Formation of intermolecular disulfide bonds on nascent immunoglobulin polypeptides.

The initial step of intermolecular covalent assembly of immunoglobulins molecules involves formation of heavy chain-light chain or heavy chain-heavy chain disulfide bonds. Using QAE-Sephadex chromatography to isolate microsomal nascent polypeptides, we have shown that this initial step of intermolecular covalent assembly occurs, to a substantial extent, on nascent heavy chains, as well as on completed heavy chains as previously demonstrated by others. In MPC 11 mouse myeloma cells, completed light chains are assembled covalently to nascent heavy chains, whereas in MOPC 21 mouse myeloma cells, completed heavy chains are assembled covalently to nascent heavy chains. These results are consisted with the heavy-light half-molecule being the major initial intermediate in the assembly of MPC 11 IgG2b and heavy-heavy dimer being the major initial intermediate formed in assembly of MOPC 21 IgG1. The nascent MPC 11 heavy chain must be at least 38,000 daltons in size before assembly with the light chain occurs, even though the heavy chain cysteine involved in this disulfide bond is 131 residues (approximately 15,000 daltons) from the NH2 terminus. In addition, pulse-chase labeling studies of MPC 11 cells have shown that the assembly of completed light chains with the nascent heavy chain must occur within a few minutes of the synthesis of the light chain even though a large excess of unassembled MPC 11 light chains remain inside the cell for an average time of 2 h before being secreted.     

Temporal relationship of translation and glycosylation of immunoglobulin heavy and light chains.

The initial glycosylation of MPC 11 gamma 2b heavy chains occurs quantitatively in vivo when the nascent heavy chains reach a size of approximately 38 000 daltons. Nonglycosylated, completed MPC 11 heavy chains cannot be glycosylated in these cells. Other classes of mouse heavy chains (i.e., mu, alpha, and gamma 1) also appear to be glycosylated as nascent chains; nonglycosylated, completed heavy chains cannot be glycosylated by the cell in any of these cases. In contrast, variant MPC 11 cells synthesizing a heavy chain with a carboxy-terminal deletion appear to glycosylate some heavy chains prior to chain completion and some heavy chains after chain completion and release from the polysomes. Similar to the variant MPC 11 cells, MOPC 46B cells (which synthesize a kappa light chain containing an oligosaccharide attached to an asparagine located 28 residues from the amino terminus) glycosylate the majority of light chains after prior to chain completion but also some light chains after chain completion and release from the polysomes. In addition, it appears that, although completed MOPC 46B light chains can be glycosylated if they are present in a monomeric form, they cannot be glycosylated if they are present in a covalent dimeric form.     

Addition of glucosamine and mannose to nascent immunoglobulin heavy chains.

We have investigated the process of protein glycosylation in an attempt to answer the question of whether glucosamine and mannose are added to nascent chains prior to chain completion or only to completed chains after release from the ribosome. The MPC 11 mouse plasmacytoma cell line used in these studies synthesizes a glycosylated gamma2b heavy chain which accounts for 12% of the total protein synthesis. Nascent chains were separated from completed chains by ion-exchange chromatography of solubilized ribosomes on QAE-Sephadex. Our results indicate that both glucosamine and mannose are incorporated into nascent heavy chains prior to chain completion and release from the ribosome. Gel analysis of specifically immunoprecipitated nascent chains indicates that the carbohydrate moiety can be added to the nascent heavy chains very soon after the presumptive asparaginyl glycosylation site (CH2 domain) is synthesized on the ribosome.     

Reduction of interchain disulfide bonds precedes the dislocation of Ig-mu chains from the endoplasmic reticulum to the cytosol for proteasomal degradation

Proteins that fail to fold or assemble in the endoplasmic reticulum (ER) are generally dislocated across the membrane to be degraded by cytosolic proteasomes. To investigate how the quality control machinery handles individual subunits that are part of covalent oligomers, we have analyzed the fate of transport-competent Ig light (L) chains that form disulfide bonds with short-lived mu heavy chains. When expressed alone, L chains are secreted. In cells producing excess mu, most L chains are retained in the ER as covalent mu-L or mu2-L2 complexes. While mu chains present in these complexes are degraded by proteasomes, L chains are stable. Few L chains are secreted; most reassociate with newly synthesized mu chains. Therefore, interchain disulfide bonds are reduced in the ER lumen before the dislocation of mu chains in a site from which freed L chains can be rapidly reinserted in the assembly line. The ER can thus sustain the simultaneous formation and reduction of disulfide bonds.     

