The roles of gamma 1 heavy chain membrane expression and cytoplasmic tail in IgG1 responses

In antibody responses, B cells switch from the expression of immunoglobulin (Ig) mu and delta heavy (H) chains to that of other Ig classes (alpha, gamma, or epsilon), each with a distinct effector function. Membrane-bound forms of alpha, gamma, and epsilon, but not mu and delta, have highly conserved cytoplasmic tails. Mutant mice unable to express membrane gamma1 H chains or producing tailless gamma1 H chains failed to generate efficient IgG1 responses and IgG1 memory. H chain membrane expression after class switching is thus required for these functions, and class switching equips the B cell antigen receptor with a regulatory cytoplasmic tail that na?ve B cells lack.     

Structural and functional analysis of J chain-deficient IgM

Previous studies have discerned two forms of polymeric mouse IgM: moderately cytolytic (complement-activating) pentamer, which contains J chain, and highly cytolytic hexamer, which lacks J chain. To investigate the relationships among polymeric structure, J chain content, and cytolytic activity, we produced IgM in J chain-deficient and J chain-proficient mouse hybridoma cell lines. Both hexamer and pentamer were produced in the absence as well as the presence of J chain. Hexameric IgM activated (guinea pig) complement approximately 100-fold more efficiently than did J chain-deficient pentamer, which, in turn, was more active than J chain-containing pentamer. These results are consistent with the hypothesis that J chain-containing pentamer cannot activate complement. We also analyzed the structure of IgM-S337, in which the mu-chain bears the C337S substitution. Like normal IgM, IgM-S337 was formed as a hexamer and as both J chain deficient- and J chain-containing pentamers. Unlike normal IgM, IgM-S337 dissociated in SDS into various subunits. For IgM-S337 pentamer, the predominant subunits migrated as mu2kappa2 and mu4kappa4, and the subunit distribution was unaltered by J chain. However, J chain was found only in the mu2kappa2 species, suggesting that some arrangement of inter-mu bonds directs incorporation of J chain. IgM-S337 hexamer also dissociated to mu2kappa2 and mu4kappa4, but also yielded several species migrating much more slowly in SDS-PAGE than wild-type mu12kappa12. To account for these forms, we propose that each mu-chain can interact with three other mu-chains and that some hexameric molecules contain two catenated mu6kappa6 circles.     

Mucosal immunity--a major adaptive defence mechanism

The epithelial glycoprotein called secretory component (SC) is quantitatively the most important receptor of the immune system because it is responsible for external transport of locally produced polymeric IgA (pIgA) to generate remarkably large amounts of secretory IgA. Antibodies of this type constitute the major mediators of specific humoral immunity. Transmembrane SC belongs to the Ig supergene family and functions as a common pIg receptor, also translocating pentameric IgM externally to form secretory IgM. The B cells responsible for mucosal pIg production are initially stimulated in organized mucosa-associated lymphoepithelial structures, particularly the Peyer's patches in the distal small intestine; from these inductive site they migrate as memory cells to exocrine tissues all over the body. Mucous membranes are thus furnished with secretory antibodies in an integrated way, ensuring a variety of specificities at every secretory effector site. There is currently great interest in exploiting this integrated or "common" mucosal immune system for oral vaccination against pathogenic infectious agents and also to induce tolerance in T cell-mediated autoimmune diseases. However, much remains to be learned about mechanisms for antigen uptake and processing necessary to elicit stimulatory or suppressive mucosal immune responses. Moreover, evidence is emerging for the existence of considerable regionalization with regard to functional links between inductive sites and effecter sites of mucosal immunity.     

