Fusion of cell ghosts with intact cells in Dictyostelium discoideum: Differential response of opposite mating-type cells

The sexual cycle of Dictyostelium discoideum is initiated by the fusion of cells that are of opposite mating types (e.g. NC4- and HM1-type cells). Cells grown in light on agar plates are not capable of sexual cell fusion, but become capable when cultured in the dark in a liquid medium. Cells in the incapable state are called fusion-incompetent cells, and cells in the latter state, fusion-competent cells. To gain some understanding of the mechanism of cell fusion, cell ghosts prepared by freeze-thawing intact cells were incubated with intact cells. The cell ghosts killed the intact cells by directly fusing with them, the extent of fusion depending on the particular strains employed and the fusion-competency of the intact cells and of the cells from which the cell ghosts had been prepared. A detailed examination revealed that fusion-competent NC4 cells were always more easily killed by cell ghosts than fusion-incompetent NC4 cells. It also became apparent that cell ghosts prepared from fusion-competent NC4 cells killed all cell types far more efficiently than did those prepared from fusion-incompetent NC4 cells. However, fusion-competent and fusion-incompetent HM1 cells were equally sensitive to cell ghosts, and cell ghosts prepared from fusion-competent HM1 cells had the same ability to kill as those prepared from fusion-incompetent HM1 cells. From these findings, it thus appears that opposite mating-type cells have distinct membrane properties related to sexual cell fusion.     

A membrane protein with possible relevance to sexual cell fusion in Dictyostelium discoideum

The molecular mechanism of sexual cell fusion in Dictyostelium discoideum was studied using the heterothallic strains HM1 and NC4. Monovalent antibodies (Fab) prepared from rabbit antiserum against a crude membrane preparation of fusion-competent HM1 cells inhibited fusion between HM1 and NC4 cells. Six out of 43 antigenic proteins were found in fusion-competent HM1 cells but not in fusion-incompetent cells. Among them, only one protein with a molecular mass of 70 kDa was able to neutralize the fusion-inhibiting activity of Fab, suggesting its possible participation in sexual cell fusion.     

Environmental factors inducing sexual development inDictyostelium discoideum

In the heterothallic strains NC4 and HM1 ofDictyostelium discoideum, sexual development is initiated by the formation of diploid zygotic giant cells produced through the fusion of these two opposite mating-type haploid cells. For sexual cell fusion, amoeboid cells must first acquire fusion competence, which requires culture under certain environmental conditions, such as darkness, excessive water, and sufficient bacteria as food. However, in the subsequent stages of cell fusion and development of the giant cells into mature macrocysts, cells do not require the above conditions. Cell fusion and development into macrocysts were able to occur even in light with minimum water and in the absence of bacteria. For cell fusion calcium ions were required.     

Fusion-inhibiting monoclonal antibodies and their relevant antigens in relation to sexual process of Dictyostelium discoideum

Sexual cell fusion occurs between NC4 and HM1, the heterothallic strains in Dictyostelium discoideum. Cells of these strains are fusion incompetent when cultured on agar plates in the light and become fusion competent upon cultivation in a liquid medium in darkness. Two cell-surface components, gp70 and gp138, have been identified and characterized as being relevant to sexual cell fusion. Both are glycoproteins, and the former is detected only in fusion-competent HM1 cells, while the latter is detected both in fusion-competent HM1 and fusion-competent NC4 cells. We therefore suspect gp 70 to be responsible for cell recognition and gp138, for membrane fusion. Therefore, NC4 cells are expected to possess specific surface molecule(s) that can be recognized by HM1 cells. In the present study, we raised monoclonal antibodies (mAbs) against membrane fractions of NC4 cells and selected fusion-inhibiting mAbs to identify novel molecules related to sexual cell fusion in D. discoideum. Out of the five mAbs we obtained three, DE1, GG6, and HH9, were characterized. DE1 recognized antigens that specifically existed in fusion-competent NC4 cells but not in fusion-incompetent NC4 or HM1 cells. GG6 recognized cell-surface proteins with approximate molecular weights of 125 and 32 kDa in both fusion-competent NC4 and fusion-competent HM1 cells. In addition GG6 also recognised other proteins commonly present in fusion-incompetent cells. The 125 kDa protein appeared to be the same as gp138. The epitope recognized by HH9 was sodium dodecyl sulfate (SDS)-sensitive.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the cell surface molecule involved in sexual cell fusion of Dictyostelium discoideum

