Amphiphysin1 inhibits vitronectin-mediated cell adhesion,spreading, and migration in vitro

To investigate the regulatory mechanism of cell adhesion, we have searched for cellular inhibitory factors which prevent cell adhesion. The brain cytosol was found to inhibit the adhesion of various transformed cells to the substratum. An inhibitory 120-kDa protein was purified by sequential column chromatography. Peptide sequencing revealed that the protein is identical to amphiphysin1. GST-amphiphysin1 suppressed the attachment of HeLa cells to the plate when cells were cultured in the serum-containing medium. Vitronectin, a major cell-adhesive protein in serum and a ligand to alpha(v)beta3 integrin, was responsible for this cell attachment, and the vitronectin action was blocked by GST-amphiphysin1. GST-amphiphysin1 also inhibited the vitronectin-mediated spreading and migration of malignant melanoma cells. Furthermore, GST-amphiphysin1 bound directly to vitronectin. These findings point to the interesting possibility that amphiphysin1 could be a useful tool to inhibit cell-adhesive vitronectin.     

Cytoplasmic domain of human Fcalpha/mu receptor is required for ligand internalization

The Fcalpha/mu receptor (Fcα/μR), a type I transmembrane protein, is an immunoglobulin Fc receptor for both IgA and IgM. Its functions in immune defense are not clear at present. In this work, human Fcα/μR was expressed in CHO, 293T, and COS-7 cells to study its biochemical functions. Fcα/μR expressed by CHO and 293T was only in monomer form in cytoplasma and the monomeric receptor could not bind IgA or IgM. In comparison, Fcα/μR expressed by COS-7 cells had both monomer and dimer forms. The binding assay showed that Fcα/μR expressed by COS-7 cells could bind IgM strongly and IgA weakly, implying that dimeric receptor could be expressed on cell membrane and functioned. The bound IgM could be internalized and the internalization was abolished when the cytoplasmic domain of Fcα/μR was truncated. Therefore, the cytoplasmic portion of human Fcα/μR is required in the internalization.     

Some peculiarities of the dynamics of the immunoglobulin M structure

The isotropic mobility of separate regions of the intact molecule of immunoglobulin M (IgM) and its Fab and (Fc)5 fragments was studied using spin-labeling of carbohydrate (2,2,6,6-tetramethyl-4-aminopiperidine-1-oxyl) and peptide (2,2,5,5-tetramethyl-3-dichlorotriazinylaminopyrrolidine-1-oxyl) moieties. The spin-labeled oligosaccharide groups (OGs) in the Fab region are shown to have much more amplitude of anisotropic motion than those in the (Fc)5 region. The spin label in the latter is evidently attached in the C mu 3 domain to one of its OGs which is probably stabilized by ionic contacts between terminal N-acetylneuraminic acid residue and the peptide moiety of the IgM molecule. When the amount of the glycosidase-cleaved carbohydrate does not exceed 10-15%, most OGs affected are of the Fab region. Upon profound splitting (greater than or equal to 50%) the OGs of the (Fc)5 region are also affected; that results evidently in loosening the ionic contacts between the shortened OGs and the peptide moiety of IgM, and consequently in increasing mobility of the former. The structure of the (Fc)5 region of IgM is labile; after detaching this moiety from the intact IgM molecule, its structure is stabilized, but one of its domains (C mu 3) becomes more mobile than it is in the intact IgM molecule; at the same time the amplitude of anisotropic motion of OG bound here is decreased. In the latter case, this decrease depends on the sequence of spin-labeling and fragmentation. The most probable cause of stabilization of the (Fc)5 fragment is the heating of IgM solution to 56 degree C during fragmentation with trypsin. At this temperature the tau value for the (Fc)5 fragment is unusually low, equaling 23 ns. The spin-labeling in the peptide part of IgM occurs mostly in the Fab region which is a rather rigid moiety as expected.     

The fine specificity of IgM anti-citrullinated protein antibodies (ACPA) is different from that of IgG ACPA

Introduction  

The antigen recognition pattern of immunoglobulin M (IgM) could, when directed against protein antigens, provide an indication of the antigenic moieties triggering new B cells. The half-life of IgM is short and memory B cells against T-cell-dependent protein antigens typically produce IgG and not IgM antibodies. In this study, we analyzed whether a difference exists between the fine specificity of IgM versus IgG anti-citrullinated protein antibodies (ACPAs).     

Demonstration of binding of dengue virus envelope protein to target cells.

