Prespore cell fate bias in G1 phase of the cell cycle in Dictyostelium discoideum

By generating a population of Dictyostelium cells that are in the G1 phase of the cell cycle we have examined the influence of cell cycle status on cell fate specification, cell type proportioning and its regulation, and terminal differentiation. The lack of observable mitosis during the development of these cells and the quantification of their cellular DNA content suggests that they remain in G1 throughout development. Furthermore, chromosomal DNA synthesis was not detectable these cells, indicating that no synthesis phase had occurred, although substantial mitochondrial DNA synthesis did occur in prespore cells. The G1-phase cells underwent normal morphological development and sporulation but displayed an elevated prespore/prestalk ratio of 5.7 compared to the 3.0 (or 3:1) ratio normally observed in populations dominated by G2-phase cells. When migrating slugs produced by G1-phase cells were bisected, each half could reestablish the 5.7 (or 5.7:1) prespore/prestalk ratio. These results demonstrate that Dictyostelium cells can carry out the entire developmental cycle in the G1 phase of the cell cycle and that passage from G2 into G1 phase is not required for sporulation. Our results also suggest that the population asymmetry provided by the distribution of cells around the cell cycle at the time of starvation is not strictly required for cell type proportioning. Finally, when developed together with G2-phase cells, G1-phase cells preferentially become prespore cells and exclude G2-phase cells from the prespore-spore cell population, suggesting that G1-phase cells have an advantage over G2-phase cells in executing the spore cell differentiation pathway.     

Changes in the DNA content of amoebae of Dictyostelium discoideum during growth and development.

A fluorimetric assay has been used to determine the DNA content of amoebae of Dictyostelium discoideum during growth and development. Amoebae grown in axenic culture tended to be multinucleate and had a greater DNA content than amoebae grown with a bacterial substrate, which were mononucleate. During the first 10 h of development there was little change in the DNA content of amoebae grown with a bacterial substrate, but the average DNA content per cell in amoebae grown axenically decreased as the amoebae became virtually mononucleate. Amoebae at 10 h development that had been harvested during exponential axenic growth were divided into two populations by countercurrent distribution in a polymer two-phase system. DNA content indicated that one population was largely in the G2-phase of the cell cycle, whereas the other population was largely in the G1-phase. Similar results were obtained at 10 h development with amoebae harvested during the stationary phase of axenic growth, although these amoebae start development all in the G2-phase of the cell cycle. Spores had a low DNA content, indicating that they were in G1-phase. It is proposed that all amoebae in G2-phase after early development differentiate, after mitosis, into spores and that stalk cells are formed from amoebae that remain in G1-phase after 10 h development.     

A prespore gene, Dd31, expressed during culmination of Dictyostelium discoideum

During culmination of Dictyostelium fruiting bodies, prespore and prestalk cells undergo terminal differentiation to form spores and a cellular stalk. A genomic fragment was isolated by random cloning that hybridizes to a 1.4-kb mRNA present during culmination. Cell type separations at culmination showed that the mRNA is present in prespore cells and spores, but not in prestalk or stalk cells. After genomic mapping, an additional 3 kb of DNA surrounding the original 1-kb fragment was cloned. The gene was sequenced and named Dd31 after the size of the predicted protein product in kilodaltons. Accumulation of Dd31 mRNA occurs immediately prior to sporulation. Addition of 20 mM 8-Br-cAMP to cells dissociated from Mexican hat stage culminants induced sporulation and the accumulation of Dd31 mRNA, while 20 mM cAMP did not. Dd31 mRNA does not accumulate in the homeotic mutant stalky in which prespore cells are converted to stalk cells rather than spores. Characterization of Dd31 extends the known temporal dependent sequence of molecular differentiations to sporulation.     

