Mediation of cell-cell adhesion by the altered contact site A glycoprotein expressed in modB mutants of Dictyostelium discoideum

In Dictyostelium discoideum, a surface glycoprotein with Mr 80,000 (gp80) has been found to mediate the EDTA-resistant contact sites A at the aggregation stage of development. To evaluate the role of the carbohydrate moiety in cell-cell adhesion, we have examined the accumulation and activity of an altered gp80 molecule in two glycosylation (modB) mutants. Both mutants synthesize an altered gp80 of lower molecular size. This modB-gp80 can be detected by the monoclonal antibody 80L5C4, which is capable of blocking cell-cell adhesion (C. -H. Siu, T. Y. Lam, and A. Choi, (1985) J. Biol. Chem. 260, 16,030-16,036). The mutant cells exhibit both EDTA-sensitive and EDTA-resistant types of cell-cell binding, though to a lesser extent than that of the parental strain, and the EDTA-resistant binding sites are blocked in the presence of 80L5C4 Fab. Mutant cells can also bind Covaspheres conjugated with gp80. These results suggest that the modB-gp80 protein still retains the domain essential for its cell binding activity and the carbohydrate moiety affected by the modB mutation is not directly involved in cell-cell adhesion.     

Molecular mechanisms of cell-cell interaction in Dictyostelium discoideum

During development of the cellular slime mold Dictyostelium discoideum, cells migrate in response to cAMP to form aggregates, which give rise to fruiting bodies consisting of two major cell types: spores and stalk cells. Multicellularity is achieved by the expression of two types of cell-cell adhesion sites. The EDTA-sensitive binding sites are expressed at the initial stage of development. At the aggregation stage, cells acquire EDTA-resistant binding sites, which are mediated by a cell-surface glycoprotein of Mr80,000 (gp80). gp80 is preferentially associated with cell surface filopodia, which are probably involved in the initiation of contact formation between cells. Covaspheres conjugated with gp80 bind specifically to aggregation-stage cells. The binding can be inhibited by precoating cells with an anti-gp80 monoclonal antibody, thus suggesting that gp80 mediates cell-cell binding via homophilic interaction. The structure of gp80 predicted from its cDNA sequence can be divided into three major domains: a membrane anchor, a hinge, and a globular region. An analysis of fusion proteins containing different gp80 segments shows that the cell-binding activity resides in the globular region. In the postaggregation stages, gp80 is replaced by other surface glycoproteins in maintaining cell-cell adhesion. One of them has a Mr of 150,000 (gp150). Anti-gp150 antibodies have no effect on aggregation-stage cells, but they disrupt cell-cell adhesion at subsequent stages. It becomes evident that the complex phenomena of cell adhesion and tissue organization involve the participation of a number of surface glycoproteins.     

Mapping of the monoclonal antibody 80L5C4 epitope on the cell adhesion molecule gp80 of Dictyostelium discoideum

EDTA-resistant cell-cell binding sites are expressed on Dictyostelium discoideum cells at the aggregation stage of development. A cell surface glycoprotein of Mr 80,000 (gp80) has been found to mediate these binding sites via homophilic interaction. We have previously raised a monospecific monoclonal antibody 80L5C4 against gp80, which blocks the cell binding site of gp80 (Siu, C.-H., Lam, T.Y. and Choi, A.H.C. (1985) J. Biol. Chem. 260, 16030-16036). To map the 80L5C4 epitope, gp80 was digested with protease V8, and the smallest proteolytic fragment that retained immunoreactivity with 80L5C4 was about 27,000 Da, corresponding to the amino-terminal fragment predicted from the cleavage sites. In addition, cDNA fragments containing different gp80 coding regions were used to construct trpE/gp80 gene fusions in the expression vector pATH10. An analysis of these fusion proteins led to the mapping of the 80L5C4 epitope to a 51 amino-acid segment between residues 123 and 173.     

