Dual Effects of cAMP on the Stability of Prespore Vesicles and 8-bromo cAMP-enhanced Maturation of Spore and Stalk Cells of Dictyostelium discoideum

It is well known that interconversion between prestalk and prespore cells occurs in 3-dimensional (3–D) isolates of Dictyostelium. The present work was undertaken to examine whether or not the interconversion occurs even in monolayer sheets. The results suggested that in monolayer sheets of either prespore or prestalk cells, the interconversion does not occur. Furthermore, effects of cAMP were examined in relation to the formation or loss of prespore vesicles (PSVs). In monolayer sheets, prespore cells retain their PSVs in the presence of cAMP, though they lose them in its absence. In 3–D masses, however, cAMP induces the conversion into stalk cells, stimulating PSV loss. In the case of prestalk cells, cAMP induces the maturation of prestalk cells to stalk cells in 3–D masses, but it does not induce stalk differentiation in monolayer sheets.
8-Bromo cAMP stimulates the maturation of prespore and prestalk cells into spore and stalk cells, respectively. However, the vegetative and the aggregative cells remain amoeboid even in its presence. These observations suggest that 8-bromo cAMP stimulates the maturation rather than inducing prespore and prestalk differentiation.     

Different synthetic profiles and developmental fates of prespore versus prestalk proteins of Dictyostelium

Abstract. Depending upon environmental conditions, developing cells of the cellular slime mold Dictyostelium discoideum may enter a slug stage in which the cell mass migrates in response to gradients of light and temperature. This developmental stage has often been used to study the divergent differentiation of the cells that will subsequently form spores and stalk in the mature fruiting body. However, still debated is the extent to which the differentiation evident in slug cells is a precondition for development of the mature cells in fruits. Using two-dimensional gel electrophoresis of polypeptides, we have examined the proteins made by prespore and prestalk cells of migrating slugs and by maturing spore and stalk cells. The data indicate that many of the cell-type specific polypeptides in prespore cells of slugs persist as cell-type specific polypeptides of mature spores. Prestalk slug cells, in contrast, do not contain significant amounts of stalk-specific proteins; these proteins appear only during culmination. The precursor cell types also differ in the times and rates of synthesis of cell-specific proteins: prestalk proteins appear much earlier in development than do the prespore, but never reach the levels of expression that the prespore proteins do later in culmination. These findings may explain the well established ability of prespore cells to regulate their cell type more rapidly than do prestalk cells. There are also implications for our general understanding of what is a 'prestalk' gene product.     

Patterns of cell differentiation revealed by L-[3H]fucose incorporation in Dictyostelium

A study of the incorporation of l-[6-³H]fucose and d-[6-³H]glucosamine hydrochloride was conducted during the development of the cellular slime mold Dictyostelium discoideum 1-H. Autoradiographs revealed that pulse-labeled vegetative amoebae incorporated [³H]fucose intracytoplasmically within 15 min. The majority of the cells had randomly scattered silver grains but the remainder were distinguished by a dense localized labeling which suggested that oligo or polysaccharide synthesis was occurring. The localized pattern of labeling attributed to active synthesis declines at aggregation and early conus formation. As the pseudoplasmodium makes the developmental transition from the conus to the culmination stages the localized pattern of [³H]fucose labeling was restricted to the prespore cells while the prestalk cells were devoid of label. Prespore vacuoles were not present at the onset of this transition and consequently [³H]fucose incorporation occurred in the cells prior to their differentiation into prespore cells. In contrast to cells composing earlier stages, mature spores exhibited [³H]fucose-containing substances at the cell surface. At appropriate stages certain cells actively synthesize slime and stalk sheath which were labeled with either [³H]fucose or [³H]glucosamine.Prestalk isolates were obtained by transecting migrating slugs. [³H]Fucose was incorporated within 10 min among the basal cells of the isolate in the localized pattern typically found in prespore cells. The incorporation of [³H]fucose occurred prior to prespore differentiation as certain preparations were devoid of prespore vacuoles. Prespore isolates differentiate prestalk cells which have lost the capacity to incorporate [³H]fucose. This investigation suggests that cell contacts and interactions may affect the incorporation of [³H]fucose.     