The nature of the initial interaction of dengue virus with target cells and the extent to which this interaction defines tropism are unknown. Infection of some cells may involve antidengue antibody-mediated immune adherence to cells bearing immunoglobulin Fc receptors; however, this mechanism does not explain primary infection or the infection of cells without Fc receptors. We hypothesized that dengue virus envelope protein mediates initial binding to target cells. To test this hypothesis, a recombinant chimeric form of dengue type 2 virus envelope protein was used as a probe to investigate binding to the surfaces of potential target cells. Envelope protein was expressed amino terminal to the heavy-chain constant region of human immunoglobulin G containing the Fc receptor binding motif; the binding mediated by envelope determinants was distinguishable from the binding mediated by immunoglobulin Fc determinants. We found that the recombinant chimera bound to Vero, CHO, endothelial, and glial cells through envelope protein determinants and to monocytes and U937 cells by Fc-Fc receptor interactions. The highest level of binding was to Vero cells; binding was dose and time dependent and saturable. Examination of partial-length recombinant envelope proteins indicated that the binding motif was expressed between amino acids 281 and 423. Recombinant envelope protein inhibited infection of Vero cells by dengue virus, indicating the functional significance of the interaction of envelope protein and target cells in infectivity. These results suggest that envelope protein binding to a non-Fc receptor could explain the cell and tissue tropism of primary dengue virus infection.     

The glycosaminoglycan-binding domain of decoy receptor 3 is essential for induction of monocyte adhesion

Decoy receptor 3 (DcR3), a soluble receptor for Fas ligand, LIGHT (homologous to lymphotoxins shows inducible expression and competes with HSV glycoprotein D for herpes virus entry mediator, a receptor expressed by T lymphocytes), and TNF-like molecule 1A, is highly expressed in cancer cells and in tissues affected by autoimmune disease. DcR3.Fc has been shown to stimulate cell adhesion and to modulate cell activation and differentiation by triggering multiple signaling cascades that are independent of its three known ligands. In this study we found that DcR3.Fc-induced cell adhesion was inhibited by heparin and heparan sulfate, and that DcR3.Fc was unable to bind Chinese hamster ovary K1 mutants defective in glycosaminoglycan (GAG) synthesis. Furthermore, the negatively charged, sulfated GAGs of cell surface proteoglycans, but not their core proteins, were identified as the binding sites for DcR3.Fc. A potential GAG-binding site was found in the C-terminal region of DcR3, and the mutation of three basic residues, i.e., K256, R258, and R259, to alanines abolished its ability to trigger cell adhesion. Moreover, a fusion protein comprising the GAG-binding region of DcR3 with an Fc fragment (DcR3_HBD.Fc) has the same effect as DcR3.Fc in activating protein kinase C and inducing cell adhesion. Compared with wild-type THP-1 cells, cell adhesion induced by DcR3.Fc was significantly reduced in both CD44v3 and syndecan-2 knockdown THP-1 cells. Therefore, we propose a model in which DcR3.Fc may bind to and cross-link proteoglycans to induce monocyte adhesion.     

Metabolic and morphologic effects of colchicine on human T-lymphocyte expression of Fc mu and Fc gamma receptors

The influence of colchicine on human T-cell Fc mu- and Fc gamma-receptor expression during culture was studied utilizing a rosette technique with bovine erythrocytes coated with IgM (EOx-IgM) or IgG (EOx-IgG). Treatment of T cells with greater than or equal to 10(-6) M concentrations of colchicine induced in these cells progressive loss of microtubules and surface microvilli, inhibited their Fc mu-, but not Fc gamma-receptor expression during culture, and increased their cyclic AMP levels. However, similar treatment of cells with lumicolchicine, a photoinactivated isomer, identically inhibited the T-cell Fc mu-receptor expression as well, without inducing loss of microtubules or microvilli or raising cyclic AMP levels in them. A direct influence on T-cell protein synthesis by either colchicine or lumicolchicine is likely, as greater than or equal to 10(-6) M concentrations of alkaloid identically inhibited [3H]leucine incorporation and Fc mu-receptor expression by T cells without inhibiting their alpha-methyl isobutyric acid transport. No impairment of optimal EOx-IgM rosette formation occurred in control T lymphocytes cultured for 24 hr and then treated with colchicine, which suggests that its effects did not directly influence the receptor-ligand interaction itself. These findings suggest colchicine has several sites of action on T cells, dependent and independent of microtubular depolymerization, which may be responsible for alterations of T-lymphocyte cellular metabolism and function.     

