Protein folding and translocation across the endoplasmic reticulum membrane

Proteins destined for secretion are translocated across or inserted into the endoplasmic reticulum membrane whereupon they fold and assemble to their native state before their subsequent transport to the Golgi apparatus. Proteins that fail to fold correctly are translocated back across the endoplasmic reticulum membrane to the cytosol where they become substrates for the cytosolic degradative machinery. Central to translocation is a protein pore in the membrane called the translocon that allows passage of proteins in and out of the endoplasmic reticulum. It is clear that the conformation of the polypeptide chain influences the translocation process and that there is a temporal relationship between modification of the chain, translocation and folding. This review will consider when and how the polypeptide chain folds, and how this might influence translocation into and out of the ER; and discuss how protein folding might affect post-translational modification of the polypeptide chain following translocation into the ER lumen.     

Protein folding and translocation across the endoplasmic reticulum membrane (Review)

Proteins destined for secretion are translocated across or inserted into the endoplasmic reticulum membrane whereupon they fold and assemble to their native state before their subsequent transport to the Golgi apparatus. Proteins that fail to fold correctly are translocated back across the endoplasmic reticulum membrane to the cytosol where they become substrates for the cytosolic degradative machinery. Central to translocation is a protein pore in the membrane called the translocon that allows passage of proteins in and out of the endoplasmic reticulum. It is clear that the conformation of the polypeptide chain influences the translocation process and that there is a temporal relationship between modification of the chain, translocation and folding. This review will consider when and how the polypeptide chain folds, and how this might influence translocation into and out of the ER; and discuss how protein folding might affect post-translational modification of the polypeptide chain following translocation into the ER lumen.     

Protein folding and quality control in the endoplasmic reticulum

The endoplasmic reticulum (ER) is a highly versatile protein factory that is equipped with chaperones and folding enzymes essential for protein folding. ER quality control guided by these chaperones is essential for life. Whereas correctly folded proteins are exported from the ER, misfolded proteins are retained and selectively degraded. At least two main chaperone classes, BiP and calnexin/calreticulin, are active in ER quality control. Folding factors usually are found in complexes. Recent work emphasises more than ever that chaperones act in concert with co-factors and with each other.     

Glycoprotein folding in the endoplasmic reticulum

Our understanding of eukaryotic protein folding in the endoplasmic reticulum has increased enormously over the last 5 years. In this review, we summarize some of the major research themes that have captivated researchers in this field during the last years of the 20th century. We follow the path of a typical protein as it emerges from the ribosome and enters the reticular environment. While many of these events are shared between different polypeptide chains, we highlight some of the numerous differences between proteins, between cell types, and between the chaperones utilized by different ER glycoproteins. Finally, we consider the likely advances in this field as the new century unfolds and we address the prospect of a unified understanding of how protein folding, degradation, and translation are coordinated within a cell.     

Protein folding includes oligomerization - examples from the endoplasmic reticulum and cytosol

A correct three-dimensional structure is a prerequisite for protein functionality, and therefore for life. Thus, it is not surprising that our cells are packed with proteins that assist protein folding, the process in which the native three-dimensional structure is formed. In general, plasma membrane and secreted proteins, as well as those residing in compartments along the endocytic and exocytic pathways, fold and oligomerize in the endoplasmic reticulum. The proteins residing in the endoplasmic reticulum are specialized in the folding of this subset of proteins, which renders this compartment a protein-folding factory. This review focuses on protein folding in the endoplasmic reticulum, and discusses the challenge of oligomer formation in the endoplasmic reticulum as well as the cytosol.     

Protein targeting to and translocation across the membrane of the endoplasmic reticulum.

Several approaches are currently being taken to elucidate the mechanisms and the molecular components responsible for protein targeting to and translocation across the membrane of the endoplasmic reticulum. Two experimental systems dominate the field: a biochemical system derived from mammalian exocrine pancreas, and a combined genetic and biochemical system employing the yeast, Saccharomyces cerevisiae. Results obtained in each of these systems have contributed novel, mostly non-overlapping information. Recently, much effort in the field has been dedicated to identifying membrane proteins that comprise the translocon. Membrane proteins involved in translocation have been identified both in the mammalian system, using a combination of crosslinking and reconstitution approaches, and in S. cerevisiae, by selecting for mutants in the translocation pathway. None of the membrane proteins isolated, however, appears to be homologous between the two experimental systems. In the case of the signal recognition particle, the two systems have converged, which has led to a better understanding of how proteins are targeted to the endoplasmic reticulum membrane.     

