The possible involvement of oscillatory cAMP signaling in multicellular morphogenesis of the cellular slime molds

The involvement of pulsatile chemoattractant emission and signal relay in aggregation and multicellular morphogenesis of a variety of cellular slime mold species was investigated. The species differ from each other in the developmental stage when pulsatile signaling first becomes evident. In D. discoideum, D. mucoroides, and D. purpureum pulsatile signal emission starts in the preaggregative field. In D. vinaceo-fuscum, D. mexicanum, P. violaceum, and P. pallidum the aggregation centers shifts from continuous to pulsatile secretion of chemoattractant during the aggregation process. In D. minutum pulsatile signaling starts after the completion of aggregation and slightly before the onset of culmination. Tip formation is a consequence of continued attraction of amoebae inside the aggregate to the center of signal emission. The occurrence of pulsatile signaling at an early stage of development is correlated with the capacity of the tip (signaling center) to organize a relatively large number of cells into a single fruiting body. Several lines of evidence suggest that cAMP is probably involved in the coordination of morphogenetic movement in the multicellular stage of all investigated species.     

Developmental decisions in Dictyostelium discoideum.

A few hours after the onset of starvation, amoebae of Dictyostelium discoideum start to form multicellular aggregates by chemotaxis to centers that emit periodic cyclic AMP signals. There are two major developmental decisions: first, the aggregates either construct fruiting bodies directly, in a process known as culmination, or they migrate for a period as "slugs." Second, the amoebae differentiate into either prestalk or prespore cells. These are at first randomly distributed within aggregates and then sort out from each other to form polarized structures with the prestalk cells at the apex, before eventually maturing into the stalk cells and spores of fruiting bodies. Developmental gene expression seems to be driven primarily by cyclic AMP signaling between cells, and this review summarizes what is known of the cyclic AMP-based signaling mechanism and of the signal transduction pathways leading from cell surface cyclic AMP receptors to gene expression. Current understanding of the factors controlling the two major developmental choices is emphasized. The weak base ammonia appears to play a key role in preventing culmination by inhibiting activation of cyclic AMP-dependent protein kinase, whereas the prestalk cell-inducing factor DIF-1 is central to the choice of cell differentiation pathway. The mode of action of DIF-1 and of ammonia in the developmental choices is discussed.     

A genetic melanotic neoplasm of Drosophila melanogaster

The construction of mature fruiting bodies occurs during the culmination stage of development of Dictyostelium discoideum. These contain at least two different cell types, spores and stalks, which originate from an initially homogenous population of vegetative amoebas. As an attempt to identify proteins whose synthesis is regulated in each cell type during differentiation, we have analyzed the two-dimensional profiles of proteins synthesized by spore and stalk cells during the culmination stage. We have identified 5 major polypeptides which are specifically synthesized by spore cells during culmination and 9 which are only made by stalk cells. Furthermore, synthesis of about 20 polypeptides appears to be enriched either in the spore or in the stalk cells. We also show that synthesis of actin, a major protein synthesized during Dictyostelium development, is specifically inhibited in the spore cells during culmination. Synthesis of most of the cell type-specific proteins initiates at 19–20 hr, during culmination. Moreover, the proteins whose synthesis is induced after formation of tight aggregates, the time when the major change in gene expression occurs, are not specifically incorporated into spores or stalk cells, and appear to be synthesized by both cell types. We conclude that a new class of genes is expressed during the culmination stage in Dictyostelium, giving rise to specific patterns of protein synthesis in spore and stalk cells.     