Role of mu heavy chain in B cell development. I. Blocked B cell maturation but complete allelic exclusion in the absence of Ig alpha/beta

There is good evidence for a signaling role played by Ig heavy chain in the developmental transition through the pre-B cell stage. We have previously described signal-capable or signal-incapable mutants of mu heavy chain in which a signaling defect is caused by failure to associate with the Ig alpha/beta heterodimer. To further characterize the role of Ig heavy chain-mediated signaling in vivo, as well as in B cell development and allelic exclusion, we have created transgenic mice in which the B cells express these signal-capable and signal-incapable mutant mu chains. Failure of mu to signal via Ig alpha/beta results in a block in B cell development in mice expressing the signal-incapable mu. A small number of B cells in these animals do escape the developmental block and are expressed in the spleen and the periphery as B220+ transgenic IgM+ cells. These cells respond to LPS by proliferating but show no response to T-independent-specific Ag. In contrast, B cells expressing the signal-capable B cell receptor show a strong signaling response to Ag-specific stimulus. There is no Ig alpha seen in association with signal-deficient IgM. Thus, the B cell receptor complex is not assembled, and no signal can be delivered. Despite the block in developmental signaling, allelic exclusion is complete. There is no detectable coexpression of transgenic IgM and endogenous murine IgM, nor is there rearrangement of the endogenous heavy chain genes. This suggests that differing signaling mechanisms are responsible for the developmental transition and allelic exclusion and thus allows for separate examination of these signaling mechanisms.     

Characterization of an IgM Fc-binding receptor on human T cells

The existence of an IgM receptor on human T cells has been suggested by T cell rosetting with IgM-coated erythrocytes. In this study we used immunofluorocytometry to demonstrate that 1) after short-term culture, a majority of the T cells can bind IgM at easily detectable levels, 2) human and mouse IgM preparations bind to human T cells but other Ig isotypes do not, 3) the IgM binding is saturable and inhibitable only by Ig of IgM isotype and 4) the Fc portion of IgM is involved in the binding to a protease-sensitive cell surface protein. Biochemical analysis of the T cell receptor for IgM reveals a cell surface protein of 60 kDa in comparison with the 58 kDa Fc mu receptors (Fc mu R) on B-lineage cells. Although Fc mu R expression is up-regulated after B cell activation, the reverse is true after T cell activation. In addition, the T cell Fc mu R is relatively resistant to phospholipase C treatment. These results indicate that T- and B-lineage cells express Fc mu R with different biologic characteristics.     

Effect of upstream RNA processing on selection of mu S versus mu M poly(A) sites

All of the regulatory factors responsible for augmenting microseconds mRNA levels preceding the dramatic increase in secretory IgM production upon B cell activation has not been totally elucidated. Whereas previous experiments have centered on the region of the gene specifying the choice between splicing to mu M exons versus selection of the mu S poly(A) site, we have found that upstream sequences within the Cmu gene, specifically the Cmu 4 acceptor splice site together with intronic sequences between the Cmu 3++ and Cmu 4 exons, play an important role in dictating the precision or the extent of splicing to the mu M exons even under conditions in which functional polyadenylation factors should be in excess. Therefore, splicing of upstream exons can affect remotely located downstream exons. These findings suggest that regulation of differential mu S/mu M mRNA expression may involve general processing enzymes that recognize specific cis -regulatory sequences residing within the body of the mu gene and account for the unique ability of activated B cells to secrete copious amounts of IgM.     

Evaluation of butanone, carbon dioxide, and 1-octen-3-OL as attractants for mosquitoes associated with north central Florida bay and cypress swamps

