Immunological analysis of glycoprotein (contact sites A) involved in intercellular adhesion of Dictyostelium discoideum

Extracellular polyphosphate signals through Ras and Akt to prime Dictyostelium discoideum cells for development

Linear chains of five to hundreds of phosphates called polyphosphate are found in organisms ranging from bacteria to humans, but their function is poorly understood. In Dictyostelium discoideum, polyphosphate is used as a secreted signal that inhibits cytokinesis in an autocrine negative feedback loop. To elucidate how cells respond to this unusual signal, we undertook a proteomic analysis of cells treated with physiological levels of polyphosphate and observed that polyphosphate causes cells to decrease levels of actin cytoskeleton proteins, possibly explaining how polyphosphate inhibits cytokinesis. Polyphosphate also causes proteasome protein levels to decrease, and in both Dictyostelium and human leukemia cells, decreases proteasome activity and cell proliferation. Polyphosphate also induces Dictyostelium cells to begin development by increasing expression of the cell-cell adhesion molecule CsA (also known as CsaA) and causing aggregation, and this effect, as well as the inhibition of proteasome activity, is mediated by Ras and Akt proteins. Surprisingly, Ras and Akt do not affect the ability of polyphosphate to inhibit proliferation, suggesting that a branching pathway mediates the effects of polyphosphate, with one branch affecting proliferation, and the other branch affecting development.

Cloning of cDNA for the contact site A glycoprotein of Dictyostelium discoideum

A cell surface glycoprotein of Dictyostelium discoideum with M(r) 80,000 (gp80) has been shown to mediate the formation of the developmentally acquired EDTA-resistant cell-cell binding sites termed contact sites A. We have isolated cDNA clones encoding gp80 by immunological screening of an expression library prepared in Escherichia coli. Double-stranded cDNA was prepared from poly(A)(+) RNA isolated from cells at 8 hr of development and cloned into the bacteriophage expression vector lambdagt11. Two recombinant phages containing cDNA inserts of 1.2 and 0.8 kilobases were isolated and shown to contain sequences coding for gp80 by the immunoselect assay. Partial DNA sequence analysis also confirmed that one of these cDNA clones, lambdaDdgp80c-19, contained the coding sequence for the amino terminus of gp80. DNA-RNA hybridization showed that the insert of lambdaDdgp80c-19 hybridized to a single mRNA transcript of approximately 2.0 kilobases. gp80 mRNA became detectable after 6 hr of development, reached its maximum level at 9 hr, and dropped to a negligible level by 15 hr. This pattern of mRNA accumulation corresponded closely to that of gp80 synthesis in D. discoideum cells, suggesting that gp80 expression is regulated at the transcriptional level.

Discrete interactions in cell adhesion measured by single-molecule force spectroscopy

Cell-cell adhesion mediated by specific cell-surface molecules is essential for multicellular development. Here we quantify de-adhesion forces at the resolution of individual cell-adhesion molecules, by controlling the interactions between single cells and combining single-molecule force spectroscopy with genetic manipulation. Our measurements are focused on a glycoprotein, contact site A (csA), as a prototype of cell-adhesion proteins. csA is expressed in aggregating cells of Dictyostelium discoideum, which are engaged in development of a multicellular organism. Adhesion between two adjacent cell surfaces involves discrete interactions characterized by an unbinding force of 23 +/- 8 pN, measured at a rupture rate of 2.5 +/- 0.5 microm s-1.

Cell adhesion in the life cycle of Dictyostelium

Three forms of cell adhesion determine the life cycle of Dictyostelium: i) adhesion of bacteria to the surface of the growing amoebae, as the prerequisite for phagocytosis; ii) cell-substrate adhesion, necessary for both locomotion of the amoebae and migration of the slug; iii) cell-cell adhesion, essential for transition from the unicellular to the multicellular stage. Intercellular adhesion has received the most attention, and fruitful approaches have been developed over the past 25 years to identify, purify and characterize cell adhesion molecules. The csA glycoprotein, in particular, which mediates adhesion during the aggregation stage, is one of the best defined cell adhesion molecules. The molecular components involved in phagocytosis and cell-substratum adhesion are less well understood, but the basis has been laid for a systematic investigation of both topics in the near future.

