Posttranslational association of immunoglobulin heavy chain binding protein with nascent heavy chains in nonsecreting and secreting hybridomas

A rat monoclonal antibody specific for immunoglobulin (Ig) heavy chain binding protein (BiP) has allowed the examination of the association of BiP with assembling Ig precursors in mouse B lymphocyte-derived cell lines. The anti-BiP monoclonal antibody immunoprecipitates BiP along with noncovalently associated Ig heavy chains. BiP is a component of the endoplasmic reticulum and binds free intracellular heavy chains in nonsecreting pre-B (mu+, L-) cell lines or incompletely assembled Ig precursors in (H+, L+) secreting hybridomas and myelomas. In the absence of light chain synthesis, heavy chains remain associated with BiP and are not secreted. The association of BiP with assembling Ig molecules in secreting hybridomas is transient and is restricted to the incompletely assembled molecules which are found in the endoplasmic reticulum. BiP loses affinity and disassociates with Ig molecules when polymerization with light chain is complete. We propose that the association of BiP with Ig heavy chain precursors is a novel posttranslational processing event occurring in the endoplasmic reticulum. The Ig heavy chains associated with BiP are not efficiently transported from the endoplasmic reticulum to the Golgi apparatus. Therefore, BiP may prevent the premature escape and eventual secretion of incompletely assembled Ig molecules.     

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.     

Immunoglobulin heavy chain and binding protein complexes are dissociated in vivo by light chain addition

Immunoglobulin heavy chain binding protein (BiP, GRP78) associates stably with the free, nonsecreted Ig heavy chains synthesized by Abelson virus transformed pre-B cell lines. In cells synthesizing both Ig heavy and light chains, the Ig subunits assemble rapidly and are secreted. Only incompletely assembled Ig molecules can be found bound to BiP in these cells. In addition to Ig heavy chains, a number of mutant and incompletely glycosylated transport-defective proteins are stably complexed with BiP. When normal proteins are examined for combination with BiP, only a small fraction of the intracellular pool of nascent, unfolded, or unassembled proteins can be found associated. It has been difficult to determine whether these BiP-associated molecules represent assembly intermediates which will be displaced from BiP and transported from the cell, or whether these are aberrant proteins that are ultimately degraded. In order for BiP to monitor and aid in normal protein transport, its association with these proteins must be reversible and the released proteins should be transport competent. In the studies described here, transient heterokaryons were formed between a myeloma line producing BiP-associated heavy chains and a myeloma line synthesizing the complementary light chain. Introduction of light chain synthesis resulted in assembly of prelabeled heavy chains with light chains, displacement of BiP from heavy chains, and secretion of Ig into the culture supernatant. These data demonstrate that BiP association can be reversible, with concordant release of transportable proteins. Thus, BiP can be considered a component of the exocytic secretory pathway, regulating the transport of both normal and abnormal proteins.     

Russell bodies: a general response of secretory cells to synthesis of a mutant immunoglobulin which can neither exit from, nor be degraded in, the endoplasmic reticulum

Dilated cisternae of the ER resembling Russell Bodies (RBs) are induced in light (L) chain producing myeloma cell lines by transfection of a mu heavy (H) chain gene lacking the first constant domain (mu delta CH1). RBs do not appear to be tissue specific, since they are also induced in a rat glioma cell line transfected with mu delta CH1 and L chain genes. Efficient RB biogenesis requires H-L assembly and polymerization. The mutant Ig is partially degraded in a pre-Golgi compartment. The remnant, however, becomes an insoluble lattice when intersubunit disulphide bonds are formed. The resulting insoluble aggregate accumulates in RBs. Replacing the COOH-terminal cysteine of mu delta CH1 chains with alanine reverses the RB-phenotype: the double mutant mu ala delta CH1 chains assemble noncovalently with L and are secreted as H2L2 complexes. Similarly, secretion of mu delta CH1 chains can be induced by culturing transfectant cells in the presence of reducing agents. The presence of RBs does not alter transport of other secretory or membrane molecules, nor does it affect cell division. Resident proteins of the ER and other secretory proteins are not concentrated in RBs, implying sorting at the ER level. Sorting could be the result of the specific molecular structure of the insoluble lattice. We propose that RBs represent a general response of the cell to the accumulation of abundant, nondegradable protein(s) that fail to exit from the ER.     

