Differences between Human and Mouse IgM Fc Receptor (FcµR).

Both non-immune "natural" and antigen-induced "immune" IgM are important for protection against pathogens and for regulation of immune responses to self-antigens. Since the bona fide IgM Fc receptor (FcµR) was identified in humans by a functional cloning strategy in 2009, the roles of FcµR in these IgM effector functions have begun to be explored. In this short essay, we describe the differences between human and mouse FcµRs in terms of their identification processes, cellular distributions and ligand binding activities with emphasis on our recent findings from the mutational analysis of human FcµR. We have identified at least three sites of human FcµR, i.e., Asn66 in the CDR2, Lys79 to Arg83 in the DE loop and Asn109 in the CDR3, responsible for its constitutive IgM-ligand binding. Results of computational structural modeling analysis are consistent with these mutational data and a model of the ligand binding, Ig-like domain of human FcµR is proposed. Serendipitously, substitution of Glu41 and Met42 in the CDR1 of human FcµR with mouse equivalents Gln and Leu, either single or more prominently in combination, enhances both the receptor expression and IgM binding. These findings would help in the future development of preventive and therapeutic interventions targeting FcµR.

Unique ligand-binding property of the human IgM Fc receptor.

The IgM Fc receptor (FcµR) is the newest FcR, and coligation of FcµR and Fas/CD95 on Jurkat cells with agonistic IgM anti-Fas mAb was shown to inhibit Fas-induced apoptosis. The ligand-binding activity of human FcµR was further examined. FcµR-mediated protection from apoptosis was partially blocked by addition of 10(4) molar excess of IgM or its soluble immune complexes, but it could be inhibited by addition of 10-fold excess of IgM anti-CD2 mAb. This suggests that FcµR binds more efficiently to the Fc portion of IgM reactive with plasma-membrane proteins than to the Fc portion of IgM in solution. The former interaction occurred in cis on the same cell surface, but not in trans between neighboring cells. This cis engagement of FcµR resulted in modulation of Ca(2+) mobilization via CD2 on Jurkat cells or BCRs on blood B cells upon cross-linkage with the corresponding IgM mAbs. Several functional changes were observed with FcµR mutants: 1) significant increase in IgM ligand binding in the cytoplasmic tail-deletion mutant, 2) enhanced cap formation in FcµR upon IgM binding at 4°C with a point mutation of the transmembrane His to Phe, and 3) less protective activity of FcµR in IgM anti-Fas mAb-mediated apoptosis assays with a point mutation of the membrane-proximal Tyr to Phe. These findings show the importance of the cis engagement of FcµR and its critical role in receptor function. Hence, FcµR on B, T, and NK cells may modulate the function of surface proteins recognized by natural or immune IgM Abs on the shared membrane cell surface.

Monoclonal antibodies specific for human IgM Fc receptor inhibit ligand-binding activity.

A panel of six different murine hybridoma clones secreting IgG monoclonal antibodies (MAbs) specific for the human IgM Fc receptor (FcµR) was generated. All MAbs specifically precipitated a major protein of ∼60 kDa from membrane lysates of FcµR-bearing, but not FcµR-negative, cells as did IgM-ligands. Pre-incubation of membrane lysate of FcµR-bearing cells with these MAbs completely removed the ∼60 kDa IgM-reactive protein. By using recombinant human/mouse chimeric FcµR proteins, the epitope recognized by HM7 and HM10 MAbs was mapped to the Ig-like domain of human FcµR, whereas the other MAbs recognized the stalk region. Pre-incubation of FcµR(+) cells with the Ig-like domain-specific MAbs, but not with others, markedly inhibited subsequent IgM-ligand binding. A similar, but much weaker, inhibition was also observed when the incubation order was reversed. When FcµR(+) cells were simultaneously incubated with both IgM-ligands and MAbs, HM7 MAb efficiently competed with IgM for FcµR binding. Unlike control Jurkat cells, FcµR-bearing cells were resistant to apoptosis induced by agonistic IgM anti-Fas MAb (CH11); however, addition of the HM7 MAb inhibited the interaction of the Fc portion of CH11 MAb with FcµR, thereby promoting apoptosis of FcµR-bearing Jurkat cells. The variable regions of the HM7 MAb were composed of Ighv14-3, Ighd1-2, and Ighj2 for the γ2b heavy chain and Igk3-4 and Igkj2 for the κ light chain. These findings suggest that HM7 MAb efficiently blocks the ligand-binding activity of FcµR.