Live imaging of the Dictyostelium cell cycle reveals widespread S phase during development, a G2 bias in spore differentiation and a premitotic checkpoint

The regulation of the Dictyostelium cell cycle has remained ambiguous owing to difficulties in long-term imaging of motile cells and a lack of markers for defining cell cycle phases. There is controversy over whether cells replicate their DNA during development, and whether spores are in G1 or G2 of the cell cycle. We have introduced a live-cell S-phase marker into Dictyostelium cells that allows us to precisely define cycle phase. We show that during multicellular development, a large proportion of cells undergo nuclear DNA synthesis. Germinating spores enter S phase only after their first mitosis, indicating that spores are in G2. In addition, we demonstrate that Dictyostelium heterochromatin is copied late in S phase and replicates via accumulation of replication factors, rather than recruitment of DNA to pre-existing factories. Analysis of variability in cycle times indicates that regulation of the cycle manifests at a single random transition in G2, and we present the first identified checkpoint in Dictyostelium, which operates at the G2-M transition in response to DNA damage.     

Cell cycle phase, cellular Ca2+ and development in Dictyostelium discoideum

In Dictyostelium discoideum, the initial differentiation of cells is regulated by the phase of the cell cycle at starvation. Cells in S and early G2 (or with a low DNA content) have relatively high levels of cellular Ca2+ and display a prestalk tendency after starvation, whereas cells in mid to late G2 (or with a high DNA content) have relatively low levels of Ca2+ and display a prespore tendency. We found that there is a correlation between cytosolic Ca2+ and cell cycle phase, with high Ca2+ levels being restricted to cells in the S and early G2 phases. As expected on the basis of this correlation, cell cycle inhibitors influence the proportions of amoebae containing high or low Ca2+. However, it has been reported that in the rtoA mutant, which upon differentiation gives rise to many more stalk cells than spores (compared to the wild type), initial cell-type choice is independent of cell cycle phase at starvation. In contrast to the wild type, a disproportionately large fraction of rtoA amoebae fall into the high Ca2+ class, possibly due to an altered ability of this mutant to transport Ca2+.     

ATP, trehalose, glucose and ammonium ion localization in the two cell types of Dictyostelium discoideum

Ultra-microfluorometric techniques were adapted to follow several compounds related to energy metabolism through the developmental cycle of Dictyostelium discoideum. Each compound (ATP, trehalose, glucose, and ammonium ion) was found to be present in stalk and/or spore cells. The accumulation of NH4+ was interpreted as an indication of protein degradation, a source of energy in this organism. During the early stages of differentiation NH4+ was localized only in prestalk cells. However, it accumulated in spore cells during culmination such that levels were comparable in the two cell types by the end of development. Trehalose, an energy source for germinating spores, was found in both cell types but was preferentially degraded in stalk cells late in development. Glucose, the degradation product of trehalose, was localized in prestalk cells and varied inversely with trehalose levels. ATP was not localized in a specific cell type during development. However, ATP declined in stalk cells at an earlier stage of development.     

The Dictyostelium cell cycle and its relationship to differentiation

Abstract The Dictyostelium vegetative cell cycle is characterized by a short mitotic period followed immediately by a short S-phase (less than 30 min) and a long and variable G2 phase. The cell cycle continues during differentiation despite a decrease in cell mass: DNA replication and mitosis occur early in development and also at the tipped aggregate stage. Cells that are in mitosis, S-phase or early G2, when starved differentiate into prestalk cells and cells that are in the middle of G2 differentiate into prespore cells. We postulate that there is a restriction point late in the G2 phase, about 1–2 h before mitosis, where the cells can be arrested either by starvation and the initiation of development, by growing into stationary phase, or by prolonged incubation at low temperature. During development, this block persists to the tipped aggregate stage, where it is specifically released in prespore cells, and these cells then go through one more round of cell division. Genes encoding components of the cell cycle machinery have recently been isolated and attemps to specifically block the cell cycle by reverse genetics to study the effects on differentiation have been initiated.     