In the sera of (NZB x NZW)F1 (B/W) mice that develop a lupus-like syndrome, increased levels of IgG antibodies (Ab) reacting with TNP have been detected before the appearance of IgG anti-DNA Ab and clinical symptoms. A single injection of trinitrophenyl-bovine serum albumin (TNP/BSA) in physiological saline into a young B/W mouse (3 months old), followed by fusion of its splenocytes 3 days later, gave rise to hybridomas simultaneously secreting IgM and IgG Ab with anti-TNP reactivity. Both mu and gamma chains were detected in culture supernatants by ELISA, and double isotype-producing cells were labeled by immunofluorescence. Molecular analysis of two of these double isotype-producing hybridomas showed the presence of mRNA coding for both mu and gamma chains of Ig, and this gamma mRNA could be translated in vitro into a gamma heavy (H) chain. Comparison of the H chain variable-region sequences of IgM and IgG revealed 100% homology between mu and gamma V(H) genes in one clone, while mu and gamma V(H) genes showed only 80% homology in the other clone. Both clones produced a single kappa light (L) chain. These two hybridomas, isolated from a B/W mouse, thus represent two different mechanisms of double isotype expression: the first one corresponds to an IgM to IgG switch, while the second one reflects a lack of allelic exclusion.     

Domain-switched mouse IgM/IgG2b hybrids indicate individual roles for C mu 2, C mu 3, and C mu 4 domains in the regulation of the interaction of IgM with complement C1q

Although polymeric IgM and monomeric IgG are potent activators of the classical complement pathway, previous studies have indicated that monomeric IgM is inactive. To understand this and to examine the roles of the individual mu domains in complement activation, we created a set of IgM/IgG2b mouse chimeric Abs in which homologous domains of both Abs have been interchanged, either singly or together with adjacent domains. The monomer subunits (H2L2) of the resulting chimeras were analyzed for their capacities to bind C1q and to initiate complement-mediated lysis (CML) of haptenated erythrocytes. When C gamma 2 was flanked by C mu 4, the inherent C1q-binding activity of the C gamma 2 domain was lost. This demonstrates that C mu 4 can suppress the C1q-binding activity of the adjacent C gamma 2 domain, and suggests that C mu 4 may exert a similar effect on the C mu 3 domain in the IgM monomer subunit. When C mu 3 was located in an IgG2b background and potentially freed from the constraints imposed by the IgM background, the monomer was not able to bind C1q or initiate CML. This suggests that these activities are not expressed inherently in the C mu 3 domain. The transplantation of C mu 3 together with C mu 4 into the IgG background permitted polymer formation. This polymer was able to bind C1q, although neither the monomer nor the polymer forms were active in CML; conversely, all IgM polymers with a transplanted C gamma 2 domain were active in both C1q binding and CML, and demonstrated apparent Kd values similar to that of wild-type IgM.     

Translocation of glucokinase in pancreatic beta-cells during acute and chronic hyperglycemia

We recently reported that Fc mu R on NK cells is a signal transducing protein that stimulates a rapid increase in the level of cytoplasmic free calcium upon binding of IgM. This study was designed to examine signal transduction via the Fc mu R on NK cells and to characterize intracellular second messengers activated by IgM. Immunoprecipitation of IgM-bound Fc mu R by IgM-specific Ab coimmunoprecipitated the zeta- and Fc epsilon RI gamma-chains. Furthermore, engagement and clustering of Fc mu R by polyclonal IgM induced tyrosine phosphorylation of the zeta- and Fc epsilon RI gamma-chains, indicating their functional association with the Fc mu R-induced signal transduction cascade. Ligand-induced clustering of the Fc mu R also induced activity of src family kinases, Lck, Fyn, Lyn, and Src, as well as their physical interaction with the receptor. Triggering via Fc mu R also induced the activity of Syk and Zap-70, tyrosine kinases demonstrated to associate with zeta and Lck. Phospholipase C-gamma 1 and phosphatidylinositol 3-kinase were identified as substrates phosphorylated on tyrosine, as down-stream components of the signaling pathway activated in NK cells by polyclonal IgM. Although the Fc mu R on NK cells has not yet been biochemically characterized, our results suggest that the zeta- and Fc epsilon RI gamma-chains are functional subunits of this as well as other important cell surface receptors and that the Fc mu R is coupled either directly or indirectly to nonreceptor tyrosine kinases, which phosphorylate and thereby activate regulatory enzymes such as phospholipase C-gamma 1 and phosphatidylinositol 3-kinase.     