A monoclonal antibody that interferes with the post-aggregation adhesion of Dictyostelium discoideum cells

A monoclonal antibody that interferes with the EDTA-resistant adhesion of Dictyostelium discoideum slug cells recognised a carbohydrate epitope on four major antigens (95, 90, 35 and 30 kDa) in slug cells. The 35 and 30 kDa antigens were specific for stalks and spores, respectively. The 30 kDa antigen was identified as the cell surface glycoprotein, PsA. Cyclic AMP, acting via cell surface receptors, induced only the 90 kDa slug cell antigen. Slug cell adhesion proteins may be involved in cell-sorting and the glycosylation of the 95 and 90 kDa antigens appeared to be abnormal in a mutant defective in cell-sorting. Previously, a 150 kDa glycoprotein has been strongly implicated in slug cell adhesion and the present work suggests that additional glycoprotein(s) are involved.

Replacement of the phospholipid-anchor in the contact site A glycoprotein of D. discoideum by a transmembrane region does not impede cell adhesion but reduces residence time on the cell surface

The contact site A (csA) glycoprotein of Dictyostelium discoideum, a cell adhesion molecule expressed in aggregating cells, is inserted into the plasma membrane by a ceramide-based phospholipid (PL) anchor. A carboxyterminal sequence of 25 amino acids of the primary csA translation product proved to contain the signal required for PL modification. CsA is known to be responsible for rapid, EDTA-resistant cohesion of cells in agitated suspensions. To investigate the role of the PL modification of this protein, the anchor was replaced by the transmembrane region and short cytoplasmic tail of another plasma membrane protein of D. discoideum. In cells transformed with appropriate vectors, PL-anchored or transmembrane csA was expressed under the control of an actin promoter during growth and development. The transmembrane form enabled the cells to agglutinate in the presence of shear forces, similar to the PL-anchored wild-type form. However, the transmembrane form was much more rapidly internalized and degraded. In comparison to other cell-surface glycoproteins of D. discoideum the internalization rate of the PL-anchored csA was extremely slow, most likely because of its exclusion from the clathrin-mediated pathway of pinocytosis. Thus, our results indicate that the phospholipid modification is not essential for the csA-mediated fast type of cell adhesion but guarantees long persistence of the protein on the cell surface.

Purification and characterization of an outer membrane protein adhesin from Haemophilus parainfluenzae HP-28

Outer membranes were isolated from Haemophilus parainfluenzae HP-28 by a mild extraction method followed by Sephadex G-150 gel filtration chromatography. The first peak (pool 1) recovered contained an activity which inhibited adherence of HP-28 cells to saliva-coated spheroidal hydroxyapatite. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of pool 1 revealed a dominant protein band of 34 kDa. The SDS-PAGE-purified 34-kDa protein was excised from the gel and used for antibody preparation in rabbits. The antiserum produced was analyzed by immunoblot and was shown to be monospecific for the 34-kDa protein. Anti-34-kDa protein antibody was purified from the rabbit antiserum by protein A-Sepharose 6MB affinity chromatography. This antibody was then cross-linked to protein A-Sepharose 6MB to construct a second affinity column. The 34-kDa proteins were purified from outer membranes by this affinity chromatography. The 34-kDa protein was homogeneous, as confirmed by SDS-PAGE, isoelectric focusing, and reverse-phase chromatography analyses. Fab and Fc fragments of the purified anti-34-kDa protein antibodies were prepared by papain digestion, followed by carboxymethyl cellulose chromatography. Fab fragments from the anti-34-kDa protein antibody and the affinity-purified 34-kDa protein both showed significant inhibition of parent H. parainfluenzae HP-28 cell adherence to experimental salivary pellicle and to Streptococcus sanguis SA-1.

Recovery of the contact site A glycoprotein of Dictyostelium discoideum from sodium dodecyl sulfate-polyacrylamide gel and characteristics of monoclonal antibodies against the recovered protein

Monoclonal antibodies were produced against a cell-cell adhesion (contact site A) glycoprotein of Dictyostelium discoideum, isolated by preparative gel electrophoresis. The glycoprotein was recovered by electroelution from a polyacrylamide gel strip and used for the production of monoclonal antibodies. Four of the five antibodies obtained bound specifically to the protein moiety of the contact site A glycoprotein. The specificities of the antibodies were in striking contrast to those of antibodies raised against the contact site A glycoprotein purified by Triton X-114 phase separation and DEAE chromatography. The majority of the latter antibodies recognized the carbohydrate moiety of the contact site A glycoprotein and cross-reacted heavily with other membrane glycoproteins.