Cell cycle phase in Dictyostelium discoideum is correlated with the expression of cyclic AMP production, detection, and degradation. Involvement of cyclic AMP signaling in cell sorting

Cell cycle phase in Dictyostelium is correlated with a different preference for either spore or stalk differentiation. Cells which start development early in the cell cycle (E cells) exhibit a strong tendency to sort to the prestalk region of slugs, while late cell cycle cells (L cells) sort to the prespore region. We investigated the expression of the cAMP chemotactic system during development of synchronized E and L cells and found that E cells exhibit cAMP-binding activity, cell surface cAMP-phosphodiesterase (mPDE) activity, and the ability to relay cAMP signals at least 2 hr earlier and to higher levels than L cells. We hypothesize that E cells are prestalk sorters because they are the first to initiate aggregation centers and respond most effectively with chemotaxis and signal relay.     

Trishanku, a novel regulator of cell-type stability and morphogenesis in Dictyostelium discoideum

We have identified a novel gene, trishanku (triA), by random insertional mutagenesis of Dictyostelium discoideum. TriA is a Broad complex Tramtrack bric-a-brac domain-containing protein that is expressed strongly during the late G2 phase of cell cycle and in presumptive spore (prespore (psp)) cells. Disrupting triA destabilizes cell fate and reduces aggregate size; the fruiting body has a thick stalk, a lowered spore: stalk ratio, a sub-terminal spore mass and small, rounded spores. These changes revert when the wild-type triA gene is re-expressed under a constitutive or a psp-specific promoter. By using short- and long-lived reporter proteins, we show that in triA(-) slugs the prestalk (pst)/psp proportion is normal, but that there is inappropriate transdifferentiation between the two cell types. During culmination, regardless of their current fate, all cells with a history of pst gene expression contribute to the stalk, which could account for the altered cell-type proportion in the mutant.     

Glutathione is required for growth and prespore cell differentiation in Dictyostelium

Glutathione (GSH) is the most abundant non-protein thiol in eukaryotic cells and acts as reducing equivalent in many cellular processes. We investigated the role of glutathione in Dictyostelium development by disruption of gamma-glutamylcysteine synthetase (GCS), an essential enzyme in glutathione biosynthesis. GCS-null strain showed glutathione auxotrophy and could not grow in medium containing other thiol compounds. The developmental progress of GCS-null strain was determined by GSH concentration contained in preincubated media before development. GCS-null strain preincubated with 0.2 mM GSH was arrested at mound stage or formed bent stalk-like structure during development. GCS-null strain preincubated with more than 0.5 mM GSH formed fruiting body with spores, but spore viability was significantly reduced. In GCS-null strain precultured with 0.2 mM GSH, prestalk-specific gene expression was delayed, while prespore-specific gene and spore-specific gene expressions were not detected. In addition, GCS-null strain precultured with 0.2 mM GSH showed prestalk tendency and extended G1 phase of cell cycle. Since G1 phase cells at starvation differentiate into prestalk cells, developmental defect of GCS-null strain precultured with 0.2 mM GSH may result from altered cell cycle. These results suggest that glutathione itself is essential for growth and differentiation to prespore in Dictyostelium.     

A retinoblastoma ortholog controls stalk/spore preference in Dictyostelium

We describe rblA, the Dictyostelium ortholog of the retinoblastoma susceptibility gene Rb. In the growth phase, rblA expression is correlated with several factors that lead to 'preference' for the spore pathway. During multicellular development, expression increases 200-fold in differentiating spores. rblA-null strains differentiate stalk cells and spores normally, but in chimeras with wild type, the mutant shows a strong preference for the stalk pathway. rblA-null cells are hypersensitive to the stalk morphogen DIF, suggesting that rblA normally suppresses the DIF response in cells destined for the spore pathway. rblA overexpression during growth leads to G1 arrest, but as growing Dictyostelium are overwhelmingly in G2 phase, rblA does not seem to be important in the normal cell cycle. rblA-null cells show reduced cell size and a premature growth-development transition; the latter appears anomalous but may reflect selection pressures acting on social ameba.     