Alpha-chain disease: analysis of alpha-chain protein and secretory component in jejunal fluid

BACKGROUND: It is unclear why different forms of alpha-chain disease protein appear in intestinal fluid. This was studied in a 23-year-old Mauritanian man in whom alpha-chain disease was diagnosed localized to the duodenum and jejunum, nasopharynx, and bone marrow. METHODS: The duodenal infiltrate was studied by immunohistochemistry. Forms of alpha chain-containing proteins in serum and jejunal fluid were analyzed by ultracentrifugation and radioimmunoassays. RESULTS: The infiltrating cells contained alpha-1 chain but no light chains, and approximately 66% showed variable expression of J chain. Serum contained a large fraction of monomeric alpha-chain disease protein, whereas both monomeric and heavier forms appeared in jejunal fluid. Some of the latter were bound to secretory component, and the fluid contained virtually no free component. CONCLUSIONS: Linkage of polymeric alpha-chain disease protein to secretory component depends on balanced synthesis of alpha chains and J chain in the proliferating B cells, giving rise to polymers with binding site for secretory component expressed as an epithelial receptor. Insufficient receptor-mediated transport capacity (either relative and/or because of intestinal crypt reduction) results in passive external transfer of polymers without bound secretory component along with leakage of serum-derived or locally produced monomeric alpha-chain disease protein, the latter presumably originating from immunocytes with little or no J-chain synthesis.     

Degradation of distinct assembly forms of immunoglobulin M occurs in multiple sites in permeabilized B cells

Protein degradation is essential for quality control which retains and eliminates abnormal, unfolded, or partially assembled subunits of oligomeric proteins. The localization of this nonlysosomal pre-Golgi degradation to the endoplasmic reticulum (ER) has been mostly deduced from kinetic studies and carbohydrate analyses, while direct evidence for degradation within the ER has been provided by in vitro reconstitution of this process. In this article, we took advantage of the transport incompetence of permeabilized cells to directly demonstrate that the selective degradation of secretory IgM (sIgM) in B lymphocytes is transport-dependent. We show that, upon permeabilization of the plasma membrane with either streptolysin O or digitonin, sIgM is not degraded unless transport is allowed. Nevertheless, upon complete reduction of interchain disulfide bonds with thiols, the free mu heavy chains are degraded by a transport-independent quality control mechanism within the ER. This latter degradation is nonselective to the secretory heavy chain mus, and the membrane heavy chain mum, which is normally displayed on the surface of the B cell, is also eliminated. Moreover, the degradation of free mus is no longer restricted to B lymphocytes, and it takes place also in the ER of plasma cells which normally secrete polymers of sIgM. Conversely, when assembled with the light chain, the degradation is selective to sIgM, is restricted to B lymphocytes, and is a transport-dependent post-ER event.     

Biogenesis and function of IgM: the role of the conserved mu-chain tailpiece glycans

The tailpiece of secretory Ig-mu-chains (mu(s)tp) is highly conserved throughout evolution: in particular, a carboxy-terminal cysteine residue (Cys575) and a glycan linked to Asn563 are found in all species sequenced so far. Here we show that the mu(s)tp oligosaccharide moieties are important for the binding of J-chains and for the process of IgM polymerization. In the absence of the mu(s)tp glycans, pentamers cannot be assembled and polymers containing six or more subunits are secreted. Despite their increased valency, these molecules have a lower association rate with antigen than wild-type polymers. Unexpectedly, the C-terminal oligosaccharides also affect kinetic parameters on unpolymerized subunits. Thus, monomers lacking the C-terminal sugars because of either site-directed mutagenesis or selective enzymatic deglycosylation with endoglycosidase H, have a lower k(on) for the antigen. Taken together, our results indicate that the C-terminal mu-chain glycans can shape the structure of mu(s2)L2 subunits and their further assembly into polymers.     