The contact site A glycoprotein mediates cell-cell adhesion by homophilic binding in Dictyostelium discoideum

Dictyostelium discoideum expresses a developmentally regulated cell surface glycoprotein of Mr 80,000 (gp80), which has been implicated in the formation of the EDTA-resistant contact sites A at the cell aggregation stage. To determine whether gp80 participates directly in cell binding and, if so, its mode of action, we conjugated purified gp80 to Covaspheres (Covalent Technology Corp., Ann Arbor, MI) and investigated their ability to bind to cells. The binding of gp80- Covaspheres was dependent on the developmental stage of the cells, with maximal interaction at the late aggregation stage. Scanning electron microscopic studies revealed the clustering of gp80-Covaspheres at the polar ends of these cells, similar to the pattern of gp80 distribution on the cell surface as reported earlier (Choi, A. H. C., and Siu, C.- H., 1987, J. Cell Biol., 104:1375-1387). Precoating cells with an adhesion-blocking anti-gp80 monoclonal antibody inhibited the binding of gp80-Covaspheres, suggesting that Covasphere-associated gp80 might undergo homophilic interaction with gp80 on the cell surface. Quantitative binding of 125I-labeled gp80 to intact cells gave an estimate of 1.5 X 10(5) binding sites per cell at the aggregation stage. Binding of soluble gp80 to cells was blocked by precoating cells with the anti-gp80 monoclonal antibody. The ability of gp80 to undergo homophilic interaction was further tested in a filter-binding assay, which showed that 125I-labeled gp80 was able to interact with gp80 bound on nitrocellulose in a dosage-dependent manner. In addition, reassociation of cells was significantly inhibited in the presence of soluble gp80, suggesting that gp80 has a single cell-binding site. These results are consistent with the notion that gp80 mediates cell- cell binding at the aggregation stage of development via homophilic interaction.     

Inhibition of cell-cell binding at the aggregation stage of Dictyostelium discoideum development by monoclonal antibodies directed against an 80,000-dalton surface glycoprotein

Monoclonal antibodies were prepared against a putative cell-cell adhesion molecule, a surface glycoprotein with an apparent Mr of 80,000 (gp80), from Dictyostelium discoideum. Seven monoclonal antibodies directed against gp80 were characterized and found to fall into three distinct classes. Class I consisted of one monoclonal antibody, is monospecific for gp80, and probably recognizes the peptide portion of the molecule. This class was capable of blocking the EDTA-resistant contact sites effectively. Class II recognized the carbohydrate moiety of gp80 and cross-reacted with a large number of glycoproteins. These monoclonal antibodies partially inhibited cell reassociation. Class III recognized gp80 and one other glycoprotein of Mr 95,000. This class had no effect on cell-cell binding. The class I monoclonal antibody was most potent in inhibiting cell reassociation at the aggregation stage of development. Its effect decreased drastically as development progressed and became negligible by the culmination stage. These observations are consistent with a direct role of gp80 in cell-cell binding and suggest a transient function for gp80 at the aggregation stage.     

Monoclonal antibody recognizing gp80, a membrane glycoprotein implicated in intercellular adhesion of Dictyostelium discoideum.

WE have raised a monoclonal antibody, designated E28D8, which reacts with an 80,000-dalton membrane glycoprotein (gp80) of Dictyostelium discoideum. gp80 has been implicated in the formation of the EDTA-resistant adhesions ("contact sites A") which appear during development. The monoclonal antibody reacted with other developmentally regulated proteins of D. discoideum, confirming previous results indicating the presence of common antigenic determinants recognized by polyclonal rabbit antibodies directed to gp80. Periodate sensitivity of the determinants suggests that carbohydrate may be necessary for reactivity. Thus, the determinant recognized by E28D8 may result from a posttranslational modification common to a number of proteins. Some of the proteins that carry the determinant were preferentially localized to posterior cells in slugs. Monoclonal antibody E28D8 did not inhibit contact-sites-A-mediated intercellular adhesion. However, gp80 affinity purified on immobilized monoclonal antibody was able to neutralize the adhesion-blocking effect of rabbit antiserum to gp80. Although gp80 itself may not be essential for cell-cell adhesion, it appears to carry the determinants associated with adhesion.     

Filopodia are enriched in a cell cohesion molecule of Mr 80,000 and participate in cell-cell contact formation in Dictyostelium discoideum

During the early phase of Dictyostelium discoideum development, cells undergo chemotactic migration to form tight aggregates. A developmentally regulated surface glycoprotein of Mr 80,000 (gp80) has been implicated in mediating the EDTA-resistant type of cell cohesion at this stage. We have used a monoclonal antibody directed against gp80 to study the topographical distribution of gp80 on the cell surface. Indirect immunofluorescence studies showed that gp80 was primarily localized on the cell surface, with a higher concentration at contact areas. Immunoelectron microscopy was carried out by indirect labeling using protein A-gold, and a nonrandom distribution of gp80 was revealed. In addition to contact regions, gold particles were found preferentially localized on filopodia. Quantitative analysis using transmission electron microscopy (TEM) showed that approximately 60% more gold particles were localized in contact regions in comparison with the noncontact regions, and the filopodial surfaces had a twofold higher gold density. Both TEM and scanning electron microscopy showed that contact areas were enriched in filopodial structures. Filopodia often appeared to adhere to either smooth surfaces or similar filopodial structures of an adjacent cell. These observations suggest that the formation of stable cell-cell contacts involves at least four sequential steps in which filopodia and gp80 probably play an important role in the initial stages of recognition and cohesion among cells.     

