Direct evidence that J chain regulates the polymeric structure of IgM in antibody-secreting B cells.

IgM is secreted in two functional polymeric forms. Secreted IgM was originally thought to be exclusively a pentameric molecule containing J (joining) chain, but many B cells also secrete hexameric IgM lacking J chain. Hexameric IgM may play an important role in the immune system, since it is up to 20 times more active than pentameric IgM in initiating the complement cascade. The predominant polymeric form of IgM secreted by B cell lines, either pentameric or hexameric, correlates with the concentration of J chain present during polymerization, and cells that express high levels of J chain secrete mostly IgM pentamers. The B cell lymphoma WEHI-231 does not express J chain, and the majority of its secreted IgM is polymerized as hexamers. When a J chain-encoding cDNA was expressed in these cells, the secreted IgM was found to be almost exclusively pentameric. However, although the expression of J chain dramatically altered the phenotype of the IgM secreted by these cells, it had little effect on their secretory rate. We conclude that J chain regulates the structure and function of the IgM polymers secreted by B cells, but it is not necessary for either IgM polymerization or secretion.     

Biosynthesis of immunoglobulin A (IgA) and immunoglobulin M (IgM). Requirement for J chain and a disulphide-exchanging enzyme for polymerization

Mouse myeloma cells secreting 19S IgM (immunoglobulin M) (MOPC 104E and TEPC 183) or monomer and polymer IgA (immunoglobulin A) (MOPC 315) were incubated with radioactive leucine and the intracellular and secreted immunoglobulins and immunoglobulin subunits were prepared by preparative sucrose-density-gradient centrifugation. Samples were reduced in the presence or absence of isolated J chain, passed over Sephadex G-25 and then incubated at 37 degrees C for 30min with or without a source of disulphide-interchange enzyme. The extent of reassembly of reduced subunits was then evaluated by electrophoresis in polyacrylamide gels. Provided that J chain and the disulphide-interchange enzyme were supplied, both IgM and IgA could be assembled from their respective subunits, obtained by reductive cleavage of polymeric forms. Under similar conditions, assembly of polymeric forms from intracellular or secreted 7S monomer subunits also occurred. Under these conditions polymerization was total, there being no residue of the monomeric form. Reassembly did not occur in the absence of either J chain or the enzyme. All of the J chain released from IgM by reductive cleavage was incorporated back into the reassembled polymer. The J chain is therefore likely to be an essential structural requirement for polymeric immunoglobulins. A variety of controls ruled out non-specific interactions, and further suggested that the amino acid sequence of polypeptide chains determines the specificity of polymerization. The fact that intracellular IgA and IgM monomer subunits known to be deficient in galactose and fucose can be completely polymerized suggests that the addition of carbohydrate does not control polymerization.     

The carboxyl-terminal domains of IgA and IgM direct isotype-specific polymerization and interaction with the polymeric immunoglobulin receptor

Mucosal surfaces are protected by polymeric immunoglobulins that are transported across the epithelium by the polymeric immunoglobulin receptor (pIgR). Only polymeric IgA and IgM containing a small polypeptide called the "joining" (J) chain can bind to the pIgR. J chain-positive IgA consists of dimers, and some larger polymers, whereas only IgM pentamers incorporate the J chain. We made domain swap chimeras between human IgA1 and IgM and found that the COOH-terminal domains of the heavy chains (Calpha3 and Cmu4, respectively) dictated the size of the polymers formed and also which polymers incorporated the J chain. We also showed that chimeric IgM molecules engineered to contain Calpha3 were able to bind the rabbit pIgR. Since the rabbit pIgR normally does not bind IgM, these results suggest that the COOH-terminal domain of the polymeric immunoglobulins is primarily responsible for interaction with the pIgR. Finally, we made a novel chimeric IgA immunoglobulin, containing the terminal domain from IgM. This recombinant molecule formed J chain-containing pentamers that could, like IgA, efficiently form covalent complexes with the human pIgR ectodomain, known as secretory component.     

