Oxysterol binding protein-related protein 2 (ORP2) is a member of the oxysterol binding protein family, previously shown to bind 25-hydroxycholesterol and implicated in cellular cholesterol metabolism. We show here that ORP2 also binds 22(R)-hydroxycholesterol [22(R)OHC], 7-ketocholesterol, and cholesterol, with 22(R)OHC being the highest affinity ligand of ORP2 (K d 1.4 3 10 28 M). We report the localization of ORP2 on cytoplasmic lipid droplets (LDs) and its function in neutral lipid metabolism using the human A431 cell line as a model. The ORP2 LD association depends on sterol binding: Treatment with 5 mM 22(R)OHC inhibits the LD association, while a mutant defective in sterol binding is constitutively LD bound. Silencing of ORP2 using RNA interference slows down cellular triglyceride hydrolysis. Furthermore, ORP2 silencing increases the amount of (5), and inhibit the processing of sterol regulatory element binding proteins (SREBPs) via binding to the Insig proteins, which retain SREBP/SCAP complexes in the endoplasmic reticulum (ER) (6). The cytosolic oxysterol receptor, oxysterol binding protein (OSBP), was identified in the 1980s (7). Families of OSBP-related proteins (ORPs) have recently been identified in practically all eukaryotic organisms studied (8). Most of the information on the ORP proteins has been obtained using yeast (Saccharomyces cerevisiae) or mammalian cells. The yeast ORPs (Osh proteins) are suggested to play major roles in the intracellular transport of sterols (9), in vesicle budding from the Golgi apparatus (10, 11), and in the establishment of cell polarity (12, 13), while mammalian ORPs have been suggested to participate in the regulation of lipid metabolism, vesicle transport, and cellular signaling (8).All ORPs contain in their C-terminal part a structure designated OSBP-related domain (ORD), which is homologous to the oxysterol binding domain of OSBP (8). In addition to the ORD, most ORPs contain an N-terminal region involved in their subcellular targeting. The N-terminal extensions containing a pleckstrin homology domain target ORP1L Abbreviations: 22(R)OHC, 22(R)-hydroxycholesterol; 25OHC, 25-hydroxycholesterol; CE, cholesteryl ester; CHO, Chinese hamster ovary; ER, endoplasmic reticulum; FCS, fetal calf serum; FFAT, two phenylalanines in an acidic tract; GST, glutathione S-transferase; LD, lipid droplet; mab, monoclonal mouse antibody; mbCD, methyl-b-cyclodextrin; ORD, oxysterol binding protein-related domain; ORP, oxysterol binding protein-related protein; OSBP, oxysterol binding protein; siRNA, short interfering RNA; SREBP, sterol regulatory element binding protein; TG, triglyceride.
Summary N-myc downstream-regulated gene 1 (NDRG1) mutations cause Charcot-Marie-Tooth disease type 4D (CMT4D). However, the cellular function of NDRG1 and how it causes CMT4D are poorly understood. We report that NDRG1 silencing in epithelial cells results in decreased uptake of low-density lipoprotein (LDL) due to reduced LDL receptor (LDLR) abundance at the plasma membrane. This is accompanied by the accumulation of LDLR in enlarged EEA1-positive endosomes that contain numerous intraluminal vesicles and sequester ceramide. Concomitantly, LDLR ubiquitylation is increased but its degradation is reduced and ESCRT (endosomal sorting complex required for transport) proteins are downregulated. Co-depletion of IDOL (inducible degrader of the LDLR), which ubiquitylates the LDLR and promotes its degradation, rescues plasma membrane LDLR levels and LDL uptake. In murine oligodendrocytes, Ndrg1 silencing not only results in reduced LDL uptake but also in downregulation of the oligodendrocyte differentiation factor Olig2. Both phenotypes are rescued by co-silencing of Idol, suggesting that ligand uptake through LDLR family members controls oligodendrocyte differentiation. These findings identify NDRG1 as a novel regulator of multivesicular body formation and endosomal LDLR trafficking. The deficiency of functional NDRG1 in CMT4D might impair lipid processing and differentiation of myelinating cells.
