A novel disintegrin domain protein affects early cell type specification and pattern formation in Dictyostelium

The cellular slime mold, Dictyostelium discoideum is a non-metazoan organism, yet we now demonstrate that a disintegrin domain-containing protein, the product of the ampA gene, plays a role in cell type specification. Disintegrin domain-containing proteins are involved in Notch signaling in Drosophila and C. elegans via an ectodomain shedding mechanism that depends on a metalloprotease domain. The Dictyostelium protein lacks a metalloprotease domain. Nonetheless, analysis of cell type specific reporter gene expression during development of the ampA null strain identifies patterning defects that define two distinct roles for the AmpA protein in specifying cell fate. In the absence of a functional ampA gene, cells prematurely specify as prespore cells. Prestalk cell differentiation and migration are delayed. Both of these defects can be rescued by the inclusion of 10% wild-type cells in the developing null mutant aggregates, indicating that the defect is non-cell autonomous. The ampA gene is also demonstrated to be necessary in a cell-autonomous manner for the correct localization of anterior-like cells to the upper cup of the fruiting body. When derived from ampA null cells, the anterior-like cells are unable to localize to positions in the interior of the developing mounds. Wild-type cells can rescue defects in morphogenesis by substituting for null cells when they differentiate as anterior-like cells, but they cannot rescue the ability of ampA null cells to fill this role. Thus, in spite of its simpler structure, the Dictyostelium ampA protein carries out the same diversity of functions that have been observed for the ADAM and ADAMTS families in metazoans.     

The anterior-like cells in Dictyostelium are required for the elevation of the spores during culmination

 Shortly after initiation of Dictyostelium fruiting body formation, prespore cells begin to differentiate into non-motile spores. Although these cells lose their ability to move, they are, nevertheless, elevated to the tip of the stalk. Removal of the amoeboid anterior-like cells, located above the differentiating spores in the developing fruiting body, prevents further spore elevation although the stalk continues to elongate. Furthermore, replacement of the anterior-like cells with anterior-like cells from another fruiting body largely restores the ability to lift the spores to the top of the stalk. However, if amoeboid prestalk cells are used to replace the anterior-like cells, there is no restoration of spore elevation. Finally, when a droplet of mineral oil replaces differentiating spores, it is treated as are the spores: the mineral oil is elevated in the presence of anterior-like cells and becomes arrested on the stalk in the absence of anterior-like cells. Because a similar droplet of mineral oil is totally ignored by slug tissue, it appears that there is a dramatic transformation in the treatment of non-motile matter at this point in Dictyostelium development. Received: 26 January 1998 / Accepted: 27 May 1998     

Regulation of the anterior-like cell state by ammonia in Dictyostelium discoideum

Ammonia appears to be an important regulatory signal for several aspects of the Dictyostelium life cycle. The postulated role of ammonia in the determination of the prespore pathway in cells of the slug stage has led us to examine the effect of ammonia on the prestalk/prespore ratio of migrating slugs. In the presence of 10(-3) M ammonium chloride, the volume of the prestalk region decreases by 40.8%. The kinetics of the process make it unlikely that this is due to a shift in the differentiation pathway. A test of the hypothesis that the decrease in volume of the prestalk region is due to the conversion of prestalk cells to anterior-like cells shows that the percent of anterior-like cells in the posterior region increases by the amount predicted by the hypothesis. This suggests that ammonia may be the molecular signal, produced by the tip, that prevents anterior-like cells from chemotactically migrating to the tip and thereby becoming anterior cells. The effect of enzymatic removal of ammonia from vitally stained migrating slugs is the appearance of a series of dark stripes beginning at the posterior end and progressing forward. We interpret this as a result of progressive removal of anterior-like cells from tip dominance and essentially as the formation of new potential tips. Indeed, in a few cases one or even two of the stripes separate from the posterior of the cell mass and form small fruiting bodies. We consider the phenomenon of stripe formation further evidence that the tip acts on anterior-like cells through ammonia.     

