Stomatin-like Protein-1 Interacts with Stomatin and Is Targeted to Late Endosomes

The human stomatin-like protein-1 (SLP-1) is a membrane protein with a characteristic bipartite structure containing a stomatin domain and a sterol carrier protein-2 (SCP-2) domain. This structure suggests a role for SLP-1 in sterol/lipid transfer and transport. Because SLP-1 has not been investigated, we first studied the molecular and cell biological characteristics of the expressed protein. We show here that SLP-1 localizes to the late endosomal compartment, like stomatin. Unlike stomatin, SLP-1 does not localize to the plasma membrane. Overexpression of SLP-1 leads to the redistribution of stomatin from the plasma membrane to late endosomes suggesting a complex formation between these proteins. We found that the targeting of SLP-1 to late endosomes is caused by a GYXXΦ (Φ being a bulky, hydrophobic amino acid) sorting signal at the N terminus. Mutation of this signal results in plasma membrane localization. SLP-1 and stomatin co-localize in the late endosomal compartment, they co-immunoprecipitate, thus showing a direct interaction, and they associate with detergent-resistant membranes. In accordance with the proposed lipid transfer function, we show that, under conditions of blocked cholesterol efflux from late endosomes, SLP-1 induces the formation of enlarged, cholesterol-filled, weakly LAMP-2-positive, acidic vesicles in the perinuclear region. This massive cholesterol accumulation clearly depends on the SCP-2 domain of SLP-1, suggesting a role for this domain in cholesterol transfer to late endosomes.Human stomatin-like protein-1 (SLP-1),³ also known as STOML-1, STORP (1), slipin-1 (2), or hUNC-24 (3), is the human orthologue of Caenorhabditis elegans UNC-24 and a member of the stomatin protein family that comprises 5 human members: stomatin (4–6), SLP-1 (1, 7), SLP-2 (8), SLP-3 (9, 10), and podocin (11). SLP-1 is predominantly expressed in the brain, heart, and skeletal muscle (7, 8) and can be identified in most other tissues (1). Its structure contains a hydrophilic N terminus, a 30-residue hydrophobic domain that is thought to anchor the protein to the cytoplasmic side of the membrane, followed by a stomatin/prohibitin/flotillin/HflK/C (SPFH) domain (12) that is also known as prohibitin (PHB) domain (13), and a C-terminal sterol carrier protein-2 (SCP-2)/nonspecific lipid transfer protein domain (14, 15). This unique structure that was first revealed in C. elegans UNC-24 (16) suggests that SLP-1 may be involved in lipid transfer and transport (17).The founder of the family, stomatin, is a major protein of the red blood cell membrane (band 7.2) and is ubiquitously expressed (18). It is missing in red cells of patients with overhydrated hereditary stomatocytosis, a pathological condition characterized by increased permeability of the red cells for monovalent ions and stomatocytic morphology (19, 20). However, the lack of stomatin is not due to a mutation in its gene but rather to a transport defect (21, 22). Stomatin is a monotopic, oligomeric, palmitoylated, cholesterol-binding membrane protein (18) that is associated with lipid rafts (23, 24) or raft-like detergent-resistant membranes (DRMs) (25), serving as a respective marker (26–28). Other stomatin family members like podocin (29, 30) and SLP-3 (9) are also enriched in DRMs. Many SPFH/PHB proteins share this property suggesting that the SPFH/PHB domain plays an important role in lipid raft/DRM targeting (13, 31). Several interactions of stomatin with membrane proteins have been revealed, notably with the acid sensing ion channels (32) and the glucose transporter GLUT1 (33, 34). Interestingly, stomatin functions as a switch of GLUT1 specificity from glucose to dehydroascorbate in the human red blood cell thus increasing vitamin C recycling and compensating the human inability to synthesize vitamin C (35).The C. elegans genome contains 10 members of the stomatin family. Defects in three of these genes (mec-2, unc-1, and unc-24) cause distinct neuropathologic phenotypes, namely uncoordinated movement and defect in mechanosensation, respectively (36, 37). These are explained by dysfunction of the respective stomatin-like proteins in complex with degenerin/epithelial sodium channels that also affects the sensitivity to volatile anesthetics (38, 39). Importantly, MEC-2 and human podocin bind cholesterol and form large supercomplexes with various ion channels thus modulating channel activity (40). The biological functions of the SLP-1 orthologue UNC-24 and stomatin orthologue UNC-1 are associated, because the unc-24 gene controls the distribution or stability of the UNC-1 protein (41). In addition, UNC-24 co-localizes and interacts with MEC-2 and is essential for touch sensitivity (36). Based on these observations, we hypothesize that human stomatin and SLP-1 similarly interact and modify the distribution of each other. These proteins may have important functions in regulating the activity of ion channels in the human brain and muscle tissues. Despite its putative role in cellular lipid distribution, SLP-1 has not been studied to date.In this work, we characterized human SLP-1 as a late endosomal protein and identified an N-terminal GYXXΦ motif as the targeting signal. We found that SLP-1 interacts with stomatin in vitro and in vivo and associates with DRMs. Regarding the proposed lipid transfer function, we showed that SLP-1 induces the formation of large, cholesterol-rich vesicles or vacuoles when cholesterol trafficking from the late endosomes is blocked suggesting a net cholesterol transfer to the late endosomes and/or lysosomes. This effect was clearly attributed to the SCP-2/nonspecific lipid transfer protein domain of SLP-1, in line with the original hypothesis.