Glycosylation causes an apparent block in translation of immunoglobulin heavy chain

Analysis of nascent heavy chains isolated from MPC11 (gamma 2b heavy chains) and MOPC 21 (gamma 1 heavy chains) mouse myeloma cells demonstrates an accumulation of nascent heavy chains which are slightly smaller in mass (approximately 35,000 daltons) than nascent heavy chains which have just been glycosylated (approximately 38,000 daltons). The accumulation of 35,000-dalton nascent heavy chain appears to be a consequence of the glycosylation process since tunicamycin, an inhibitor of glycosylation, abolishes the apparent translational block manifested by the accumulation of 35,000-dalton nascent chains. Tunicamycin also causes a 15 to 25% increase n the relative rate of synthesis of heavy chain compared to the corresponding rate of synthesis of the nonglycosylated light chain synthesized by the same cell. These results suggest that the translation block, caused by the glycosylation process, of heavy chain synthesis contributes to the imbalance of heavy chain and light chain biosynthesis observed in malignant and normal lymphoid cells.     

BiP and Immunoglobulin Light Chain Cooperate to Control the Folding of Heavy Chain and Ensure the Fidelity of Immunoglobulin Assembly

The immunoglobulin (Ig) molecule is composed of two identical heavy chains and two identical light chains (H2L2). Transport of this heteromeric complex is dependent on the correct assembly of the component parts, which is controlled, in part, by the association of incompletely assembled Ig heavy chains with the endoplasmic reticulum (ER) chaperone, BiP. Although other heavy chain-constant domains interact transiently with BiP, in the absence of light chain synthesis, BiP binds stably to the first constant domain (CH1) of the heavy chain, causing it to be retained in the ER. Using a simplified two-domain Ig heavy chain (VH-CH1), we have determined why BiP remains bound to free heavy chains and how light chains facilitate their transport. We found that in the absence of light chain expression, the CH1 domain neither folds nor forms its intradomain disulfide bond and therefore remains a substrate for BiP. In vivo, light chains are required to facilitate both the folding of the CH1 domain and the release of BiP. In contrast, the addition of ATP to isolated BiP-heavy chain complexes in vitro causes the release of BiP and allows the CH1 domain to fold in the absence of light chains. Therefore, light chains are not intrinsically essential for CH1 domain folding, but play a critical role in removing BiP from the CH1 domain, thereby allowing it to fold and Ig assembly to proceed. These data suggest that the assembly of multimeric protein complexes in the ER is not strictly dependent on the proper folding of individual subunits; rather, assembly can drive the complete folding of protein subunits.     

Glycosylation of endogenous protein(s) of the rough and smooth microsomes by a lipid sugar intermediate

Summary Several problems regarding the protein acceptor of the oligosaccharide from GEA (glucosylated endogenous acceptor) were investigated in the present work using rat liver microsomal subfractions. It was found that the acceptor molecule is present in rough and smooth liver microsomes. Furthermore both fractions have closely similar specific activities. The problem of whether nascent peptides must be ribosome bound for glycosylation to occur was studied. The results suggests that binding of peptides to ribosomes is not a necessary condition for the transfer of GEA oligosaccharide to protein. The increase in specific activity found after partial release of the microsomal vesicular content suggests that the acceptor protein for GEA is membrane bound. Evidence obtained in attempting to elucidate whether nascent or completed chains are glycosylated favours the later possibility.Dedicated to ProfessorLuis F. Leloir on the occasion of his 70th birthday.     

The synthesis and secretion of cartilage procollagen.