Localization of glycogen phosphorylase in specific cell types during differentiation of Dictyostelium discoideum

The localization of glycogen phosphorylase was studied during the differentiation of prespore and prestalk cells in Dictyostelium discoideum. Ultramicrotechniques were utilized to assay the enzyme activity in cell samples as small as 0.02 μg dry wt in reaction volumes of 0.1 μl. The activity was assayed using an amplification procedure employing the enzymatic cycling of pyridine nucleotides. Glycogen phosphorylase from individual organisms was assayed during the developmental period. Early in development, activity was low but gradually increased to a maximum value at culmination. From culmination to sorocarp, enzyme activity decreased rapidly. Cell-specific assays of spores showed that phosphorylase activity increased slightly to culmination, and then decreased. Prestalk cells showed the greatest activity in the area of stalk sheath construction and elongation. Stalk cells showed a decreasing gradient of enzyme activity from the tip of the stalk to the base. Enzyme activity in the spores may be sufficient to provide glucose units for trehalose synthesis and spore coat production. The prestalk enzyme may degrade glycogen to provide glycosyl units for production of the stalk sheath and trehalose. Possible models of cell-specific biochemical events in Dictyostelium discoideum are discussed.     

Stalk cell formation in monolayers of Dictyostelium discoideum V12-M2

Stalk cell formation in low-cell-density monolayers of Dictyostelium discoideum, strain V12-M2, occurs following the sequential addition of cyclic AMP and the differentiation-inducing factor (DIF). Both cyclic AMP and DIF are essential for the appearance of the prestalk-specific isozyme alkaline phosphatase-II, which suggests that both factors are necessary for prestalk cell formation. The available evidence suggests that the cyclic AMP requirement for stalk cell formation is mediated through the cell surface cyclic AMP receptor. However, stalk cell formation is inhibited by caffeine and this inhibition is reversed by the cell-permeable analogue 8-Br-cyclic AMP, which suggests in addition a possible involvement for elevated intracellular cyclic AMP concentrations in stalk cell formation. During in vivo development cells first become independent of cyclic AMP at the tipped aggregate stage, but the acquisition of cyclic AMP independence is advanced by several hours when cells are incubated in the presence of cyclic AMP for 2 hours. Cells do not become independent of DIF until the culmination stage of development, which suggests the possibility that DIF is required for the conversion of prestalk cells to stalk cells. There is an absolute requirement for DIF for stalk cell formation in low-density monolayers of prestalk cells but only part of population exhibits a requirement for cyclic AMP, which suggests that the prestalk cell population consists of two distinct cell types. Stalk cell formation from prespore cells is totally dependent on both cyclic AMP and DIF.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression of an activated rasD gene changes cell fate decisions during Dictyostelium development.

It has been previously demonstrated that the expression of an activated rasD gene in wild-type Dictyostelium cells results in formation of aggregates with multitips, instead of the normal single tips, and a block in further development. In an attempt to better understand the role of activated RasD development, we examined cell-type-specific gene expression in a strain stably expressing high levels of RasD[G12T]. We found that the expression of prestalk cell-specific genes ecmA and tagB was markedly enhanced, whereas the expression of the prespore cell-specific gene cotC was reduced to very low levels. When the fate of cells in the multitipped aggregate was monitored with an ecmA/lacZ fusion, it appeared that most of the cells eventually adopted prestalk gene expression characteristics. When mixtures of the [G12T]rasD cells and Ax3 cells were induced to differentiate, chimeric pseudoplasmodia were not formed. Thus, although the [G12T]rasD transformant had a marked propensity to form prestalk cells, it could not supply the prestalk cell population when mixed with wild-type cells. Both stalk and spore cell formation occurred in low cell density monolayers of the [G12T]rasD strain, suggesting that at least part of the inhibition of stalk and spore formation during multicellular development involved inhibitory cell interactions within the cell mass. Models for the possible role of rasD in development are discussed.     

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.     

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.     

The role of the cell cycle in differentiation of the cellular slime mould Dictyostelium discoideum

Summary During development and differentiation of the cellular slime mould Dictyostelium discoideum there appears to be a relationship between the cell cycle and cell fate: amoebae halted in G2 phase during early development differentiate into spores whereas stalk cells are formed from amoebae halted in GI phase. It is proposed that this is because a major effect of the cell cycle is to generate heterogeneity in the cell surface properties of the developing amoebae.