Mouse M290 is the functional homologue of the human mucosal lymphocyte integrin HML-1: antagonism between the integrin ligands E-cadherin and RGD tripeptide.

Human mucosal lymphocyte antigen-1 (HML-1, alphaEbeta7) and E-cadherin, two members of unrelated cell adhesion superfamilies, have evolved to play cooperative roles in gut mucosal immunity. Human E-cadherin is self-ligand mediating intercellular adhesion of epithelial cells, as well as adhesion of intra-epithelial lymphocytes to intestinal enterocytes via an interaction with HML-1. Herein we report that both dimeric and monomeric forms of recombinant mouse E-cadherin-human immunoglobulin Fc chimera self-associate and support attachment of E-cadherin+ mouse colon epithelial cells. Both forms also support the adhesion of mouse MTC-1 T cells via M290, thereby establishing M290 as the functional mouse homologue of HML-1 and revealing that E-cadherin homophilic and heterophilic binding sites are distinct. Adhesion of MTC-1 cells to E-cadherin-Fc was inhibited by arginine-glycine-aspartate (RGD) peptides and vice versa cells bound to immobilized RGD polymer in an M290-dependent fashion, where adhesion was inhibitable with soluble E-cadherin-Fc. Hence, E-cadherin and RGD integrin ligands antagonize cell binding by one another, either by inducing integrin cross-talk or by binding to shared or overlapping sites within M290. Binding of E-cadherin-Fc by HML-1 costimulated the CD3-induced proliferation of purified CD4+ T cells, suggesting that E-cadherin expressed on dendritic cells may play a T cell costimulatory role in addition to facilitating dendritic cell-keratinocyte adhesion.     

Streptococcal Fc receptors. I. Isolation and partial characterization of the receptor from a group C streptococcus

A receptor for the Fc region of immunoglobulin G was extracted from a group C streptococcus, purified and physicochemically characterized. The Fc receptor was extracted in high yield by lysis of the bacteria after infection with bacteriophage. The soluble receptor was purified to functional homogeneity by sequential chromatography on cellulose phosphate, DEAE, and selective elution from a column of immobilized human IgG. Four hundred micrograms of the functionally pure protein was obtained per gram (wet weight) of bacteria extracted. The affinity-purified receptor was functionally homogeneous in binding to the Fc region of human IgG; however, the product was heterogeneous on both non-denaturing and SDS polyacrylamide gels. Four major protein bands were observed, with the predominant form of the Fc receptor having an m.w. of 64,000 daltons. Antibody prepared against the major Fc receptor protein ( FcRc -II) was capable of reacting with all the fractions and completely inhibiting functional activity. The results of the competitive binding studies suggest that the purified Fc receptor behaves as a single receptor, and that the differences in charge and size were probably due to covalently bound cell wall constituents.     

The C-terminal region of NELL1 mediates osteoblastic cell adhesion through integrin α3β1

NELL1 is a secretory osteogenic protein containing several structural motifs that suggest that it functions as an extracellular matrix component. To determine the mechanisms underlying NELL1-induced osteoblast differentiation, we examined the cell-adhesive activity of NELL1 using a series of recombinant NELL1 proteins. We demonstrated that NELL1 promoted osteoblastic cell adhesion through at least three cell-binding domains located in the C-terminal region of NELL1. Adhesion of cells to NELL1 was strongly inhibited by function-blocking antibodies against integrin α3 and β1 subunits, suggesting that osteoblastic cells adhered to NELL1 through integrin α3β1. Further, focal adhesion kinase activation is involved in NELL1 signaling.     

Some Peculiarities of the Dynamics of the Immunoglobulin M Structure

Abstract

The isotropic mobility of separate regions of the intact molecule of immunoglobulin M (IgM) and its Fab and (Fc)₅ fragments was studied using spin-labeling of carbohydrate (2,2,6,6-tetramethyl-4-aminopiperidine-l-oxyl) and peptide (2,2,5,5-tetramethyl-3-dichloro-triazinylaminopyrrolidine-l-oxyl) moieties.

The spin-labeled oligosaccharide groups (OGs) in the Fab region are shown to have much more amplitude of anisotropic motion than those in the (Fc)₅ region. The spin label in the latter is evidently attached in the Cμ3 domain to one of its OGs which is probably stabilized by ionic contacts between terminal N-acetylneuraminic acid residue and the peptide moiety of the IgM molecule.

