Independent and cooperative roles of N-glycans and molecular chaperones in the folding and disulfide bond formation of the low-density lipoprotein (LDL) receptor-related protein

The low-density lipoprotein receptor-related protein (LRP) is a large receptor that contains extensive glycosylation sites and disulfide bonds. Here we analyzed how N-linked glycosylation and molecular chaperones function during LRP folding. Treatment of cells with a glycosylation inhibitor tunicamycin significantly impaired LRP folding, although binding to receptor-associated protein (RAP), a specialized chaperone for LRP, was not affected. The effects of tunicamycin on LRP folding were not due to an inhibition of RAP glycosylation since a mutant RAP that harbors a mutation at its sole glycosylation site was still capable of promoting LRP folding. The roles of N-linked glycosylation and the lectin chaperone, calnexin, in LRP folding were further dissected using LRP minireceptors that carry mutations at individual glycosylation sites. Interestingly, we found that RAP interacts with oxidoreductase ERp57 and mediates its interaction with LRP. Since previous studies have shown that N-glycan-bound calnexin/calreticulin are also capable of recruiting ERp57, our results suggest that N-linked glycosylation and RAP can independently and cooperatively recruit oxidoreductases to facilitate protein folding and proper disulfide bond formation.     

Identification of the minimal functional unit in the low density lipoprotein receptor-related protein for binding the receptor-associated protein (RAP). A conserved acidic residue in the complement-type repeats is important for recognition of RAP

The low density lipoprotein receptor-related protein (LRP), a member of the low density lipoprotein receptor family, mediates the internalization of a diverse set of ligands. The ligand binding sites are located in different regions of clusters consisting of approximately 40 residues, cysteine-rich complement-type repeats (CRs). The 39-40-kDa receptor-associated protein, a folding chaperone/escort protein required for efficient transport of functional LRP to the cell surface, is an antagonist of all identified ligands. To analyze the multisite inhibition by RAP in ligand binding of LRP, we have used an Escherichia coli expression system to produce fragments of the entire second ligand binding cluster of LRP (CR3-10). By ligand affinity chromatography and surface plasmon resonance analysis, we show that RAP binds to all two-repeat modules except CR910. CR10 differs from other repeats in cluster II by not containing a surface-exposed conserved acidic residue between Cys(IV) and Cys(V). By site-directed mutagenesis and ligand competition analysis, we provide evidence for a crucial importance of this conserved residue for RAP binding. We provide experimental evidence showing that two adjacent complement-type repeats, both containing a conserved acidic residue, represent a minimal unit required for efficient binding to RAP.     

RAP,a specialized chaperone,prevents ligand-induced ER retention and degradation of LDL receptor-related endocytic receptors.

The multifunctional low density lipoprotein (LDL) receptor-related protein (LRP) forms a complex with a receptor-associated protein (RAP) within the secretory pathway. RAP inhibits ligand binding to LRP and is required for normal functional expression of LRP in vivo, suggesting a physiological function as a specialized chaperone. We have used RAP-deficient mice, generated by gene targeting, to investigate the role of RAP in the biosynthesis and biological activity of LRP and other members of the LDL receptor gene family in various organs and in embryonic fibroblasts. Our results demonstrate that RAP is required for the proper folding and export of the receptors from the endoplasmic reticulum (ER) by preventing the premature binding of co-expressed ligands. Overexpression of apolipoprotein E (apoE), a high affinity ligand for LRP, results in dramatically reduced cellular LRP expression, an effect that is prevented by co-expression of RAP. RAP thus defines a novel class of molecular chaperones that selectively protect endocytic receptors by binding to newly synthesized receptor polypeptides, thereby preventing ligand-induced aggregation and subsequent degradation in the ER.     