Structural requirements for polymeric immunoglobulin assembly and association with J chain

Both IgM and IgA exist as polymeric immunoglobulins. IgM is assembled into pentamers with J chain and hexamers lacking J chain. In contrast, polymeric IgA exists mostly as dimers with J chain. Both IgM and IgA possess an 18-amino acid extension of the C terminus (the tail-piece (tp)) that participates in polymerization through a penultimate cysteine residue. The IgM (mutp) and IgA (alphatp) tail-pieces differ at seven amino acid positions. However, the tail-pieces by themselves do not determine the extent of polymerization. We now show that the restriction of polymerization to dimers requires both C(alpha)3 and alphatp and that more efficient dimer assembly occurs when C(alpha)2 is also present; the dimers contain J chain. Formation of pentamers containing J chain requires C(mu)3, C(mu)4, and the mutp. IgM-alphatp is present mainly as hexamers lacking J chain, and mumugammamu-utp forms tetramers and hexamers lacking J chain, whereas IgA-mutp is present as high order polymers containing J chain. In addition, there is heterogeneous processing of the N-linked carbohydrate on IgA-mutp, with some remaining in the high mannose state. These data suggest that in addition to the tail-piece, structural motifs in the constant region domains are critical for polymer assembly and J chain incorporation.     

Intermolecular disulfide bonding in IgM: effects of replacing cysteine residues in the mu heavy chain.

The conventional model of polymeric IgM depicts a unique structure in which the mu heavy chains and J chain are joined by well defined disulfide bonds involving cysteine residues at positions 337, 414 and 575 of the mu chain. To test this model, we have used site directed mutagenesis to produce IgM in which these cysteines have been replaced by serine. In each case the single mutants were able to assemble polymeric IgM, which was analyzed for its size, morphology, J chain content and activity in complement dependent cytolysis. Whereas normal polymeric IgM is composed predominantly of pentameric and hexameric molecules, the mutant IgM-Ser414 is covalently assembled as pentamers and smaller forms; IgM-Ser575 is assembled as covalent hexamers. IgM-Ser337 appears to include the same pentameric and hexameric forms as normal IgM except that, unlike normal polymeric IgM, most pentameric/hexameric IgM-Ser337 is not covalently assembled. J chain is present in polymeric IgM-Ser337 but absent in polymeric IgM-Ser414 and IgM-Ser575. IgM-Ser414 is defective in activating the classical pathway of complement dependent cytolysis. Our observations are consistent with models in which the covalent linkages between mu chains are mediated by disulfide bonded Cys337-Cys337, Cys414-Cys414 and Cys575-Cys575 but indicate that the arrangement of these Cys-Cys pairs in series and in parallel varies among and within IgM molecules.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gene transfer of immunoglobulin light chain restores heavy chain secretion

Several lines of evidence suggest that immunoglobulin (Ig) light (L) chain plays a role in the secretion of heavy (H) chain. For example, myeloma variant lines, which synthesize the Ig H chain but not the L chain, fail to secrete H chain protein. Here we have tested directly the role of chain assembly in the control of Ig secretion by the transfer of functional L chain genes into two such L chain-defective myeloma mutants. A lambda 2 or kappa L chain gene was introduced into variant lines of the mouse myelomas MOPC 315 (IgA, lambda 2) or PC7 (IgM, kappa), respectively. Although the two mutant lines are unable to secrete the H chain they produce, rescue of secretion of complete Ig protein molecules (IgA or IgM) was observed after transfection. These results imply that the secretory apparatus of these cells is intact and that the failure to secrete free H chain reflects a structural feature intrinsic to that protein. The implications of these results with respect to control of secretion of multi-subunit proteins are discussed.     

The incorporation of J chain into reassembled human immunoglobulin M

Human IgM (immunoglobulin M) was reduced with 24mm-mercaptoethylamine. This atreatment resulted in complete dissociation to IgMs subunits and free J chain. Intr-subunit interchain disulphide bonds remained intact. The mixture then was encouraged to reoxidize. The schlieren pattern of the reoxidized mixture showed the presence of a considerable quantity of IgM in addition to residual IgMs. The isolated reassembled IgM did not dissociate in 5m-guanidinium hydrochloride. It apparently contained the same amount of covalently attached J chain as did native IgM. The J chain was a part of the high-molecular-weight Fc fragment obtained from the reassembled IgM.     

Mutations affecting the structure and function of immunoglobulin M.