Modelling Dictyostelium discoideum morphogenesis: the culmination

The culmination of the morphogenesis of the cellular slime mould Dictyostelium discoideum involves complex cell movements which transform a mound of cells into a globule of spores on a slender stalk. We show that cyclic AMP signalling and differential adhesion, combined with cell differentiation and slime production, are sufficient to produce the morphogenetic cell movements which lead to culmination. We have simulated the process of culmination using a hybrid cellular automata/partial differential equation model. With our model we have been able to reproduce the main features that occur during culmination, namely the straight downward elongation of the stalk, its anchoring to the substratum and the formation of the long thin stalk topped by the spore head. We conclude that the cyclic AMP signalling system is responsible for the elongation and anchoring of the stalk, but in a roundabout way: pressure waves that are induced by the chemotaxis towards cyclic AMP squeeze the stalk through the cell mass. This mechanism forces the stalk to elongate precisely in the direction opposite to that of the chemotactically moving cells. The process turns out to be ‘guided’ by inactive ‘pathfinder’ cells, which form the tip of the stalk. We show that the entire development is enacted by means of the aforementioned building blocks. This means that no global gradients or different modes of chemotaxis are needed to complete the culmination. MPEG movies of the simulations are available on-line: http://www-binf.bio. uu.nl/stan/bmb.     

cAMP induces a transient elevation of cGMP levels during early culmination of Dictyostelium minutum

Oscillatory cAMP signals very likely organize the cell movement which leads to fruiting body construction in Dictyostelium minutum [Schaap, P., Konijn, T.M. and Van Haastert, P.J.M.: Proc. Natl. Acad. Sci. USA 81, 2122-2126 (1984)]. Stimulation with cAMP induces a transient elevation of cGMP in cells at the early culmination stage, which peaks at 12-18 s. A half maximal cGMP response is induced by 10(-7) M cAMP and saturation of the response is reached at 10(-5) M cAMP. No cGMP accumulation was induced by stimulation of vegetative or aggregative cells of D. minutum by cAMP. Since the transient increase of cGMP is most likely involved in the transduction of chemotactic signals, our results indicate that cAMP signals organize fruiting body formation by inducing chemotaxis inside the aggregate.     

cAMP relay during early culmination of Dictyostelium minutum

Abstract. It has recently been found that the culmination process of Dictyostelium minutum is accompanied by the appearance of oscillatory cell movement, cell-surface cAMP receptors, and cAMP phosphodiesterase. In the present study, it is demonstrated that the cAMP analog 2'deoxyc-AMP induces a transient accumulation and secretion of cAMP in culminating structures. At least 50-fold-less cAMP is accumulated during relay of D. minutum than during relay of Dictyostelium discoideum aggregative cells. No cAMP relay could be induced in vegetative or aggregative cells of D. minutum . These combined results yield evidence that oscillatory cAMP secretion and relay are involved in the organization of cell movement during the culmination of D. minutum .     

Glycogen degradation during migration of presumptive cell types in Dictyostelium discoideum.

During the time course of differentiation in Dictyostelium discoideum, glycogen was found to accumulate from the amoebae stage to the culmination stage of development. Upon sorocarp formation (23 h), glycogen was rapidly degraded. Ultramicrotechniques, utilizing amplification of glycogen by enzymatic cycling, were used to follow glycogen metabolism in pre-stalk and prespore cells during the differentiation cycle. Both cell types accumulated glycogen at nearly the same rate. By the pseudoplasmodium stage of development glycogen had accumulated to 50% of its maximum value, and no differences were found between pre-stalk and pre-spore cells. Glycogen was degraded as pre-stalk cells migrated into the position for stalk construction. At the culmination stage of development stalk cells near the base were devoid of glycogen while pre-stalk cells near the apex of the stalk showed no loss of glycogen. The complete loss of glycogen from stalk cells occurred over a distance occupied by approximately 100 cells, and over a time period of approx. 1 h. Pre-spore cells at the culmination stage showed no loss of glycogen even though separated from stalk cells by only a thin cellulose sheath. The degradation of prespore cell glycogen did not commence until stalk construction was completed and the pre-spore mass had reached the apex of the stalk. Pre-spore cells at the culmination stage contained high levels of glycogen while only 2 h later, total degradation had occurred.     