The receptor-associated protein (RAP) interacts with several resident proteins of the endoplasmic reticulum including a glycoprotein related to actin

The receptor-associated protein (RAP) is a chaperone found primarily in the endoplasmic reticulum (ER) that plays a necessary role in the folding and exocytic trafficking of members of the LDL receptor gene family including megalin and the LDL receptor-related protein (LRP). Recently, RAP has been shown to interact with a growing number of proteins including several that are unrelated to the LDL receptor family as well as new members of this rapidly expanding family. Based on these observations, we have applied chemical crosslinking procedures to identify additional novel RAP-interacting proteins, and thereby better characterize the scope of RAP's ER-related function. In this study, we have identified eight proteins with molecular weights of 32, 35, 46, 55, 70, 95, 170, and 200 kDa that interact with endogenous RAP. These proteins were found to associate with RAP in multiple cell types from different species, suggesting that their expression and interactions with RAP are ubiquitous. Results of pulse-chase experiments show that most of the proteins remain sensitive to endoglycosidase-H digestion, and also remain stably associated with RAP over an extended period, suggesting that they are ER resident proteins. All of the RAP-associated proteins appear to be largely soluble as they partition into the aqueous phase following TX-114 detergent extraction. Sequence analysis and immunoblotting of the 46-kDa RAP-associated glycoprotein (gp46) shows that it is structurally and immunologically related to actin. If gp46 is also functionally related to actin as an intracellular structural protein, it may represent a novel component of the putative ER matrix.     

Identification of ERp29, an endoplasmic reticulum lumenal protein, as a new member of the thyroglobulin folding complex

Folding and post-translational modification of the thyroid hormone precursor, thyroglobulin (Tg), in the endoplasmic reticulum (ER) of the thyroid epithelial cells is facilitated by several molecular chaperones and folding enzymes, such as BiP, GRP94, calnexin, protein disulfide isomerase, ERp72, and others. They have been shown to associate simultaneously and/or sequentially with Tg in the course of its maturation, thus forming large heterocomplexes in the ER of thyrocytes. Here we present evidence that such complexes include a novel member, an ER-resident lumenal protein, ERp29, which is present in all mammalian tissues with exceptionally high levels of expression in the secretory cells. ERp29 was induced upon treatment of FRTL-5 rat thyrocytes with the thyroid-stimulating hormone, which is essential for the maintenance of thyroid cells and Tg biosynthesis. Chemical cross-linking followed by the cell lysis and immunoprecipitation of ERp29 or Tg revealed association of these proteins and additionally, immunocomplexes that also included major ER chaperones, BiP and GRP94. Sucrose density gradient analysis indicated co-localization of ERp29 with Tg and BiP in the fractions containing large macromolecular complexes. This was supported by immunofluorescent microscopy showing co-localization of ERp29 with Tg in the putative transport vesicular structures. Affinity chromatography using Tg as an affinity ligand demonstrated that ERp29 might be selectively isolated from the FRTL-5 cell lysate or purified lumenal fraction of rat liver microsomes along with the other ER chaperones. Preferential association with the urea-denatured Tg-Sepharose was indicative of either direct or circuitous ERp29/Tg interactions in a chaperone-like manner. Despite the presence of the C-terminal ER-retrieval signal, significant amounts of ERp29 were also recovered from the culture medium of stimulated thyrocytes, indicating ERp29 secretion. Based on these data, we suggest that the function of ERp29 in thyroid cells is connected with folding and/or secretion of Tg.     

Redox signaling loops in the unfolded protein response

The endoplasmic reticulum (ER) is the first compartment of secretory pathway. It plays a major role in ER chaperone-assisted folding and quality control, including post-translational modification such as disulfide bond formation of newly synthesized secretory proteins. Protein folding and assembly takes place in the ER, where redox conditions are distinctively different from the other organelles and are favorable for disulfide formation. These reactions generate the production of reactive oxygen species (ROS) as a byproduct of thiol/disulfide exchange reaction among ER oxidoreductin 1 (Ero1), protein disulfide isomerase (PDI) and ER client proteins, during the formation of disulfide bonds in nascent or incorrectly folded proteins. When uncontrolled, this phenomenon perturbs ER homeostasis, thus aggravating the accumulation of improperly folded or unfolded proteins in this compartment (ER stress). This results in the activation of an adaptive mechanism named the unfolded protein response (UPR). In mammalian cells, the UPR is mediated by three ER-resident membrane proteins (PERK, IRE1 and ATF6) and regulates the expression of the UPR target genes, which themselves encode ER chaperones, folding enzymes, pro-apoptotic proteins and antioxidants, with the objective of restoring ER homeostatic balance. In this review, we will describe redox dependent activation (ER) and amplification (cytosol) loops that control the UPR and the consequences these regulatory loops have on cell fate and physiology.     