Association with BiP and aggregation of class II MHC molecules synthesized in the absence of invariant chain.

Class II molecules of the major histocompatibility complex (MHC) are composed of two polymorphic glycoprotein chains (alpha and beta), that associate in the ER with a third, non-polymorphic glycoprotein known as the invariant chain (Ii). We have examined the relationship between the intracellular transport and physico-chemical characteristics of various combinations of murine alpha, beta and Ii chains. Biochemical and morphological analyses of transfected fibroblasts expressing class II MHC chains show that both unassembled alpha and beta chains, as well as a large fraction of alpha+beta complexes synthesized in the absence of Ii chain, are retained in the ER in association with the immunoglobulin heavy chain binding protein, BiP. Analyses by sedimentation velocity on sucrose gradients show that most incompletely assembled class II MHC species exist as high molecular weight aggregates in both transfected fibroblasts and spleen cells from mice carrying a disruption of the Ii chain gene. This is in contrast to the sedimentation properties of alpha beta Ii complexes from normal mice, which migrate as discrete, stoichiometric complexes of M(r) approximately 200,000-300,000. These observations suggest that assembly with the Ii chain prevents accumulation of aggregated alpha and beta chains in the ER, which might relate to the known ability of the Ii chain to promote exit of class II MHC molecules from the ER.     

In vivo expression of mammalian BiP ATPase mutants causes disruption of the endoplasmic reticulum.

BiP possesses ATP binding/hydrolysis activities that are thought to be essential for its ability to chaperone protein folding and assembly in the endoplasmic reticulum (ER). We have produced a series of point mutations in a hamster BiP clone that inhibit ATPase activity and have generated a species-specific anti-BiP antibody to monitor the effects of mutant hamster BiP expression in COS monkey cells. The enzymatic inactivation of BiP did not interfere with its ability to bind to Ig heavy chains in vivo but did inhibit ATP-mediated release of heavy chains in vitro. Immunofluorescence staining and electron microscopy revealed vesiculation of the ER membranes in COS cells expressing BiP ATPase mutants. ER disruption was not observed when a "44K" fragment of BiP that did not include the protein binding domain was similarly mutated but was observed when the protein binding region of BiP was expressed without an ATP binding domain. This suggests that BiP binding to target proteins as an inactive chaperone is responsible for the ER disruption. This is the first report on the in vivo expression of mammalian BiP mutants and is demonstration that in vitro-identified ATPase mutants behave as dominant negative mutants when expressed in vivo.     

Regulation of endoplasmic reticulum stress proteins in COS cells transfected with immunoglobulin mu heavy chain cDNA

The mechanism by which endoplasmic reticulum (ER) stress proteins are induced by the accumulation of incompletely assembled or malfolded proteins in the ER is poorly understood. The 78-kDa glucose-regulated protein (BiP), one of the ER stress proteins, has often been detected in stable complexes with these accumulated proteins. We have transfected COS cells with an immunoglobulin (Ig) mu heavy chain expression plasmid. Expressed mu-chain accumulated in the cells and formed stable complexes with BiP. As a result, the synthesis of three ER stress proteins, BiP, the 94-kDa glucose-regulated protein (GRP94/ERp99), and ERp72, was increased as were their mRNA levels. In addition, the degradation rate of BiP was increased, possibly because of its interaction with mu-chain. Cotransfection of the mu-chain plasmid with an Ig lambda light chain expression plasmid resulted in the appearance of mu-chain in the media in a covalent complex with lambda-chain. An intracellular consequence of this was a reduction in the levels of BiP.mu-chain complex, and a diminished stimulation in the synthesis of the ER stress proteins. These results suggest that the BiP.mu-chain complex in the ER may be involved in the signaling pathway for the induction of ER stress proteins and may represent one regulatory mechanism operating in differentiating B-lymphocytes.     