Regulation of slug size by the cell adhesion molecule gp80 in Dictyostelium discoideum

We previously provided in vitro evidence that the cell surface glycoprotein of Mr80,000 (gp80) of Dictyostelium discoideum is capable of mediating EDTA-resistant cell-cell binding. Expression of gp80 is specific for the aggregation stage when cells form tight aggregates. To investigate the physiological role of gp80, Dictyostelium cells were transformed with a vector containing gp80 cDNA fused to an actin promoter. gp80 transcripts were detected in transformed cells in their vegetative growth phase. Transformants at this stage also exhibited EDTA-resistant cell cohesion, thus providing direct in vivo evidence that gp80 mediates cell-cell binding via homophilic interaction. While aggregates of the parental strain KAX3 had the tendency to break up to form small slugs, transformants expressing an increased amount of gp80 were able to maintain the integrity of aggregates, giving rise to larger slugs, resulting in the formation of bigger fruiting bodies. To further demonstrate that the increase in slug size could be correlated with the expression of gp80, cells of the parental strain were treated with exogenous cAMP pulses to stimulate an over-expression of gp80. The treated cells also gave rise to larger slugs, consistent with the notion that slug size is influenced by intercellular adhesiveness during development.

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.

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.

Identification of an octapeptide involved in homophilic interaction of the cell adhesion molecule gp80 of dictyostelium discoideum

During development of Dictyostelium discoideum, a surface glycoprotein of Mr 80,000 (gp80) is known to mediate EDTA-resistant cell-cell adhesion via homophilic interaction. Antibodies directed against a 13 amino acid sequence (13-mer) near the NH2 terminus of the protein were found to inhibit cell reassociation. This 13-mer also inhibited gp80-cell interaction and gp80-gp80 interaction. The cell binding site was mapped to the octapeptide sequence YKLNVNDS by using shorter peptide sequences to inhibit gp80 interaction. High salt concentrations inhibited homophilic interactions of both the 13-mer and gp80, suggesting that ionic interactions are involved in the forward binding reaction. Since disruption of homophilic interactions between the bound molecules required the presence of Triton X-100, hydrophobic interactions may occur after the initial ionic binding.

Developmental changes in protein composition and the actin-binding protein ponticulin in Dictyostelium discoideum plasma membranes purified by an improved method

We have used a new combination of previously-described methods to obtain a 29-fold purification of plasma membranes from Dictyostelium discoideum. In this procedure, the pellet from a cell lysate is centrifuged through a high-pH sucrose gradient and then through a Renografin gradient. Electron microscopy shows that the resultant "Renografin membranes" are essentially homogeneous. As measured by enzymatic marker assays, contamination with mitochondria, lysosomes, and endoplasmic reticulum is minimal. As assayed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), the protein composition of Renografin membranes is similar to that of highly purified membranes isolated using concanavalin A stabilization and detergent extraction. Using Renografin membranes, we have examined developmental changes in the membrane protein composition. In agreement with previous investigations, we observe major changes in lectin-binding glycoproteins and cell-surface-labeled proteins during the first 18 h of D. discoideum development. In contrast to most previous work, which may have employed plasma membranes of lesser purity, we also observe major changes in silver-stained membrane proteins. We conclude that many developmentally regulated proteins, previously thought to be minor membrane constituents, are a larger proportion of the plasma membrane than originally believed. The observed changes in membrane protein composition may correlate with changes in plasma membrane functions during development. For instance, ponticulin, the major salt-sensitive F-actin-binding protein in plasma membranes from vegetative cells, increases at least twofold in plasma membranes during early development when the cells are chemotaxing into large aggregates. The amount of plasma membrane ponticulin then decreases during the pseudoplasmodial stage.