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.     

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.     

Localization of glycogen synthetase during differentiation of presumptive cell types in Dictyostelium discoideum.

Ultramicrochemical techniques were utilized to assay glycogen synthetase (EC 2.4.1.11) activity in cell samples of Dictyostelium discoideum as small as 0.01 mug (dry weight) in reaction volumes of 0.1 mul. The activity was assayed by an amplification procedure employing the enzymatic cycling of pyridine nucleotides. These techniques were used to determine the extent of localization of glycogen synthetase in the two cell types during differentiation of D. discoideum. Localization studies in developing spore cells revealed decreasing enzyme activity to the culmination stage. During this phase of development, the enzyme required the presence of soluble glycogen for activity. From culmination to sorocarp stage, enzyme activity increased and was independent of the soluble glycogen. In developing stalk cells, synthetase showed a decreasing gradient of activity. In sorocarps, the cells in the stalk apex showed synthetase activity similar to that of the spores. The cells at the bottom of the stalk had no detectable activity.     

Biological Activity of the Alternative Promoters of the Dictyostelium discoideum Adenylyl Cyclase A Gene

Amoebae of the Dictyostelium discoideum species form multicellular fruiting bodies upon starvation. Cyclic adenosine monophosphate (cAMP) is used as intercellular signalling molecule in cell-aggregation, cell differentiation and morphogenesis. This molecule is synthesized by three adenylyl cyclases, one of which, ACA, is required for cell aggregation. The gene coding for ACA (acaA) is transcribed from three different promoters that are active at different developmental stages. Promoter 1 is active during cell-aggregation, promoters 2 and 3 are active in prespore and prestalk tip cells at subsequent developmental stages. The biological relevance of acaA expression from each of the promoters has been studied in this article. The acaA gene was expressed in acaA-mutant cells, that do not aggregate, under control of each of the three acaA promoters. acaA expression under promoter 1 control induced cell aggregation although subsequent development was delayed, very small fruiting bodies were formed and cell differentiation genes were expressed at very low levels. Promoter 2-driven acaA expression induced the formation of small aggregates and small fruiting bodies were formed at the same time as in wild-type strains and differentiation genes were also expressed at lower levels. Expression of acaA from promoter 3 induced aggregates and fruiting bodies formation and their size and the expression of differentiation genes were more similar to that of wild-type cells. Expression of acaA from promoters 1 and 2 in AX4 cells also produced smaller structures. In conclusion, the expression of acaA under control of the aggregation-specific Promoter 1 is able to induce cell aggregation in acaA-mutant strains. Expression from promoters 2 and 3 also recovered aggregation and development although promoter 3 induced a more complete recovery of fruiting body formation.     

A myb-related protein required for culmination in Dictyostelium.

The avian retroviral v-myb gene and its cellular homologues throughout the animal and plant kingdoms contain a conserved DNA binding domain. We have isolated an insertional mutant of Dictyostelium unable to switch from slug migration to fruiting body formation i.e. unable to culminate. The gene that is disrupted, mybC, codes for a protein with a myb-like domain that is recognized by an antibody against the v-myb repeat domain. During development of myb+ cells, mybC is expressed only in prestalk cells. When developed together with wild-type cells mybC- cells are able to form both spores and stalk cells very efficiently. Their developmental defect is also bypassed by overexpressing cAMP-dependent protein kinase. However even when their defect is bypassed, mybC null slugs and culminates produce little if any of the intercellular signalling peptides SDF-1 and SDF-2 that are believed to be released by prestalk cells at culmination. We propose that the mybC gene product is required for an intercellular signaling process controlling maturation of stalk cells and spores and that SDF-1 and/or SDF-2 may be implicated in this process.     