Functional mimicry of the LDL receptor-associated protein through multimerization of a minimized third domain

The LDL receptor-associated protein (RAP) is a ligand for the LDL receptor-related protein (LRP1). The first and third domains of RAP can each bind to one of many sequence-related pairs of complement-type repeats (CR) found within the LRP1 ectodomain. Multiple sites of interaction between the multivalent RAP ligand and the multivalent LRP1 receptor yield strong binding avidity for the complex. The third domain of RAP can be significantly truncated, with material retention of monovalent CR pair-binding affinity, provided that the minimized sequence is stabilized with an intramolecular disulfide bond. We demonstrate that the avidity of full-length RAP for LRP1 in vitro can be partially reconstituted by assembly of truncated, disulfide-linked RAP peptides on tetravalent streptavidin or bivalent immunoglobulin scaffolds. The peptide complex with streptavidin shows pronounced hepatotropism in vivo, replicating the biodistribution of full-length RAP.     

The low density lipoprotein receptor-related protein mediates fibronectin catabolism and inhibits fibronectin accumulation on cell surfaces

Low density lipoprotein receptor-related protein (LRP) is a member of the low density lipoprotein receptor family, which functions as an endocytic receptor for diverse ligands. In this study, we demonstrate that murine embryonic fibroblasts (MEF-2 cells) and 13-5-1 Chinese hamster ovary cells, which are LRP-deficient, accumulate greatly increased levels of cell-surface fibronectin (Fn), compared with LRP-expressing MEF-1 and CHO-K1 cells. Increased Fn was also detected in conditioned medium from LRP-deficient MEF-2 cells; however, biosynthesis of Fn by MEF-1 and MEF-2 cells was not significantly different. When LRP-deficient cells were dissociated from monolayer culture, increased levels of Fn remained with the cells, as determined by cell-surface protein biotinylation, suggesting an intimate relationship with cell surface-binding sites. The LRP antagonist, receptor-associated protein (RAP), promoted Fn accumulation in association with MEF-1 cells, whereas expression of full-length LRP in MEF-2 cells substantially decreased Fn accumulation, confirming the role of LRP in this process. Purified LRP bound directly to immobilized Fn, and this interaction was inhibited by RAP. Furthermore, MEF-1 cells degraded (125)I-Fn at an increased rate, compared with MEF-2 cells. (125)I-Fn degradation by MEF-1 cells was inhibited by RAP. These results demonstrate that LRP functions as a catabolic receptor for Fn. The function of LRP in Fn degradation and the ability of LRP to regulate levels of other plasma membrane proteins represent possible mechanisms whereby LRP prevents Fn accumulation on cell surfaces.     

39 kDa receptor-associated protein is an ER resident protein and molecular chaperone for LDL receptor-related protein.

The low density lipoprotein receptor-related protein (LRP) is a multifunctional endocytic receptor with the ability to bind and endocytose several structurally and functionally distinct ligands. A 39 kDa receptor-associated protein (RAP) inhibits all ligand interactions with LRP in vitro. In the present study, we demonstrate that RAP is an endoplasmic reticulum (ER) resident protein. The tetrapepetide sequence HNEL at the C-terminus of RAP is both necessary and sufficient for RAP retention within the ER. Metabolic labeling combined with cross-linking studies show that RAP interacts with LRP in vivo. Pulse-chase analysis reveals that this association is transient early in the secretory pathway and coincides with LRP aggregation and reduced ligand binding activity. Both internal triplicated LRP binding domains on RAP and multiple RAP binding domains on LRP appear to contribute to the aggregation of LRP and RAP. Dissociation of RAP from LRP results from the lower pH encountered later in the secretory pathway and correlates with an increase in LRP ligand binding activity. Taken together, our results thus suggest that RAP functions intracellularly as a molecular chaperone for LRP and regulates its ligand binding activity along the secretory pathway.     

