Correlation of axenic linkage groups with the position of the microtubule-organizing center in aggregating Dictyostelium.

Positioning of the microtubule-organizing center (MTOC) in Dictyostelium discoideum was found to be genetically regulated. We examined the wild-type strain NC-4 cells independently maintained in different laboratories, freshly recovered cells from spores stocked for over 20 years, the temperature-sensitive growth mutant HU49 isolated from NC-4, as well as strain V-12 which is the opposite mating-type to NC-4. During aggregation on nonnutrient agar plates, all these strains showed similar cell polarity, as defined by the alignment of the nucleus ahead of the MTOC. By contrast, in Ax2 and Ax3, axenic strains carrying axenic mutations on linkage groups II and III, the MTOC was usually positioned ahead of the nucleus. Cells containing axenic linkage group II but not III positioned the MTOC ahead of the nucleus. Conversely cell polarity of strains including axenic linkage group III but not II was similar to that of wild-type cells. Thus axenic linkage group II, probably axeC or other linked gene(s) not yet identified, is responsible for the location of the MTOC anterior to the nucleus during aggregation. The anterior positioning of the MTOCs was prevented by growth on bacteria in cells carrying both axenic linkage groups, but not in those carrying only axenic linkage group II.     

Control of phototactic migration in Dictyostelium discoideum

Phototactic migration of pseudoplasmodia of the cellular slime mold, Dictyostelium discoideum, is directed by a response at the anterior tip. Horizontal light appears to be focused by refraction at the surface of the pseudoplasmodium such that it acts preferentially on the distal cells. We have been able to show that light stimulates the rate of pseudoplasmodial movement up to 80%. This increase is dependent on the intensity of the incident light. Thus it appears that light can control the direction of migration by increasing the rate of movement on the distal side. The anterior cells are then turned toward the light by cohesion to the more slowly moving proximal side. Migration rate in the dark may be limited by the rate of synthesis or deposition of the surface sheath surrounding the pseudoplasmodium. It is suggested that light increases the rate of migration by stimulating the formation of the surface sheath. Localized stimulation would then result in a turning response.     

Cell-cycle regulation of center initiation in Dictyostelium discoideum

The center-initiating behavior of Dictyostelium discoideum amoebae in various cell-cycle phases was investigated. Small populations of synchronized AX-2 cells were seeded 1 in 1000 into cultures of a nonsignaling mutant (NP160) incapable of initiating centers. The ability of the wild-type AX-2 cells to initiate centers among mutant amoebae displayed cell-cycle regulation. Approximately 50% of a population of S-phase cells initiated centers while only 7.5% of a population of late G2-phase cells resulted in center formation. The timing of center formation also varied with cycle position. Synchronous cultures containing only AX-2 S-phase amoebae (no NP160) displayed the initial signs of aggregation after 4.5 hr of starvation and streaming into the aggregate was complete after 6 hr. In contrast, cultures of late G2-phase amoebae initiated aggregation centers after 5.5 hr of starvation and did not complete streaming until 7.5 hr. In addition, the number of aggregates formed by these synchronous cultures of AX-2 cells also varied with cycle position. In general, these results suggest a cell-cycle modulation of the autonomous signaling responsible for center initiation.     

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.     

Staurosporine induced poly (ADP-ribose) polymerase independent cell death in Dictyostelium discoideum

In the present study D. discoideum has been used as a model organism to understand the role of poly (ADP-ribose) polymerase (PARP) in caspase independent paraptotic cell death pathways. D. discoideum lacks caspases and Bcl-2 family proteins; nevertheless it has 9 potential genes for PARP. PARP has been known to get activated in various cell death associated diseases. In this study kinetics of cell death induced by staurosporine (STS), a bacterial alkaloid, was established to unravel the role of PARP. It was found that STS induced cell death in D. discoideum did not involve PARP activation, however it involved cathepsin D. Results indicated that an alternative mechanism may be existing in D. discoideum that lacks Bcl-2 family proteins for STS induced cell death that evades Bax involvement.     

Translocation of cAMP-dependent protein kinase to the nucleus during development of Dictyostelium discoideum

The distribution of the catalytic and regulatory subunits of the cAMP-dependent protein kinase between cytoplasm and nucleus was determined during the development of Dictyostelium discoideum. In vegetative amoebae approximately 2% of the subunits were in the nucleus. During development there was an approximately 5-fold increase in total soluble cAMP-dependent protein kinase and a 15- to 30-fold increase of enzyme in the nuclear fraction. There was a reverse translocation from nucleus to cytoplasm, when Tipped Aggregates were disrupted and the resultant amoebae incubated in single-cell suspension. The addition of cAMP to these single-cell suspensions brought about the reentry of the subunits into the nucleus. The findings are discussed in relation to the potential role of the cAMP-dependent protein kinase in the regulation of mRNA and protein synthesis.     

Cyclic AMP is an inhibitor of stalk cell differentiation in Dictyostelium discoideum

Cyclic AMP and DIF-1 (1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)-1-hexanone) together induce stalk cell differentiation in vitro in Dictyostelium discoideum strain V12M2. The induction can proceed in two stages: in the first, cyclic AMP brings cells to a DIF-responsive state; in the second, DIF-1 alone can induce stalk cell formation. We report here that during the DIF-1-dependent stage, cyclic AMP is a potent inhibitor of stalk cell differentiation. Addition of cyclic AMP at this stage to V12M2 cells appreciably delays, but does not prevent, stalk cell formation. In contrast, stalk cell differentiation in the more common strain NC4 is completely suppressed by the continued presence of cyclic AMP. This fact explains earlier failures to induce stalk cells in vitro in NC4. We now consistently obtain efficient stalk cell induction in NC4 by removing cyclic AMP in the DIF-1-dependent stage. Cyclic AMP also inhibits the production of a stalk-specific protein (ST310) in both NC4 and a V12M2 derivative. Adenosine, a known antagonist of cyclic AMP action, does not relieve this inhibition by cyclic AMP and does not itself promote stalk cell formation. Finally, stalk cell differentiation of NC4 cells at low density appears to require factors in addition to cyclic AMP and DIF-1, but their nature is not yet known. The inhibition of stalk cell differentiation by cyclic AMP may be important in establishing the prestalk/prespore pattern during normal development, and in preventing the maturation of prestalk into stalk cells until culmination.     