Mouse myeloma cells that make short immunoglobulin heavy chains: pleiotropic effects on glycosylation and chain assembly

Two variants in immunoglobulin heavy chain production, derived from the MPC 11 mouse myeloma cell line, make short heavy (H) chains with identical precise deletions of the CH3 domain. The CH3 domain is expressed in the H chain mRNA from both variants. Although in vitro translation of this mRNA produces one H chain species, deleted heavy chains are secreted as heavy-light (HL) and H2L2 moieties in contrast to MPC 11, which secretes only H2L2 . The heavy chains of HL apparently contain more carbohydrate (CHO+) than do the H chains of H2L2 , and inhibition of N-linked glycosylation results in the secretion of relatively more H2L2 . Here we present evidence suggesting that (a) the absence of the CH3 domain has led to conformational changes in these molecules, (b) these changes permit posttranslational glycosylation, and (c) unrestrained glycosylation can frequently yield unusual CHO+ structures that make complete assembly unlikely.     

Mutation of a single conserved residue in VH complementarity-determining region 2 results in a severe Ig secretion defect

During an immune response, somatic mutations are introduced into the VH and VL regions of Ig chains. The consequences of somatic mutation in highly conserved residues are poorly understood. Ile51 is present in 91% of murine VH complementarity-determining region 2 sequences, and we demonstrate that single Ile51-->Arg or Lys substitutions in the PCG1-1 Ab are sufficient to severely reduce Ig secretion (1-3% of wild-type (WT) levels). Mutant H chains, expressed in the presence of excess L chain, associate with Ig binding protein (BiP) and GRP94 and fail to form HL and H2L assembly intermediates efficiently. The mutations do not irreversibly alter the VH domain as the small amount of mutant H chain, which assembles with L chain as H2L2, is secreted. The secreted mutant Ab binds phosphocholine-protein with avidity identical with that of WT Ab, suggesting that the combining site adopts a WT conformation. A computer-generated model of the PCG1-1 variable region fragment of Ig (Fv) indicates that Ile51 is buried between complementarity-determining region 2 and framework 3 and does not directly contact the L chain. Thus, the Ile51-->Arg or Ile51-->Lys mutations impair association with the PCG1-1 L chain via indirect interactions. These interactions are in part dependent on the nature of the L chain as the PCG1-1 VH single Ile51-->Arg or Ile51-->Lys mutants were partially rescued when expressed with the J558L lambda1 L chain. These results represent the first demonstration that single somatic mutations in V(H) residues can impair Ig secretion and suggest one reason for the conservation of Ile51 in so many Ig VH.     

The In Vivo Association of BiP with Newly Synthesized Proteins Is Dependent on the Rate and Stability of Folding and Not Simply on the Presence of Sequences That Can Bind to BiP

Immunoglobulin heavy chain-binding protein (BiP) is a member of the hsp70 family of chaperones and one of the most abundant proteins in the ER lumen. It is known to interact transiently with many nascent proteins as they enter the ER and more stably with protein subunits produced in stoichiometric excess or with mutant proteins. However, there also exists a large number of secretory pathway proteins that do not apparently interact with BiP. To begin to understand what controls the likelihood that a nascent protein entering the ER will associate with BiP, we have examined the in vivo folding of a murine λI immunoglobulin (Ig) light chain (LC). This LC is composed of two Ig domains that can fold independent of the other and that each possess multiple potential BiP-binding sequences. To detect BiP binding to the LC during folding, we used BiP ATPase mutants, which bind irreversibly to proteins, as “kinetic traps.” Although both the wild-type and mutant BiP clearly associated with the unoxidized variable region domain, we were unable to detect binding of either BiP protein to the constant region domain. A combination of in vivo and in vitro folding studies revealed that the constant domain folds rapidly and stably even in the absence of an intradomain disulfide bond. Thus, the simple presence of a BiP-binding site on a nascent chain does not ensure that BiP will bind and play a role in its folding. Instead, it appears that the rate and stability of protein folding determines whether or not a particular site is recognized, with BiP preferentially binding to proteins that fold slowly or somewhat unstably.     