Developmentally regulated cell-cell adhesion in Dictyostelium purpureum is mediated by a glycoprotein synthesized in nonadhesive cells

Upon starvation the cellular slime mold, Dictyostelium purpureum, develops a form of cell-cell adhesion aiding in the formation of large multicellular aggregates, which are capable of further differentiation. The molecule that mediates this adhesion is a glycoprotein of Mr approximately 40,000. The protein shares a common carbohydrate epitope with another well-characterized cell adhesion molecule from Dictyostelium discoideum, contact sites A, but the polypeptides to which it is attached differ for each species. Although mediating a developmental form of adhesiveness, the protein is synthesized in vegetative cells at a time when they do not adhere. Most of the vegetative protein is associated with cell membranes and appears to be on the surface of these cells. The protein is compared to other cell adhesion molecules from other species of cellular slime molds, and possible explanations for its inability to function in vegetative cells are discussed.

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.

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.

Expression of the contact site A glycoprotein in Dictyostelium discoideum: quantitation and developmental regulation

We have previously reported that a monoclonal antibody directed specifically against a surface glycoprotein of Mr 80,000 (gp80) inhibits the EDTA-resistant contact sites A of Dictyostelium discoideum (Siu, C.-H., and Choi, A.H.C. (1985) J. Biol. Chem. 260, 16030-16036). In this report, we describe an assay using this monoclonal antibody to quantitate the amount of gp80 expressed at different developmental stages. Under normal conditions, gp80 is detectable after 6 h of development and it rapidly accumulates between 6 and 10 h, corresponding to the time when cells acquire their EDTA-resistant binding sites. At the peak level, there are 1.5.10(5) gp80 molecules per cell. More than 90% of the cellular gp80 is located on the cell surface. When cells are given exogenous pulses of cAMP, a precocious and enhanced expression of gp80 is induced. At the peak level, the cAMP-pulsed cells accumulate five times more gp80 than the non-pulsed cells. This is preceeded by an equally rapid accumulation of gp80 transcripts, suggesting that cAMP regulates gp80 synthesis at the transcriptional level.

Cell-cell adhesion in Dictyostelium discoideum

Three separate mechanisms of cell-cell adhesion have been shown to appear at different stages of development in Dictyostelium discoideum. During the first few hours of development, the cells synthesize and accumulate a glycoprotein of 24,000 daltons (gp24) that is positioned in the membrane. The time of appearance of gp24 correlates exactly with the time of appearance of cell-cell adhesion in two strains in which temporal control varies by several hours. Antibodies specific to gp24 are able to block cell-cell adhesion during the first few hours of development but not during later development. By 8 hr of development, another glycoprotein, gp80, that is not recognized by antibodies to gp24 accumulates on the surface of cells. This membrane protein mediates an independent adhesion mechanism during the aggregation stage that is resistant to 10 mM EDTA. Antibodies specific to gp80 can block EDTA-resistant adhesion during this stage. During subsequent development, gp80 is removed from the cell surface and replaced by another adhesion mechanism that is insensitive to antibodies to either gp24 or gp80. A lambda gt11 expression vector carrying a Dictyostelium cDNA insert was isolated that directs the synthesis of a fusion protein recognized by antibodies specific to gp24. This cDNA was used to probe a genomic library. A clone carrying a 1.4-kb insert of genomic DNA was recognized by the cDNA and shown to hybridize to a 0.7-kb mRNA that accumulates early in development. This unusually small RNA could code for the small protein, gp24. Southern analysis of restriction fragments generated by various enzymes on Dictyostelium DNA with both the cDNA and genomic clones indicated the presence of two tandem copies of the gene. This may account for the failure to recover mutations resulting in the lack of gp24. Mutations have been recovered that result in the lack of accumulation of gp80, and cells carrying these mutations have been shown to be missing the second adhesion mechanism. These mutant strains are able to complete development because the other adhesion mechanisms are not impaired. Sequential addition of adhesion mechanisms provides a means for the formation of multicellular organisms from previously solitary cells.

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.

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.

Surface glycoprotein, gp24, involved in early adhesion of Dictyostelium discoideum