1. Isolation of free and membrane-bound ribosomes from embryonic chick sternal-cartilage cells labelled for 4min with [14C]proline and their subsequent analysis for hydroxy[14C]proline indicated that cartilage procollagen biosynthesis occurs on bound ribosomes. 2. Nascent procollagen polypeptides on bound ribosomes isolated from cells labelled with [14C]lysine were found to contain hydroxy[14C]lysine indicating that hydroxylation of lysine commences while the growing chains are still attached to the ribosomes. 3. Analysis of bound ribosomes labelled with either [14C]proline or [14C]lysine on sucrose density gradients indicated that cartilage procollagen is synthesized on large polyribosomes in the range 250-400S. 4. Microsomal preparations isolated from cells pulse-labelled for 4 min with [14C]proline were used to determine the direction of release of nascent procollagen polypeptides. Puromycin induced the vectorial release of nascent procollagen polypeptides into the microsomal vesicles suggesting that the first step in the secretion of procollagen polypeptides is their transfer from the ribosomes through the membrane of the endoplasmic reticulum into the cisternal space. 5. The procollagen polypeptides secreted by cartilage cells were shown to be linked by inter-chain disulphide bonds. 6. Examination of the state of aggregation of pro-alpha chains in subcellular fractions isolated from cartilage cells labelled with [14C]proline for various periods of time have provided data on the timing and location of inter-chain disulphide-bond formation. This process commences in the rough endoplasmic reticulum after the release of completed pro-alpha chains from membrane-bound ribosomes. Pro-alpha chains isolated from fractions of smooth endoplasmic reticulum were virtually all present as disulphide-bonded aggregates, suggesting that either disulphide bonding is completed in this cellular compartment, or that procollagen needs to be in a disulphide-bonded form to be transferred to this region of the endoplasmic reticulum. 7. Comparison of these results with previously published data on disulphide bonding in tendon cells suggest that the rate of inter-chain disulphide-bond formation is significantly slower in cartilage cells.     

Direct probing of the interaction between the signal sequence of nascent preprolactin and the signal recognition particle by specific cross-linking

We have studied the interaction between the signal sequence of nascent preprolactin and the signal recognition particle (SRP) during the initial events in protein translocation across the endoplasmic reticulum membrane. A new method of affinity labeling was used, whereby lysine residues, carrying the photoreactive group 4-(3-trifluoromethyldiazirino) benzoic acid in their side chains, are incorporated into a protein by means of modified lysyl-tRNA, and cross-linking to the interacting component is induced by irradiation. SRP interacts through its Mr 54,000 polypeptide component with the signal sequences of nascent preprolactin chains containing about 70 residues, and with decreasing affinity with longer chains as well; it causes inhibition of elongation. Binding of SRP is reversible and requires the nascent chain to be bound to a functional ribosome. SRP cross-linked to the signal sequence still inhibits elongation but does not prevent it completely. We conclude that SRP does not block the exit site of the polypeptide chain on the ribosome. The SRP receptor of the endoplasmic reticulum membrane displaces the signal sequence from SRP and, even if SRP is cross-linked, releases elongation arrest.     

An energy-dependent maturation step is required for release of the cystic fibrosis transmembrane conductance regulator from early endoplasmic reticulum biosynthetic machinery

Polytopic proteins are synthesized in the endoplasmic reticulum (ER) by ribosomes docked at the Sec61 translocation channel. It is generally assumed that, upon termination of translation, polypeptides are spontaneously released into the ER membrane where final stages of folding and assembly are completed. Here we investigate early interactions between the ribosome-translocon complex and cystic fibrosis transmembrane conductance regulator (CFTR), a multidomain ABC transporter, and demonstrate that this is not always the case. Using in vitro and Xenopus oocyte expression systems we show that, during and immediately following synthesis, nascent CFTR polypeptides associate with large, heterogeneous, and dynamic protein complexes. Partial-length precursors were quantitatively isolated in a non-covalent, puromycin-sensitive complex (>3,500 kDa) that contained the Sec61 ER translocation machinery and the cytosolic chaperone Hsc70. Following the completion of synthesis, CFTR was gradually released into a smaller (600-800 kDa) ATP-sensitive complex. Surprisingly, release of full-length CFTR from the ribosome and translocon was significantly delayed after translation was completed. Moreover, this step required both nucleotide triphosphates and cytosol. Release of control proteins varied depending on their size and domain complexity. These studies thus identify a novel energy-dependent step early in the CFTR maturation pathway that is required to disengage nascent CFTR from ER biosynthetic machinery. We propose that, contrary to current models, the final stage of membrane integration is a regulated process that can be influenced by the state of nascent chain folding, and we speculate that this step is influenced by the complex multidomain structure of CFTR.     

