Calnexin discriminates between protein conformational states and functions as a molecular chaperone in vitro.

Although calnexin is thought to function as a molecular chaperone for glycoproteins, a prevalent view is that it cannot distinguish between protein conformational states, binding solely through its lectin site to monoglucosylated oligosaccharides. Using purified components in vitro, calnexin effectively prevented the aggregation not only of glycoproteins bearing monoglucosylated oligosaccharides but also proteins lacking N-glycans, an effect enhanced by ATP. It also suppressed the thermal denaturation of nonglycosylated proteins and enhanced their refolding in conjunction with other cellular components. Calnexin formed stable complexes with unfolded conformers of these proteins but not with the native molecules. Therefore, in addition to being a lectin, calnexin functions as a bona fide molecular chaperone capable of interacting with polypeptide segments of folding glycoproteins.     

Relationship between calnexin and BiP in suppressing aggregation and promoting refolding of protein and glycoprotein substrates

Calnexin (CNX) is a membrane protein of the endoplasmic reticulum that has been defined primarily as a lectin, yet is capable of functioning as a molecular chaperone with non-glycosylated proteins in vitro. Here, we assess the relative contributions of the oligosaccharide- and polypeptide-binding sites of CNX to its in vitro chaperone functions by comparing it with the Hsp70 chaperone of the endoplasmic reticulum, BiP. Both proteins were equally effective in preventing the aggregation of non-glycosylated citrate synthase, indicating that the polypeptide-binding site of CNX is capable of functioning at a level similar to that of Hsp70. However, when confronted with glycoprotein substrates, the lectin site of CNX provided a significant advantage over BiP in suppressing aggregation. CNX also cooperated with BiP and the J domain of Sec63p in the ATP-dependent refolding of glycoprotein and non-glycosylated substrates. The lectin site of CNX was essential for refolding of the glycoprotein. These findings reinforce the function of CNX as a bona fide chaperone and illustrate how its lectin site confers advantages relative to other chaperones when confronted with glycoprotein substrates.     

Lectin-deficient calnexin is capable of binding class I histocompatibility molecules in vivo and preventing their degradation

Calnexin is a membrane-bound lectin of the endoplasmic reticulum (ER) that binds transiently to newly synthesized glycoproteins. By interacting with oligosaccharides of the form Glc(1)Man(9)GlcNAc(2), calnexin enhances the folding of glycoprotein substrates, retains misfolded variants in the ER, and in some cases participates in their degradation. Calnexin has also been shown to bind polypeptides in vivo that do not possess a glycan of this form and to function in vitro as a molecular chaperone for nonglycosylated proteins. To test the relative importance of the lectin site compared with the polypeptide-binding site, we have generated six calnexin mutants defective in oligosaccharide binding using site-directed mutagenesis. Expressed as glutathione S-transferase fusions, these mutants were still capable of binding ERp57, a thiol oxidoreductase, and preventing the aggregation of a nonglycosylated substrate, citrate synthase. They were, however, unable to bind Glc(1) Man(9)GlcNAc(2) oligosaccharide and were compromised in preventing the aggregation of the monoglucosylated substrate jack bean alpha-mannosidase. Two of these mutants were then engineered into full-length calnexin for heterologous expression in Drosophila cells along with the murine class I histocompatibility molecules K(b) and D(b) as model glycoproteins. In this system, lectin site-defective calnexin was able to replace wild type calnexin in forming a complex with K(b) and D(b) heavy chains and preventing their degradation. Thus, at least for class I molecules, the lectin site of calnexin is dispensable for some of its chaperone functions.     