The regulative capacity of prespore amoebae as demonstrated by fluorescence-activated cell sorting and green fluorescent protein

The ability of prespore Dictyostelium discoideum amoebae to undergo redifferentiation so as to reestablish normal spore/stalk proportioning has been demonstrated in various ways over the years, beginning with the classic microdissection work of K. Raper. The discovery of anterior-like cells in the slug posterior, however, cast doubt on that ability, and more recent experiments using a cell-specific toxin suggested that prespore redifferentiation may not in fact occur. To reexamine this question, we performed fluorescence-activated cell sorting (FACS) upon amoebae expressing a mutated green fluorescent protein gene (S65T-GFP) under the control of a prespore-specific (PsA) promoter. FACS produced prespore cell populations with purities, measured by GFP expression, as high as 99. 5%. Sorted GFP(+) cells were developmentally competent and produced normally proportioned fruits, indistinguishable from those of "sham-sorted" (permissively gated, mixed GFP(+) and GFP(-)) amoebae. This result confirms the developmental totipotency of prespore amoebae.     

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.     

An analysis of culmination in Dictyostelium using prestalk and stalk-specific cell autonomous markers

The ecmA (pDd63) and ecmB (pDd56) genes encode extracellular matrix proteins of the slime sheath and stalk tube of Dictyostelium discoideum. Using fusion genes containing the promoter of one or other gene coupled to an immunologically detectable reporter, we previously identified two classes of prestalk cells in the tip of the migrating slug; a central core of pstB cells, which express the ecmB gene, surrounded by pstA cells, which express the ecmA gene. PstB cells lie at the position where stalk tube formation is initiated at culmination and we show that they act as its founders. As culmination proceeds, pstA cells transform into pstB cells by activating the ecmB gene as they enter the stalk tube. The prespore region of the slug contains a population of cells, termed anterior-like cells (ALC), which have the characteristics of prestalk cells. We show that the ecmA and ecmB genes are expressed at a low level in ALC during slug migration and that their expression in these cells is greatly elevated during culmination. Previous observations have shown that ALC sort to surround the prespore cells during culmination (Sternfeld and David, 1982 Devl Biol. 93, 111-118) and we find just such a distribution for pstB cells. We believe that the ecmB protein plays a structural role in the stalk tube and its presence, as a cradle around the spore head, suggests that it may play a further function, perhaps in ensuring integrity of the spore mass during elevation. If this interpretation is correct, then a primary role of anterior-like cells may be to form these structures at culmination. We previously identified a third class of prestalk cells, pstO cells, which lie behind pstA cells in the slug anterior and which appeared to express neither the ecmA nor the ecmB gene. Using B-galactosidase fusion constructs, which give more sensitive detection of gene expression, we now find that these cells express the ecmA gene but at a much lower level than pstA cells. We also show that expression of the ecmA gene becomes uniformly high throughout the prestalk zone when slugs are allowed to migrate in the light. Overhead light favours culmination and it may be that increased expression of the ecmA gene in the pst 'O' region is a preparatory step in the process.     

A study of PstB cells during Dictyostelium migration and culmination reveals a unidirectional cell type conversion process

Summary The prestalk region of the Dictyostelium slug has recently been shown by Williams and his collaborators to consist of two distinct cell types, pstA and pstB cells. Here the movement of these cells in both the slug and culmination stages has been examined with the use of vital dyes. In the slug some of the pstB cells are continually lost from the prestalk region as small clusters of cells. These cells move through the prespore region and temporarily lie in the rearguard region at the posterior end of the slug. They are finally left in the slug's slime track as single cells or groups of a few cells. When culmination is initiated the pstB cells move as a whole from the prestalk region to the base where they join the rearguard cells to form the basal disc of the fruiting body. Transplantation experiments reveal that the rearguard cells form an outer ring portion of the basal disc and the pstB cells form an inner portion to which the stalk attaches. The continuous loss of one cell type during the slug stage without any change in cell type proportions suggests that cell types are redifferentiating. Grafting and transplantation experiments reveal that there is a unidirectional flow of cells through successive steps of cell type conversion. Prespore cells redifferentiate as anterior-like cells which migrate to the prestalk region and become pstA cells. The pstA cells then replace the pstB cells that are lost from the slug.     

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.     