Dictyostelium discoideum was used as a model system for elucidating the molecular mechanism of sexual cell fusion. In heterothallic strains NC4 and HM1 of D. discoideum, complements in mating type, amoeboid cells acquire fusion competence only under certain environmental conditions, such as the presence of excess water and a certain period of darkness, to fuse sexually. The surface of cells which acquired fusion competence was found to possess specific antigens. Monovalent antibodies prepared from rabbit antiserum against fusion-competent NC4 cells inhibit the sexual cell fusion of these cells completely. Two specific antigenic proteins, 39 and 138 k Da in relative molecular mass and specific for fusion-competent cells, were detected. Only one, the 138-k Da protein, was capable of neutralizing the fusion-inhibitory activity of the monovalent antibody. These results show that the 139-k Da protein is the one involved in the sexual cell fusion of NC4 and HM1 strains in D. discoideum.     

Nuclear fusion in multinucleated giant cells during the sexual development of Dictyostelium discoideum

Macrocyst development in Dictyostelium discoideum, is generally considered a sexual phase. This development is initiated by the formation of a giant cell, the result of the fusion of two different mating type haploid cells, such as NC4 and HM1. The giant cell engulfs unfused surrounding cells to develop into a macrocyst. Therefore, if the macrocyst is a sexual structure, the giant cell must be a diploid zygote. However, under certain conditions, a very large multinucleated giant cell containing several dozens of nuclei is formed, followed by normal development into a macrocyst. In such a multinucleated giant cell, it was found that only two nuclei fuse together to produce a diploid zygote and all others disappear at the early stage of development. The diploid nucleus undergoes meiosis and subsequently subdivides into a number of haploid progeny cells later released from the macrocyst to initiate new life cycles.     

Possible existence of a light-inducible protein that inhibits sexual cell fusion in Dictyostelium discoideum.

Sexual cell fusion is an initial step of macrocyst formation in Dictyostelium discoideum and requires environmental conditions such as darkness, plenty of water and the presence of calcium ions. We have been analyzing the mechanism of sexual cell fusion between HM1 and NC4, heterothallic strains in D. discoideum. Cells of these strains have been shown to be fusion competent when cultured in a liquid medium in darkness, but not so when cultured on agar plates or in a liquid medium in the light. Two cell-surface proteins, gp70 and gp138, have been identified as target molecules for fusion-blocking antibodies and therefore as relevant to sexual cell fusion. In the present study, gp70 was shown to be present in HM1 cells cultured in the light, and fusion incompetent. Intact HM1 cells cultured in the light were unable to absorb the fusion-blocking activity of antibodies against membrane components of fusion-competent HM1 cells, whose activity had been shown to be absorbed by gp70, but they did so after separation of proteins in the SDS-PAGE. In addition, fusion-competent HM1 cells were found to lose their fusion competence by subsequent cultivation in the light. This loss of competence was cycloheximide sensitive, indicating that de novo synthesis of proteins was necessary for this inhibition. From these results, we presume that light induces a protein that hinders the interaction of gp70 in HM1 cells with its receptor on the NC4 cell surface and thereby inhibits the sexual process between these strains.     

Protein Synthesis Initiated by Cell Fusion in Dictyostelium discoideum

D. discoideum has two alternative developmental pathways. If cells of two complement mating-type strains, NC4 and HM1, fuse sexually, a giant cell is produced which subsequently develops into a macrocyst, the sexual structure of this organism. However, if fusion fails to occur and cells are starved, a fruiting-body is produced instead of a macrocyst. In this paper, a two-dimensional polypeptide gel electrophoresis study showed that giant cells produce specific polypeptides which may possibly be involved in macrocyst development. Out of total 497 polypeptides which appeared in a giant cell during an incubation period of 13 hr, 92 were the specific for giant cells. Four of these polypeptides were appeared within only 1 hr after the cell fusion. The other 405 were non-specific polypeptides which appeared in both giant cells and NC4 or/and HM1 cells. However, the patterns and the rates of production of each polypeptide during the incubation period were different between these cells.     