Inhibition of cell-cell adhesion and morphogenesis of Dictyostelium by carnitine.

Carnitine (gamma-trimethylammonium beta-hydroxy-butyric acid) possesses the novel property of preventing cell aggregation elicited by clusterin or by fibrinogen (I.B. Fritz and K. Burdzy, J. Cell. Physiol., 140:18-28 [1989]). In investigations reported here, we show that carnitine also affects cell-cell adhesion in Dictyostelium discoideum, a cellular slime mold whose cells interact in specific and complex manners during discrete stages of development. Two types of cell adhesion systems sequentially appear on the surface of developing Dictyostelium cells, involving the surface glycoprotein gp24 which mediates EDTA-sensitive binding sites, and the surface glycoprotein gp80 which mediates the EDTA-resistant binding sites. Addition of increasing concentrations of D(+)-carnitine and L(-)-carnitine resulted in a progressive inhibition of both the EDTA-sensitive binding sites and the EDTA-resistant binding sites of Dictyostelium cells at different stages of development. In contrast, comparable or higher concentrations of choline, acetyl-beta-methylcholine, or deoxycarnitine had no detectable effects on cell aggregation. Concentrations of carnitine required for 50% inhibition of EDTA-resistant adhesion sites were found to be dependent upon levels of gp80 expressed by Dictyostelium, with greatest inhibition by carnitine of reassociation of cells containing the lowest levels of gp80. Removal of carnitine from cells by washing resulted in the rapid restoration of the ability of Dictyostelium to form aggregates and to resume normal development. We discuss possible mechanisms by which carnitine inhibits the aggregation of cells.     

Mutations affecting a surface glycoprotein, gp80, of Dictyostelium discoideum.

We isolated two independent mutations in Dictyostelium discoideum that result in the absence of the antigenic determinant recognized by monoclonal antibody E28D8. This antibody reacts with a post-translational modification on the surface glycoprotein gp80 and several other proteins. Both of the mutations occur in the same locus, modB, which was mapped to linkage group VI. The modB mutations result in sufficient alteration of gp80 that it is absent or unrecognizable by two-dimensional gel electrophoresis. Strains carrying modB mutations exhibit "contact sites A"-mediated cell-cell adhesion although more weakly than do wild-type strains and develop to fruiting bodies carrying viable spores. Although gp80 has been implicated in the mechanism of cell-cell adhesion in D. discoideum, it is clear from the behavior of these mutant strains that the determinant on gp80 recognized by E28D8 is not necessary for either morphogenesis or reduced EDTA-resistant adhesion.     

Cell-cell adhesion molecules in Dictyostelium

Multicellularity in the cellular slime mold Dictyostelium discoideum is achieved by the expression of two types of cell-cell adhesion sites. The EDTA-sensitive adhesion sites are expressed very early in the development cycle and a surface glycoprotein of 24,000 Da is known to be responsible for these sites. The EDTA-resistant contact sites begin to accumulate on the cell surface at the aggregation stage of development. Several glycoproteins have been implicated in the EDTA-resistant type of cell-cell binding and the best characterized one has an Mr of 80,000 (gp80). gp80 mediates cell-cell binding via homophilic interaction and its cell binding site has been mapped to an octapeptide sequence. The mechanism by which gp80 mediates cell-cell adhesion will be discussed.     

The hepatic interleukin-6 receptor. Down-regulation of the interleukin-6 binding subunit (gp80) by its ligand.

Interleukin-6 (IL6) exerts its action via a cell surface receptor composed of an 80 kDa IL6-binding protein (gp80) and a 130 kDa polypeptide involved in signal transduction (gp130). We studied the role of gp80 in binding, internalization and down-regulation of the hepatic IL6-receptor (IL6R) by its ligand in human hepatoma cells (HepG2). Comparison of transfected HepG2 cells overexpressing gp80 with parental cells indicate that gp80 is responsible for low affinity binding (Kd = 500 pM) of IL6. Furthermore, gp80 is rate-limiting in internalization and degradation of IL6. Internalization resulted in a rapid down-regulation (t1/2 approximately 15-30 min) of IL6-binding sites at the cell surface. More than 80% of the internalized [125I]rhIL6 was degraded. The reappearance of IL6-binding sites at the cell surface required greater than 8 h and was sensitive to cycloheximide, suggesting that gp80 is not recycled after internalization. The down-regulation of the hepatic IL6R by its ligand might play an important role as a protection against overstimulation.     