Versatility of the endoplasmic reticulum protein folding factory

The endoplasmic reticulum (ER) is dedicated to import, folding and assembly of all proteins that travel along or reside in the secretory pathway of eukaryotic cells. Folding in the ER is special. For instance, newly synthesized proteins are N-glycosylated and by default form disulfide bonds in the ER, but not elsewhere in the cell. In this review, we discuss which features distinguish the ER as an efficient folding factory, how the ER monitors its output and how it disposes of folding failures.     

Protein quality control in the endoplasmic reticulum

Protein folding and quality control in the endoplasmic reticulum (ER) are synchronized mechanisms ensuring that only properly folded proteins are integrated in the plasma membrane or secreted from the cell. These mechanisms act in close collaboration with the molecular machinery involved in retrograde-translocation and degradation of non-native proteins and with the ER-stress activated signalling systems. The common goal of these mechanisms is to prevent expression and secretion of misfolded proteins. Protein misfolding can be detrimental to the cell and contributes to the disease mechanism in several inherited disorders, e.g. cystic fibrosis, familial hypercholesterolemia and diabetes insipidus. This review outlines the molecular mechanisms in protein quality control occurring in the ER, signalling caused by ER stress, and finally ER associated protein degradation.     

Protein secretion and the endoplasmic reticulum

In a complex multicellular organism, different cell types engage in specialist functions, and as a result, the secretory output of cells and tissues varies widely. Whereas some quiescent cell types secrete minor amounts of proteins, tissues like the pancreas, producing insulin and other hormones, and mature B cells, producing antibodies, place a great demand on their endoplasmic reticulum (ER). Our understanding of how protein secretion in general is controlled in the ER is now quite sophisticated. However, there remain gaps in our knowledge, particularly when applying insight gained from model systems to the more complex situations found in vivo. This article describes recent advances in our understanding of the ER and its role in preparing proteins for secretion, with an emphasis on glycoprotein quality control and pathways of disulfide bond formation.     

The protein translocation machinery of the endoplasmic reticulum

The rough endoplasmic reticulum (r.e.r.) has been postulated to possess a single translation-coupled translocation system (in multiple copies) that effects signal sequence-mediated translocation of all secretory and lysosomal proteins and integration of all integral membrane proteins whose port of entry is the rough endoplasmic reticulum (G. Blobel 1980 Proc. natn. Acad. Sci. U.S.A. 77, 1496-1500). Two proteins have been isolated that are components of the r.e.r. translocation system. Their properties and function in protein translocation across and integration into membranes are discussed.     

Protein folding in the endoplasmic reticulum: lessons from the human chorionic gonadotropin beta subunit.

There have been few studies of protein folding in the endoplasmic reticulum of intact mammalian cells. In the one case where the in vivo and in vitro folding pathways of a mammalian secretory protein have been compared, the folding of the human chorionic gonadotropin beta subunit (hCG-beta), the order of formation of the detected folding intermediates is the same. The rate and efficiency with which multidomain proteins such as hCG-beta fold to native structure in intact cells is higher than in vitro, although intracellular rates of folding of the beta subunit can be approached in vitro in the presence of an optimal redox potential and protein disulfide isomerase. Understanding how proteins fold in vivo may provide a new way to diagnose and treat human illnesses that occur due to folding defects.     

Protein translocation into the endoplasmic reticulum: a light at the end of the tunnel

Intracellular transport of secretory of proteins and many membrane proteins in eukaryotic cells commences with their translocation into or across the membrane of the rough endoplasmic reticulum. Several components of the cellular machinery that mediates this process have been elucidated using in vitro assays or by genetic means. An analysis of how they function will depend on the ability to reassemble them into translocation-competent lipid vesicles.     

Polypeptide translocation across the endoplasmic reticulum membrane.

Many polypeptides have been postulated to play direct roles in secretory protein translocation based on genetic criteria, cross-linking, and antibody inhibition. Much of the excitement in the next few years will come from the resolution of current controversies. What is the nature of the ribosome receptor, and is it essential for translocation? Is BiP required for translocation in mammalian cells? Are all of the polypeptides of signal peptidase and oligosaccharyltransferase required for catalytic function, or do some of them mediate steps of protein translocation? One of the best ways to resolve these problems will be to determine the importance of each in reconstituted translocation reactions by fractionation or immunodepletion, or by analysis in a purified reaction. Another approach is to identify homologues of these molecules in S. cerevisiae and to assess their importance in in vivo translocation. Several mechanistic questions remain to be addressed as well. Does the protein translocation apparatus consist of protein, or lipid, or both? How are integral membrane proteins inserted? How is the translocon gated to admit only unfolded or partially folded secretory polypeptides and to exclude cytoplasmic molecules? The answers to these questions will illuminate a basic enigma in cell biology that has remained unanswered for many years.     

Competition between folding and glycosylation in the endoplasmic reticulum.