When the amount of the glycosidase-cleaved carbohydrate does not exceed 10–15%, most OGs affected are of the Fab region. Upon profound splitting (≥50%) the OGs of the (Fc)₅region are also affected; that results evidently in loosening the ionic contacts between the shortened OGs and the peptide moiety of IgM, and consequently in increasing mobility of the former.

The structure of the (Fc)₅ region of IgM is labile; after detaching this moiety from the intact IgM molecule, its structure is stabilized, but one of its domains (Cμ3) becomes more mobile than it is in the intact IgM molecule; at the same time the amplitude of anisotropic motion of OG bound here is decreased. In the latter case, this decrease depends on the sequence of spin-labeling and fragmentation.

The most probable cause of stabilization of the (Fc)₅ fragment is the heating of IgM solution to 56°C during fragmentation with trypsin. At this temperature the τ value for the (Fc)₅ fragment is unusually low, equaling 23 ns.

The spin-labeling in the peptide part of IgM occurs mostly in the Fab region which is a rather rigid moiety as expected.     

Fibronectin's cell-adhesive domain and an amino-terminal matrix assembly domain participate in its assembly into fibroblast pericellular matrix

Fibroblasts organize the modular cell-adhesive glycoprotein fibronectin into a highly structured pericellular matrix by poorly understood mechanisms. Previous studies implicated an amino-terminal domain in matrix assembly and suggested that fibronectin's cell-adhesive domain and the corresponding fibroblast receptor were not involved in this process. To further elucidate the fibronectin region(s) involved in matrix assembly, we mapped a library of proteolytic fragments and antibodies to various fibronectin domains. The fragments and antibodies were used to probe the role of fibronectin's amino-terminal and cell-adhesive domains in a fibroblast matrix assembly assay. We found that fibronectin fragments including the first 25-kDa sequence of fibronectin and antibodies to amino-terminal domains inhibited pericellular matrix assembly. Polyclonal antibodies to the 40-kDa collagen binding domain following the 25-kDa amino-terminal domain also inhibited matrix assembly. However, collagen binding is not required for matrix assembly as neither monoclonals blocking collagen binding nor purified collagen binding domains themselves inhibited matrix assembly. Therefore, the amino-terminal region of fibronectin contains a site important in matrix assembly, and most activity is present in the first 25-kDa of fibronectin. Fibronectin's cell-adhesive domain and the fibroblast receptor binding to this domain also play an important role in fibronectin matrix assembly. Apart from a monoclonal antibody to the amino-terminal domain, only monoclonal antibodies binding to fibronectin's cell-adhesive domain and inhibiting cell adhesion also inhibited matrix assembly. In addition a 105-kDa fragment containing the cell-adhesive domain inhibited matrix assembly. We conclude that at least two discrete and widely separated sites in fibronectin with different binding properties--the carboxyl-terminal fibroblast cell-adhesive domain and an amino-terminal matrix assembly domain localized primarily within the first 25 kDa--are required for fibronectin pericellular matrix assembly by fibroblasts. Fibronectin's cell-adhesive domain and its cell surface-receptor complex appear to be involved in the matrix assembly process prior to a step involving the amino-terminal domain. We believe that this step is likely to be the initiation of cell-associated fibronectin fibril formation by the fibronectin-adhesive-receptor complex.     

Recognition of a B cell lymphoma by anti-idiotypic T cells

Idiotypic IgM derived from a B cell lymphoma can act as a tumor-associated Ag, in that immunization with this purified protein generates an anti-idiotypic immune response that specifically suppresses tumor development. Spleens of immune mice contain T cells that proliferate in response to idiotypic IgM. However, idiotypic Ag is presented to the T cells most efficiently in its natural form at the surface of the lymphoma cells, than as soluble IgM plus presenting cells. Variant tumors that display either little or no idiotypic IgM at the cell surface, but which are otherwise indistinguishable from parental tumor, induce a weak response or fail to stimulate the T cells, respectively. Anti-idiotypic lines and clones have been derived from the splenic T cells by growth in the presence of irradiated tumor cells. Phenotypic analysis revealed that cells from both lines and clones express CD3 and CD4 Ag, but not CD8. Recognition of tumor Id, which required no added presenting cells, was inhibited by antibody against MHC class II Ag, and variably by anti-CD4. Proliferative responses were inhibited by anti-idiotypic antibodies, but also by antibodies against the constant region of the mu H chain, indicating that perturbation of the surface IgM abrogates availability of idiotypic determinants to the T cells.     