An auto-inhibitor of zygote giant cell formation in Dictyostelium discoideum

The first observable event of sexual development in mated cultures (NC4x V12) of Dictyostelium discoideum is the appearance of zygote giant cells which are the product of cell fusions. The increase in the number of giant cells, which begins at about 21 h, is complete by 28 h. In this paper we show that a low molecular weight auto-inhibitor of zygote giant cell formation is present in 28-h cultures. The data presented suggest that this auto-inhibitor is a natural regulator of sexual development in D. discoideum.     

Cell Fusion Promoting Factor Common to Homothallic and Heterothallic Mating Systems in Dictyostelium discoideum1

Cellular slime mould Dictyostelium discoideum propagates as single haploid cells and under certain environmental conditions enters into a sexual cycle called macrocyst formation. There are homothallic and heterothallic strains reported, the former being able to form macrocysts in clonal cell populations while the latter to do so only in the presence of opposite mating-type strains. Molecular basis for differential mating systems is an intersting subject totally unknown yet. In the present study, sexual cell interactions in AC4, a homothallic strain of D. discoideum, was studied in comparison with the heterothallic mating system. The conditoned medium of AC4 cells was found to promote the sexual cell fusion among themselves. In addition, it also enhanced the cell fusion between heterothallic strains. Furthermore, the conditioned medium obtained from the mated culture of heterothallic strains reported to induce the sexual cell fusion in the heterothallic strains (Saga and Yanagisawa, 1983) was found also to promote the cell fusion in AC4. These results suggest that common regulatory mechanisms operate for sexual cell fusion among different mating systems in D. discoideum.     

Involvement of Cell Surface Carbohydrates in the Sexual Cell Fusion of Dictyostelium discoideum

In order to analyze the molecular mechanism of sexual cell fusion between cells of HM1 and NC4 (opposite mating type strains in Dictyostelium discoideum ), monoclonal antibodies were raised against partially-purified gp 70, a fusion-related protein of HM1 cells. The antibodies were screened for activity to inhibit cell fusion and 9 hybridoma clones were obtained. One of the fusion-blocking monoclonal antibodies, mAb1G7, was used for further analysis. It recognized nearly ten bands in an immunoblot of fusion competent HM1 cells, but no bands when HM1 membrane proteins had been deglycosylated. These results suggest the importance of carbohydrates in the cell fusion process. To confirm this possibility, effects of sugars or lectins on cell fusion were examined. Although inhibition by the sugars was incomplete, Con A, WGA, LCA, strongly inhibited cell fusion. Furthermore, tunicamycin inhibited the acquisition of fusion competence in HM1 cells, indicating the importance of N-linked glycosylation of proteins in cell fusion. All above results suggest that N-linked carbohydrates on HM1 cell surface are involved in the sexual cell fusion of D. discoideum .     

Ca and cell fusion during sexual development in liquid cultures of Dictyostelium discoideum

Cell fusion resulting in zygote giant cell formation is the first observable event of sexual development in D. discoideum. The results reported here show that this process is Ca²⁺-dependent and that by increasing the level of Ca²⁺ in the medium the number of cell fusions can be increased 57-fold over control cultures. The data also suggest that Ca²⁺ has both an early and late function in the development of zygotes and these functions are mediated at the cell surface. These results plus the availability of a liquid culture for generating large volumes of cells make sexual development in D. discoideum an excellent system for the analysis of membrane fusion in eukaryotes.     

