Both the environment and somatic mutations govern the aggregation pathway of pathogenic immunoglobulin light chain.

Deposition of monoclonal immunoglobulin light chain (LC) aggregates in tissues is the hallmark of a class of fatal diseases with no effective treatment. In the most prevalent diseases two different types of LC aggregates are observed: fibrillar deposits in LC amyloidosis (AL) and granular aggregates in LC deposition disease (LCDD). The mechanisms by which a given LC forms either type of aggregate are not understood. Although some LCs are more aggregation-prone than others, this does not appear to be due to specific sequence determinants, but more likely from global properties that can be introduced by multiple somatic mutations. Moreover, a single LC isotype can sometimes form both fibrillar and granular aggregates within the same patient. To better understand how the different aggregation pathways arise, we developed a series of in vitro assays to analyze the formation of distinct aggregate types. The recombinant kappa IV LC (SMA) assembles into fibrils when agitated. We now show that SMA can also form granular aggregates upon exposure to copper, and that this aggregation can occur not only in vitro, but also in cells. A constellation of somatic mutations, consisting of His89/His94/Gln96, is sufficient to confer sensitivity to copper on wild-type kappa IV proteins. The formation of both types of aggregates is inhibited by synthetic peptides derived from the LC variable domain. However, the peptide that inhibits fibrillar aggregation is different from the peptide that inhibits copper-induced aggregation. Thus, distinct molecular surfaces of the LC underly each type of aggregate. We conclude that both the intrinsic properties of the sequence and extrinsic conditions govern the aggregation pathway of a LC.

Hsp70 and antifibrillogenic peptides promote degradation and inhibit intracellular aggregation of amyloidogenic light chains.

In light chain (LC) amyloidosis an immunoglobulin LC assembles into fibrils that are deposited in various tissues. Little is known about how these fibrils form in vivo. We previously showed that a known amyloidogenic LC, SMA, can give rise to amyloid fibrils in vitro when a segment of one of its beta sheets undergoes a conformational change, exposing an Hsp70 binding site. To examine SMA aggregation in vivo, we expressed it and its wild-type counterpart, LEN, in COS cells. While LEN is rapidly oxidized and subsequently secreted, newly synthesized SMA remains in the reduced state. Most SMA molecules are dislocated out of the ER into the cytosol, where they are ubiquitinylated and degraded by proteasomes. A parallel pathway for molecules that are not degraded is condensation into perinuclear aggresomes that are surrounded by vimentin-containing intermediate filaments and are dependent upon intact microtubules. Inhibition of proteasome activity shifts the balance toward aggresome formation. Intracellular aggregation is decreased and targeting to proteasomes improved by overexpression of the cytosolic chaperone Hsp70. Importantly, transduction into the cell of an Hsp70 target peptide, derived from the LC sequence, also reduces aggresome formation and increases SMA degradation. These results demonstrate that an amyloidogenic LC can aggregate intracellularly despite the common presentation of extracellular aggregates, and that a similar molecular surface mediates both in vitro fibril formation and in vivo aggregation. Furthermore, rationally designed peptides can be used to suppress this aggregation and may provide a feasible therapeutic approach.

Inhibition of amyloid fiber assembly by both BiP and its target peptide.

Immunoglobulin light chain (LC) normally is a soluble, secreted protein, but some LC assemble into ordered fibrils whose deposition in tissues results in amyloidosis and organ failure. Here we reconstitute fibril formation in vitro and show that preformed fibrils can nucleate polymerization of soluble LC. This prion-like behavior has important physiological implications, since somatic mutations generate multiple related LC sequences. Furthermore, we demonstrate that fibril formation in vitro and aggregation of whole LC within cells are inhibited by BiP and by a synthetic peptide that is identical to a major LC binding site for BiP. We propose that LC form fibrils via an interprotein loop swap and that the underlying conformational change should be amenable to drug therapy.

Protein folding in the ER.

The endoplasmic reticulum (ER) is a major protein folding compartment for secreted, plasma membrane and organelle proteins. Each of these newly-synthesized polypeptides folds in a deterministic process, affected by the unique conditions that exist in the ER. An understanding of protein folding in the ER is a fundamental biomolecular challenge at two levels. The first level addresses how the amino acid sequence programs that polypeptide to efficiently arrive at a particular fold out of a multitude of alternatives, and how different sequences obtain similar folds. At the second level are the issues introduced by folding not in the cytosol, but in the ER, including the risk of aggregation in a molecularly crowded environment, accommodation of post-translational modifications and the compatibility with subsequent intracellular trafficking. This review discusses both the physicochemical and cell biological constraints of folding, which are the challenges that the ER molecular chaperones help overcome.