Assembly, secretion, and vacuolar delivery of a hybrid immunoglobulin in plants

Secretory immunoglobulin (Ig) A is a decameric Ig composed of four alpha-heavy chains, four light chains, a joining (J) chain, and a secretory component (SC). The heavy and light chains form two tetrameric Ig molecules that are joined by the J chain and associate with the SC. Expression of a secretory monoclonal antibody in tobacco (Nicotiana tabacum) has been described: this molecule (secretory IgA/G [SIgA/G]) was modified by having a hybrid heavy chain sequence consisting of IgG gamma-chain domains linked to constant region domains of an IgA alpha-chain. In tobacco, about 70% of the protein assembles to its final, decameric structure. We show here that SIgA/G assembly and secretion are slow, with only approximately 10% of the newly synthesized molecules being secreted after 24 h and the bulk probably remaining in the endoplasmic reticulum. In addition, a proportion of SIgA/G is delivered to the vacuole as at least partially assembled molecules by a process that is blocked by the membrane traffic inhibitor brefeldin A. Neither the SC nor the J chain are responsible for vacuolar delivery, because IgA/G tetramers have the same fate. The parent IgG tetrameric molecule, containing wild-type gamma-heavy chains, is instead secreted rapidly and efficiently. This strongly suggests that intracellular retention and vacuolar delivery of IgA/G is due to the alpha-domains present in the hybrid alpha/gamma-heavy chains and indicates that the plant secretory system may partially deliver to the vacuole recombinant proteins expected to be secreted.     

The endoplasmic reticulum stress protein GRP94, in addition to BiP, associates with unassembled immunoglobulin chains.

The molecular chaperone BiP/GRP78 associates with various polypeptides in the endoplasmic reticulum, including immunoglobulin chains. We now show, using chemical cross-linking, that another endoplasmic reticulum stress protein, GRP94, associates with newly synthesized immunoglobulin light and heavy chains. We demonstrate the presence of ternary complexes composed of immunoglobulin chains, BiP and GRP94. Because both BiP and GRP94 associate far less with fully assembled immunoglobulin than with unassembled subunits, our data suggest that GRP94, like BiP, functions as a molecular chaperone. The presence of both BiP and GRP94 in the same complex further suggests that the two stress proteins work in concert during the folding and assembly of immunoglobulins.     

Endoplasmic reticulum chaperones stabilize nicotinic receptor subunits and regulate receptor assembly

We examined interactions between the endoplasmic reticulum (ER) chaperones calnexin (CN), ERp57, and immunological heavy chain-binding protein (BiP) and nicotinic acetylcholine receptor (nAChR) subunits. The three chaperones rapidly associate with newly synthesized nAChR subunits. Interactions between nAChR subunits and ERp57 occur via transient intermolecular disulfide bonds and do not require subunit N-linked glycosylation. The associations of ERp57 or CN with AChR subunits are long lived and prolong subunit lifetime approximately 10-fold. Coexpression of CN or ERp57 alone does not affect nAChR assembly or trafficking, but together they cause a significant decrease in nAChR expression and assembly. In contrast, associations with BiP are shorter lived and do not alter nAChR expression and assembly. However, a mutated BiP that slows its dissociation significantly increases its associations and decreases nAChR expression and assembly. Our results suggest that interactions with the chaperones regulate the levels of nAChRs assembled in the ER by stabilizing and sequestering subunits during assembly.     