Premature ligand-receptor interaction during biosynthesis limits the production of growth factor midkine and its receptor LDL receptor-related protein 1

Protein production within the secretory pathway is accomplished by complex but organized processes. Here, we demonstrate that the growth factor midkine interacts with LDL receptor-related protein 1 (LRP1) at high affinity (K(d) value, 2.7 nm) not only at the cell surface but also within the secretory pathway during biosynthesis. The latter premature ligand-receptor interaction resulted in aggregate formation and consequently suppressed midkine secretion and LRP1 maturation. We utilized an endoplasmic reticulum (ER) retrieval signal and an LRP1 fragment, which strongly bound to midkine and the LRP1-specialized chaperone receptor-associated protein (RAP), to construct an ER trapper. The ER trapper efficiently trapped midkine and RAP and mimicked the premature ligand-receptor interaction, i.e. suppressed maturation of the ligand and receptor. The ER trapper also diminished the inhibitory function of LRP1 on platelet-derived growth factor-mediated cell migration. Complementary to these results, an increased expression of RAP was closely associated with midkine expression in human colorectal carcinomas (33 of 39 cases examined). Our results suggest that the premature ligand-receptor interaction plays a role in protein production within the secretory pathway.     

Two structural and functional domains of MESD required for proper folding and trafficking of LRP5/6

How the endoplasmic reticulum (ER) folding machinery coordinates general and specialized chaperones during protein translation and folding remains an important unanswered question. Here, we show two structural domains in MESD, a specialized chaperone for LRP5/6, carry out dual functions. The chaperone domain forms a complex with the immature receptor, maintaining the β-propeller (BP) domain in an interaction competent state for epidermal growth factor-repeat binding. This promotes proper folding of the BP domain, causing a binding switch from the chaperone domain to the escort domain. The escort complex ensures LRP5/6 safe-trafficking from the ER to the Golgi by preventing premature ligand-binding. Inside the Golgi, the BP domain may contain a histidine switch, regulating MESD dissociation and retrieval. Together, we generate a plausible cell biology picture of the MESD/LRP5/6 pathway, suggesting that it is the specialized chaperones, MESD, that serves as the folding template to drive proper folding and safe trafficking of large multidomain proteins LRP5/6.     

Mammalian cell expression of an active site mutant of Pseudomonas exotoxin disrupts LRP1 maturation

Low density lipoprotein receptor-related protein 1, (LRP1) is a large multifunctional receptor that binds more than 25 physiologic ligands. In addition, it functions as the surface receptor for several Rhinoviruses, HIV-tat and Pseudomonas exotoxin (PE). We report that the expression of PE within mammalian cells can serve as a probe of LRP1 maturation and functionality. To avoid cell killing, an enzymatically inactive form of the toxin (PEΔ553) was expressed. A permanent cell line (termed CY301) was established whereby PEΔ553 was expressed continually into the ER of CHO cells. CY301 cells were 100-fold resistant to exogenously added active PE but exhibited no cross-resistance to other toxins. Our studies indicate that PEΔ553 bound to immature LRP1 in the ER, prevented its maturation to the cell surface and thereby produced a toxin resistant phenotype. By confocal microscopy, cell-associated PEΔ553 was localized to the ER and co-localized with LRP1. Further characterization of CY301 cells indicated that RAP, the chaperone that aids in LRP1 folding, was released to the growth media. Thus the intracellular expression of PEΔ553 appears to be a valuable probe of LRP1 maturation and trafficking.     

Functional duplication of ligand-binding domains within low-density lipoprotein receptor-related protein for interaction with receptor associated protein, alpha2-macroglobulin, factor IXa and factor VIII

The low-density lipoprotein receptor-related protein (LRP) binds a range of proteins including receptor associated protein (RAP), activated alpha2-macroglobulin (alpha2M*), factor IXa (FIXa), and factor VIII (FVIII) light chain. The binding is mediated by the complement-type repeats, which are clustered in four distinct regions within LRP. Cluster II of 8 repeats (CR3-10) and cluster IV of 11 repeats (CR21-31) have been implicated in ligand-binding. Previous studies have aimed to identify the cluster II repeats involved in binding alpha2M* and RAP. We now evaluated the binding to RAP, alpha2M*, FIXa and FVIII light chain of triplicate repeat-fragments of not only clusters II but also of cluster IV. Employing surface plasmon resonance analysis, we found that most efficient ligand-binding was displayed by the repeats within region CR4-8 of cluster II and within region CR24-28 of cluster IV. Whereas the binding to RAP could be attributed to two consecutive repeats (CR5-6, CR26-27), combinations of three repeats showed most efficient binding to FIXa (CR6-8, CR26-28), FVIII light chain (CR5-7, CR6-8, CR24-26), and alpha2M* (CR4-6, CR24-26). The results imply that there is an internal functional duplication of complement-type repeats within LRP resulting in two clusters that bind the same ligands.     