The old but new IgM Fc receptor (FcµR).

IgM is the first Ig isotype to appear during phylogeny, ontogeny and the immune response. The importance of both pre-immune "natural" and antigen-induced "immune" IgM antibodies in immune responses to pathogens and self-antigens has been established by studies of mutant mice deficient in IgM secretion. Effector proteins interacting with the Fc portion of IgM, such as complement and complement receptors, have thus far been proposed, but fail to fully account for the IgM-mediated immune protection and regulation of immune responses. Particularly, the role of the Fc receptor for IgM (FcµR) in such effector functions has not been explored until recently. We have identified an authentic FcµR in humans using a functional cloning strategy and subsequently in mice by RT-PCR and describe here its salient features and the immunological consequences of FcµR deficiency in mice. Since the FcµR we cloned was identical to Toso or Fas inhibitory molecule 3 (FAIM3), there have been spirited debates regarding the real function of FcµR/Toso/FAIM3 and we will also comment on this topic.

Enhanced auto-antibody production and Mott cell formation in FcµR-deficient autoimmune mice.

The IgM-Fc receptor (FcµR) is involved in IgM homeostasis as evidenced by increased pre-immune serum IgM and natural auto-antibodies of both IgM and IgG isotypes in Fcmr-deficient C57BL/6 (B6) mice. To determine the impact of Fcmr-ablation on autoimmunity, we introduced the Fcmr null mutation onto the Fas-deficient autoimmune-prone B6.MRL Fas (lpr/lpr) mouse background (B6/lpr). Both IgM and IgG auto-antibodies against dsDNA or chromatin appeared earlier in FcµR(-) B6/lpr than FcµR(+) B6/lpr mice, but this difference became less pronounced with age. Splenic B2 cells, which were 2-fold elevated in FcµR(+) B6/lpr mice, were reduced to normal B6 levels in FcµR(-) B6/lpr mice, whereas splenic B1 cells were comparable in both groups of B6/lpr mice. By contrast, marginal zone (MZ) B cells were markedly reduced in FcµR(-) B6/lpr mice compared with either FcµR(+) B6/lpr or wild type (WT) B6 mice. This reduction appeared to result from rapid differentiation of MZ B cells into plasma cells in the absence of FcµR, as IgM antibody to a Smith (Sm) antigen, to which MZ B cells are known to preferentially respond, was greatly increased in both groups (B6/lpr and B6) of FcµR(-) mice compared with FcµR(+) B6/lpr or B6 mice. Mott cells, aberrant plasma cells with intra-cytoplasmic inclusions, were also increased in the absence of FcµR. Despite these abnormalities, the severity of renal pathology and function and survival were all indistinguishable between FcµR(-) and FcµR(+) B6/lpr mice. Collectively, these findings suggest that FcµR plays important roles in the regulation of auto-antibody production, Mott cell formation and the differentiation of MZ B cells into plasma cells in B6.MRL Fas (lpr/lpr) mice.

The long elusive IgM Fc receptor, FcµR.

IgM exists as both a monomer on the surface of B cells and a pentamer secreted by plasma cells. Both pre-immune "natural" and antigen-induced "immune" IgM antibodies are important for protective immunity and for immune regulation of autoimmune processes by recognizing pathogens and self-antigens. Effector proteins interacting with the Fc portion of IgM, such as complement and complement receptors, have thus far been proposed but fail to fully account for the IgM-mediated protection and regulation. A major reason for this deficit in our understanding of IgM function seems to be lack of data on a long elusive Fc receptor for IgM (FcµR). We have recently identified a bona fide FcµR in both humans and mice. In this article we briefly review what we have learned so far about FcµR.