Tumor-produced secreted form of binding of immunoglobulin protein elicits antigen-specific tumor immunity

Binding of immunoglobulin protein (BiP) is a major molecular chaperone localized in endoplasmic reticulum (ER). It has been demonstrated to interact with nascent Ig. However, contrary to other ER-resident heat shock proteins such as gp96, calreticulin, and ORP150, it is not clear whether tumor-derived BiP plays a role in inducing antitumor immunity. In this study, we show that the tumor-derived secreted form of BiP is capable of inducing antitumor CD8(+) T cell responses. We constructed an ER-retention signal KDEL-deleted mutant of BiP cDNA and transfected it to tumor cells, which resulted in continuous secretion of tumor-derived BiP into the extracellular milieu. We show that this secreted BiP is taken up by bone marrow-derived dendritic cells, and thereafter BiP-associated Ag peptide is cross-presented in association with MHC class I molecules, resulting in elicitation of an Ag-specific CD8(+) T cell response and antitumor effect. This strategy to boost antitumor immune responses shows that a tumor could be its own cellular vaccine via gene modification of the secretion of the tumor Ag-BiP complex.     

Distinct intracellular fates of membrane and secretory immunoglobulin heavy chains in a pre-B cell line

The intracellular fates of membrane and secretory immunoglobulin heavy chains were examined in a pre-B cell line that has switched to the gamma isotype. The membrane form of the heavy chain (gamma m) was rapidly degraded while the secretory form (gamma s) was retained intracellularly in association with BiP. The degradation of gamma m could not be inhibited by ammonium chloride, chloroquine, or monensin suggesting that it occurred in a nonlysosomal compartment. The inability to detect any Endo H-resistant form of gamma m before its degradation suggested that degradation occurs before entry into the Golgi compartment. Degradation of gamma m could be inhibited by incubation at 24 degrees C. In a derivative of this cell line expressing a transfected kappa gene, gamma s formed disulfide linked tetramers with kappa and was secreted, while gamma m, although associated with kappa, continued to be rapidly degraded. These observations suggest that membrane and secretory heavy chain proteins are retained by distinct intracellular mechanisms. Although masking of the CH1 domain abrogates gamma s retention, this domain does not influence the intracellular fate of gamma m.     

Somatic cell hybrids of mouse myeloma cells and B lymphocytes from a patient with agammaglobulinemia: failure to secrete human immunoglobulin.

Somatic cell hybrid clones were isolated from the fusion of RPC5.4 mouse myeloma cells and B lymphocytes from a patient with common varied agammaglobuinemia. The patient has B lymphocytes that synthesize immunoglobulin but fail to secrete immunoglobulin. The hybrid character of the six clones was established by examination of metaphase chromosome spreads. Most of the hybrid clones expressed mouse and human surface immunoglobulin. All of the clones synthesized immunoglobulin of mouse and human parental origin. Mouse parental immunoglobulin was secreted, whereas the human parental immunoglobulin was not secreted. Human light chain molecules were secreted as part of hybrid H2L2 molecules formed with mouse heavy chains. Human heavy chains had a reduced m.w. in comparison to the mouse heavy chains. Kinetic experiments indicated that human Ig was synthesized in amounts that were comparable to the mouse Ig. Pulse-chase experiments showed that that the intracellular human Ig was removed from the cytoplasm, probably by degradation. These experiments demonstrate that the hybrid cells are an in vitro model of naturally occurring failure of immunoglobulin secretion from agammaglobulinemia. The failure of fusion with mouse myeloma cells to complement the secretion defect suggests that these B cells produce an altered immunoglobulin molecule that is not programmed for secretion.     