Potent lectin-independent chaperone function of calnexin under conditions prevalent within the lumen of the endoplasmic reticulum

Calnexin is a membrane-bound chaperone of the endoplasmic reticulum (ER) that participates in the folding and quality control of newly synthesized glycoproteins. Binding to glycoproteins occurs through a lectin site with specificity for Glc1Man9GlcNAc2 oligosaccharides as well as through a polypeptide binding site that recognizes non-native protein conformations. The latter interaction is somewhat controversial because it is based on observations that calnexin can suppress the aggregation of non-glycosylated substrates at elevated temperature or at low calcium concentrations, conditions that may affect the structural integrity of calnexin. Here, we examine the ability of calnexin to interact with a non-glycosylated substrate under physiological conditions of the ER lumen. We show that the soluble ER luminal domain of calnexin can indeed suppress the aggregation of non-glycosylated firefly luciferase at 37 degrees C and at the normal resting ER calcium concentration of 0.4 mM. However, gradual reduction of calcium below the resting level was accompanied by a progressive loss of native calnexin structure as assessed by thermal stability, protease sensitivity, intrinsic fluorescence, and bis-ANS binding. These assays permitted the characterization of a single calcium binding site on calnexin with a Kd = 0.15 +/- 0.05 mM. We also show that the suppression of firefly luciferase aggregation by calnexin is strongly enhanced in the presence of millimolar concentrations of ATP and that the Kd for ATP binding to calnexin in the presence of 0.4 mM calcium is 0.7 mM. ATP did not alter the overall stability of calnexin but instead triggered the localized exposure of a hydrophobic site on the chaperone. These findings demonstrate that calnexin is a potent molecular chaperone that is capable of suppressing the aggregation of substrates through polypeptide-based interactions under conditions that exist within the ER lumen.     

Localization of the lectin,ERp57 binding,and polypeptide binding sites of calnexin and calreticulin

Calnexin and calreticulin are membrane-bound and soluble chaperones, respectively, of the endoplasmic reticulum (ER) which interact transiently with a broad spectrum of newly synthesized glycoproteins. In addition to sharing substantial sequence identity, both calnexin and calreticulin bind to monoglucosylated oligosaccharides of the form Glc(1)Man(5-9)GlcNAc(2), interact with the thiol oxidoreductase, ERp57, and are capable of acting as chaperones in vitro to suppress the aggregation of non-native proteins. To understand how these diverse functions are coordinated, we have localized the lectin, ERp57 binding, and polypeptide binding sites of calnexin and calreticulin. Recent structural studies suggest that both proteins consist of a globular domain and an extended arm domain comprised of two sequence motifs repeated in tandem. Our results indicate that the primary lectin site of calnexin and calreticulin resides within the globular domain, but the results also point to a much weaker secondary site within the arm domain which lacks specificity for monoglucosylated oligosaccharides. For both proteins, a site of interaction with ERp57 is centered on the arm domain, which retains approximately 50% of binding compared with full-length controls. This site is in addition to a Zn(2+)-dependent site located within the globular domain of both proteins. Finally, calnexin and calreticulin suppress the aggregation of unfolded proteins via a polypeptide binding site located within their globular domains but require the arm domain for full chaperone function. These findings are integrated into a model that describes the interaction of glycoprotein folding intermediates with calnexin and calreticulin.     

Delineation of the lectin site of the molecular chaperone calreticulin

Calreticulin (CRT) is a soluble molecular chaperone of the endoplasmic reticulum that functions to promote protein folding as well as to retain misfolded proteins. Similar to its membrane-bound paralog calnexin (CNX), CRT is a lectin that preferentially interacts with glycoproteins bearing Glc1Man5-9GlcNAc2 oligosaccharides. Although the lectin site of CNX has been delineated through X-ray crystallographic and mutagenic studies, the corresponding site for CRT has not been as well characterized. To address this issue, we attempted to construct lectin-deficient CRT mutants, using the structure of CNX as a guide to identify potential oligosaccharide-binding residues. Mutation of 4 such CRT residues (Y109, K111, Y128, D317) completely abrogated oligosaccharide binding. In contrast, mutation of CRT residues M131 and D160, which correspond to important residues in the lectin site of CNX, had no effect on oligosaccharide binding. These findings suggest that the organization of the lectin site in CRT largely resembles that of CNX but is not identical. The deficiency in oligosaccharide binding by the mutants was not due to misfolding because they exhibited wild-type protease digestion patterns, were capable of binding the thiol oxidoreductase ERp57, and functioned just as efficiently as wild-type CRT in suppressing the aggregation of the nonglycosylated substrate citrate synthase. However, they were impaired in their ability to suppress the aggregation of the glycosylated substrate jack bean alpha-mannosidase. This provides the first direct demonstration of the importance of CRT's lectin site in suppressing the aggregation of nonnative glycoproteins.     