GRP94, an ER chaperone with protein and peptide binding properties.

GRP94 is the ER representative of the HSP90 family of stress-induced proteins. It binds to a limited number of proteins in the secretory pathway, apparently by recognizing advanced folding intermediates or incompletely assembled proteins, GRP94 also binds peptides and can act as a tumor vaccine, delivering the peptides for presentation to T lymphocytes. Here, we review the current data about GRP94 and propose a structural model that integrates the biochemical data and known functions of the protein.

Mapping the major interaction between binding protein and Ig light chains to sites within the variable domain.

Newly synthesized Ig chains are known to interact in vivo with the binding protein (BiP), a major peptide-binding chaperone in the endoplasmic reticulum. The predominant interactions between the light chain and BiP are observed early in the folding pathway, when the light chain is either completely reduced, or has only one disulfide bond. In this study, we describe the in vitro reconstitution of BiP binding to the variable domain of light chains (VL). Binding of deliberately unfolded VL was dramatically more avid than that of folded VL, mimicking the interaction in vivo. Furthermore, VL binding was inhibited by addition of ATP, was competed with excess unlabeled VL, and was demonstrated with several different VL proteins. Using this assay, peptides derived from the VL sequence were tested experimentally for their ability to bind BiP. Four peptides from both beta sheets of VL were shown to bind BiP specifically, two with significantly higher affinity. As few as these two peptide sites, one from each beta sheet of VL, are sufficient to explain the association of BiP with the entire light chain. These results suggest how BiP directs the folding of Ig in vivo and how it may be used in shaping the B cell repertoire.

Pathogenic light chains and the B-cell repertoire.

Dysfunctional immunoglobulins (Igs) that are prone to aggregation are unavoidably generated by the diverse repertoire of B cells. Here, Fred Stevens and Yair Argon analyse the patterns of mutations that lead to pathological Igs, account for non-random mutations in human Ig sequences and suggest the exertion of selective forces, which contribute to determining and limiting the Ig repertoire.

Interaction of radicicol with members of the heat shock protein 90 family of molecular chaperones.

The Hsp90 family of proteins in mammalian cells consists of Hsp90 alpha and beta, Grp94, and Trap-1 (Hsp75). Radicicol, an antifungal antibiotic that inhibits various signal transduction proteins such as v-src, ras, Raf-1, and mos, was found to bind to Hsp90, thus making it the prototype of a second class of Hsp90 inhibitors, distinct from the chemically unrelated benzoquinone ansamycins. We have used two novel methods to immobilize radicicol, allowing for detailed analyses of drug-protein interactions. Using these two approaches, we have studied binding of the drug to N-terminal Hsp90 point mutants expressed by in vitro translation. The results point to important drug contacts with amino acids inside the N-terminal ATP/ADP-binding pocket region and show subtle differences when compared with geldanamycin binding. Radicicol binds more strongly to Hsp90 than to Grp94, the Hsp90 homolog that resides in the endoplasmic reticulum. In contrast to Hsp90, binding of radicicol to Grp94 requires both the N-terminal ATP/ADP-binding domain as well as the adjacent negatively charged region. Radicicol also specifically binds to yeast Hsp90, Escherichia coli HtpG, and a newly described tumor necrosis factor receptor-interacting protein, Trap-1, with greater homology to bacterial HtpG than to Hsp90. Thus, the radicicol-binding site appears to be specific to and is conserved in all members of the Hsp90 family of molecular chaperones from bacteria to mammals, but is not present in other molecular chaperones with nucleotide-binding domains.

Partial block in B lymphocyte development at the transition into the pre-B cell receptor stage in Vpre-B1-deficient mice.