Lysosome-associated protein transmembrane-4b (LAPTM4B) associates with poor prognosis in several cancers, but its physiological function is not well understood. Here we use novel ceramide probes to provide evidence that LAPTM4B interacts with ceramide and facilitates its removal from late endosomal organelles (LEs). This lowers LE ceramide in parallel with and independent of acid ceramidase-dependent catabolism. In LAPTM4B-silenced cells, LE sphingolipid accumulation is accompanied by lysosomal membrane destabilization. However, these cells resist ceramide-driven caspase-3 activation and apoptosis induced by chemotherapeutic agents or gene silencing. Conversely, LAPTM4B overexpression reduces LE ceramide and stabilizes lysosomes but sensitizes to drug-induced caspase-3 activation. Together, these data uncover a cellular ceramide export route from LEs and identify LAPTM4B as its regulator. By compartmentalizing ceramide, LAPTM4B controls key sphingolipid-mediated cell death mechanisms and emerges as a candidate for sphingolipid-targeting cancer therapies.
Hormone secretion by pituitary cells is decreased by roscovitine, an inhibitor of cyclin-dependent kinase 5 (Cdk5). Roscovitine treatment reorganizes cortical actin and ultrastructural analysis demonstrates that roscovitine limits the ability of secretory granules to approach the plasma membrane or one another. Trio, a multifunctional RhoGEF expressed in pituitary cells, interacts with peptidylglycine α-amidating monooxygenase, a secretory granule membrane protein known to affect the actin cytoskeleton. Roscovitine inhibits the ability of Trio to activate Rac, and peptides corresponding to the Cdk5 consensus sites in Trio are phosphorylated by Cdk5. Together, these data suggest that control of the cortical actin cytoskeleton, long known to modulate hormone exocytosis and subsequent endocytosis, involves Cdk5-mediated activation of Trio.
Secretory granules carrying fluorescent cargo proteins are widely used to study granule biogenesis, maturation, and regulated exocytosis. We fused the soluble secretory protein peptidylglycine ␣-hydroxylating monooxygenase (PHM) to green fluorescent protein (GFP) to study granule formation. When expressed in AtT-20 or GH3 cells, the PHM-GFP fusion protein partitioned from endogenous hormone (adrenocorticotropic hormone, growth hormone) into separate secretory granule pools. Both exogenous and endogenous granule proteins were stored and released in response to secretagogue. Importantly, we found that segregation of content proteins is not an artifact of overexpression nor peculiar to GFP-tagged proteins. Neither luminal acidification nor cholesterol-rich membrane microdomains play essential roles in soluble content protein segregation. Our data suggest that intrinsic biophysical properties of cargo proteins govern their differential sorting, with segregation occurring during the process of granule maturation. Proteins that can self-aggregate are likely to partition into separate granules, which can accommodate only a few thousand copies of any content protein; proteins that lack tertiary structure are more likely to distribute homogeneously into secretory granules. Therefore, a simple "self-aggregation default" theory may explain the little acknowledged, but commonly observed, tendency for both naturally occurring and exogenous content proteins to segregate from each other into distinct secretory granules. INTRODUCTIONThe cellular life of secretory proteins begins with the cotranslational translocation of their nascent polypeptide chains into the lumen of the endoplasmic reticulum (ER). These proteins then proceed in the anterograde direction, through the Golgi complex and into the trans-Golgi network (TGN), which is considered a "sorting station" for secretory proteins (Farquhar and Palade, 1981). At the TGN, vesicles destined for different subcellular compartments bud while acquiring their cargo. In all cell types, a "constitutive secretory pathway" delivers soluble and membrane secretory proteins necessary for housekeeping functions to the appropriate compartment (e.g., plasma membrane or endosomes/ lysosomes; Turner and Arvan, 2000). Besides this constitutive pathway, specialized cell types such as endocrine, exocrine, neuroendocrine cells, and neurons possess a "regulated pathway" in which specialized organelles, the secretory granules, store proteins for release in response to an incoming signal (Arvan and Castle, 1998). The soluble proteins found in constitutive vesicles and regulated secretory granules differ, and the processes responsible for this segregation are the object of intensive investigation.Two models, "sorting for entry" and "sorting by retention," both having experimental support, have been proposed to explain how sorting of soluble content proteins occurs (Arvan and Castle, 1998). The sorting for entry hypothesis postulates the existence of one or more "membrane receptors" able to selectivel...
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