Role of ribosome and translocon complex during folding of influenza hemagglutinin in the endoplasmic reticulum of living cells

Protein folding in the living cell begins cotranslationally. To analyze how it is influenced by the ribosome and by the translocon complex during translocation into the endoplasmic reticulum, we expressed a mutant influenza hemagglutinin (a type I membrane glycoprotein) with a C-terminal extension. Analysis of the nascent chains by two-dimensional SDS-PAGE showed that ribosome attachment as such had little effect on ectodomain folding or trimer assembly. However, as long as the chains were ribosome bound and inside the translocon complex, formation of disulfides was partially suppressed, trimerization was inhibited, and the protein protected against aggregation.     

Translocation of nascent secretory proteins across membranes can occur late in translation.

Signal recognition particle (SRP) causes an arrest in the translation of nascent secretory proteins in a wheat germ cell-free system. In order to examine at what point during the synthesis of a secretory protein its translocation across the endoplasmic reticulum (ER) membrane can occur, SRP was used to arrest nascent chain elongation at various times during a synchronous translation, thus allowing the generation of nascent chains of increasing length. It was found that SRP can still bring about an arrest as late as when an average of two-thirds of nascent IgG light chain was completed. Rough microsomes were added to translations blocked with SRP to determine if such relatively long nascent chains could still be translocated across the membrane. It was found that nascent chains which had been arrested by SRP, regardless of their length, could be translocated into rough microsomes. In the case of IgG light chain, translocation levels of 50% were still observed with nascent chains corresponding to as much as 70-75% of the intact preprotein. Similar results were observed for the nascent bovine prolactin precursor. These results demonstrate that the synthesis of secretory proteins can be uncoupled from their translocation, and that fairly large nascent chains are capable of crossing the membrane of the ER post-translationally.     

Relationships between translation of pro α1(I) and pro α2(I) mRNAs during synthesis of the type I procollagen heterotrimer

Final assembly of the procollagen I heterotrimeric molecule is initiated by interactions between the carboxyl propeptide domains of completed, or nearly completed nascent pro α chains. These interactions register the chains for triple helix folding. Prior to these events, however, the appropriate nascent chains must be brought within the same compartments of the endoplasmic reticulum (ER). We hypothesize that the co-localization of the synthesis of the nascent pro α1(I) and pro α2(I) chains results from an interaction between their translational complexes during chain synthesis. This has been investigated by studying the polyribosomal loading of the pro α-chain messages during in vitro translation in the presence and absence of microsomal membranes, and in cells which have the ability to synthesize the pro α1 homotrimer or the normal heterotrimer. Recombinant human pro α1(I) and pro α2(I) C DNAs were inserted into plasmids and then transcribed in vitro. The resulting RNAs were translated separately and in mixture in a cell-free rabbit reticulocyte lysate ± canine pancreatic microsomes. Cycloheximide (100 μg/ml) was added and the polysomes were collected and fractionated on a 15–50% sucrose gradient. The RNA was extracted from each fraction and the level of each chain message was determined by RT-PCR. Polysomes from K16 (heterotrimer-producing), W8 (pro α1(I) homotrimer), and A2′ (heterotrimer + homotrimer) cells were similarly analyzed. Translations of the pro α1(I) and pro α2(I) messages proceeded independently in the cell-free, membrane-free systems, but were coordinately altered in the presence of membrane. The cell-free + membrane translation systems mimicked the behavior of the comparable cell polysome mRNA loading distributions. These data all suggest that there is an interaction between the pro α chain translational complexes at the ER membrane surface which temporally and spatially localize the nascent chains for efficient heteromeric selection and folding. © 1995 Wiley-Liss, Inc.     

