosphatidylcholine (PC) 1 and sphingomyelin (SM) to form minute patches (40 -100 nm wide) of lipids in a liquid-ordered phase (3-7), creating specialized lipid microenvironments called "rafts" within the disordered fluid phase formed by unsaturated lipids (8). These ordered microdomains control the access and egress of subsets of membrane proteins, regulating signaling systems at the cell surface (9). liquidordered domains resist solubilization in non-ionic detergents (6, 7, 10 -13), enabling them to be isolated as detergent-resistant membranes (DRMs) that float at low density upon gradient centrifugation (14). Lipid-anchored proteins partition into both leaflets of these domains, the glycosylphosphatidylinositol (GPI)-anchored proteins into the outer (surface) layer and the diacylated cytoplasmic proteins into the inner layer (9, 15, 16). The membrane environment of GPI-anchored prion protein (PrP) is of particular interest since it is a candidate for chaperoning the conversion of PrP to the altered pathogenic conformation associated with prion disease (17-19). Immunolabeling shows PrP to be present on the neuronal surface in different, albeit often closely adjacent, d...
Mutations in the retinitis pigmentosa protein gene RP2 account for up to 15% of X-linked retinitis pigmentosa. RP2 is a novel protein of unknown function, which is targeted to the plasma membrane by dual N-terminal acyl-modification. Dual-acylated proteins are targeted to lipid rafts, and some are subject to polarized sorting. Therefore we investigated the organization of RP2 on the plasma membrane. Endogenous RP2 protein was predominantly localized at the plasma membrane, and exogenously expressed green-fluorescent-protein-tagged protein was also targeted to the membrane in a wide range of cultured cells. High levels of endogenous RP2 protein were present in HeLa cells and in the retinal pigment epithelium-derived cell line ARPE19. A significant proportion of RP2 in cultured neuroblastoma cells was associated with detergent-resistant membranes (DRMs), but much less than other dually acylated proteins (e.g. Lyn and Fyn). In contrast, the RP2-interacting protein Arl3 (ADP-ribosylation factor-like 3) was not found to be associated with DRMs. The association of RP2 with DRMs was cholesterol-dependent. In polarized epithelial cells in culture and in vivo, RP2 was present in both the apical and basolateral domains of the plasma membrane. These data show that RP2 is not specific to either domain, unlike some other dually acylated proteins. Interestingly, the level of RP2 protein increased in the epithelial cell line Caco-2 with differentiation and polarization. These data show that RP2 is present on the membrane of all cell types examined both in vitro and in vivo, and that RP2 associates with lipid rafts, suggesting a potential role for the protein in signal transduction.
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