Molecular chaperone RAP interacts with LRP1 in a dynamic bivalent mode and enhances folding of ligand-binding regions of other LDLR family receptors

The low-density lipoprotein receptor (LDLR) family of receptors are cell-surface receptors that internalize numerous ligands and play crucial role in various processes, such as lipoprotein metabolism, hemostasis, fetal development, etc. Previously, receptor-associated protein (RAP) was described as a molecular chaperone for LDLR-related protein 1 (LRP1), a prominent member of the LDLR family. We aimed to verify this role of RAP for LRP1 and two other LDLR family receptors, LDLR and vLDLR, and to investigate the mechanisms of respective interactions using a cell culture model system, purified system, and in silico modelling. Upon coexpression of RAP with clusters of the ligand-binding complement repeats (CRs) of the receptors in secreted form in insect cells culture, the isolated proteins had increased yield, enhanced folding, and improved binding properties compared with proteins expressed without RAP, as determined by circular dichroism and surface plasmon resonance. Within LRP1 CR-clusters II and IV, we identified multiple sites comprised of adjacent CR doublets, which provide alternative bivalent binding combinations with specific pairs of lysines on RAP. Mutational analysis of these lysines within each of isolated RAP D1/D2 and D3 domains having high affinity to LRP1 and of conserved tryptophans on selected CR-doublets of LRP1, as well as in silico docking of a model LRP1 CR-triplet with RAP, indicated a universal role for these residues in interaction of RAP and LRP1. Consequently, we propose a new model of RAP interaction with LDLR family receptors based on switching of the bivalent contacts between molecules over time in a dynamic mode.     

Disulfide bonds in ER protein folding and homeostasis

Proteins that are expressed outside the cell must be synthesized, folded, and assembled in a way that ensures they can function in their designate location. Accordingly, these proteins are primarily synthesized in the endoplasmic reticulum (ER), which has developed a chemical environment more similar to that outside the cell. This organelle is equipped with a variety of molecular chaperones and folding enzymes that both assist the folding process, while at the same time exerting tight quality control measures that are largely absent outside the cell. A major post-translational modification of ER-synthesized proteins is disulfide bridge formation, which is catalyzed by the family of protein disulfide isomerases. As this covalent modification provides unique structural advantages to extracellular proteins, multiple pathways to disulfide bond formation have evolved. However, the advantages that disulfide bonds impart to these proteins come at a high cost to the cell. Very recent reports have shed light on how the cell can deal with or even exploit the side reactions of disulfide bond formation to maintain homeostasis of the ER and its folding machinery.     

Receptor-associated protein facilitates proper folding and maturation of the low-density lipoprotein receptor and its class 2 mutants

Familial hypercholesterolemia is the consequence of various mutations in the low-density lipoprotein receptor (LDLR). In the current study, we show that a specialized molecular chaperone, the receptor-associated protein (RAP), promotes proper folding and subsequent exocytic trafficking of the wild-type LDLR and several of its class 2 mutants. Co-immunoprecipitation with anti-RAP antibody demonstrates that RAP interacts with the LDLR. Kinetic analyses of LDLR posttranslational folding and maturation in the absence or presence of RAP coexpression show that RAP prevents aggregation and promotes the maturation of the LDLR. Additionally, depletion of Ca(2+) in intact cells impairs LDLR folding, and coexpression of RAP partially corrects this misfolding. Finally, we show that the increased mature cell surface LDLR in the presence of RAP coexpression is functional in its ability to endocytose and degrade (125)I-LDL. Taken together, our results show that the folding, trafficking, and maturation of the LDLR and its class 2 mutants are promoted by RAP.