A membrane glycoprotein of 24,000 Da (gp24) was purified from developed cells of Dictyostelium discoideum and shown to neutralize a crude antiserum (R695) that blocks EDTA-sensitive cell-cell adhesion during the early developmental stages of this organism. Purified gp24 was used to raise rabbit polyclonal antibodies and mouse monoclonal antibodies. Rabbit antiserum R851 was shown to be highly specific to gp24 by both Western analysis and immunoprecipitation. IgG of R851 is able to block adhesion of dissociated cells swirled in suspension. Adhesion of wild-type cells is blocked by R851 antibodies during the first 8 hr of development but not thereafter when other adhesion mechanisms come into play. The glycoprotein gp80 plays an essential role in the second adhesion system that appears during the aggregation stage of D. discoideum. By adding both anti-gp24 and anti-gp80 antibodies, adhesion of aggregation stage cells could be blocked. Late in development a third adhesion mechanism appears that is not blocked by either antibodies to gp24 or gp80 or both antibodies together. Western analysis and immunoprecipitation with monoclonal antibody mLJ11, specific for gp24, indicated that gp24 is absent in cells growing exponentially on bacteria but is rapidly synthesized and accumulated following the initiation of development. Synthesis of gp24 is maximal during the first 4 hr of development and then continues at a reduced rate throughout the remainder of development. The coordinate appearance of gp24 and EDTA-sensitive cell-cell adhesion as well as the ability of this glycoprotein to neutralize the adhesion blocking activity of R695 and R851 antibodies indicates that it plays a role in early cell-cell adhesion.

Cell surface carbohydrates and cell recognition in Dictyostelium

Carbohydrate ligands and complementary receptors have been detected on the surface of Dictyostelium cells, using lectins, monoclonal antibodies, and immobilized sugar probes. They have been implicated in cell recognition processes, such as phagocytosis and intercellular adhesion, and could act as membrane signals for differentiation. Specific glycoproteins have been proposed to mediate intercellular adhesion in Dictyostelium discoideum and Polysphondylium pallidum and to account for the species-specificity of adhesion displayed by these species. Recent studies with the inhibitor of N-glycosylation, tunicamycin, and with glycosylation defective mutants suggest that some carbohydrate groups in these glycoproteins play a role in cell adhesion.

A characterization of the preaggregative period of Dictyostelium discoideum

The preaggregative period of Dictyostelium discoideum has been characterized by measuring the reduction in time for the onset of aggregation under conditions which hinder close cell-cell associations, inhibit protein synthesis, and/or include continuous high concentrations or pulsed low concentrations of exogenous cAMP. The results demonstrate that: the preaggregative period (normally 7 hr for cells from log phase cultures) can be dissected into two distinct components: an initial component which includes the first 4.5 hr, and a second component which includes the last 2.5 hr; the first component will progress at normal rate in the continuous absence of close cell-cell associations (as single amoebae in suspension) or in the continuous absence of de novo protein synthesis; the second component will not progress in the continuous absence of close cell-cell associations or de novo protein synthesis; high concentrations of cAMP continuously present in suspension cultures do not affect progress through the first component, nor do they support progress through the second component; however, if cells are allowed to form close cell-cell associations during progress through the first component, high concentrations of cAMP will support progress through the second component in the absence of close cell-cell associations; these associations, which render cells sensitive to cAMP, will occur in the absence of de novo protein synthesis and before the acquisition of contact sites A; these associations may be completely bypassed if suspended cells are continuously pulsed with low concentrations of cAMP; in this case, pulses of cAMP will support progress through the final component in continuous suspension cultures; and the acquisition of contact sites A will not occur in the absence of progress through the second component; in contrast, the acquisition of cAMP binding sites on the cell's surface will occur. These results are considered in terms of the complexity and regulation of the preaggregative period of Dictyostelium.

Protein-linked oligosaccharide implicated in cell-cell adhesion in two Dictyostelium species

Monoclonal antibody d-41, previously shown to block in vitro cell-cell adhesion in aggregating Dictyostelium discoideum, also blocks adhesion in aggregating D. purpureum. In both species the antibody reacts with proteins with Mr approximately 80,000, 37,000, and 27,000, presumed to be glycoproteins since the d-41 epitope is destroyed by periodate oxidation but unaffected by extensive Pronase digestion. Polyclonal antibodies raised against the mixture of d-41 reactive glycoproteins that had been purified by immunoaffinity chromatography are potent inhibitors of D. discoideum adhesion, and adhesion-blocking activity is neutralized extensively and equivalently by each of the purified glycoproteins from D. discoideum with which d-41 reacts. In contrast, polyclonal antibodies raised against the same purified glycoproteins after they had been oxidized with periodate do not block cell-cell adhesion although they react with the glycoproteins with Mr approximately 80,000, 37,000, and 27,000 and bind as extensively to the surface of aggregating D. discoideum cells as do the adhesion-blocking polyclonal antibodies. When taken together, these results raise the possibility that some component of the d-41 binding oligosaccharide participates in cell-cell adhesion.