The interplay between calcium and the in vitro lectin and chaperone activities of calreticulin

The ER resident protein calreticulin fulfills at least two important roles. It works as a chaperone preventing Golgi exit of non-native protein species and enhancing protein folding efficiency in either N-glycan-dependent, lectin chaperone, or classical chaperone, N-glycan-independent, modes and is one of the main calcium buffers in the cell. This last feature is independent from the lectin chaperone properties of the protein as this last activity is also observed in a CRT fragment lacking calcium buffer capacity. Here we study the interplay between calcium and the lectin and chaperone activities of CRT. The affinity of CRT for monoglucosylated glycans measured in solution by equilibrium dialysis and fluorescence anisotropy was not affected by the absence of calcium. Binding of CRT to monoglucosylated neoglycoproteins displaying either native or molten globule-like conformations was also independent of calcium concentration. Moreover, calcium and monoglucosylated glycans stabilized the CRT structure in an apparent additive, independent manner when the protein was subjected to thermal or urea-induced denaturation. In addition, the ability of CRT to decrease the level of aggregation of a chemically denatured monoglucosylated and nonglycosylated protein was also independent of calcium level.     

Structural and functional relationships between the lectin and arm domains of calreticulin

Calreticulin and calnexin are key components in maintaining the quality control of glycoprotein folding within the endoplasmic reticulum. Although their lectin function of binding monoglucosylated sugar moieties of glycoproteins is well documented, their chaperone activity in suppressing protein aggregation is less well understood. Here, we use a series of deletion mutants of calreticulin to demonstrate that its aggregation suppression function resides primarily within its lectin domain. Using hydrophobic peptides as substrate mimetics, we show that aggregation suppression is mediated through a single polypeptide binding site that exhibits a K(d) for peptides of 0.5-1 μM. This site is distinct from the oligosaccharide binding site and differs from previously identified sites of binding to thrombospondin and GABARAP (4-aminobutyrate type A receptor-associated protein). Although the arm domain of calreticulin was incapable of suppressing aggregation or binding hydrophobic peptides on its own, it did contribute to aggregation suppression in the context of the whole molecule. The high resolution x-ray crystal structure of calreticulin with a partially truncated arm domain reveals a marked difference in the relative orientations of the arm and lectin domains when compared with calnexin. Furthermore, a hydrophobic patch was detected on the arm domain that mediates crystal packing and may contribute to calreticulin chaperone function.     

The lectin chaperone calnexin utilizes polypeptide-based interactions to associate with many of its substrates in vivo

Calnexin and calreticulin are molecular chaperones of the endoplasmic reticulum that bind to newly synthesized glycoproteins in part through a lectin site specific for monoglucosylated (Glc(1)Man(7-9)GlcNAc(2)) oligosaccharides. In addition to this lectin-oligosaccharide interaction, in vitro studies have demonstrated that calnexin and calreticulin can bind to polypeptide segments of both glycosylated and nonglycosylated proteins. However, the in vivo relevance of this latter interaction has been questioned. We examined whether polypeptide-based interactions occur between calnexin and its substrates in vivo using the glucosidase inhibitor castanospermine or glucosidase-deficient cells to prevent the formation of monoglucosylated oligosaccharides. We show that if care is taken to preserve weak interactions, the block in lectin-oligosaccharide binding leads to the loss of some calnexin-substrate complexes, but many others remain readily detectable. Furthermore, we demonstrate that calnexin is capable of associating in vivo with a substrate that completely lacks Asn-linked oligosaccharides. The binding of calnexin to proteins that lack monoglucosylated oligosaccharides could not be attributed to nonspecific adsorption nor to its inclusion in protein aggregates. We conclude that both lectin-oligosaccharide and polypeptide-based interactions occur between calnexin and diverse proteins in vivo and that the strength of the latter interaction varies substantially between protein substrates.     