The alpha and beta subunit of the nascent polypeptide-associated complex have distinct functions

Nascent polypeptide-associated complex (NAC) is probably the first cytosolic protein to contact nascent polypeptide chains emerging from ribosomes. In this way NAC prevents inappropriate interactions with other factors. Eventually other factors involved in targeting and folding, like the Signal Recognition Particle or cytosolic chaperones, must gain access to the nascent chain. All NAC preparations to date consist of two copurifying polypeptides. Here we rigorously show that these two polypeptides, termed alpha- and betaNAC, form a very stable complex in vivo and in vitro and that a functional complex can be reconstituted from the individual subunits. A dissection of the contributions of the individual subunits to NACs function revealed that both subunits are in direct contact with nascent polypeptide chains on the ribosome and that both contribute to the prevention of inappropriate interactions. However, betaNAC alone directly binds to the ribosome and is sufficient to prevent ribosome binding to the endoplasmic reticulum membrane.     

Regulation of membrane IgM expression in secretory B cells: translational and post-translational events.

IgM secreting cells express little or no membrane IgM. This is not always due to absence of the relevant mRNA. To investigate the synthesis and processing of membrane (micron) and secreted (microseconds) polypeptides in secretory B cells, myeloma cells were transfected either with a plasmid containing an intact mu gene or with one only capable of directing micron (not microseconds) mRNA synthesis. Although myeloma transfectants could make abundant levels of micron mRNA, they did not express IgM on the cell surface. In the myeloma host, micron mRNA is translated some 5-fold less efficiently than microseconds mRNA. However, this translational control does not totally preclude micron synthesis, indicating post-translational regulatory events. No difference between micron and microseconds chains could be detected in their rate of assembly with light chains or in their stability, although both types of heavy chain were degraded more rapidly when synthesized in the absence of light chain, or when the hydrophobic nature of the leader sequence was destroyed by site-directed mutagenesis. However, whereas intracellular microseconds chains in IgM-secreting plasmacytoma were found to be concentrated in the Golgi, the micron chains were mainly located in the endoplasmic reticulum. Retention in the endoplasmic reticulum is also observed for both micron and microseconds when synthesized in the absence of light chain. We propose that it is the expansion of the endoplasmic reticulum that accompanies B cell to plasma cell differentiation which is in part responsible for the down-regulation of surface IgM expression. Such a mechanism may also affect the expression of other surface proteins.     

The affinity of signal recognition particle for presecretory proteins is dependent on nascent chain length.

We have developed an assay in which incomplete preprolactin chains of varying lengths are targeted to the endoplasmic reticulum (ER) membrane in an elongation independent manner. The reaction had the same molecular requirements as nascent chain translocation across the ER membrane, namely, it was signal recognition particle (SRP) dependent, and required the nascent chain to be present as peptidyl tRNA (i.e. most likely ribosome associated) and to have its signal sequence exposed outside the ribosome. We found that the efficiency of the targeting reaction dropped dramatically as the chains grew longer than 140 amino acids in length, which probably reflected a decrease in affinity of the nascent chain-ribosome complex for SRP. Thus at physiological SRP concentrations (10 nM) there appears a sharp cut-off point in the ability of these chains to be targeted, while at high SRP concentrations (270 nM) all chains could be targeted. In kinetic experiments, high concentrations of SRP were found to change the time in elongation after which translocation of the nascent polypeptide could no longer occur.     