Using a hybridoma cell line which secretes hapten-specific immunoglobulin M (IgM), we have isolated a variety of mutants which produce abnormal immunoglobulin. Immunoglobulin was tested for the size and composition of the component heavy and light chains and for variable and constant region related functional and serological activities. Some mutants secrete IgM which seems to be defective in hapten binding; others make IgM which appears not to activate complement. Many of the mutants secrete monomeric as opposed to pentameric IgM. In some cases, the defect apparently correlates with structural alterations in the mu heavy chain: partial deletion, polypeptide addition, and abnormal glycosylation have been observed. These mutant cell lines provide a means of identifying the structural basis of IgM function and of studying the biochemistry of IgM synthesis and processing.     

Selective proteolysis of the J chain component in human polymeric immunoglobulin.

To clarify the losses that have been observed in the J chain portion of human IgM and IgA, were carried out studies on the enzymatic susceptibility of the J polypeptide. When Waldenstr?m macroglobulins and myeloma IgA polymers were subjected to limited proteolysis with various endopeptidases, only subtilisin was found to attack the J chain component. The pattern of cleavage was a function of the polymer species. The J chain in IgM was highly susceptible to digestion, quantitative cleavage being achieved at very low enzyme to IgM ratios and without significant changes in the remaining pentamer structure. Analyses of the digestion products showed that the initial cleavage occurred at an exposed region midway in the J sequence and was followed by extensive degradation of the carboxy-terminal segment. These findings indicated that the observed loss of the IgM J component can be explained by the inadvertent introduction of subtilisin in vitro or by the attack of in vivo enzymes with a specificity similar to subtilisin. In contrast, the IgA J chain was found to be much more resistant to subtilisin proteolysis; its cleavage required higher enzyme concentrations and was accompanied by significant degradation of the alpha-chains. Thus, it appears unlikely that the IgA J polypeptide is degraded by either in vitro or in vivo enzymes unless its accessibility is first enhanced by changes in the IgA Fc structure.     

Investigations of the structural function of the J chain in human immunoglobulin M

Human IgM molecules were treated with Na(2)SO(3) or mercaptoethylamine in concentrations ranging from 2 to 14mm or 2 to 22mm respectively. The dissociation of IgM to IgM(s) varied from 0% to 100%. At the intermediate concentrations of either reagent the amount of freed J chains was less than expected. In an attempt to find an explanation for this, IgM was partially dissociated to IgM(s) with mercaptoethylamine. The IgM(s) isolated by gel filtration was divided according to the ascending and descending portions of the elution curve. These portions were treated with 24mm-mercaptoethylamine and analysed for the presence of J chains. Only the ascending portion contained free J chains. Thus, after mild reduction where not all the IgM molecules are dissociated to IgM(s), some J chains remain covalently attached to some IgM(s) molecules although most of the J chains are freed. It was concluded that the J chain could serve as a ;hitch' for IgM(s) molecules forming intact IgM.     

Effect of a disulfide-interchange enzyme on the assembly of human secretory immunoglobulin A from immunoglobulin A and free secretory component.

A disulfide-interchange enzyme from rat liver microsomes was found to promote binding in vitro of human free secretory component (SC) to dimeric serum-type IgA containing J chain, as assessed by immune precipitation and gel filtration. This effect was greater withe native than with partially reduced SC. Most of the bound SC was covalently linked, as determined by electrophoresis in polyacrylamide gels in detergent. The enzyme did not promote binding of native or partially reduce SC to IgG, IgA monomer, IgA dimer without J chain, or IgM. In the case of IgM, the enzyme did, however, promote covalent bonding of previously non-covalently linked SC. The results overall suggest that a disulfide-interchange enzyme could play a role in vivo in the cell-associated assembly of secretory IgA by promoting the covalent attachment of SC to a dimer of serum-type IgA and that the J chain in the IgA dimer contributes to the enzyme effect.     