Predominant usage of the proximal poly(A) site in alpha mRNAs is not intrinsic to the 3' termini

The maturation of IgM-expressing B cells to IgM-secreting plasma cells is associated with both an increase in mu mRNA and the ratio of secreted to membrane forms of mu mRNA. In contrast, previous studies demonstrated that in vitro the secreted form of alpha mRNA (alpha s mRNA) predominates regardless of the stage of B cell differentiation. The present study demonstrates that alpha s mRNA predominates in both B cells derived from the germinal centers of murine Peyer's patches and in the functional IgA memory population, suggesting that in vitro events accurately represent the generation of a secretory IgA response in vivo. Although the predominant usage of the alpha s poly(A) site is due to RNA processing, it does not depend on either the alpha s poly(A) site, the 3' splice site associated with the exon encoding the membrane exon of IgA (alphaM) or the alphaM poly(A) sites. Analysis of the sequence of the intron between the alpha s terminus and alphaM (alpha s-alphaM intron) demonstrates the existence of several potential regulatory elements. Furthermore, the effects of deletions within the alpha s-alphaM intron on 3' terminus usage demonstrate that the predominant usage of the proximal terminus is not strictly dependent on the length of the intron. Together with previous work, these observations support the idea that choice of 3' terminus for all Ig heavy chain genes is regulated by a similar mechanism, but specific sequences within a heavy chain gene can impinge upon that mechanism.     

The murine IgM secretory poly(A) site contains dual upstream and downstream elements which affect polyadenylation

Regulation of polyadenylation efficiency at the secretory poly(A) site plays an essential role in gene expression at the immunoglobulin (IgM) locus. At this poly(A) site the consensus AAUAAA hexanucleotide sequence is embedded in an extended AU-rich region and there are two downstream GU-rich regions which are suboptimally placed. As these sequences are involved in formation of the polyadenylation pre-initiation complex, we examined their function in vivo and in vitro . We show that the upstream AU-rich region can function in the absence of the consensus hexanucleotide sequence both in vivo and in vitro and that both GU-rich regions are necessary for full polyadenylation activity in vivo and for formation of polyadenylation-specific complexes in vitro . Sequence comparisons reveal that: (i) the dual structure is distinct for the IgM secretory poly(A) site compared with other immunoglobulin isotype secretory poly(A) sites; (ii) the presence of an AU-rich region close to the consensus hexanucleotide is evolutionarily conserved for IgM secretory poly(A) sites. We propose that the dual structure of the IgM secretory poly(A) site provides a flexibility to accommodate changes in polyadenylation complex components during regulation of polyadenylation efficiency.     

Fentanyl and its analogs desensitize the cloned mu opioid receptor

Fentanyl, and its structural analogs lofentanil and sufentanil, are potent analgesics used clinically in the management of pain. However, the high analgesic potency of these compounds is limited by the development of tolerance after chronic use. To investigate whether their tolerance development may be related to mu receptor desensitization, the cloned mouse mu receptor as well as mutant forms of the receptor were stably expressed in HEK 293 cells and tested for their response to continuous opioid treatment. Fentanyl and its analogs potently bound to the mu receptor and effectively inhibited cAMP accumulation. Three-hour pretreatment of mu receptors with fentanyl and its analogs desensitized the mu receptor by uncoupling it from adenylyl cyclase. The fentanyl analogs caused a slight internalization of the mu receptor as accessed by antibody binding to the epitope-tagged mu receptor. Truncation of the mu receptor by removal of its carboxyl terminus at Glu341 did not affect the ability of the fentanyl analogs to bind to and activate the mu receptor nor did it prevent the fentanyl analogs from desensitizing the receptor. In a previous study we showed that morphine did not desensitize the cloned mu receptor even though it is a potent and effective agonist at the mu receptor. Mutagenesis studies revealed that morphine interacts differently with the mu receptor to activate it than do the fentanyl analogs which may explain its lack of desensitization of the mu receptor. These results indicate that desensitization of the mu receptor may be a molecular basis for the development of tolerance to fentanyl and its analogs.     