An N-linked glycan modulates the interaction between the CD1d heavy chain and beta 2-microglobulin

Human CD1d molecules consist of a transmembrane CD1 (cluster of differentiation 1) heavy chain in association with beta(2)-microglobulin (beta(2)m). Assembly occurs in the endoplasmic reticulum (ER) and involves the initial glycan-dependent association of the free heavy chain with calreticulin and calnexin and the thiol oxidoreductase ERp57. Folding and disulfide bond formation within the heavy chain occurs prior to beta(2)m binding. There are four N-linked glycans on the CD1d heavy chain, and we mutated them individually to ascertain their importance for the assembly and function of CD1d-beta(2)m heterodimers. None of the four were indispensable for assembly or the ability to bind alpha-galactosyl ceramide and to present it to human NKT cells. Nor were any required for the CD1d molecule to bind and present alpha-galactosyl ceramide after lysosomal processing of a precursor lipid, galactosyl-(alpha1-2)-galactosyl ceramide. However, one glycan, glycan 2 at Asn-42, proved to be of particular importance for the stability of the CD1d-beta(2)m heterodimer. A mutant CD1d heavy chain lacking glycan 2 assembled with beta(2)m and transported from the ER more rapidly than wild-type CD1d and dissociated more readily from beta(2)m upon exposure to detergents. A mutant expressing only glycan 1 dissociated completely from beta(2)m upon exposure to the detergent Triton X-100, whereas a mutant expressing only glycan 2 at Asn-42 was more stable. In addition, glycan 2 was not processed efficiently to the complex form in mature wild-type CD1d molecules. Modeling the glycans on the published structure indicated that glycan 2 interacts significantly with both the CD1d heavy chain and beta(2)m, which may explain these unusual properties.     

Antigen presentation and the association of class-I molecules.

We have identified two mutant cell lines which are not able to present epitopes of influenza virus synthesized in the cytoplasm but can present the same epitope when exposed to it as a peptide in the extracellular medium. The cell lines also have a defect in class-I assembly, with reduced expression of assembled alpha chain: beta 2M heterodimers at their cell surface. This led to the suggestion that the two traits were the result of the same mutation and that stable assembly of class-I molecules is dependent on peptide binding. Consistent with this idea was the finding that exposure to specific peptides in the extracellular fluid promotes stable association of class-I heavy chains with beta 2M and restores expression of class-I at the cell surface. We have gone on to show that stable assembly of class-I molecules can be supported in detergent extracts of the mutant cells when specific peptides are added. Peptides stabilized a conformational change in the class-I heavy chain and association with beta 2M by binding to the complexes. This effect is apparent at peptide concentrations around 100-fold lower than required in "peptide feeding" experiments with whole cells. We have also demonstrated that the conformational change induced in heavy chain is influenced by the concentration of beta 2M, and consequently have been able to demonstrate the formation of empty class-I molecules.     

ERdj3, a stress-inducible endoplasmic reticulum DnaJ homologue, serves as a cofactor for BiP's interactions with unfolded substrates

We recently identified ERdj3 as a component of unassembled immunoglobulin (Ig) heavy chain:BiP complexes. ERdj3 also associates with a number of other protein substrates, including unfolded light chains, a nonsecreted Ig light chain mutant, and the VSV-G ts045 mutant at the nonpermissive temperature. We produced an ERdj3 mutant that was unable to stimulate BiP's ATPase activity in vitro or to bind BiP in vivo. This mutant retained the ability to interact with unfolded protein substrates, suggesting that ERdj3 binds directly to proteins instead of via interactions with BiP. BiP remained bound to unfolded light chains longer than ERdj3, which interacted with unfolded light chains initially, but quickly disassociated before protein folding was completed. This suggests that ERdj3 may bind first to substrates and serve to inhibit protein aggregation until BiP joins the complex, whereas BiP remains bound until folding is complete. Moreover, our findings support a model where interactions with BiP help trigger the release of ERdj3 from the substrate:BiP complex.