Control of cell type proportions by a secreted factor in Dictyostelium discoideum

It has been shown that, in Dictyostelium discoideum, conversion of prestalk cells to prespore cells in suspension cultures is inhibited by coexisting prespore cells. To examine whether the inhibition of conversion requires direct cell contact or is mediated by substances secreted by the cells, prestalk cells and prespore cells were incubated in shaken suspension, separated from each other by a dialysis membrane, and conversion of the prestalk cells to prespore cells scored after 24 h. Prestalk-to-prespore conversion was significantly inhibited if the density of the prespore cells was sufficiently high. In contrast, prestalk cells had little influence on prestalk-to-prespore conversion. Media conditioned by prespore cells, but not by prestalk cells, also inhibited the conversion of prestalk cells. Adenosine, propionate, diethylstilboestrol and differentiation inducing factor (DIF), all of which are known to influence the prestalk/prespore differentiation, were examined for their effects on prestalk-to-prespore conversion. Among these, all except adenosine significantly inhibited the conversion. Based on these results, possible mechanisms for maintenance of the constant cell-type ratio in D. discoideum slugs were discussed.     

A demonstration of pattern formation without positional information in Dictyostelium

Although positional information, conveyed by morphogen gradients, is a widely accepted way of forming patterns during development, an alternative method is conceivable, based on the intermingled differentiation of cells with different fates, followed by their sorting into discrete pattern elements. It has been proposed that Dictyostelium prestalk and prespore cells behave in this way at the mound stage of development. However, it has been difficult to conclusively demonstrate that they initially differentiate intermingled, because rapid cell movement within the mound makes it impossible to be sure where prestalk and prespore cells originate. We have taken a novel approach to address this problem by blocking cell movement at different stages in development, using the actin-depolymerizing drug, latrunculin-A. Prestalk and prespore cells differentiate with essentially normal efficiency and timing in such paralyzed structures. When movement is blocked sufficiently early, the major cell types all subsequently differentiate at scattered positions throughout the aggregate, and even in the streams leading into it. Our work strongly supports the idea that the prestalk/prespore pattern in Dictyostelium forms without positional information and demonstrate that latrunculin-A may provide a useful tool for the investigation of patterning in other organisms.     

Folic acid stimulation of the Gα4 G protein-mediated signal transduction pathway inhibits anterior prestalk cell development in Dictyostelium

In Dictyostelium discoideum, several G proteins are known to mediate the transduction of signals that direct chemotactic movement and regulate developmental morphogenesis. The G protein alpha subunit encoded by the Galpha4 gene has been previously shown to be required for chemotactic responses to folic acid, proper developmental morphogenesis, and spore production. In this study, cells overexpressing the wild type Galpha4 gene, due to high copy gene dosage (Galpha4HC), were found to be defective in the ability to form the anterior prestalk cell region, express prespore- and prestalk-cell specific genes, and undergo spore formation. In chimeric organisms, Galpha4HC prespore cell-specific gene expression and spore production were rescued by the presence of wild-type cells, indicating that prespore cell development in Galpha4HC cells is limited by the absence of an intercellular signal. Transplanted wild-type tips were sufficient to rescue Galpha4HC prespore cell development, suggesting that the rescuing signal originates from the anterior prestalk cells. However, the deficiencies in prestalk-specific gene expression were not rescued in the chimeric organisms. Furthermore, Galpha4HC cells were localized to the prespore region of these chimeric organisms and completely excluded from the anterior prestalk region, suggesting that the Galpha4 subunit functions cell-autonomously to prevent anterior prestalk cell development. The presence of exogenous folic acid during vegetative growth and development delayed anterior prestalk cell development in wild-type but not galpha4 null mutant aggregates, indicating that folic acid can inhibit cell-type-specific differentiation by stimulation of the Galpha4-mediated signal transduction pathway. The results of this study suggest that Galpha4-mediated signals can regulate cell-type-specific differentiation by promoting prespore cell development and inhibiting anterior prestalk-cell development.     