The surrogate light chain (SL) is composed of two polypeptides, Vpre-B and lambda5. In large pre-BII cells the SL chain associates with Ig mu heavy chain (muH) to form the pre-B cell receptor (pre-BCR). In mice there are two Vpre-B genes which are 98% identical within the coding regions. The two genes are co-expressed at the RNA level and encode functional proteins that can assemble with lambda5. However, it is not known whether both gene products serve the same function in vivo. Here we have established mice that lack the Vpre-B1 gene (VpreB1(-/-)), but still express the Vpre-B2 gene, both as RNA and protein. In Vpre-B1(-/-) mice, the bone marrow cellularity and the percentage of B220+ cells is normal. However, among the B220+ cells, the percentage of pre-BI cells is increased, and the percentage of pre-BII and immature B cells is slightly decreased, suggesting that the lack of Vpre-B1 causes a partial block at the transition from pre-BI to pre-BII cells, i.e. into the pre-BCR stage. The number of cells that produce a functional pre-BCR is thus lower, but the cells that reach this stage are normal as they can be expanded by proliferation and then differentiate into more mature cells. The spleens of Vpre-B1 homozygous mutant mice show normal numbers of B and T lymphocytes. Moreover, the Ig loci are allelicly excluded and the homozygous mutant mice respond with normal levels of antigen-specific antibodies to T-dependent antigens. These results demonstrate that VpreB2 alone is capable of supporting B lymphocyte development in the bone marrow and can give rise to immuno-competent cells in the periphery.

Folding of insulin receptor monomers is facilitated by the molecular chaperones calnexin and calreticulin and impaired by rapid dimerization.

Many complex membrane proteins undergo subunit folding and assembly in the ER before transport to the cell surface. Receptors for insulin and insulin-like growth factor I, both integral membrane proteins and members of the family of receptor tyrosine kinases (RTKs), are unusual in that they require homodimerization before export from the ER. To better understand chaperone mechanisms in endogenous membrane protein assembly in living cells, we have examined the folding, assembly, and transport of the human insulin receptor (HIR), a dimeric RTK. Using pulse-chase labeling and nonreducing SDS-PAGE analysis, we have explored the molecular basis of several sequential maturation steps during receptor biosynthesis. Under normal growth conditions, newly synthesized receptor monomers undergo disulfide bond formation while associated with the homologous chaperones calnexin (Cnx) and calreticulin (Crt). An inhibitor of glucose trimming, castanospermine (CST), abolished binding to Cnx/Crt but also unexpectedly accelerated receptor homodimerization resulting in misfolded oligomeric proreceptors whose processing was delayed and cell surface expression was also decreased by approximately 30%. Prematurely-dimerized receptors were retained in the ER and more avidly associated with the heat shock protein of 70 kD homologue binding protein. In CST-treated cells, receptor misfolding followed disordered oligomerization. Together, these studies demonstrate a chaperone function for Cnx/Crt in HIR folding in vivo and also provide evidence that folding efficiency and homodimerization are counterbalanced.

Phosphotransferases associated with the regulation of kinesin motor activity.

Kinesin, a plus-end-directed microtubule motor protein, functions in concert with accessory factors that have been shown to regulate enzyme activity and may also provide cargo specificity. This report identifies teh 79-kDa kinesin-associated phosphoprotein as a phosphoisoform of kinesin light chain. Increased phosphorylation of this light chain isoform is sufficient to account for the increase in kinesin-mediated microtubule-gliding activity. Additionally, it was found that the degree of phosphorylation of this isoform is regulated by a 100-kDa kinase and 150-kDa type 1 phosphatase. Both the kinesin light chain kinase and phosphatase co-purify with the kinesin heavy chain, suggesting that kinesin exists in a large complex capable of self-regulation.

Ig light chains are secreted predominantly as monomers.

Ig light (L) chains are secreted not only as part of assembled Ab molecules, but also as free L chains, the latter process being involved in the pathology of several diseases. The secretion competence of free L chains distinguishes them from free subunits of other oligomeric proteins, which are usually retained intracellularly. We used several techniques to test the idea that secretion of free L chains is dependent on dimerization. Coexpression of pairs of L chains, differing in only one amino acid, which alters the secretory phenotype, shows that these L chains behave independently: the wild-type chains are secreted, whereas the mutants are retained intracellularly. A survey of kappa- or lambda-producing cell lines by nonreducing gel electrophoresis shows that a negligible fraction of these L chains exists as disulfide-bonded dimers. Moreover, chemical cross-linking and density gradient centrifugation demonstrate that there is no significant pool of noncovalent L chain dimers. Noncovalent heterodimers can be detected readily between a kappa-chain and a chimera consisting of a heavy chain variable domain linked to the kappa-chain constant domain. This confirms that noncovalent L chain homodimers would have been detected if they were present. These findings about the association state of free L chains are independent of the host cell, as they are observed in both myeloma cells and COS fibroblasts. We conclude that L chain dimerization is a rare event that neither facilitates secretion nor is required for it.