Cloning and expression of the chicken immunoglobulin joining (J)-chain cDNA

 The J chain is a component of polymeric immunoglobulin (Ig) molecules and may play an important role in their polymerization and the transport of polymeric Ig across epithelial cells. In this study, the primary structure of the chicken J chain was determined by sequencing cDNA clones. The cDNA had an open reading frame of 476 nucleotides encoding a putative protein of 158 amino acid residues including the signal sequence. The 3′ untranslated region consisted of 1216 nucleotides and a poly(A) tail. The deduced amino acid sequence of the chicken J chain had a high degree of homology to that of human, cow, rabbit, mouse, frog, and earthworm, with eight conserved Cys residues identical to the mammalian J chains. Northern blot hybridization performed with total RNA from various chicken tissues revealed high levels of J-chain mRNA expression in spleen, intestine, Harderian gland, and bursa of Fabricius, and low levels in the thymus. The J chain was expressed in the bursa as early as day 15 of embryogenesis. These data indicated that the chicken J-chain gene displays a high degree of homology with that of other species, and is expressed at an early stage of development of the chicken immune system. Received: 21 May 1999 / Revised: 30 August 1999     

Polymerization of human immunoglobulin M.

The repolymerization of human IgM following mild reductive cleavage was studied as a model for intracellular polymer assembly. Repolymerization was found to require the presence of J chain and a disulfide exchanging system which could be furnished either intrinsically by the use of the monofunctional thiol mercaptoethylamine or extrinsically by the inclusion of a protein-mercaptan mixed disulfide, and/or a disulfide exchanging enzyme. The degree of repolymerization was dependent on the extent of monomer reduction and the product covalently incorporated one J chain per five monomer units. Disulfide exchanging enzyme probably served as a source of mixed disulfides rather than as an enzymatic catalyst of the reaction. These results are discussed in terms of a tentative mechanism for IgM polymerization.     

Characterization of serum immunoglobulin M of the Antarctic teleost Trematomus bernacchii

Trematomus bernacchii immunoglobulin M concentration was determined in the serum by ELISA; the mean concentration value was 2.7 mg/ml corresponding to 9.6% of the total serum proteins. Purified IgM was analyzed by SDS-polyacrylamide gel electrophoresis, isoelectrofocusing and 2D electrophoresis. The relative molecular mass of the polymeric form was 830 kDa; that of separated H and L chains was, respectively, 78 and 25 kDa. The isoelectric points of the entire molecule ranged from 4.4 to 6.5, that of isolated H chains was between 4.0 and 6.0. Separated H chains were shown to reaggregate in tetrameric form. The cleavage site of trypsin was at the end of the CH1 domain, as confirmed by the N-terminal amino acid sequence of one of the resultant peptides. Immunoblotting was used to detect carbohydrates in the H and L chains labeled with digoxigenin. Glycosyl residues were detected only in the H chain. The carbohydrate content was evaluated to be 12.8% of the entire chain. Purified Igs were hydrolyzed by N-glycosidase F at different conditions and at least four different hydrolytic sites were revealed by limited deglycosylation. T. bernacchii IgM was also compared to those of five other polar fish species.     

High level expression of functional human IgMs in human PER.C6? cells

Natural IgM antibodies play an important role in the body''s defense mechanisms against transformed cells in the human body and are currently being exploited both in prognoses of malignant lesions and in the therapy of cancer patients. However, despite growing interest and clinical promise, thus far the IgM class of antibodies has failed to gain widespread commercial interest as these are considered to be difficult to produce recombinantly. IgMs are polymeric and have a relatively large mass. In addition, IgM molecules are heavily glycosylated and, when produced in non-human cell lines, they may contain non-human glycan structures which may be potentially immunogenic. Clearly, production systems capable of expressing human recombinant IgM antibodies are needed. We have successfully used PER.C6® cells—a human cell line—to generate three separate human recombinant monoclonal IgMs in suspension cultures in protein-free medium. All three of the IgMs were constructed with joining (J) chain and were expressed in the pentameric form. One of the IgMs was also expressed as a hexamer without J chain. Clones with cell specific productivities greater than 20 pg/cell/day were generated, which led to yields of 0.5 g/L to 2g/L in fed-batch production. All the IgMs expressed were biologically active as shown in binding and cytotoxicity assays. These studies demonstrate the potential of PER.C6® cells for the production of high levels of functional recombinant IgM and other polymeric molecules, using a straightforward and rapid stable cell line generation method.Key words: PER.C6®, IgM, expression, hexamer, pentamer, J chain     

Biosynthesis of immunoglobulin A (IgA) and immunoglobulin M (IgM). Control of polymerization by J chain