Differential Cell Cohesiveness Expressed by Prespore and Prestalk Cells of Dictyostelium discoideum

Pseudoplasmodia of Dictyostelium discoideum at the culmination stage were separated into two cell populations by sedimentation in a discontinuous renografin gradient. The two lighter fractions (I and II) had enzymatic activities characteristic of the anterior prestalk cells, while the heaviest fraction (III) showed enzyme activities characteristic of the posterior prespore cells. Cell-cell adhesion among prespore cells is much more resistant to EDTA dissociation than 10-h cells and prestalk cells. Fab fragments prepared from antibodies directed against a specific cell surface glycoprotein gp150 were more effective in dissociating prespore cells than prestalk cells. In addition, prespore cells contained an approximately 2-fold higher concentration of the endogenous carbohydrate binding protein discoidin-I than prestalk cells. These differences may account for the differential cohesiveness of these two cell populations and provide a basis for cell recognition and cell sorting at the slug stage.     

A model for the prestalk/prespore patterning in the slug of the slime mold Dictyostelium discoideum

Abstract. We propose that the prestalk/prespore pattern in Dictyostelium is generated in two steps: In a first process, an intermingled, non-position dependent prestalk/prespore pattern is generated by a cell-restricted autocatalysis and the antagonistic action of a long-ranging substrate which becomes depleted during this autocatalysis. By computer simulations we show that the assumed interaction accounts for several experimentally observed features of the prestalk/ prespore pattern: The size-independent ratio of both cell types, the pattern regulation after removal of one cell type, the development towards one or the other pathway before the slug obtains its final shape or even before aggregation is completed. Our hypothetical substrate may be identical with an experimentally found differentiation-inducing factor (DIF). Alternative molecular realizations of the basic mechanism are discussed. A second process leads to the aggregation of the prestalk cells in a particular region of the aggregate, the future tip region. Interactions which en-able tip formation and the coupling between the prestalk/prespore and the tip-forming system are discussed. Our model shows that the formation of a single large patch of differentiated cells and its size regulation requires conflicting parameters. By a separation into a mechanism which determines the position and a second one which determines the size of a structure, each mechanism can be optimized individually without requiring compromises for the other. Such a separation also seems to occur in other developmental systems.     

Separation and properties of prestalk and prespore cells of Dictyostelium discoideum

We describe a method of separating prestalk and prespore cells of Dictyostelium discoideum slugs using a self-generating Percoll gradient. This method gives quantitative recovery of cells and good purity. Separated prestalk and prespore cells possess different levels of the enzymes UDP galactose :polysaccharide transferase, cAMP phosphodiesterase and glycogen phosphorylase. We have used this method, as well as mechanical dissection of slugs, to examine the fate of separated prestalk and prespore cells in Dictyostelium strains that are able to give rise to mature stalk and spore cells in cell monolayers. The results from such experiments provide direct evidence that prestalk and prespore cells from the migrating slug stage are programmed to differentiate into stalk and spore cells respectively.     

Dynamics of Cell Redifferentiation in Dictyostelium mucoroides

During migration of a D. mucoroides slug, prespore cells at the immediate edge of the prespore-prestalk junction advance into the prestalk region in approximately 1.5 min. Redifferentiation of the prespore into prestalk cells occurs during this period. Evidence that the cells redifferentiated required autoradiographic, electron microscopic, and staining techniques. These methods determined that glycoprotein synthesis declined; prespore vesicles, the organelles found specifically in prespore cells, were degraded; and staining was reduced during this developmental transition into prestalk cells.     

Calcium stores in differentiated Dictyostelium discoideum: prespore cells sequester calcium more efficiently than prestalk cells

Dictyostelium discoideum pseudoplasmodia exhibit a gradient of the cytosolic free Ca2+-concentration ([Ca2+]i) along their anterior-posterior axis involved in cell-type specific differentiation. [Ca2+]i is high in prestalk and low in prespore cells. We determined the content and localization of calcium and other elements in cryosectioned cells of pseudoplasmodia and fruiting bodies by X-ray microanalysis. Granular stores rich in Ca, Mg and P were identified. Average Ca was higher in prespore than prestalk granules (225vs 111 mmol/kg dry weight). Total Ca stored in granules was also higher in prespore than prestalk cells. The amount of P and S in granules differed between the two cell types indicating different store composition. In spores mean granular Ca was 120 mmol/kg dry weight. Stalk cells had smaller granules with 360 mmol Ca/kg dry weight. Complementary to microanalysis, vesicular Ca2+-fluxes were studied in fractionated cell homogenates. The rate of Ca2+-uptake was higher in pellet fractions of prespore than prestalk amoebae (4.7 vs 3.4 nmol/min x mg). Ca2+-release was greater in supernatant fractions from prestalk than prespore cells (16.5vs 7.7 nmol/10(8)cells). In summary, prestalk and prespore cells possess qualitatively different, high-capacity stores containing distinct amounts of Ca and probably being involved in regulation of the anterior-posterior [Ca2+]i-gradient.     