Inhibition of immunoglobulin folding and secretion by dominant negative BiP ATPase mutants.

A group of resident ER proteins have been identified that are proposed to function as molecular chaperones. The best characterized of these is BiP/GRP78, an hsp70 homologue that binds peptides containing hydrophobic residues in vitro and unfolded or unassembled proteins in vivo. However, evidence that mammalian BiP plays a direct role in protein folding remains circumstantial. In this study, we examine how BiP interacts with a particular substrate, immunoglobulin light chain (lambda LC), during its folding. Wild-type hamster BiP and several well-characterized BiP ATPase mutants were used in transient expression experiments. We demonstrate that wild-type lambda LCs showed prolonged association with mutant BiP which inhibited their secretion. Both wild-type and mutant BiP bound only to unfolded and partially folded LCs. The wild-type BiP was released from the incompletely folded LCs, allowing them to fold and be secreted, whereas the mutant BiP was not released. As a result, the LCs that were bound to BiP mutants were unable to undergo complete disulfide bond formation and were retained in the ER. Our experiments suggest that LCs undergo both BiP-dependent and BiP-independent folding steps, demonstrating that both ATP binding and hydrolysis activities of BiP are essential for the completion of LC folding in vivo and reveal that BiP must release before disulfide bond formation can occur in that domain.

The murine VpreB1 and VpreB2 genes both encode a protein of the surrogate light chain and are co-expressed during B cell development.

The surrogate light chain is composed of two polypeptides, VpreB and lambda 5. In the mouse there are two VpreB genes which are 99% identical within the coding regions. Extensive restriction enzyme mapping and sequencing of these two genes showed that only the coding region and immediate 5' and 3' flanking sequences exhibited such high homology. More distal sequences have diverged considerably. The region 5' of the respective gene directed transcription of a reporter gene in a pre-B cell line, indicating that it contained promoter, and perhaps enhancer function. The VpreB2 gene is functional, as it directed the production in COS cells of a 16-kDa protein that assembled with lambda 5 and was recognized by a VpreB-specific monoclonal antibody. Using transfected COS cells expressing either VpreB1 or VpreB2, a PCR assay was developed to examine the steady state level of transcripts from each gene. When this assay was applied to a number of cell lines representing early stages of B cell differentiation, co-expression of the two genes was observed in every case. VpreB1 and VpreB2 were co-expressed in the fetal liver of CB17 mice, where peak expression of each gene occurred at days 16-17 of gestation. Similarly, adult bone marrow from several strains of mice expressed both genes. In sorted bone marrow cells expression of both VpreB genes was detected in pro-B/pre-BI and large pre-BII cells, while the RNA steady state levels were at least 100-fold lower in small pre-BII and immature/mature B cells. Finally, single-cell reverse transcriptase-polymerase chain reaction on such sorted bone marrow cells detected VpreB1 and VpreB2 expression in at least 30% of all pro-B/pre-BI cells and large Ig heavy chain, surrogate light chain (pre-B receptor) expressing pre-BII cells. These results demonstrate that the control of expression of the two VpreB genes overlaps during development. They suggest that both VpreB1 and VpreB2 polypeptides can assemble with lambda 5 and mu to form pre-B cell receptor complexes.

Molecular chaperones and the biosynthesis of antigen receptors.

Oligomeric antigen receptors must fold and assemble in the endoplasmic reticulum (ER) before they can be expressed on the surface of lymphocytes. It is increasingly evident that these processes are facilitated by molecular chaperones. Here, Jeffrey Melnick and Yair Argon review the known ER chaperones, summarize their roles in the maturation of antigen receptors, and discuss how they may affect lymphocyte differentiation and function.

Structure and biogenesis of lytic granules.

Lytic granules are specialized secretory organelles which appear after activation of CTLs and NK cells. The lytic granules contain a series of proteins that mediate target cell destruction after secretion from the cell. In addition, these organelles serve as the lysosomes of these lymphocytes. At the EM level three types of granules with distinct regions are distinguished. Intriguingly, lytic and lysosomal proteins are localized in distinct regions. This is particularly interesting because lysosomal and lytic proteins can use the same sorting mechanisms to be targeted to this compartment. We favor the idea that a combination of sorting mechanisms result in this final segregation: the MPR receptor sorts both lysosomal proteins and granzymes from the Golgi complex, but a second event, such as selective aggregation with proteoglycans, then results in the segregation of lytic and lysosomal proteins in the granule. Lytic granules provide a way to store and simultaneously secrete the lytic proteins in a highly specific fashion. The granules are able to move along microtubules using a kinesin-like motor, and thus can cluster at the site of membrane contact with a target cell. Once polarized, the granules exocytose their contents, using a molecular machinery that is as yet poorly defined. Understanding the machinery involved in both functions of the lytic granules will provide ways to control the action of cytotoxic lymphocytes, ultimately in clinical situations.

