New prestalk and prespore inducing signals in Dictyostelium

The differentiation-inducing signals (DIFs) currently known in Dictyostelium appear unable to account for the full diversity of cell types produced in development. To search for new signals, we analyzed the differentiation in monolayers of cells expressing prestalk (ecmAO, ecmA, ecmO, ecmB and cAR2) and prespore (psA) markers. Expression of each marker drops off as the cell density is reduced, suggesting that cell interaction is required. Expression of each marker is inhibited by cerulenin, an inhibitor of polyketide synthesis, and can be restored by conditioned medium. However, the known stalk-inducing polyketide, DIF-1, could not replace conditioned medium and induce the ecmA or cAR2 prestalk markers, suggesting that they require different polyketide inducers. Polyketide production by fungi is stimulated by cadmium ions, which also dramatically stimulates differentiation in Dictyostelium cell cultures and the accumulation of medium factors. Factors produced with cadmium present were extracted from conditioned medium and fractionated by HPLC. A new factor inducing prespore cell differentiation, called PSI-2, and two inducing stalk cell differentiation (DIFs 6 and 7) were resolved. All are distinct from currently identified factors. DIF-6, but not DIF-7 or PSI-2, appears to have an essential carbonyl group. Thus Dictyostelium may use extensive polyketide signaling in its development.     

Expression of prestalk and prespore proteins in minute, two-dimensional Dictyostelium slugs.

We show that exceedingly small two-dimensional slugs of Dictyostelium differentiate normally and have an anterior prestalk zone and a posterior prespore zone. Using GFP as a marker attached to the appropriate promoter, prestalk expression is concentrated in the anterior, while prespore expression is produced in the posterior, closely resembling what is found in normal, large slugs.     

Cellular and subcellular distribution of a cAMP-regulated prestalk protein and prespore protein in Dictyostelium discoideum: a study on the ontogeny of prestalk and prespore cells

We have analyzed a developmentally and spatially regulated prestalk-specific gene and a prespore-specific gene from Dictyostelium. The prestalk gene, pst-cathepsin, encodes a protein highly homologous to the lysosomal cysteine proteinases cathepsin H and cathepsin B. The prespore gene encodes a protein with some homology to the anti-bacterial toxin crambin and has been designated beejin. Using the lambda gtll system, we have made polyclonal antibodies directed against a portion of the protein encoded by pst-cathepsin and other antibodies directed against the beejin protein. Both antibodies stain single bands on Western blots. By immunofluorescence and Western blots, pst-cathepsin is not present in vegetative cells or developing cells during the first approximately 10 h of development. It then appears with a punctate distribution in a subset of developing cells. Beejin is detected only after approximately 15 h of development, also in a subset of cells. Pst-cathepsin is distributed in the anterior approximately 1/10 of migrating slugs and on the peripheral posterior surfaces of slugs. Beejin is distributed in the posterior region of slugs. Expression of both pst-cathepsin and beejin can be induced in subsets of isolated cultured cells by a combination of conditioned medium and extracellular cAMP in agreement with the regulation of the mRNAs encoding these proteins. We have used the antibodies as markers for cell type to examine the ontogeny and the spatial distribution of prestalk and prespore cells throughout multicellular development. Our findings suggest that prestalk cell differentiation is independent of position within the aggregate and that the spatial localization of prestalk cells within the multicellular aggregate arises from sorting of the prestalk cells after their induction. We have also found a class of cell in developing aggregates that contains neither the prestalk nor the prespore markers.     

Production and turnover of cAMP signals by prestalk and prespore cells in Dictyostelium discoideum cell aggregates

Dictyostelium discoideum prestalk cells and prespore cells from migrating slugs and culminating cell aggregates were isolated by Percoll density centrifugation. Several activities relevant to the generation, detection, and turnover of extracellular cyclic AMP (cAMP) signals were determined. It was found that: the two cell types have the same basal adenylate cyclase activity; prespore cells and prestalk cells are able to relay the extracellular cAMP signal equally well; intact prestalk cells show a threefold higher cAMP phosphodiesterase activity on the cell surface than prespore cells, whereas their cytosolic activity is the same; intact prestalk cells bind three to four times more cAMP than prespore cells; no large differences in cAMP metabolism and detection were observed between cells derived from migrating slugs and culminating aggregates. The results are discussed in relation to the possible morphogenetic role of extracellular cAMP in Dictyostelium cell aggregates. On the basis of the properties of the isolated cells we assume that a gradient of extracellular cAMP exists in Dictyostelium aggregates. This gradient appears to be involved in the formation and stabilization of the prestalk-prespore cell pattern.     

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.     