Carbohydrate and other epitopes of the contact site A glycoprotein of Dictyostelium discoideum as characterized by monoclonal antibodies

A series of monoclonal antibodies against a developmentally regulated protein of Dictyostelium discoideum, the contact site A glycoprotein, were used in immunoblots to label proteins of cells harvested at three stages of development: during the growth phase, at the aggregation competent stage, and at the slug stage. The antibodies fell into two groups according to their reactivity with partially or fully deglycosylated forms of the 80 kDa glycoprotein. Group A antibodies reacted not only with a 66 kDa, but also with a 53 kDa product of tunicamycin-treated wild-type cells, and they reacted with a 68 kDa component produced by HL220, a mutant that carries a specific defect in glycosylation. The 68 kDa product of the mutant was not completely unglycosylated. Like the 80 kDa glycoprotein of the wild type, which carried sulfate at carbohydrate residues, the mutant product was sulfated. In the presence of tunicamycin, the mutant produced a 53 kDa component indistinguishable from that of the wild type, which represents, most likely, the non-N-glycosylated protein portion of the contact site A glycoprotein. The group A antibodies showed almost no cross-reactivity with other proteins of the developmental stages tested, in accord with their postulated specificity for the protein moiety of the contact site A molecule. Group B antibodies did not react with the 53 kDa product of tunicamycin-treated cells, nor with the 68 kDa component of mutant HL220. These antibodies were of varying specificity. Some of them were almost as specific as group A antibodies, others cross-reacted with many proteins, particularly of the slug stage. Competition or non-competition between various group B antibodies for binding to the contact site A glycoprotein allowed sub-classification of these antibodies. According to two criteria, group B antibodies were characterized as anti-carbohydrate antibodies: (1) some of these antibodies were blocked by N-acetylglucosamine; (2) none of them reacted with the 68 kDa product or any other protein of mutant HL220. These results indicate that the 80 kDa glycoprotein carries two types of carbohydrate: type 1 carbohydrate that is sulfated and present on the 68 kDa product of mutant HL220, and type 2 carbohydrate that reacts with group B antibodies and is present on the 66 kDa product of tunicamycin-treated wild-type cells. Type 2 carbohydrate moieties are also present on many glycoproteins that are enriched in the prespore area of the slugs.(ABSTRACT TRUNCATED AT 400 WORDS)

Adhesion mutants of Dictyostelium discoideum lacking the saccharide determinant recognized by two adhesion-blocking monoclonal antibodies

A mutant of Dictyostelium discoideum, strain HL260, was isolated based on its failure to bind d-41, a monoclonal antibody that blocks developmentally regulated cell-cell adhesion. The mutant fails to normally acquire cell-cell adhesion as assayed with cells shaken in 10 mM EDTA, but aggregates and and constructs fruiting bodies. Other mutant strains, HL216 and HL220, previously shown to have impaired cell-cell adhesion, also lack the determinant that binds d-41. The three strains all carry mutations in a gene designated mod B, which directs a post-translational modification of several developmentally regulated D. discoideum glycoproteins. Diploids formed between independent mod B mutant haploid strains also lack this determinant and show marked impairment of cell-cell adhesion in EDTA, indicating that mutations in mod B, rather than other mutations not shared by the haploid strains, are related to the adhesion defect. The results are consistent with other evidence that an oligosaccharide carried on several developmentally regulated glycoproteins plays an essential role in EDTA-resistant cell-cell adhesion in D. discoideum. However, this type of adhesion is not essential for morphogenesis in that the only defect detected thus far in mod B mutant strains is that they construct relatively smaller fruiting bodies that contain fewer spores.

cAMP-stimulated adenylate cyclase activation in Dictyostelium discoideum is inhibited by agents acting at the cell surface