Sequential interaction of the chaperones BiP and GRP94 with immunoglobulin chains in the endoplasmic reticulum.

During their transit through the endoplasmic reticulum, newly synthesized light and heavy chains of immunoglobulins associate with two endoplasmic reticulum stress proteins. BiP/GRP78, a member of the HSP70 family, binds these polypeptides, presumably through promiscuously exposed hydrophobic sequences, soon after their translocation into the endoplasmic reticulum. GRP94, another endoplasmic reticulum stress protein homologous to HSP90, also associates with unassembled immunoglobulin chains, but its interaction is biochemically, kinetically and structurally distinct from BiP's. We report here that whereas BiP preferentially binds an early disulphide intermediate of light chain and dissociates within a few minutes, GRP94 exclusively binds fully oxidized molecules and dissociates with a half-time of 50 min. These results indicate that GRP94 is itself a chaperone which acts after BiP.

Regulation of kinesin activity by phosphorylation of kinesin-associated proteins.

The mechanochemical motor proteins of the kinesin and cytoplasmic dynein families play important roles in microtubule-based intracellular motility. Although movement and distribution of organelles like secretory granules, vesicles, endoplasmic reticulum, and chromosomes depend on the activity of these motor proteins, little is known about the regulation of this movement. We report here that the hyperphosphorylation of components of the kinesin complex by treatment with okadaic acid increases kinesin motor activity at least 2-fold. The stimulation was observed using both a granule motility assay and a microtubule gliding assay, indicating that phosphorylation enhances the activity of the motor itself, rather than the affinity of the motor for membrane organelles. Under stimulatory conditions, three proteins that co-purify with kinesin (with mobilities of 150, 79, and 73 kDa) are consistently hyperphosphorylated. Dephosphorylation of these proteins reduces kinesin activity to basal levels. Therefore, we conclude that kinesin motor activity is directly modulated by the phosphorylation state of kinesin-associated proteins.

The giant organelles in beige and Chediak-Higashi fibroblasts are derived from late endosomes and mature lysosomes.

Chediak-Higashi Syndrome (CHS) is an autosomal recessive disease affecting secretory granules and lysosomes-like organelles. In CHS fibroblasts, acidic organelles are abnormally large and clustered in the perinuclear area. We have analyzed fibroblast cell lines from a CHS patient and from the murine model for CHS, the beige mouse, to determine which lysosome-like compartments are affected. Uptake of neutral red showed that in both beige and CHS cell lines, the acidic organelles were markedly clustered in the perinuclear region of the cells. Giant organelles (> 4 microns) were observed in a fraction of the cells, and these were more dramatic in the beige fibroblasts than in the CHS fibroblasts. The total dye uptake of both mutant cell lines was similar to their respective wild type fibroblasts, suggesting that the overall volume of acidic compartments is unaffected by the disorder. Histochemistry and immunofluorescence showed that the giant organelles in both beige and CHS fibroblasts were positive for cathepsin D, lysosome-associated membrane protein (LAMP) 1, LAMP 2, and a 120-kD lysosomal glycoprotein, all marker proteins for late endosomes and lysosomes. The giant organelles were also negative for transferrin receptor and mannose-6-phosphate receptor, and most of them were also negative for rab 7. This distribution of marker proteins shows that the giant organelles in both beige and CHS are derived from late compartments of the endocytic pathway. This conclusion was confirmed using endocytic tracers. BSA was transported to the giant organelles, but only after long incubation times, and only at 37 degrees C. alpha 2-Macroglobulin was taken up and degraded at similar rates by CHS or beige cells and their respective wild type control cells. Taken together, our results indicate that the mutation in CHS specifically affects late endosomes and lysosomes, with little or no effect on early endosomes. Although the mutation clearly causes mislocalization of these organelles, it appears to have little effect on their endocytic and degradative functions.