Stabilization and Augmentation of Circulating AIM in Mice by Synthesized IgM-Fc

Owing to rapid and drastic changes in lifestyle and eating habits in modern society, obesity and obesity-associated diseases are among the most important public health problems. Hence, the development of therapeutic approaches to regulate obesity is strongly desired. In view of previous work showing that apoptosis inhibitor of macrophage (AIM) blocks lipid storage in adipocytes, thereby preventing obesity caused by a high-fat diet, we here explored a strategy to augment circulating AIM levels. We synthesized the Fc portion of the soluble human immunoglobulin (Ig)M heavy chain and found that it formed a pentamer containing IgJ as natural IgM does, and effectively associated with AIM in vitro. When we injected the synthesized Fc intravenously into mice lacking circulating IgM, it associated with endogenous mouse AIM, protecting AIM from renal excretion and preserving the circulating AIM levels. As the synthesized Fc lacked the antigen-recognizing variable region, it provoked no undesired immune response. In addition, a challenge with the Fc-human AIM complex in wild-type mice, which exhibited normal levels of circulating IgM and AIM, successfully maintained the levels of the human AIM in mouse blood. We also observed that the human AIM was effectively incorporated into adipocytes in visceral fat tissue, suggesting its functionality against obesity. Thus, our findings reveal potent strategies to safely increase AIM levels, which could form the basis for developing novel therapies for obesity.     

Secretion of a novel cell-adhesive protein distinct from fibronectin by mouse L.P3 cells growing in protein- and lipid-free synthetic medium

Several cell lines growing in protein- and lipid-free synthetic medium secreted cell-adhesive protein(s) into the medium. The conditioned medium (CM) of one of these cell lines, mouse L.P3, showed the highest cell attachment-promoting activity (CPA) among them. Cell-adhesive protein(s) in the CM of L.P3 cells (L.P3-CM) were separated into two types by sequential affinity column chromatography employing gelatin-Sepharose 4B and heparin-Sepharose 4B. One was a gelatin- and heparin-binding cell-adhesive protein (GCP), and was identified as a cellular form of mouse fibronectin. The other was a gelatin-non-binding and heparin-binding cell-adhesive protein (GNCP). The CPA of GNCP preparation was effective for the cell-attachment and spreading of both epithelial and fibroblastic cells. The CPA of GNCP preparation was not blocked by the antiserum and scarcely inhibited in the presence of the synthetic cell attachment-promoting peptide Gly-Arg-Gly-Asp-Ser-Pro, a competitive inhibitor of fibronectin. This suggests that the structure of the cell-attachment site of GNCP is different from that of fibronectin. The GNCP preparation showed little cross-reactivity with anti-mouse laminin antiserum in enzyme-linked immunosorbent assay (ELISA). These results demonstrate the possibility that GNCP in L.P3-CM is a novel cell-adhesive protein distinct from fibronectin or laminin. The secretion of the two types of cell-adhesive proteins by L.P3 cells is discussed.     

Immunochemical properties of a 60 kDa cell surface-associated heat shock-protein (Hsp60) from Helicobacter pylori

Abstract Western blot analysis (immunoblotting) of cell surface-associated proteins from Helicobacter pylori confirmed our previous findings that binding of human IgG is a common property (among H. pylori strains). Purification of the IgG-binding proteins (IGBP) was achieved by two purification steps, affinity chromatography on IgG-Sepharose and nickel chelate affinity chromatography. SDS-PAGE and immunoblotting analysis revealed a 60 kDa protein with affinity for peroxidase labeled human IgG. Solid phase binding assays showed that IgG binds to an immobilized protein (IGBP). The 60 kDa IGBP binds human IgG₁, IgG₃ and IgM. Binding could be inhibited by the kappa chain of the human IgG, but not with its Fc fragment, nor with IgA or IgM. In addition, rabbit polyclonal antibodies raised against the 60 kDa IGBP blocked IgG binding. Monoclonal antibodies, specific to the Hsp60 heat shock protein of H. pylori recognized the 60 kDa IGBP as revealed by immunoblotting analysis, both in crude preparations and in the purified fractions.     