Zellfunktionen und Zellfunktionswechsel in der Entwicklung vonDictyostelium discoideum

Summary EDTA and ethylurethan specifically interferes with the formation of normalDictyostelium fruiting bodies without inhibiting the cellular differentiation into spores and stalk cells. Thus differentiation is largely independent from the normal culmination process.On the other hand a preferential inhibition of the differentiation has been observed with 2-mercaptoethanol, the spores being more sensitive than the stalk cells.

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Herrn Prof. Dr. Dr. W.Weidel danke ich für anregende Diskussionen und großzügige Unterstützung der Arbeit.     

The control of chemotactic cell movement during Dictyostelium morphogenesis

Differential cell movement is an important mechanism in the development and morphogenesis of many organisms. In many cases there are indications that chemotaxis is a key mechanism controlling differential cell movement. This can be particularly well studied in the starvation-induced multicellular development of the social amoeba Dictyostelium discoideum. Upon starvation, up to 10(5) individual amoebae aggregate to form a fruiting body The cells aggregate by chemotaxis in response to propagating waves of cAMP, initiated by an aggregation centre. During their chemotactic aggregation the cells start to differentiate into prestalk and prespore cells, precursors to the stalk and spores that form the fruiting body. These cells enter the aggregate in a random order but then sort out to form a simple axial pattern in the slug. Our experiments strongly suggest that the multicellular aggregates (mounds) and slugs are also organized by propagating cAMP waves and, furthermore, that cell-type-specific differences in signalling and chemotaxis result in cell sorting, slug formation and movement.     

Cell Patterning During Slug Migration and Early Culmination in Dictyostelium discoideum

Abstract. The effects of migration and culmination on patterning of presumptive (prespore and prestalk) cells and mature (spore and stalk) cells of D. discoideum were investigated. The ratio of prespore to total cells, as determined by staining with fluorescein-conjugated antispore globulin, was constant (77%) up until 8 h of slug migration, but then decreased to a level (64%) which thereafter remained unchanged during migration. Cells which lost prespore antigen during migration were located in the posterior (prespore) part next to the agar surface.
Upon induction of culmination, however, the ratio of prespore cells quickly increased to the normal level (77%) within 1–2 h. During the transition between migration and culmination prestalk and prespore cells were considerably intermixed within the cell mass, before the normal prestalk-prespore pattern was reestablished at the preculmination (Mexican hat) stage. Spore: stalk ratios within fruiting bodies were normal irrespective of the lengths of slug migration.     

Differentiation of Various Cell Types during Fruiting Body Formation of Dictyostelium Discoideum*

The processes of differentiation of the presumptive cells (prespore and prestalk cens) into mature spores, stalk and basal-disc cells in Dictyotelium discoideum was investigated. The number of stalk and disc cells in pre-labeled culminating cell masses was estimated by determining the radioactivity of the undissociable fraction separated by filtration from the dissociable fraction containing presumptive cells and spores. Changes in the proportion of amoeboid cells stainable with fluorescein-conjugated antispore serum and encapsulated spores were also followed in the dissociable fraction. Formation of stalk and disc cells began at 17 hr of development and was completed at 26 hr, while formation of morphologically identifiable spores began at 18 hr and was completed at 20 hr, long before completion of stalk formation. At the onset of culmination, unstained cells abruptly increased with an accompanying decrease of stained cells, when unstained rear-guard cells appeared in the hind region. Although some of the rear-guard cells soon differentiated into basal-disc cells, the rest remained amoeboid in the upper part of the spore mass (sorus) after complete formation of a fruiting body. Despite the presence of the amoeboid cells in mature sori, the proportion of the sorus to the stalk and disc of a fruiting body was approximately equal to that of stained (prespore) to unstained (prestalk) cells in a migrating slug.     