Peripheral morphine analgesia: synergy with central sites and a target of morphine tolerance

Morphine injected s.c. in the tail is a potent analgesic in the tail-flick assay when the radiant heat source is focused directly over the injection site (ED50, 4.5 micrograms), but not if the radiant heat source is moved 1 cm proximally or distally to the injection site. Naloxone given systemically reverses this peripheral analgesia. Antisense oligodeoxynucleotides directed against exons 1 and 4 of MOR-1, a cloned mu opioid receptor, administered intrathecally (i.t.) block the local analgesic effect of morphine in the tail, indicating that the local response is mediated through mu receptors located on the terminals of sensory neurons from the dorsal root ganglia. Combinations of morphine given locally in the tail and spinally (i.t.) are synergistic. Spinal morphine also synergizes with systemic morphine in analgesia assays. Supraspinal morphine enhances systemic morphine analgesia, but less dramatically. We also examined tolerance on these analgesic systems by using a daily morphine injection paradigm which shifts the dose-response curve for systemic morphine approximately 2-fold after 5 days. In this paradigm, morphine's analgesic potency after either supraspinal or spinal administration alone does not change. However, the dose-response curve for local morphine in the tail is shifted by over 19-fold. The analgesic activity of the combination of supraspinal and systemic morphine is lowered approximately 2-fold and the combination of i.t. and systemic morphine by 12-fold. These studies confirm the presence of a peripheral mechanism for morphine analgesia mediated by mu receptors located on sensory neurons from the dorsal root ganglia, which is extremely sensitive to chronic morphine dosing.     

Enzyme-linked immunosorbent assay of neocarzinostatin chromophore (NCS-chr) by use of a monoclonal antibody against NCS-chr analog

Allelic exclusion at the IgH locus was examined in B lineage cells of wild-type mice and mice unable to express the surrogate light chain molecule lambda 5 using a single-cell PCR approach. By analyzing B precursor cells containing two VHDHJH rearrangements, we found that in wild-type animals, cells are allelically excluded as soon as mu chains are expressed. Furthermore, we provide evidence that in cells expressing D mu proteins VH-->DHJH rearrangement is inhibited. In contrast, in the absence of lambda 5 protein, B precursor cells were allelically "included", indicating that allelic exclusion at the IgH locus requires expression of the pre-B cell receptor either containing a mu chain or a D mu chain. However, although mu chain double-producing B precursor cells are generated in lambda 5-deficient mice, such cells were not detected among surface immunoglobulin positive B cells.     

Small intestine in lymphocytic and collagenous colitis: mucosal morphology, permeability, and secretory immunity to gliadin

There is a recognised association between the "microscopic" forms of colitis and coeliac disease. There are a variety of subtle small intestinal changes in patients with "latent" gluten sensitivity, namely high intraepithelial lymphocyte (IEL) counts, abnormal mucosal permeability, and high levels of secretory IgA and IgM antibody to gliadin. These changes have hitherto not been investigated in microscopic colitis. Nine patients (four collagenous, five lymphocytic colitis) with normal villous architecture were studied. Small intestinal biopsies were obtained by Crosby capsule; small intestinal fluid was aspirated via the capsule. IEL counts were expressed per 100 epithelial cells, and intestinal IgA and IgM antigliadin antibody levels were measured by ELISA. Small intestinal permeability was measured by the lactulose:mannitol differential sugar permeability test. IEL counts were normal in all cases, median 17, range 7-30. Intestinal antigliadin antibodies were measured in six cases and were significantly elevated in two patients (both IgA and IgM). Intestinal permeability was measured in eight cases and was abnormal in two and borderline in one. These abnormalities did not overlap: four of nine patients had evidence of abnormal small intestinal function. Subclinical small intestinal disease is common in the two main forms of microscopic colitis.