The ability of Dictyostelium discoideum amoebae to synthesize and secrete cAMP in response to exogenous cAMP is called cAMP signaling. Concanavalin A is a potent, rapid, noncompetitive inhibitor of this response, with the rate of inhibition consistent with its rate of binding. The concanavalin A does not deplete cellular ATP, alter cAMP binding to its surface receptors, or affect basal adenylate cyclase activity, but blocks the cAMP-stimulated activation of adenylate cyclase. Therefore, concanavalin A appears to inhibit a step between the receptor and the adenylate cyclase which is necessary for the transduction of the cAMP signal. Wheat germ agglutinin, a polyclonal antibody against an 80-kDa glycoprotein, four monoclonal antibodies against the amoebal surface, and a chemical cross-linking agent which reacts with cell surface primary amines also inhibit signaling. To determine the importance of cross-linking in the inhibition, succinylated concanavalin A and the unlinked, reactive portion of the chemical cross-linker were tested and found to be relatively ineffective inhibitors. Thus it appears that ligands capable of cross-linking molecules on the external surface of D. discoideum amoebae inhibit cAMP signaling. It is proposed that these cross-linking agents prevent membrane or cytoskeletal rearrangement and that this rearrangement must occur before the adenylate cyclase is activated.

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.

Protein synthesis during development and differentiation in the cellular slime mould Dictyostelium discoideum

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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.

Monoclonal antibody against cytoplasmic lectins of Dictyostelium discoideum: cross-reactivity with a membrane glycoprotein, contact site A, and with E. coli beta-galactosidase and lac repressor

Monoclonal antibodies were raised against two soluble, galactose-binding lectins from cells of Dictyostelium discoideum, discoidin I and II. These antibodies reacted not only with both discoidins, but also with a plasma membrane glycoprotein of aggregation competent cells, called contact site A, and with two carbohydrate-binding proteins of E. coli, beta-galactosidase and lac repressor. The possibility that the antibody recognizes a structure common to different carbohydrate-binding proteins is discussed. The two carbohydrate-binding proteins of E. coli share with discoidin I the sequence -Ser-X-X-Ile-His(Pro)-Pro(His)-Leu-Thr- which might be responsible for the cross-reactivity.

Developmental regulation of Dictyostelium discoideum plasma membrane proteins

Developmental changes in the plasma membrane proteins of Dictyostelium discoideum have been studied using metabolic labeling with [35S]methionine and two-dimensional electrophoresis. Pulse labeling for 1 h at the early interphase, late interphase, aggregation, and tip formation stages of development showed that the profile of newly synthesized plasma membrane proteins changed dramatically over this interval. Only 14% of the polypeptide species were synthesized at all four stages at detectable levels; 86% of the species changed over this developmental interval according to the criterion that they were synthesized at some but not all of the four stages tested. Long-term labeling during vegetative growth followed by initiation of development showed that the "steady-state" levels of the plasma membrane proteins changed very little over the same period. The only changes were in minor species (33% overall change). Similar analyses of whole cell proteins showed 27 and 20% change, respectively. Cell surface radioiodination revealed 52 external proteins in the plasma membrane. Comparison with the uniform methionine labeling results showed that these proteins were, with one notable exception, minor membrane components. In these external proteins, also, developmental changes were limited and were observed in the less abundant species. These results demonstrate the existence of two general classes of plasma membrane proteins. The first is a population of high-abundance proteins that are present in vegetative cells and are largely conserved through development. These possibly serve "housekeeping" functions common to all stages. The second class consists of low-abundance species that are expressed in a highly stage-specific manner and which presumably participate in developmentally important functions.

Spore coat proteins of Dictyostelium discoideum are packaged in prespore vesicles

Previous studies have shown that Dictyostelium discoideum spore coat proteins are found in prespore cells, which are localized to the posterior region of migrating slugs, and in the coats of mature spores. Prespore vesicles, identified by morphology and by staining with anti-D. mucoroides spore serum, are also localized in the posterior region of migrating slugs. Using antisera specific to the spore coat proteins, we show that the spore coat proteins are packaged in prespore vesicles. They are present in the vesicles as a complex which can be dissociated by denaturation. The anti-D. mucoroides spore serum reacts with at least five proteins in whole spore extracts including the spore coat proteins SP96 and SP70.

Mutants of Dictyostelium discoideum blocked in expression of all members of the developmentally regulated discoidin multigene family

Mutant strains of D. discoideum are described that can complete morphogenesis and cytodifferentiation but which express vastly reduced levels of the galactose-binding lectins discoidin I and II (less than 1% and 1%-2% respectively) compared to the wild-type control. Mutant cells proceeding through development lack lectin activity, lectin protein, and specific lectin mRNA. In contrast, the genes encoding these proteins are present in their wild-type configurations in the genome. Since these proteins are encoded by four to five discrete genes, the mutations in these strains are most likely in genes involved in the regulation of the expression of members of this multigene family. The results also indicate that the discoidin lectins may not be required for fruiting body construction in this organism. Finally, coupled with the recent ability to transform D. discoideum, these mutants open the way to identification and isolation of regulatory genes and their products.