Exploitation of other social amoebae by Dictyostelium caveatum

Dictyostelium amoebae faced with starvation trigger a developmental program during which many cells aggregate and form fruiting bodies that consist of a ball of spores held aloft by a thin stalk. This developmental strategy is open to several forms of exploitation, including the remarkable case of Dictyostelium caveatum, which, even when it constitutes 1/10(3) of the cells in an aggregate, can inhibit the development of the host and eventually devour it. We show that it accomplishes this feat by inhibiting a region of cells, called the tip, which organizes the development of the aggregate into a fruiting body. We use live-cell microscopy to define the D. caveatum developmental cycle and to show that D. caveatum amoebae have the capacity to ingest amoebae of other Dictyostelid species, but do not attack each other. The block in development induced by D. caveatum does not affect the expression of specific markers of prespore cell or prestalk cell differentiation, but does stop the coordinated cell movement leading to tip formation. The inhibition mechanism involves the constitutive secretion of a small molecule by D. caveatum and is reversible. Four Dictyostelid species were inhibited in their development, while D. caveatum is not inhibited by its own compound(s). D. caveatum has evolved a predation strategy to exploit other members of its genus, including mechanisms of developmental inhibition and specific phagocytosis.     

Establishment and maintenance of stable spatial patterns in lacZ fusion transformants of Polysphondylium pallidum.

Polysphondylium pallidum cells were transformed with a construct containing the Dictyostelium discoideum ecmA promoter fused to a lacZ reporter gene. Two stably transformed lines, one in which beta-galactosidase (beta-gal) is expressed in apical cells of the fruiting body (p63/2.1), and one in which it is expressed in basal cells (p63/D), have enabled us to infer how cells move during aggregation and culmination. Several types of cell movement proposed to occur during slime mold culmination, such as random cell mixing and global cell circulation, can be ruled out on the basis of our observations. Cells of the two transformant lines express beta-gal very early in development. In both cases, stained cells are randomly scattered in a starving population. By mid to late aggregation, characteristic spatial patterns emerge. Marked cells of p63/2.1 are found predominantly at tips of tight aggregates; those of p63/D accumulate at the periphery. These patterns are conserved throughout culmination, showing that marked cells maintain their relative positions within the multicellular mass following aggregation. Neither the apical nor the basal pattern appears to be regulated within the primary sorogen by de novo gene expression or by cell sorting as whorls are formed. However, marked cells within a whorl re-establish the original pattern in secondary sorogens. This must be achieved by cell migration, since beta-gal is not re-expressed.     

The requirement for DIF for prestalk and stalk cell formation in Dictyostelium discoideum: a comparison of in vivo and in vitro differentiation conditions

In Dictyostelium discoideum stalk cell formation is induced by cyclic AMP and differentiation-inducing factor (DIF) when cells are plated in in vitro monolayers (Kay et al., 1979, Differentiation 13: 7-14). The in vivo developmental stages at which cells became independent of these factors were determined. Independence was defined as the stage at which dispersed cells no longer required the factors for stalk cell formation in low density monolayers. Cyclic AMP independent cells were first detected at around 12 hr of development, a time that corresponds to the transition between the tipped aggregate and the first finger stages. In contrast cells did not become independent of DIF until late culmination. The prestalk cell-specific isozyme acid phosphatase II and a stalk cell-specific 41,000 Mr antigen (ST 41) were expressed during differentiation in low density monolayers in the presence of both cyclic AMP and DIF, but neither component was expressed in the presence of cyclic AMP alone. This result implies that DIF is essential for both prestalk and stalk cell formation. The two components were expressed within 2 hr of each other during differentiation in vitro, whereas during development in vivo acid phosphatase II was first detected at the first finger stage and ST 41 was first detected during late culmination, 8-12 hr later. These contrasting results suggest that the conversion of prestalk cells to stalk cells is unrestrained in monolayers, following directly after prestalk cell induction, but restrained in vivo until the culmination stage. This interpretation is consistent with the finding that cells become independent of DIF early during in vitro differentiation (A. Sobolewski, N. Neave, and G. Weeks, 1983, Differentiation 25, 93-100), but do not become independent of DIF until the culmination stage when differentiating in vivo.