Identification and analysis of the regulation of a prestalk cell-surface antigen of Dictyostelium discoideum

The properties of two differentiation antigens, rsa 4.2 and rsa 3.1, were examined. Both appear on the cell surface early in differentiation, but they differ with respect to their cell-type specificity. rsa 4.2 appears 1-2 h after differentiation has begun and is present on all cells during all stages of differentiation. In contrast, rsa 3.1 appears after 1-2 h on all aggregating amebae and later becomes restricted to prestalk cells. The pattern of regulation of rsa 3.1 indicates that this prestalk antigen appears on all cells early in differentiation but disappears in cells that differentiate along the prespore pathway. As a result, only cells in the anterior of migrating slugs carry this antigen. Predictions of two competing models of Dictyostelium pattern formation, i.e., position-dependent differentiation and random, position-independent differentiation, were tested by flow cytometry and immunochemical staining of sections of cells at the mound and mound-with-tip stages. Our results do not rule out either model, although they are incompatible with the simplest interpretation of the model for position-independent differentiation. The results clearly indicate that cells that ultimately differentiate along the spore pathway pass through an earlier cell state that includes the presence of a prestalk cell-surface antigen identified as rsa 3.1.     

Identification and analysis of the regulation of a prestalk cell-surface antigen of Dictyostelium discoideum

Abstract. The properties of two differentiation antigens, rsa 4.2 and rsa3.1, were examined. Both appear on the cell surface early in differentiation, but they differ with respect to their cell-type specificity. rsa 4.2 appears 1-2 h after differentiation has begun and is present on all cells during all stages of differentiation. In contrast, rsa 3.1 appears after 1-2 h on all aggregating amebae and later becomes restricted to prestalk cells. The pattern of regulation of rsa 3.1 indicates that this prestdlk antigen appears on all cells early in differentiation but disappears in cells that differentiate along the prespore pathway. As a result, only cells in the anterior of migrating slugs carry this antigen. Predictions of two competing models of Dictyostelium pattern formation, i.e., position-dependent differentiation and random, position-independent differentiation, were tested by flow cytometry and immunochemical staining of sections of cells at the mound and mound-with-tip stages. Our results do not rule out either model, although they are incompatible with the simplest interpretation of the model for position-independent differentiation. The results clearly indicate that cells that ultimately differentiate along the spore pathway pass through an earlier cell state that includes the presence of a prestalk cell-surface antigen identified as rsa 3.1.     

Ammonia differentially suppresses the cAMP chemotaxis of anterior-like cells and prestalk cells indictyostelium discoideum

A drop assay for chemotaxis to cAMP confirms that both anterior-like cells (ALC) and prestalk cells (pst cells) respond to cAMP gradients. We present evidence that the chemotactic response of both ALC and pst cells is suppressed by ammonia, but a higher concentration of ammonia is required to suppress the response in pst cells. ALC show a chemotactic response to cAMP when moving on a substratum of prespore cells in isolated slug posteriors incubated under oxygen. ALC chemotaxis on a prespore cell substratum is suppressed by the same concentration of ammonia that suppresses ALC chemotaxis on the agar substratum in drop assays. Chemotaxis suppression is mediated by the unprotonated (NH₃) species of ammonia. The observed suppression, by ammonia, of ALC chemotaxis to cAMP supports our earlier hypothesis that ammonia is the tip-produced suppressor of such chemotaxis. We discuss implications of ammonia sensitivity of pst cells and ALC with regard to the movement and localization of ALC and pst cells in the slug and to the roles played by ALC in fruiting body formation. In addition, we suggest that a progressive decrease in sensitivity to ammonia is an important part of the maturation of ALC into pst cells.     

Role of Cell Sorting in Pattern Formation in Dictyostelium discoideum

To examine the relationship between cell sorting and cell differentiation in the development of Dictyostelium discoideum , labeled cells grown in the absence of glucose [G(–) cells] and unlabeled cells grown in its presence [G(+) cells] were mixed and either allowed to undergo normal morphogenesis or cultured under submerged conditions. Changes in the distributions within a cell aggregate of labeled cells and cells stained with the conjugated antispore serum (prespore cells) were followed on the same sections by the methods of autoradiography and immunohistochemistry. In normal morphogenesis, differentiation of prespore cells apparently initiated and proceeded coincident with sorting out between G(+) and G(–) cells, during formation of a standing slug. By contrast, within an aggregate formed under submerged conditions, prespore cells began to differentiate long before G(+) and G(–) cells were sorted out, indicating that the cell sorting is not a prerequisite for the cell differentiation. The sorting out, however, brought about an accumulation of prespore cells in a hemisphere, thus producing a prestalk-prespore pattern within the aggregate.     