Nuclear Behavior in Artificially Induced Multi-Nuclear Cells of Dictyostelium discoideum

The culture medium of the strain CK-8 of the cellular slime mold Polysphondylium pallidum contains a cell-fusion induction factor. Cells of the two opposite mating type strains NC-4 and HM1 of Dictyostelium discoideum were treated to induce cell fusion with the diluted fraction of CK-8 cultures, F2, which contains the factor and consequently numerous multinuclear cells were produced. NC-4 and HM1 usually fuse in the sexual cycle and form large multinuclear cells, called giant cells, which develop into macrocysts. These cells are very similar in morphology to the multinuclear cells produced following F2 treatment, however, the latter cells did not develop into macrocysts. In the sexually formed multinuclear cells, only two haploid nuclei fused to form a diploid nucleus and all others degenerate as previously reported. However, in the artificially produced multinuclear cells, no nuclear-fusion and degeneration took place. They stayed as heterokaryons and seem to lyse within 20 h incubation.     

Isolation and Characterization of Dictyostelium Mutants Defective in Sexual Cell Fusion

Sexual cell fusion in the cellular slime mold Dictyostelium discoideum occurs between cells of opposite (heterothallic system) or same (homothallic system) mating types. It also requires certain environmental conditions such as darkness and abundance of water, and thus offers an interesting model system for analyzing mechanisms of cell recognition and of cellular response to environmental factors. We have been studying the mechanism of sexual cell fusion, using two heterothallic strains, NC4 and HM1 of D. discoideum. Two cell-surface glycoproteins, gp70 and gp138, have been identified as relevant molecules in the cell fusion of these strains. The former is specific to mat a cells (HM1) and the latter, common to both mat a and mat A (NC4). Involvement of cell-surface carbohydrates has also been suggested. However, the fuctions of the above fusion-related molecules are still elusive. In the present study, we isolated fusion-deficient mutants from a mutagenized mat A strain of D. discoideum to set up combined genetic and biochemical analyses. Among the three nonconditional mutants obtained, two were normal in the fruiting-body formation, asexual development, but one was aggregateless ( agg ⁻). Further analysis of these mutants would provide detailed information on the mechanism of sexual cell fusion.     

Ca2+ and cell fusion during sexual development in liquid cultures of Dictyostelium discoideum

Cell fusion resulting in zygote giant cell formation is the first observable event of sexual development in D. discoideum. The results reported here show that this process is Ca²⁺-dependent and that by increasing the level of Ca²⁺ in the medium the number of cell fusions can be increased 57-fold over control cultures. The data also suggest that Ca²⁺ has both an early and late function in the development of zygotes and these functions are mediated at the cell surface. These results plus the availability of a liquid culture for generating large volumes of cells make sexual development in D. discoideum an excellent system for the analysis of membrane fusion in eukaryotes.     

Genes involved in Dictyostelium discoideum sexual reproduction

Macrocyst formation in the cellular slime moulds is a sexual process induced under dark and humid conditions. Normal development life cycle in these organisms involves proliferation by cell division and, upon starvation, formation of multicellular aggregates and fruiting bodies, consisting of spores and stalk cells. Macrocyst formation, cell division by binary fission and spore formation are thus three alternative modes of reproduction, for which it is of interest to understand how a choice is made. The genetic basis of asexual development and fruiting body formation is well known, by contrast information on the genetic control of sexual reproduction during macrocyst formation is scarce. In Dictyostelium discoideum, the most widely used species, several cell-surface proteins relevant to sexual cell fusion have been identified using cell fusion-blocking antibodies, but isolation of the relevant genes has been unsuccessful. Analysis of sexually deficient mutants, some of which are normal for asexual development, has shown that sexual reproduction is regulated by both specific genes and genes that are also involved in asexual development. Reverse genetic analysis of 24 genes highly enriched in a gamete-specific subtraction library has revealed four genes involved in the regulation of sexual cell interactions. One of them was found to be a novel regulator of the cAMP signalling pathway specific to sexual development. Studies on the molecular genetic control of the sexual cycle will be reviewed and their contribution to our understanding of the organization and function of the D. discoideum genome as a whole discussed.     