Cell suspensions of mouse plasma-cell tumours secreting IgA (immunoglobulin A) and IgM (immunoglobulin M) were incubated with radioactive leucine for various periods of time. The secreted immunoglobulins were precipitated from the culture medium with specific rabbit antisera to determine the relative distribution of radioactivity among the different molecular species, and to estimate the fraction of total radioactivity in the J chain. For IgM-secreting cells there is a balanced synthesis of 7S subunits and J chains, and the secreted product is uniformly assembled to the pentamer. In cells secreting IgA, however, the results demonstrate that the pool of intracellular J chain is less than the intracellular IgA pool. The concentration of J chain is therefore limiting and is less than the requirement for complete polymerization. The major factor that determines whether an intracellular monomer is secreted as such or is polymerized with the addition of J chain is therefore the amount of intracellular J chain. When this is limiting, as it is in cells secreting IgA, then monomer will be secreted.     

High level expression of functional human IgMs in human PER.C6® cells

Natural IgM antibodies play an important role in the body’s defense mechanisms against transformed cells in the human body and are currently being exploited both in prognoses of malignant lesions and in the therapy of cancer patients. However, despite growing interest and clinical promise, thus far the IgM class of antibodies has failed to gain widespread commercial interest as these are considered to be difficult to produce recombinantly. IgMs are polymeric and have a relatively large mass. In addition, IgM molecules are heavily glycosylated and, when produced in non-human cell lines, they may contain non-human glycan structures which may be potentially immunogenic. Clearly, production systems capable of expressing human recombinant IgM antibodies are needed. We have successfully used PER.C6® cells – a human cell line - to generate three separate human recombinant monoclonal IgMs in suspension cultures in protein-free medium. All three of the IgMs were constructed with joining (J) chain and were expressed in the pentameric form. One of the IgMs was also expressed as a hexamer without J chain. Clones with cell specific productivities greater than 20 pg/cell/day were generated, which led to yields of 0.5 g/L to 2g/L in fed-batch production. All the IgMs expressed were biologically active as shown in binding and cytotoxicity assays. These studies demonstrate the potential of PER.C6® cells for the production of high levels of functional recombinant IgM and other polymeric molecules, using a straightforward and rapid stable cell line generation method.     

The intracellular ratio of the membrane to the secreted form of immunoglobulin M heavy chain is a measure of the developmental stage of B cell lymphomas

Tumors of B lymphocyte origin have been used as models for normal B cells “frozen” at particular stages of their development. Surface properties, amount, and intracellular location of immunoglobulin and the synthesis of J chain have all been used as indicators of developmental stages. Each requires special techniques or yields data that are difficult to compare from one experiment to the next. For these reasons, we have developed a metric for B cell development that is simple to perform and allows quick quantitative comparisons of cell lines. It has recently been established that the membrane (μ_m) and secreted (μ_s) forms of the IgM heavy chain differ at their extreme carboxy termini. The two proteins differ slightly in size and are easily distinguished when they are compared without their carbohydrate on sodium dodecyl sulfate (SDS) polyacrylamide gels. We have examined four mouse tumors derived from the B lymphocyte lineage whose phenotypes resemble late pre-B cells (internal μ only; uninduced 70Z/3), small B lymphocytes (high levels of surface IgM; LPS-induced 70Z/3, WEHI 231), lymphoblasts (both membrane and secreted IgM; WEHI 279.1), and plasma cells (copious IgM secretion; MOPC 104E). Despite the fact the 70Z/3 and WEHI 231 secrete no detectable IgM, all of the tumors synthesize at least intracellular forms of both μ_m and μ_s. The proportion of μ_m is stable and is characteristic of each tumor. The 70Z/3 cells and WEHI 231 cells synthesize about 75% of their total μ as μ_m; WEHI 279.1 cells synthesize about 30% and MOPC 104E cells about 5% of their total μ as μ_m. The population of LPS-stimulated B lymphocytes shows a similar progression during its differentiation. The proportion of μ_m correlates with other developmentally regulated parameters (Fc receptor, Ia and plasma cell antigen levels, and J chain) and can be used as a simple metric for comparison with developing B lymphocytes and determination of the developmental stage of a B cell tumor.