Gentamicin binds to the lectin site of calreticulin and inhibits its chaperone activity

Recently, it became clear that aminoglycoside antibiotics affect protein-protein interactions involving protein disulfide isomerase as well as protein synthesis in the endoplasmic reticulum. In this study, we used affinity column chromatography to screen gentamicin-binding proteins in microsomes derived from bovine kidney in order to learn about the possible mechanisms of gentamicin-associated nephrotoxicity. One of the gentamicin-binding proteins was identified as calreticulin (CRT) by N-terminal amino acid sequence analysis. Interestingly, gentamicin inhibited the chaperone and oxidative refolding activities of CRT when N-glycosylated substrates such as alpha1-antitrypsin and alpha-mannosidase were used as substrates, but it did not inhibit the chaperone activity of CRT when unglycosylated citrate synthase was used. Moreover, CRT suppressed the aggregation of deglycosylated and denatured alpha-mannosidase, but gentamicin did not inhibit its chaperone activity. Experiments with domain mutants suggest that the lectin site of CRT is the main target for gentamicin binding and that binding of gentamicin to this site inhibits the chaperone activity of CRT.     

Glucosidase II and N-glycan mannose content regulate the half-lives of monoglucosylated species in vivo

Glucosidase II (GII) sequentially removes the two innermost glucose residues from the glycan (Glc(3)Man(9)GlcNAc(2)) transferred to proteins. GII also participates in cycles involving the lectin/chaperones calnexin (CNX) and calreticulin (CRT) as it removes the single glucose unit added to folding intermediates and misfolded glycoproteins by the UDP-Glc:glycoprotein glucosyltransferase (UGGT). GII is a heterodimer in which the α subunit (GIIα) bears the active site, and the β subunit (GIIβ) modulates GIIα activity through its C-terminal mannose 6-phosphate receptor homologous (MRH) domain. Here we report that, as already described in cell-free assays, in live Schizosaccharomyces pombe cells a decrease in the number of mannoses in the glycan results in decreased GII activity. Contrary to previously reported cell-free experiments, however, no such effect was observed in vivo for UGGT. We propose that endoplasmic reticulum α-mannosidase-mediated N-glycan demannosylation of misfolded/slow-folding glycoproteins may favor their interaction with the lectin/chaperone CNX present in S. pombe by prolonging the half-lives of the monoglucosylated glycans (S. pombe lacks CRT). Moreover, we show that even N-glycans bearing five mannoses may interact in vivo with the GIIβ MRH domain and that the N-terminal GIIβ G2B domain is involved in the GIIα-GIIβ interaction. Finally, we report that protists that transfer glycans with low mannose content to proteins have nevertheless conserved the possibility of displaying relatively long-lived monoglucosylated glycans by expressing GIIβ MRH domains with a higher specificity for glycans with high mannose content.     

A polypeptide binding conformation of calreticulin is induced by heat shock, calcium depletion, or by deletion of the C-terminal acidic region

It is widely believed that the chaperone activity of calreticulin is mediated by its ability to bind glycoproteins containing monoglucosylated oligosaccharides. However, calreticulin is also a polypeptide binding protein. Here we show that heat shock, calcium depletion, or deletion of the C-terminal acidic domain enhance binding of purified calreticulin to polypeptide substrates and enhance calreticulin's chaperone activity. These conditions also enhance calreticulin oligomerization, but oligomerization per se is not required for enhanced polypeptide binding. In cells, calreticulin oligomerization intermediates accumulate in response to conditions that induce protein misfolding (heat shock and tunicamycin treatments), and upon calcium depletion. Additionally, in cells, calreticulin binds to deglycosylated major histocompatibility complex class I heavy chains when significant levels of calreticulin oligomerization intermediates are induced. Thus, cell stress conditions that generate nonnative substrates of calreticulin also affect the conformational properties of calreticulin itself, and enhance its binding to substrates, independent of substrate glucosylation.     