Using carboxypeptidase Y in Saccharomyces cerevisiae as a model system, the in vivo relationship between protein folding and N-glycosylation was studied. Seven new sites for N-glycosylation were introduced at positions buried in the folded protein structure. The level of glycosylation of such new acceptor sites was analysed by pulse-labelling under two sets of conditions that are known to reduce the rate of folding: (i) addition of dithiothreitol to the growth medium and (ii) introduction of deletions in the propeptide. A variety of effects was observed, depending on the position of the new acceptor sites. In some cases, all the newly synthesized mutant protein was modified at the novel site while in others no modification took place. In the most interesting category of mutants, the level of glycosylation was dependent on the conditions for folding. This shows that folding and glycosylation reactions can compete in vivo and that glycosylation does not necessarily precede folding. The approach described may be generally applicable for the analysis of protein folding in vivo.     

Protein translocation mutants defective in the insertion of integral membrane proteins into the endoplasmic reticulum.

Yeast mutants defective in the translocation of soluble secretory proteins into the lumen of the endoplasmic reticulum (sec61, sec62, sec63) are not impaired in the assembly and glycosylation of the type II membrane protein dipeptidylaminopeptidase B (DPAPB) or of a chimeric membrane protein consisting of the multiple membrane-spanning domain of yeast hydroxymethylglutaryl CoA reductase (HMG1) fused to yeast histidinol dehydrogenase (HIS4C). This chimera is assembled in wild-type or mutant cells such that the His4c protein is oriented to the ER lumen and thus is not available for conversion of cytosolic histidinol to histidine. Cells harboring the chimera have been used to select new translocation defective sec mutants. Temperature-sensitive lethal mutations defining two complementation groups have been isolated: a new allele of sec61 and a single isolate of a new gene sec65. The new isolates are defective in the assembly of DPAPB, as well as the secretory protein alpha-factor precursor. Thus, the chimeric membrane protein allows the selection of more restrictive sec mutations rather than defining genes that are required only for membrane protein assembly. The SEC61 gene was cloned, sequenced, and used to raise polyclonal antiserum that detected the Sec61 protein. The gene encodes a 53-kDa protein with five to eight potential membrane-spanning domains, and Sec61p antiserum detects an integral protein localized to the endoplasmic reticulum membrane. Sec61p appears to play a crucial role in the insertion of secretory and membrane polypeptides into the endoplasmic reticulum.     

Calnexin and BiP act as sequential molecular chaperones during thyroglobulin folding in the endoplasmic reticulum

Before secretion, newly synthesized thyroglobulin (Tg) folds via a series of intermediates: disulfide-linked aggregates and unfolded monomers-->folded monomers-->dimers. Immediately after synthesis, very little Tg associated with calnexin (a membrane-bound molecular chaperone in the ER), while a larger fraction bound BiP (a lumenal ER chaperone); dissociation from these chaperones showed superficially similar kinetics. Calnexin might bind selectively to carbohydrates within glycoproteins, or to hydrophobic surfaces of secretory proteins while they form proper disulfide bonds (Wada, I., W.-J. Ou, M.-C. Liu, and G. Scheele, J. Biol. Chem. 1994. 269:7464-7472). Because Tg has multiple disulfides, as well as glycans, we tested a brief exposure of live thyrocytes to dithiothreitol, which resulted in quantitative aggregation of nascent Tg, as analyzed by SDS-PAGE of cells lysed without further reduction. Cells lysed in the presence of dithiothreitol under non-denaturing conditions caused Tg aggregates to run as reduced monomers. For cells lysed either way, after in vivo reduction, Tg coprecipitated with calnexin. After washout of dithiothreitol, nascent Tg aggregates dissolved intracellularly and were secreted ultimately. 1 h after washout, > or = 92% of labeled Tg was found to dissociate from calnexin, while the fraction of labeled Tg bound to BiP rose from 0 to approximately 40%, demonstrating a "precursor-product" relationship. Whereas intralumenal reduction was essential for efficient Tg coprecipitation with calnexin, Tg glycosylation was not required. These data are among the first to demonstrate sequential chaperone function involved in conformational maturation of nascent secretory proteins within the ER.     

Protein transport across the endoplasmic reticulum membrane

A decisive step in the biosynthesis of many eukaryotic proteins is their partial or complete translocation across the endoplasmic reticulum membrane. A similar process occurs in prokaryotes, except that proteins are transported across or are integrated into the plasma membrane. In both cases, translocation occurs through a protein-conducting channel that is formed from a conserved, heterotrimeric membrane protein complex, the Sec61 or SecY complex. Structural and biochemical data suggest mechanisms that enable the channel to function with different partners, to open across the membrane and to release laterally hydrophobic segments of membrane proteins into lipid.