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.     

Three steps in prespore differentiationin Dictyostelium discoideum with different requirements of cellular interaction

Abstract. Extracellular cAMP and a secreted factors have been known to be involved in prespore differentiation of Dictyostelium discoideum . Here we show that cAMP, a secreted factor(s) and some other interactions are required for prespore differentiation and that they work in completely different periods; a secreted factor(s) and other interactions are required only in the stages earlier than the cAMP-dependent stage. According to the results the process of prespore differentiation can be dissected into three sequential stages, stage I, II and III. The processes in stage I and II depend on high cell density. The requirement for high cell density in stage II could be replaced with a secreted factor(s) in conditioned medium, whereas it could not in stage I. The factor(s) in conditioned medium does not appear to be cAMP, ammonia, or methionine. In contrast to these two stages, the process in stage III, the last stage, proceeds even at low cell density if cAMP is supplied, where other interactions would be negligible. Therefore cells that have proceeded to the end of stage II are considered to have acquired a competence to differentiate to prespore cells without further cellular interactions other than cAMP.
cAMP pulses are not essential for the processes of any stage of prespore differentiation, since they proceed in the presence of caffeine, an inhibitor of cAMP pulse production, or in a mutant strain (Frigid A) which is deficient in cAMP relay systems.     

Cell Sorting daring Pattern Formation in Dictyostelium

Formation of the prestalk-prespore pattern in Dictyostelium was investigated in slugs and submerged clumps of cells. Prestalk and prespore cells were identified by staining with vital dyes, which are shown to be stable cell markers. Dissociated slug cells reaggregate and form slugs that contain a prestalk-prespore pattern indistinguishable from the original pattern. The pattern forms by sorting out of stained prestalk cells from unstained prespore cells. Sorting also occurs in clumps of dissociated slug cells submerged in liquid or agar. A pattern arises in 2 h in which a central core of stained cells is surrounded by a periphery of unstained cells. Sorting appears to be due to differential chemotaxis of stained and unstained cells to cAMP since exogenous cAMP (>10⁻⁷ M) reverses the normal direction of sorting-out such that stained cells sort to the periphery of the clumps.
Isolated portions of slugs regenerate a new prestalk-prespore pattern. Posterior isolates regenerate a pattern within 2 h due to sorting of a population of vitally stained 'anterior-like' cells present in posteriors. Anterior-like cells do not sort in intact slugs due to the influence of a diffusible inhibitor secreted by the anterior region. During posterior regeneration this signal is absent and anterior-like cells rapidly acquire the ability to sort. Anterior isolates regenerate a staining pattern more slowly than posterior isolates by a process that requires conversion of stained prestalk cells to unstained prespore cells.
The results suggest that pattern formation in Dictyostelium consists of two processes: establishment of appropriate proportions of two cell types and establishment of the pattern itself by a mechanism of sorting-out.     

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.     

Quantitative studies on cell differentiation during morphogenesis of the cellular slime mold Dictyostelium discoideum

Taking advantage of the fact that differentiation of the prespore cell of Dictyostelium discoideum is characterized by synthesis of a prespore specific antigen, the process of its differentiation during the course of morphogenesis was quantitatively studied by determining the proportion of prespore cells and their cellular contents of the antigen, using the method of microfluorometry in combination with immunocytochemistry with antispore serum. The cells synthesizing the antigen became first detectable in the early aggregation center which was about to form a papilla. As the papilla elongated, the number of prespore cells rapidly increased up to the stationary level (70–80% of total cells) before completion of slug formation. During the process antigenic contents of prespore cells were gradually increased and leveled off in the early migration stage. When culmination was induced, antigenic contents were markedly increased to the maximum, which was followed by a sudden decrease immediately before spore formation. On the other hand, the proportions of prespore to total cells were kept constant at the stationary level all through the migration and culmination stages, in spite of a persistent decrease during culmination in the total number of cells due to continuous differentiation of the prestalk into the mature stalk cells. These results were discussed in relation to possible mechanisms of differentiation in this organism.