Stalk cell formation in monolayers from isolated prestalk and prespore cells of Dictyostelium discoideum: evidence for two populations of prestalk cells

Cells from the pseudoplasmodial stage of Dictyostelium discoideum differentiation were dispersed and separated on Percoll gradients into prestalk and prespore cells. The requirements for stalk cell formation in low-density monolayers from the two cell types were determined. The isolated prespore cells required both the Differentiation Inducing Factor (DIF) and cyclic AMP for stalk cell formation. In contrast, only part of the isolated prestalk cell population required both cyclic AMP and DIF, the remainder requiring DIF alone, suggesting the possibility that there were two populations of prestalk cells, one independent of cyclic AMP and one dependent on cyclic AMP for stalk cell formation. The finding that part of the prestalk cell population required only a brief incubation in the presence of DIF to induce stalk cell formation, whilst the remainder required a considerably longer incubation in the presence of both DIF and cyclic AMP was consistent with this idea. In addition, stalk cell formation from cyclic-AMP-dependent prestalk cells was relatively more sensitive to caffeine inhibition than stalk cell formation from cyclic-AMP-independent prestalk cells. The latter cells were enriched in the most anterior portion of the migrating pseudoplasmodium, indicating that there is spatial segregation of the two prestalk cell populations. The conversion of prespore cells to stalk cells took longer and was more sensitive to caffeine when compared to stalk cell formation from cyclic-AMP-dependent prestalk cells.     

The effects of presumptive morphogens on prestalk and prespore cell gene expression in monolayers of Dictyostelium discoideum

Abstract. The expression of three prestalk cell-specific genes ( ecm A, ecm B and pDd26) was examined during in vitro differentiation in cell monolayers, in an attempt to explain the spatial heterogeneity of the prestalk region of migrating Dictyostelium pseudoplasmodia. Under these conditions ecm A, ecm B and pDd26 mRNAs were expressed sequentially in response to the addition of differentiation inducing factor-1 (DIF)-1, a temporal sequence similar to that observed during normal development. ecm A and ecm B mRNAs reached a maximum level 2–4 h after DIF-1 supplementation and then declined, whereas pDd26 mRNA levels increased more slowly but remained high 24 h after DIF addition. The increases in expression in response to increasing concentrations of either DIF-1 or DIF-2 were identical for the three genes, suggesting that neither alteration in DIF concentration nor species was an important determinant of spatial heterogeneity. Ammonia had the same inhibitory effect on the expression of all three prestalk cell-specific genes and stimulated the expression of the prespore cell-specific gene, D19. These results indicate that ammonia is also not responsible for the spatial heterogeneity of the prestalk cell region. In contrast, cyclic AMP had a differential effect on the expression of the prestalk cell specific genes: ecm A expression was variably stimulated, pDd26 expression was inhibited and ecm B expression was sometimes stimulated and sometimes inhibited. These results are difficult to explain in terms of a gradient of cyclic AMP in the prestalk region. We postulate that temporal responses are more important than spatial responses to cyclic AMP in regulating stalk cell differentiation.     

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.     

Correlations between tip dominance, prestalk/prespore pattern, and CAMP-relay efficiency in slugs of Dictyostelium discoideum

Abstract. It is very likely that oscillatory cAMP secretion and cAMP relay organize postaggregative cell movement in the cellular slime molds. We present evidence indicating that cAMP signaling may also be involved in the formation of the prestalk/prespore pattern in slugs of Dictyostelium discoideum. Reduction of cAMP relay in slugs caused by caffeine increased the proportion of prespore tissue. An even stronger increase was observed in a mutant with a very low CAMP-relay response. The effects on pattern resulting from a reduction of cAMP relay are not due to a reduction in the amount of cAMP in the slug, but to an as yet undefined property of oscillatory cAMP signaling.     

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.     

Changes of plasma membrane proteins during prespore differentiation in Dictyostelium discoideum

By the use of a shake culture system, we have previously shown (Oyama, M., Okamoto, K., & Takeuchi, I. (1982) J. Cell Sci. 56, 223-232) that both cAMP and cAMP-dependent cell contact are required for prespore differentiation in Dictyostelium discoideum. The present study was undertaken to examine changes of the plasma membrane proteins during prespore differentiation in the shake culture system. Rabbit antibodies prepared against the plasma membrane fraction of the differentiated cells inhibited the reaggregation of the differentiated cells but not that of aggregation-competent cells. This result indicates that new contact sites are formed in the differentiated cells. By the combined use of the antibody-conjugated immuno-adsorbent with sodium dodecyl sulfate-polyacrylamide gel electrophoresis, changes of membrane proteins were analyzed with the cells incubated under various conditions. Three proteins were found to be present specifically in the differentiated cells only in the presence of cAMP, one of which (105K protein) appeared when cells became adhesive, but before prespore specific proteins were detected. Two others (80K and 58K proteins) appeared during prespore differentiation after cells formed agglomerates.     

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.     