Early Recognition of Prespore Differentiation in Dictyostelium discoideum and its Significance for Models on Pattern Formation

An electron microscopic study revealed that during aggregation the cytoplasm of a number of cells increases in electron density. Increased electron density is shown to be the consequence of cell shrinkage, which causes a closer packing of cytoplasmic components. Originally electron-dense cells are spread randomly over the aggregate. The anterior prestalk region of the slug is almost devoid of electron-dense cells. In the posterior prespore region, cells with varying degrees of electron density are intermixed with 15–20% electron-lucent cells. During culmination all cells of the prespore region become very electron dense. Besides introducing a new criterion to recognize prespore cells at an early stage of development, our data give further evidence that induction of prespore cell differentiation is not necessarily position dependent.     

Mutation of the Dictyostelium fbxA gene affects cell-fate decisions and spatial patterning

Cell-fate decisions and spatial patterning in Dictyostelium are regulated by a number of genes. Our studies have implicated a gene called fbxA, which codes for an F-box protein, in these pathways. The FbxA protein is one of the controls on a cAMP phosphodiesterase called RegA, mediating its degradation via ubiquitin-linked proteolysis. Using marked strains, we showed that the fbxA^– mutant has defective cell-type proportioning, with a dearth of prestalk cells compared to prespore cells. In this work, we show that this effect occurs earlier during the 24 hour developmental cycle than previously thought. The normal sorting of the prestalk and prespore cells in aggregates and mounds is not affected by the mutation. The mutant cells sort abnormally at the tipped mound stage, when prespore and prestalk cells normally distribute into their proper compartments. The fbxA^– mutant forms prestalk cells in low numbers when not in chimeras, but in the presence of wild-type amoebae the mutant preferentially forms viable spores, driving the wild type to form non-viable stalk cells. In an attempt to identify the signal transduction pathway that mediates proportionality in prestalk and prespore cells, we asked whether certain signal transduction mutants were immune to the effects of the fbxA^–cells and formed spores in chimeras.     

Cell behavior during formation of prestalk/prespore pattern in submerged agglomerates of Dictyostelium discoideum

When cells dissociated from Dictyostelium discoideum slugs were cultured in roller tubes, they formed agglomerates in which prestalk cells were initially dispersed but soon sorted out to the center and then moved to the edge to reconstitute the prestalk/prespore pattern. To examine the mechanism of sorting out, individual prestalk cells were traced by a videotape recorder. The radial component of the rate of movement toward the center of the presumptive prestalk region was calculated. Prestalk cells did not move randomly, but rather directionally toward the center. Their movement was pulsatile, with a period of ca. 15 min, and accompanied by occasional formation of cell streams, thus resembling the movement observable during cell aggregation. These results favor the idea that prestalk cells sort out to the prestalk region due to differential chemotaxis rather than differential adhesiveness. After formation of the prestalk/prespore pattern, the prestalk region rotated along the circumference of the agglomerates. This appears comparable to migration of slugs on the substratum, the rate of rotation being similar to that of slug migration. To examine the processes of pattern formation during development, washed vegetative cells were cultured in roller tubes. Prespore cells identified by antispore immunoglobulin initially appeared randomly within the agglomerates, but then nonprespore cells accumulated in the center and finally moved to the edge to establish the prestalk/prespore pattern, the processes being similar to those of pattern reconstruction with differentiated prestalk and prespore cells.     

Glycoantigen expression is regulated both temporally and spatially during development in the cellular slime molds Dictyostelium discoideum and D. mucoroides