Molecular characteristics of IgA and IgM Fc binding to the Fcalpha/muR

Fcalpha/mu receptor (Fcalpha/muR), a novel Fc receptor for IgA and IgM, is a type I transmembrane protein with an immunoglobulin (Ig)-like domain in the extracellular portion. Although IgA and IgM bind to Fcalpha/muR, the molecular and structural characteristics of the ligand-receptor interactions have been undetermined. Here, we developed twelve monoclonal antibodies (mAbs) against murine Fcalpha/muR by immunizing mice deficient in Fcalpha/muR gene. Eight mAbs totally or partially blocked IgA and IgM bindings to Fcalpha/muR. These blocking mAbs bound to a peptide derived from the Ig-like domain of murine Fcalpha/muR, which is conserved not only in human and rat Fcalpha/muR but also in polymeric Ig receptor (poly-IgR), another Fc receptor for IgA and IgM. These results suggest that IgA and IgM bind to an epitope in the conserved amino acids in the Ig-like domain of Fcalpha/muR as well as poly-IgR.     

Studies on the interaction between protein A and immunoglobulin G. I. Effect of protein A on the functional activity of IgG.

Staphylococcal protein (A (PA) and IgG anti-Forssman immunoglobulin formed complexes that behaved functionally like IgM in their ability to lyse sheep erythrocytes (E) in the presence of whole guinea pig complement (GPC) and to fix purified guinea pig C1. Concanavalin A, a plant lectin that inhibited IgM but not IgG hemolytic activity, inhibited the hemolytic activity of IgG-protein A complexes that behaved like IgM but had no effect on complexes that behaved functionally like IgG. Since Con A is known to bind specifically to glucose and mannose residues, our results suggested that the interaction of protein A with the Fc region of IgG led to exposure of sugar moieties that may participate in complement (C) binding. The production of IgM-like complexes depended on the ratio of protein A to IgG and the empirical formula of these IgM-like complexes was found to be [(IgG)2PA]n. As the ratio of PA to IgG was increased, the resulting complexes tended to behave functionally like IgG but with reduced hemolytic activity and C1 fixing ability. Furthermore, the binding of C1 to EIgG was inhibited by PA and the binding of PA to EIgG was inhibited by C1 indicating that the binding sites for C1 and PA were located near each other or were identical. Our results offer a reasonable explanation for the reported effects of PA or mixtures of PA and IgG in vitro and in vivo.     

Incomplete glycosylation of ASN 563 in mouse immunoglobulin M

Mouse immunoglobulin IgM was prepared from MOPC 104E ascites fluid and [3H]-mannose labeled tumor cells. The purified protein was used to prepare Fc fragments which were cleaved by cyanogen bromide. Gel filtration allows complete separation of the C-terminal glycosylation site. Amino acid and carbohydrate analyses show that Asn 563 of murine IgM is glycosylated only about 44% of the time.     

Expression, distribution and specificity of Fc receptors for IgM on murine B cells

Subpopulations of normal adult murine splenic B cells and a panel of murine B cell tumors were examined for their ability to bind murine IgM specifically. By using two-color flow cytometric analyses, we have demonstrated that 90 to 95% of surface (s)IgD+ B cells express surface membrane receptors for IgM (Fc mu R). The binding of pentameric murine IgM to splenocyte Fc mu R was IgM-specific since it was totally inhibited by other polymeric IgM proteins, but not by Ig of other H chain classes or by mAb specific for the murine IgG or IgE FcR. Binding of IgM to splenic cells was saturable. Fc mu R were co-expressed with the Fc gamma R as well as the Fc epsilon R on the majority of splenic B cells. Minor populations of splenic mononuclear cells expressed only an Fc mu R, Fc gamma R or Fc epsilon R. In a survey of B tumor cell lines representing different stages of B cell development, we observed that the Fc mu R was expressed on pre-B cell lines and that Fc mu R detection was maximal on immature B cell lines that expressed sIgM and low amounts of sIgD and Ia. Fc mu R were not detected on cell lines that had switched from sIgM to the expression of another sIg, or on plasmacytomas and hybridomas. The studies with normal splenocytes establish that the majority of sIgD+ B lymphocytes in adult BALB/c mice express surface membrane receptors that specifically bind IgM. The studies with B lineage tumor cells suggest that the expression of Fc mu R on B cells is developmentally regulated and that the pattern of expression exhibited by Fc mu R during B cell ontogeny differs from the patterns that have been previously found for IgG and IgE FcR. These observations raise the possibility that Fc mu R might have a functional significance in some aspect of B cell maturation and activation. By using a family of IgM H chain constant region domain deletional mutants, we have further demonstrated that, like the T cell Fc mu R, the B cell Fc mu R also requires a C mu 3 domain for binding to occur, raising the possibility that the T and B cell Fc mu R in mice may be structurally related molecules.