The prespore vesicles of Dictyostelium discoideum. Purification, characterization, and developmental regulation

The coordinate fusion of the prespore vesicles (PSVs) with the plasma membrane at the terminal stage of spore differentiation in Dictyostelium discoideum is an important example of developmentally regulated protein secretion. However, little is known about the composition of the vesicles, the molecular signals regulating secretion, or the mechanics of the membrane fusion. Taking a biochemical approach, we purified PSVs from different developmental stages. These preparations are highly enriched for their specific cargo of spore coat proteins while devoid of markers for other cellular compartments. Electron microscopic observations show that the PSV preparations are homogenous, with the soluble spore coat protein PsB/SP85 distributed throughout the lumen and the acid mucopolysaccharide localized in the central core. During development the PSVs increase in size and density concomitant with an increase in their protein cargo. The PSVs contain approximately 80 proteins, and we have identified a PSV-specific GTP-binding protein that may be involved in regulating vesicle fusion. The PSVs are not clathrin-coated and do not contain the SpiA spore coat protein. The PSV preparations are ideal for a global proteome analysis to identify proteins involved in signal reception, vesicle movement, docking, and fusion in this developmentally regulated organelle.     

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.     

Prespore cell inducing factor, ψ factor,controls both prestalk and prespore gene expression in Dictyostelium development

Prespore cell‐inducing (psi, ψ) factor (PsiA), encoded by the psiA gene of Dictyostelium, is a secreted signal glycoprotein that induces prespore cell differentiation when added to monolayer cultures. In situ hybridization during normal development showed that the psiA gene is highly expressed in scattered cells at the mound stage and in prespore cells at the onset of culmination. The conventional prespore‐cell marker genes, cotC and pspA, were expressed normally in psiA^? and psiA overexpressing strains. Expressions of rnrB and cudA are repressed in the prestalk cells of a wild type slug to render prespore specific pattern. However, a promoter‐reporter fusion gene, rnrB:lacZ, showed an ectopic expression in the prestalk cells of the psiA^? strain while cudA(psp):lacZ did so in those of the psiA overexpressing strain. Overexpression of psiA delayed expression of the prestalk specific gene, ecmB, during development, while knocking out psiA promoted its expression. In addition, overexpression inhibited DIF‐1‐induced stalk formation in monolayer cultures. Together with the known prespore inducing activity, the results indicate that PsiA regulates both prespore and prestalk/stalk cell differentiation. These results indicate that PsiA is also involved in prestalk cell differentiation.     

Immuno-localization and separation of multiple prestalk cell types in Dictyostelium

Abstract. The ecm A and ecm B genes of Dictyostelium encode closely related extracellular matrix proteins. The major prestalk cell population, pstA cells, expresses the ecm A gene but not the ecm B gene. PstAB cells, a minor prestalk cell population that we show to express both the ecm A and ecm B genes, form a core in the centre of the slug tip. The rear, prespore region of the slug contains amoebae, termed anterior-like cells (ALC), that display many of the properties of prestalk cells. The ecm A and B genes are weakly expressed in about 30% of the ALC and these comprise a mixture of pstA cells, pstAB cells and a third class, pstB cells. The latter cell type express the ecm B gene but show no detectable expression of the ecm A gene. The demonstration of the existence of pstB cells suggests a separate pathway of ecm B gene induction, wherein expression of the ecm A gene is absent or at a very low level. Pst A, AB and B cells most probably differ in their surface properties because they are partially separable by Counter Current Distribution (CCD), a chromatographic technique which, in the conditions used, is dependent upon differences in cell surface hydrophobicity.     

Cell sorting within the prestalk zone of Dictyostelium discoideum

Abstract. The prestalk zone of slugs of Dictyostelium discoideum has been shown to contain three subregions in which the extracellular matrix genes ecmA and ecmB are differentially expressed; it is generally thought that these regions are defined by extracellular signals. Using β-galactosidase as a cell marker, we have shown that cells can sort specifically to all three regions. Cells from the posterior-prestalk zone ("prestalk 0 zone") which are injected into the slug tip move within 60 min back to their position of origin. When cells from the anterior prestalk zone (presumably containing a mixture of ecmA and ecmB expressers) are transplanted to the posterior prestalk zone, they move to the tip ("prestalk A zone") within 1 h and about 30 min subsequently are often found in a cone-shaped region within the tip ("prestalk B zone"). Cells transplanted to their own positions do not move significantly within this period. Since the sub-regions of the prestalk zone can be defined by sorting, it is possible that they are normally formed in this way rather than by position-dependent signals. Cells transplanted without a change in anterior-posterior position and cells which have sorted back to their positions of origin eventually spread out throughout the prestalk zone. This suggests that sorting preferences of cells are respecified. When posterior prestalk cells are transplanted to the prespore zone, respecification of sorting preference is suspended until the cells return to the prestalk zone and anterior-prestalk cells acquire posterior-prestalk sorting preferences.