A low-molecular-weight factor which stimulates loss of EDTA-resistant cell cohesion in Dictyostelium

Abstract. During dedifferentiation, mutant HI4 of Dictyostelium discoideum loses the capacity to release and respond chemotactically to cyclic adenosine monophosphate (cAMP) in a normal fashion, but it retains EDTA-resistant cohesiveness, the membrane glycoprotein gp80, and the capacity to reaggregate rapidly by non chemotactic means [21]. In wild-type cells, these last three characteristics are lost at prescribed times in the normal program of dedifferentiation. In the present study, we tested whether dedifferentiating wild-type cells or medium conditioned by dedifferentiating wild-type cells will stimulate the loss of EDTA-resistant cohesiveness in dedifferentiating mutant cells. Results are presented which demonstrate that wild-type cells release a factor into the medium which causes the loss of EDTA-resistant cohesiveness in mutant cells at the correct time in the dedifferentiation program. The factor is heat sensitive, resistant to lyophilization, and exhibits a molecular weight of less than 5,000 daltons. However, although the factor stimulates the loss of EDTA-resistant cohesiveness, it does not stimulate the loss of the glycoprotein gp80, the membrane molecule implicated in cohesion. Several explanations for these results are proposed.     

Mapping of a cell-binding domain in the cell adhesion molecule gp80 of Dictyostelium discoideum

At the aggregation stage of Dictyostelium discoideum development, a cell surface glycoprotein of Mr 80,000 (gp80) has been found to mediate the EDTA-resistant type of cell-cell adhesion via homophilic interaction (Siu, C.-H., A. Cho, and A. H. C. Choi. 1987. J. Cell Biol. 105:2523-2533). To investigate the structure-function relationships of gp80, we have isolated full length cDNA clones for gp80 and determined the DNA sequence. The deduced structure of gp80 showed three major domains. An amino-terminal globular domain composed of the bulk of the protein is supported by a short stalk region, which is followed by a membrane anchor at the carboxy terminus. Structural analysis suggested that the cell-binding domain of gp80 resides within the globular domain near the amino terminus. To investigate the relationship of the cell-binding activity to this region of the polypeptide, three protein A/gp80 (PA80) gene fusions were constructed using the expression vector pRIT2T. These PA80 fusion proteins were assayed for their ability to bind to aggregation stage cells. Binding of 125I-labeled fusion proteins PA80I (containing the Val123 to Ile514 fragment of gp80) and PA80II (Val123 to Ala258) was dosage dependent and could be inhibited by precoating cells with the cell cohesion-blocking mAb 80L5C4. On the other hand, there was no appreciable binding of PA80III (Ile174 to Ile514) to cells. Reassociation of cells was significantly inhibited in the presence of PA80I or PA80II. In addition, 125I-labeled PA80II exhibited homophilic interaction with immobilized PA80I, PA80II, or gp80. The results of these studies lead to the mapping of a cell-binding domain in the region between Val123 and Leu173 of gp80 and provide direct evidence that the cell-binding activity of gp80 resides in the protein moiety.     

A dedifferentiation-defective mutant of Dictyostelium that retains the capacity to aggregate in the absence of chemotaxis

During slime mold development, cells acquire the capacity to rapidly recapitulate morphogenesis in roughly a tenth the original time. When developing cells are disaggregated and refed, they completely loss this capacity in a rapid and synchronous step referred to as the “erasure event.” The erasure event sets in motion a program of dedifferentiation during which developmentally acquired functions are lost at different times. In this report, we describe the phenotype of HI4, which is a mutant partially defective in the dedifferentiation program but normal in all aspects of growth, morphogenesis, and rapid recapitulation. HI4 cells progress through the erasure event, losing in a relatively normal fashion (I) the capacity to rapidly recapitulate later stages of morphogenesis, (2) the capacity to release a cAMP signal, and (3) the capacity to respond chemotactically to a cAMP signal. However, erased HI4 cells abnormally retain the capacity to rapidly reaggregate, even though they have lost chemotactic functions. Erased HI4 cells also abnormally retain EDTA-resistant cohesion (contact sites A) and the surface glycoprotein gp80. It appears that erased HI4 cells rapidly reaggregate owing to random collisions followed by tight cell cohesion.     