Altered Ig levels and antibody responses in mice deficient for the Fc receptor for IgM (FcµR).

Cell surface Fc receptor for IgM antibody (FcµR) is the most recently identified member among FcRs. We determined the cellular distribution of mouse FcµR and the functional consequences of Fcmr disruption. Surface FcµR expression was restricted to B-lineage cells, from immature B to plasma cells, except for a transient down-modulation during germinal center reactions. Fcmr ablation had no significant effect on overall B- and T-cell development, but led to a reduction of marginal zone B cells and an increase in splenic B1 B cells. Preimmune serum IgM in mutant mice was significantly elevated as were natural autoantibodies. When immunized with live attenuated pneumococci, mutant mice mounted robust antibody responses against phosphorylcholine, but not protein, determinants compared with wild-type mice. By contrast, upon immunization with a hapten-carrier conjugate, nitrophenyl-coupled chicken γ-globulin (NP-CGG), the mutant mice had a diminished primary IgG1 response to both NP and CGG. These findings suggest that FcµR has an important role in IgM homeostasis and regulation of humoral immune responses.

Enhanced levels of both the membrane-bound and soluble forms of IgM Fc receptor (FcµR) in patients with chronic lymphocytic leukemia.

The association of an IgM-Fc receptor (FcµR) with chronic lymphocytic leukemia (CLL) was suggested more than 30 years ago, but its authenticity has never been formally addressed. We examined the expression of the recently identified FcµR by B and T cells in CLL patients using receptor-specific monoclonal antibodies. CLL B cells (CD5(+)/CD19(+)) expressed much higher levels of FcµR on their cell surface than B cells from healthy donors. Such enhanced expression was more evident in immunoglobulin heavy chain variable region (IGHV)-mutated, CD38(-) or early Rai-stage CLL than in IGHV-unmutated, CD38(+), or advanced Rai-stage CLL. Intriguingly, surface FcµR levels also were significantly elevated in the non-CLL B cells (CD5(-)/CD19(+)) and T cells (CD5(+)/CD19(-)), especially in IGHV-mutated CLL. CLL patients also had high serum titers of FcµR compared with healthy donors, and serum FcµR levels correlated significantly with circulating lymphocyte numbers but not with the IGHV mutation status or Rai stage. The serum FcµR was resolved as an ∼ 40-kDa protein, distinct from the cell surface FcµR of ∼ 60 kDa, and it was produced by both CLL B and non-CLL B cells. Mass spectrometric analysis revealed that the serum FcµR is a soluble form of the receptor encoded by an alternatively spliced FcµR transcript. These findings indicate enhanced levels of both membrane-bound and soluble forms of FcµR in CLL patients.

Identity of the elusive IgM Fc receptor (FcmuR) in humans.

Although Fc receptors (FcRs) for switched immunoglobulin (Ig) isotypes have been extensively characterized, FcR for IgM (FcmuR) has defied identification. By retroviral expression and functional cloning, we have identified a complementary DNA (cDNA) encoding a bona fide FcmuR in human B-lineage cDNA libraries. FcmuR is defined as a transmembrane sialoglycoprotein of approximately 60 kD, which contains an extracellular Ig-like domain homologous to two other IgM-binding receptors (polymeric Ig receptor and Fcalpha/muR) but exhibits an exclusive Fcmu-binding specificity. The cytoplasmic tail of FcmuR contains conserved Ser and Tyr residues, but none of the Tyr residues match the immunoreceptor tyrosine-based activation, inhibitory, or switch motifs. Unlike other FcRs, the major cell types expressing FcmuR are adaptive immune cells, including B and T lymphocytes. After antigen-receptor ligation or phorbol myristate acetate stimulation, FcmuR expression was up-regulated on B cells but was down-modulated on T cells, suggesting differential regulation of FcmuR expression during B and T cell activation. Although this receptor was initially designated as Fas apoptotic inhibitory molecule 3, or TOSO, our results indicate that FcmuR per se has no inhibitory activity in Fas-mediated apoptosis and that such inhibition is only achieved when anti-Fas antibody of an IgM but not IgG isotype is used for inducing apoptosis.