Expression and characterization of Saccharomyces cerevisiae Cne1p, a calnexin homologue

The calnexin homologue (Cne1p) of Saccharomyces cerevisiae was expressed in Escherichia coli to evaluate its chaperone function. The chaperone function was examined as to the effects on the suppression of thermal denaturation and the enhancement of refolding, using citrate synthase (CS) as a nonspecific chaperone substrate. Cne1p effectively suppressed the thermal denaturation of CS and enhanced the refolding of thermally or chemically denatured CS in a concentration-dependent manner. In addition, the chaperone function of Cne1p was greatly affected in the presence of monoglucosylated oligosaccharides (G1M9) that specifically bind to the lectin site. These results indicated that Cne1p functions as a molecular chaperone in Saccharomyces cerevisiae.     

Retention of glucose units added by the UDP-GLC:glycoprotein glucosyltransferase delays exit of glycoproteins from the endoplasmic reticulum

It has been proposed that the UDP-Glc:glycoprotein glucosyltransferase, an endoplasmic reticulum enzyme that only glucosylates improperly folded glycoproteins forming protein-linked Glc1Man7-9-GlcNAc2 from the corresponding unglucosylated species, participates together with lectin- like chaperones that recognize monoglucosylated oligosaccharides in the control mechanism by which cells only allow passage of properly folded glycoproteins to the Golgi apparatus. Trypanosoma cruzi cells were used to test this model as in trypanosomatids addition of glucosidase inhibitors leads to the accumulation of only monoglucosylated oligosaccharides, their formation being catalyzed by the UDP- Glc:glycoprotein glucosyltransferase. In all other eukaryotic cells the inhibitors produce underglycosylation of proteins and/or accumulation of oliogosaccharides containing two or three glucose units. Cruzipain, a lysosomal proteinase having three potential N-glycosylation sites, two at the catalytic domain and one at the COOH-terminal domain, was isolated in a glucosylated form from cells grown in the presence of the glucosidase II inhibitor 1-deoxynojirimycin. The oligosaccharides present at the single glycosylation site of the COOH-terminal domain were glucosylated in some cruzipain molecules but not in others, this result being consistent with an asynchronous folding of glycoproteins in the endoplasmic reticulum. In spite of not affecting cell growth rate or the cellular general metabolism in short and long term incubations, 1-deoxynojirimycin caused a marked delay in the arrival of cruzipain to lysosomes. These results are compatible with the model proposed by which monoglucosylated glycoproteins may be transiently retained in the endoplasmic reticulum by lectin-like anchors recognizing monoglucosylated oligosaccharides.     

Conformational requirements for glycoprotein reglucosylation in the endoplasmic reticulum

Newly synthesized glycoproteins interact during folding and quality control in the ER with calnexin and calreticulin, two lectins specific for monoglucosylated oligosaccharides. Binding and release are regulated by two enzymes, glucosidase II and UDP-Glc:glycoprotein:glycosyltransferase (GT), which cyclically remove and reattach the essential glucose residues on the N-linked oligosaccharides. GT acts as a folding sensor in the cycle, selectively reglucosylating incompletely folded glycoproteins and promoting binding of its substrates to the lectins. To investigate how nonnative protein conformations are recognized and directed to this unique chaperone system, we analyzed the interaction of GT with a series of model substrates with well defined conformations derived from RNaseB. We found that conformations with slight perturbations were not reglucosylated by GT. In contrast, a partially structured nonnative form was efficiently recognized by the enzyme. When this form was converted back to a nativelike state, concomitant loss of recognition by GT occurred, reproducing the reglucosylation conditions observed in vivo with isolated components. Moreover, fully unfolded conformers were poorly recognized. The results indicated that GT is able to distinguish between different nonnative conformations with a distinct preference for partially structured conformers. The findings suggest that discrete populations of nonnative conformations are selectively reglucosylated to participate in the calnexin/calreticulin chaperone pathway.     