Cell fusion, nuclear fusion, and zygote differentiation during sexual development of Dictyostelium discoideum

The fluorescent nuclear stain Hoechst 33258 was used to study the nuclear events during mating of Dictyostelium discoideum in liquid culture. These studies revealed that cell fusion begins about 11 hr after the sexually compatible cultures are mixed and continues until 26 hr. Approximately 37% of the cells fuse during this 15-hr period. At first the fused cells are relatively small, but by 20 hr the fusion products become evident as morphologically distinct giant cells. Starting at 22 hr these giant cells are transformed into true zygotes as nuclear fusion begins. Both the fusion of amebae and the differentiation of zygote giant cells are Ca²⁺-dependent events as revealed by studies using EGTA. The nuclear events of zygote differentiation involve nuclear swelling, migration, and fusion. The precise timing of these events has been detailed. Of particular interest for genetic analyses via the macrocyst is the presence of a small population of multinucleate cells (maximum level is 1.67% of the cell population) which usually possess 3 or 4 nuclei but may have as many as 10 or more. Although these multinucleate cells contain many nuclei, our evidence suggests that only one is a zygote nucleus. The genetic implications of these data and the potential value of using the mating system for the analysis of cell fusion are discussed.     

Vesicular stomatitis virus G protein acquires pH-independent fusion activity during transport in a polarized endometrial cell line

Entry of vesicular stomatitis virus (VSV), the prototype member of the rhabdovirus family, occurs by receptor-mediated endocytosis. Subsequently, during traversal through the endosomal compartments, the VSV G protein acquires a low-pH-induced fusion-competent form, allowing for fusion of the viral membrane with endosomal and lysosomal membranes. This fusion event releases genomic RNA into the cytoplasm of the cell. Here we provide evidence that the VSV G protein acquires a fusion-competent form during exocytosis in a polarized endometrial cell line, HEC-1A. VSV infection of HEC-1A cells results in high viral yields and giant cell formation. Syncytium formation is blocked in a concentration-dependent manner by treatment with the lysosomotropic weak base ammonium chloride, which raises intravesicular pH. Virus release is somewhat delayed by treatment with ammonium chloride, but virus yields gradually reach those of control cells. In addition, inhibition of vacuolar H(+)-ATPases by treatment with bafilomycin A1 also inhibited cell to cell fusion without altering virus yields. Virions released from infected HEC cells were themselves not fusion competent, since viral entry required an active H(+)-ATPase and a low-pH-induced conformational change in the viral G protein. Thus, the conformation change leading to fusion competence during exocytotic transport is reversible and reverts during or after release of the virion from the infected cell.     

Signalling and sex in the social amoebozoans

The social amoebozoans have a life tricycle consisting of asexual multicellular development leading to fruiting bodies, sexual multicellular development resulting in macrocysts, and unicellular development generating microcysts. This review covers the events of sexual development in the best‐studied heterothallic (Dictyostelium discoideum) and homothallic (D. mucoroides) mating systems. Sexual development begins with pheromonal interactions that produce fusion‐competent cells (gametes) which undergo cell and pronuclear fusion. Calcium‐ and calmodulin‐mediated signalling mediates these early events. As they initiate chemotactic signalling, each zygote increases in size becoming a zygote giant cell. Using cyclic AMP (cAMP), the zygote chemotactically lures in amoebae and engulfs them in an act of cannibalistic phagocytosis. Chemotaxis proceeds more quickly than endocytosis because the breakdown products of cAMP (5‐AMP, adenosine) bind to a presumptive adenosine receptor to inhibit sexual phagocytosis. This slowing of phagocytosis allows amoebae to accumulate around the zygote to form a precyst aggregate. Zygote giant cells also produce several other signalling molecules that feed back to regulate early events. The amoebae surrounding the zygote seal their fate as zygotic foodstuff by secreting a primary cellulose wall, the extracellular sheath, around the zygote and aggregated amoebae, which prevents their escape. Phagocytosis within this precyst continues until all peripheral amoebae are internalized as endocytes and the final macrocyst wall is formed. Endocyte digestion results in a mature macrocyst with a uniform cytoplasm containing a diploid nucleus. After detailing the morphological events of heterothallic and homothallic mating, we review the various intercellular signalling events and other mechanisms involved in each stage. This complete and comprehensive review sets the stage for future research on the unique events that characterize sex in the social amoebozoans.