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.

Loss and resynthesis of a developmentally regulated membrane protein (gp80) during dedifferentiation and redifferentiation in Dictyostelium

When developing cultures of Dictyostelium discoideum are disaggregated and resuspended in nutrient medium, they lose the capacity to rapidly reaggregate after 90 min, in a rapid and synchronous step referred to as the "erasure event." They then proceed to lose remaining developmentally acquired functions in a program of dedifferentiation culuminating with the loss of EDTA-resistant cohesion roughly 5 hr later. Immediately following the erasure event, cells can be stimulated to reenter the developmental program even though they still possess a number of developmentally acquired functions. These cells therefore appear to undergo dedifferentiation and redifferentiation simultaneously (D. R. Soll and L. H. Mitchell, 1982, Dev. Biol. 91, 183-190). In this report, we have employed an antiserum made against a developmentally acquired membrane glycoprotein, gp80, to examine whether gp80 is lost during dedifferentiation and whether it is either reutilized or resynthesized during redifferentiation. Results are presented which demonstrate that (1) when 9-hr developing cells are disaggregated and resuspended in nutrient medium, gp80 continues to accumulate for several hours after the erasure event, then is lost at roughly the same time as EDTA-resistant cohesion; (2) when cells are stimulated to reenter the developmental program immediately after the erasure event, both gp80 and EDTA-resistant cohesion are still lost according to the program of dedifferentiation, but are then reacquired soon afterwards according to the program of redifferentiation; (3) during redifferentiation, cells do not reutilize gp80 which had been synthesized during initial development; rather they synthesize gp80 de novo; and (4) developing cells of a dedifferentiation-defective variant, HI4, when disaggregated and resuspended in nutrient medium, retain gp80, EDTA-resistant cohesion, and the capacity to rapidly reinitiate aggregation for at least 12 hr. This last result indicates that the loss of gp80 is regulated by the dedifferentiation process and is not an independent response to disaggregation or the reintroduction of nutrients. Together, these results reinforce the conclusion that dedifferentiation and redifferentiation can function independently and simultaneously in the same cells.

Adhesion-blocking antibodies prepared against gp150 react with gp80 of Dictyostelium

A membrane glycoprotein of 150 000 D, gp150, has been implicated in the mechanism of cell-cell adhesion which arises during development of Dictyostelium discoideum. This conclusion was founded on the observation that monovalent Fab' fragments prepared from an antiserum raised against partially purified gp150 are able to block cell-cell adhesion. We show that this serum contains antibodies to a distinct membrane glycoprotein, gp80, previously implicated in cell-cell adhesion. Reaction of Fab' to this surface molecule can account for the adhesion-blocking activity in the antiserum to gp 150. Moreover, binding of gp80 neutralized Fab' to gp150 does not block adhesion. If gp150 carries other determinants which bind adhesion-blocking Fab', these determinants must also be present on gp80. Thus, it is not clear that gp150 is directly involved in cell-cell adhesion of Dictyostelium.

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.

Evidence for another cell-adhesion molecule in Dictyostelium discoideum

We raised a rabbit antiserum that completely blocked cell-cell adhesion of aggregating Dictyostelium discoideum cells in an in vitro assay. All adhesion-blocking activity of this antiserum was adsorbed with a D. discoideum fraction containing molecules having molecular weights as high as about 10(6), even after the material had been extensively digested with Pronase. The properties of this fraction indicate that the antigenic determinants in this macromolecule are saccharide residues. Antigen-rich material is found on vegetative cells but accumulates on or around differentiating D. discoideum cells as they aggregate. The cell surface of an aggregating cell contains about 5 X 10(5) antigenic sites. Antigen is also abundant in the medium of D. discoideum cells starved in suspension, which proved the most convenient starting material for its purification. Like several other macromolecules already discovered in D. discoideum by using this immunological approach, the material identified here may play a direct or indirect role in cell-cell adhesion and merits tentative consideration as a cell-adhesion molecule.