The membrane glycoprotein gp150 is encoded by the lagC gene and mediates cell-cell adhesion by heterophilic binding during Dictyostelium development

gp150 is a membrane glycoprotein which has been implicated in cell-cell adhesion in the postaggregation stages of Dictyostelium development. An analysis of its tryptic peptides by mass spectrometry has identified gp150 as the product of the lagC gene, which was previously shown to play a role in morphogenesis and cell-type specification. Antibodies raised against the GST-LagC fusion protein specifically recognized gp150 in wild-type cells and showed that it is missing in lagC-null cells. Immunolocalization studies have confirmed its enrichment in cell-cell contact regions. In mutant cells that lack the aggregation stage-specific cell adhesion molecule gp80, gp150 is expressed precociously. Moreover, these cells acquire EDTA-resistant cell-cell binding during aggregation, suggesting a role for gp150 in this process. Cells in which the genes encoding gp80 and gp150 are both inactivated do not acquire EDTA-resistant cell adhesion during aggregation. Strains transformed with an actin 15::lagC construct express gp150 precociously, but do not show EDTA-resistant adhesion during early development. However, vegetative cells expressing gp150 can be recruited into aggregates of 16-h lagC-null cells. These results, together with those obtained with the cell-to-substratum binding assay, indicate that gp150 mediates cell-cell adhesion via heterophilic interactions with another component that accumulates during the aggregation stage.     

Cell-cell adhesion and morphogenesis in Dictyostelium discoideum

During development of Dictyostelium discoideum, cells acquire EDTA-resistant cell-cell adhesion at the aggregation stage. The EDTA-resistant cell binding activity is associated with a cell surface glycoprotein of Mr 80,000 (gp80), which mediates cell-cell binding via homophilic interaction. Analysis of the structure of gp80 deduced from cDNA sequence reveals the presence of three internally homologous segments in the NH2-terminal domain, which also contains regions with homology to the neural cell adhesion molecule. Secondary structure predictions show an abundance of beta-structures and very few alpha-helices. This is confirmed by circular dichroism measurements. It is likely that the homologous segments are organized into globular structures, extended from the cell surface by a Pro-rich stalk domain. The cell binding activity of gp80 resides within the first globular repeat of the NH2-terminal domain and has been mapped to a 51 amino acid region between Val123 and Leu173. Synthetic oligopeptides corresponding to sequences within this region have been prepared and assayed for their ability to bind to cell surface gp80. Results lead to identification of the homophilic binding site to an octapeptide sequence within this region. Synthetic peptides containing this octapeptide sequence and univalent antibodies directed against this site block the formation of organized cell streams during aggregation. Although cell aggregates are eventually formed, most fail to undergo further development to give rise to slugs and fruiting bodies, indicating that cell-cell adhesion involving gp80 is an important step in normal morphogenesis.     

Complement activation by human monoclonal antibodies to human immunodeficiency virus.

It has been shown that the incubation of human immunodeficiency virus (HIV) with polyclonal antibodies from HIV-infected persons and complement results in complement-mediated neutralization due, at least in part, to virolysis. The current study was performed to determine whether any of a panel of 16 human monoclonal antibodies to HIV could activate complement and, if so, which determinants of the HIV envelope could serve as targets for antibody-dependent complement-mediated effects. Human monoclonal antibodies directed to the third variable region (V3 region) of HIVMN gp120 induced C3 deposition on infected cells and virolysis of free virus. Antibodies to two other sites on HIVMN gp120 and two sites on gp41 induced few or no complement-mediated effects. Similarly, only anti-V3 antibodies efficiently caused complement-mediated effects on the HIVIIIB isolate. In general, the level of C3 deposition on infected cells paralleled the relative level of bound monoclonal antibodies. As expected, pooled polyclonal antibodies from infected persons were much more efficient than monoclonal antibodies inducing C3 deposition per unit of bound immunoglobulin. Treatment of virus or infected cells with soluble CD4 resulted in increases in anti-gp41 antibody-mediated virolysis and C3 deposition but decreases in anti-V3 antibody-mediated virolysis and C3 deposition. In general, virolysis of HIV was more sensitive as an indicator of complement-mediated effects than infected-cell surface C3 deposition, suggesting the absence of or reduced expression of functional complement control proteins on the surface of free virus. Thus, this study shows that human monoclonal antibodies to the V3 region of gp120 are most efficient in causing virolysis of free virus and C3 deposition on infected cells. Elution of gp120 with soluble CD4 exposes epitopes on gp41 that can also bind antibody, resulting in virolysis and C3 deposition. These findings establish a serologically defined model system for the further study of the interaction of complement and HIV.