Six monoclonal antibodies were isolated which react with common antigens shared by multiple glycoconjugate species in the cellular slime mold Dictyostelium discoideum. Based on competition of antibody binding by glycopeptides and simple sugars, and inhibition of antibody binding by antigen pretreatment with Na periodate, it is argued that at least five of the six antibodies recognize epitopes which contain carbohydrate. These epitopes are consequently referred to as glycoantigens (GAs).Three of the GAs are expressed during growth and throughout the developmental cycle, but are eventually enriched in prestalk and stalk cells. The remaining three are expressed only during and/or after aggregation and are exclusively expressed or highly enriched in prespore cells and spores. These conclusions are derived from Western blot immunoanalysis of purified cell types, immunofluorescence, and EM immunocytochemistry.The two GAs found only in prespore cells appear to be exclusively enclosed within prespore vesicles. The third GA of this type, which is only enriched in prespore cells compared to prestalk cells, is also found in other vesicle types as well as on the cell surface.Two of the GAs enriched in prestalk cells are initially found in all cells of the slug. They are undetectable in spores and prominent in stalk cells. The third GA, though found in the interiors of both prestalk and prespore cells, is enriched on the cell surface of prestalk cells.The chief characteristics of expression of four of these GAs are conserved in the related species D. mucoroides. This species is characterized by continuous trans differentiation of prespore cells into prestalk cells. This shows that the prespore cells maintain specific mechanisms for turning over their cell type specific GAs and that prestalk cells express a specific mechanism for inducing at least one of their cell-type specific GAs.These observations identify specific carbohydrate structures (as GAs) whose synthesis, subsequent localization and turnover are developmentally regulated. The exclusive association of two GAs with prespore vesicles identifies these GAs as markers for this organelle and raises questions regarding the functional significance of this association. The restricted cell surface localization of the other four GAs, together with data from cell adhesion studies, suggest the possibility of a potential role for these GAs in intercellular recognition leading to cell sorting.This paper is dedicated to the memory of the late Daniel McMahon.     

A secreted 80 x 10(3) Mr protein mediates sensing of cell density and the onset of development in Dictyostelium.

In submerged monolayer culture, Dictyostelium cells can differentiate into prespore and prestalk cells at high cell densities in response to cAMP but not at low cell densities. However, cells at low densities will differentiate in medium taken from developing cells starved at a high density. The putative factor in the medium was designated CMF for conditioned medium factor (Mehdy and Firtel, Molec. cell. Biology 5, 705-713, 1985). In this report, we size-fractionate conditioned medium and show that the activity that allows low density cells to differentiate can be separated into high and low Mr (relative molecular mass) fractions. Interestingly, the two fractions both have the same activity and do not need to be combined to allow differentiation. The large conditioned medium factor is a protein, as determined by trypsin sensitivity, that can be purified to a single 80 x 10(3) Mr band on a silver-stained SDS-polyacrylamide gel, and has CMF activity at a concentration of approximately 4 pM (0.3 ng ml-1). Our results suggest that CMF is a secreted factor that functions in vivo as an indicator of cell density in starved cells. At high cell densities, the concentration of CMF is sufficient to enable cells to enter the multicellular stage of the developmental cycle. When present below a threshold concentration, cells do not initiate the expression of genes required for early development. This factor plays an essential role in the regulatory pathway necessary for cells to obtain the developmental competence to induce prestalk and prespore gene expression in response to cAMP.     

Changes in the Cell Surface Level of GP126 during Development of Dictyostelium discoideum

The developmental regulation of the vegetative cohesion molecule, gp 126, has been monitored in the cellular slime mould Dictyostelium discoideum. As judged by immunoprecipitation using an anti-vegetative cell, cohesion blocking antibody, gp126 persisted until at least the grex stage of development although a decline in the level of the molecule was observed thereafter. Further, after the grex stage, cells showed an increasing loss of ability to absorb the cohesion-blocking effect of an anti-vegetative cell Fab. Therefore, the decline of gp 126 could be ascribed to a loss from the cell surface. By radio-iodination of vegetative cells followed by liquid-scintillation counting of gp 126, developmental-regulation could be determined quantitatively.
At the grex stage of development, whole aggregates were embedded in wax. Longitudinal sections were then stained with a monospecific anti-gp 126 Fab, followed by a fluorescent sheep anti-rabbit IgG. Fluorescence was observed only at the tip (the prestalk) region, thereby showing that gp 126 is a prestalk marker.
To confirm the above result, grexes were dissociated and cells were separated into prespore and prestalk populations on a gradient of Percoll. Prestalk but not prespore cells were able to absorb the cohesion-blocking effect of an anti-vegetative cell Fab.
To examine the biosynthesis of gp 126, cells were pulsed with radioactive glucosamine, mannose or acetate. The pattern of incorporation of radioactivity suggested that the de novo synthesis of gp 126 ceases upon commencement of development.