How sugars convey information on protein conformation in the endoplasmic reticulum

The N-glycan-dependent quality control of glycoprotein folding prevents endoplasmic reticulum to Golgi exit of folding intermediates, irreparably misfolded glycoproteins and not completely assembled multimeric complexes. It also enhances folding efficiency by preventing aggregation and facilitating formation of proper disulfide bonds. The control mechanism essentially involves four components, resident lectin-chaperones that recognize monoglucosylated polymannose glycans, a lectin-associated oxidoreductase acting on monoglucosylated glycoproteins, a glucosyltransferase and a glucosidase that creates monoglucosylated epitopes in glycans transferred in protein N-glycosylation or removes the glucose units added by the glucosyltransferase. This last enzyme is the only mechanism component sensing glycoprotein conformations as it creates monoglucosylated glycans exclusively in not properly folded species or in not completely assembled complexes. The purpose of the review is to describe the most significant recent findings on the mechanism of glycoprotein folding and assembly quality control and to discuss the main still unanswered questions.     

Identification and Crystallization of a Protease-Resistant Core of Calnexin That Retains Biological Activity

Calnexin is a molecular chaperone that facilitates folding of glycoproteins in the endoplasmic reticulum (ER). The cloned lumenal domain of canine calnexin, cnxΔTMC, retains its biological activity without the transmembrane and cytosolic region. For the purpose of structure determination we generated a crystallizable core by mild proteolysis and identified its termini by N-terminal sequencing and molecular mass determination. A truncated gene was cloned accordingly. Its product, cnxΔN25C15, was purified to apparent homogeneity and crystallized. This truncated variant remains biologically active as shown by its binding to monoglucosylated oligosaccharides and functional interaction with ERp57. A heavy atom derivative was identified.     

UDP-GlC:glycoprotein glucosyltransferase-glucosidase II,the ying-yang of the ER quality control

The N-glycan-dependent quality control of glycoprotein folding prevents endoplasmic to Golgi exit of folding intermediates, irreparably misfolded glycoproteins and incompletely assembled multimeric complexes. It also enhances folding efficiency by preventing aggregation and facilitating formation of proper disulfide bonds. The control mechanism essentially involves four components, resident lectin-chaperones that recognize monoglucosylated polymannose glycans, a lectin-associated oxidoreductase acting on monoglucosylated glycoproteins, a glucosyltransferase that creates monoglucosytlated epitopes in protein-linked glycans and a glucosidase that removes the glucose units added by the glucosyltransferase. This last enzyme is the only mechanism component sensing glycoprotein conformations as it creates monoglucosylated glycans exclusively in not properly folded species or in not completely assembled complexes. The glucosidase is a dimeric heterodimer composed of a catalytic subunit and an additional one that is partially responsible for the ER localization of the enzyme and for the enhancement of the deglucosylation rate as its mannose 6-phosphate receptor homologous domain presents the substrate to the catalytic site. This review deals with our present knowledge on the glucosyltransferase and the glucosidase.     

Reglucosylation of glycoproteins and quality control of glycoprotein folding in the endoplasmic reticulum of yeast cells

Proteins entering the secretory pathway may be glycosylated upon transfer of an oligosaccharide (Glc₃Man₉GlcNAc₂) from a dolichol-P-P derivative to nascent polypeptide chains in the lumen of the endoplasmic reticulum (ER). Oligosaccharides are then deglucosylated by glucosidases I and II (GII). Also in the ER, glycoproteins acquire their final tertiary structures, and species that fail to fold properly are retained and eventually degraded in the proteasome. It has been proposed that in mammalian cells the monoglucosylated oligosaccharides generated either by partial deglucosylation of the transferred compound or by reglucosylation of glucose-free oligosaccharides by the UDP-Glc:glycoprotein glucosyltransferase (GT) are recognized by ER resident lectins (calnexin and/or calreticulin). GT is a sensor of glycoprotein conformation as it only glucosylates misfolded species. The lectin-monoglucosylated oligosaccharide interaction would retain glycoproteins in the ER until correctly folded, and also facilitate their acquisition of proper tertiary structures by preventing aggregation. GII would liberate glycoproteins from the calnexin/calreticulin anchor, but species not properly folded would be reglucosylated by GT, and so continue to be retained by the lectins. Only when the protein becomes properly folded would it cease to be retained by the lectins. This review presents evidence suggesting that a similar quality control mechanism of glycoprotein folding is operative in Schizosaccharomyces pombe and that the mechanism in Saccharomyces cerevisiae probably differs substantially from that occurring in mammalian and Sch. pombe cells.