Guanosine triphosphate promotes the post-translational integration of opsin into the endoplasmic reticulum membrane

Membrane integration of a nascent opsin polypeptide was examined to determine whether insertion of proteins into the endoplasmic reticulum is dependent upon energy provided by ribonucleotide triphosphate hydrolysis. A discrete-sized nascent chain was obtained by in vitro translation of a mRNA which lacked a termination codon yet encoded the first 156 residues of bovine opsin. Ribosomes bearing the newly synthesized opsin chains were post-translationally incubated with canine pancreas microsomal membrane vesicles after addition of exogenous ribonucleotides or ribonucleotide analogues. Post-translational membrane integration and glycosylation of the 156-residue nascent polypeptide was found to require either the presence of guanosine triphosphate or a nonhydrolyzable GTP analogue. ATP did not promote post-translational integration of the nascent polypeptide. Although ribonucleotide hydrolysis was not obligatorily required for integration of opsin, we observed an increase in the proportion of glycosylated opsin chains in post-translational incubations that contained hydrolyzable ribonucleotide triphosphates. We conclude that a GTP-binding protein performs an essential role during integration of opsin into the endoplasmic reticulum.     

Heavy chain binding protein recognizes incompletely disulfide-bonded forms of vesicular stomatitis virus G protein

To investigate the function of heavy chain binding protein (BiP, GRP 78) in the endoplasmic reticulum, we have characterized its interaction with a model plasma membrane glycoprotein, the G protein of vesicular stomatitis virus. We used a panel of well characterized mutant G proteins and immunoprecipitation with anti-BiP antibodies to determine if BiP interacted with newly synthesized G protein and/or mutant G proteins retained in the endoplasmic reticulum. We made three major observations: 1) BiP bound transiently to folding intermediates of wild-type G protein which were incompletely disulfide-bonded; 2) BiP did not bind stably to all mutant G proteins which remain in the endoplasmic reticulum; and 3) BiP bound stably only to mutant G proteins which do not form correct intrachain disulfide bonds.     

Identification of a Novel Stage of Ribosome/Nascent Chain Association with the Endoplasmic Reticulum Membrane

Protein translocation in the mammalian endoplasmic reticulum (ER) occurs cotranslationally and requires the binding of translationally active ribosomes to components of the ER membrane. Three candidate ribosome receptors, p180, p34, and Sec61p, have been identified in binding studies with inactive ribosomes, suggesting that ribosome binding is mediated through a receptor-ligand interaction. To determine if the binding of nascent chain-bearing ribosomes is regulated in a manner similar to inactive ribosomes, we have investigated the ribosome/nascent chain binding event that accompanies targeting. In agreement with previous reports, indicating that Sec61p displays the majority of the ER ribosome binding activity, we observed that Sec61p is shielded from proteolytic digestion by native, bound ribosomes. The binding of active, nascent chain bearing ribosomes to the ER membrane is, however, insensitive to the ribosome occupancy state of Sec61p. To determine if additional, Sec61p independent, stages of the ribosome binding reaction could be identified, ribosome/nascent chain binding was assayed as a function of RM concentration. At limiting RM concentrations, a protease resistant ribosome-membrane junction was formed, yet the nascent chain was salt extractable and cross-linked to Sec61p with low efficiency. At nonlimiting RM concentrations, bound nascent chains were protease and salt resistant and cross-linked to Sec61p with higher efficiency. On the basis of these and other data, we propose that ribosome binding to the ER membrane is a multi-stage process comprised of an initial, Sec61p independent binding event, which precedes association of the ribosome/nascent chain complex with Sec61p.     

The structure of ribosome-channel complexes engaged in protein translocation

Cotranslational translocation of proteins requires ribosome binding to the Sec61p channel at the endoplasmic reticulum (ER) membrane. We have used electron cryomicroscopy to determine the structures of ribosome-channel complexes in the absence or presence of translocating polypeptide chains. Surprisingly, the structures are similar and contain 3-4 connections between the ribosome and channel that leave a lateral opening into the cytosol. Therefore, the ribosome-channel junction may allow the direct transfer of polypeptides into the channel and provide a path for the egress of some nascent chains into the cytosol. Moreover, complexes solubilized from mammalian ER membranes contain an additional membrane protein that has a large, lumenal protrusion and is intercalated into the wall of the Sec61p channel. Thus, the native channel contains a component that is not essential for translocation.