The cell cycle and its relationship to development in Dictyostelium discoideum.

When deprived of exogenous nutrients some amoebas of Dictyostelium discoideum do continue to progress through the cell cycle. There are two distinct periods when mitotic cell division occurs. Labeling studies show that during the first period, which begins at the onset of development and ceases at the first visible signs of aggregation (rippling), only those cells which are beyond a certain point in G2 at the initiation of development divide. The second period of mitotic activity begins at tip formation, reaches maximum activity at the grex stage, and ceases during early culmination. Significantly, examination of the development of amoebas harvested when in the stationary phase of growth (and thus arrested in G2) shows that these cells still undergo mitotic cell division during the second period but do not show any such division during the preaggregation phase. The extent to which increases in cell number can be taken to be indicative of mitotic cell division varies from one culture to another due to the presence of variable numbers of multinucleate cells which become mononucleate during the first 10 hr of development. However, when due allowance has been made for the existence of these cells in axenically growing amoebal populations, our data show that by completion of fruiting body construction there has been a doubling in cell number as a direct result of mitotic cell division. Nuclear DNA synthesis also occurs at two distinct periods during development, these coinciding with the periods of mitotic activity. However, since no more than 35% of the cells have undergone nuclear DNA synthesis by the end of the developmental phase, our results are inconsistent with the conclusion that all cells accumulate at a position in G2 at the time of aggregation. Our results do suggest, however, that mitotic cell division of a fraction of the cells may be an integral part of the developmental phase.     

Dictyostelium protein kinase C-delta-like protein is localized in the cell nucleus

The molecular mechanism whereby protein kinase C (PKC) molecules transduce signals into the cell nucleus is unknown. In this study, we provide evidence that Dictyostelium discoideum contains PKCδ-like protein that is localized in the nucleus. The Dictyostelium PKCδ-like protein has an apparent molecular mass of 76 kDa. This protein is already highly expressed in vegetative Dictyostelium cells. The expression level remained constant up to 12 h of development, and sharply decreased after 16 h. The PKCδ-like protein is phosphorylated in vivo in response to cAMP and phorbol ester stimulation. Immunofluorescent studies, as well as subcellular fractionation experiments, have indicated that Dictyostelium PKCδ-like protein is permanently located in the nucleus. Our results may indicate that PKCδ-like protein in Dictyostelium functions as a link between cAMP and the tumor-promoting phorbol esters, and events that take place in the nucleus.     

Cyclic-AMP binding to the cell surface during development of Dictyostelium discoideum

Abstract. Cell aggregation in Dictyostelium discoideum is a chemotactic process mediated by cyclic adenosine monophosphate (CAMP), which is detected by cell surface receptors. The cAMP signal is degraded by cAMP phosphodiesterase. The possibility that cAMP signals are also used for cell communication in the multicellular stages was studied by determining whether the cAMP receptors, which are essential for signal transduction, continue to function in these stages. During slug migration, the number of binding sites per cell decreases to about 15% of the maximum level acquired during aggregation. At the onset of fruiting body formation, a three- to Four-Fold increase in cAMP binding activity occurs. This increase coincides with an increase in cAMP phosphodiesterase. Both phenomena suggest that cell-cell communication mediated by cAMP is used during culmination. During both slug migration and early culmination, the prestalk cells exhibit about twice as much binding activity as the prespore cells.     

Periodic cell aggregation in suspensions of Dictyostelium discoideum

Abstract. Periodic activities of Dictyostelium discoideum can be observed in cell suspension as two types of oscillations in the light-scattering properties, spike-shaped and sinusoidal. Responses of suspended cells to applied chemoattractants are also reflected by transient changes in light scattering. Alterations in the light-scattering properties are due to structural changes such as changes in cell shape and/or changes in the size of cell aggregates. Therefore, changes in the aggregation state during autonomous oscillations and during attractant-induced responses were investigated. In order to be able to withdraw multiple samples and larger sample volumes from optically monitored cell suspensions, a photometer comprising glass fiber optics immersable in a cell suspension was constructed. Samples were fixed with formaldehyde and photographed. The aggregation state of the samples was quantified by counting the number of particles (cells and cell aggregates) per volume. Folic acid elicited in suspensions of undifferentiated cells a transient decrease in the number of particles per volume as did cAMP in suspensions of preaggregation cells. Periodic changes in the number of particles per volume occurred synchronously with spike-shaped and sinusoidal oscillations. The relative amplitude of the oscillations in particle number was larger during sinusoids than during spikes. Photographs showed periodic changes in the aggregate size during sinusoidal oscillations. In each cycle, the cell-aggregation phase was followed by a phase of partial disaggregation. The recurring loosening of cell-cell contacts may be relevant for sorting out the different cell types. The potential role of contact site as synchronizer and as constituent of an oscillator is discussed.     

Inhibition of cell adhesion in Dictyostelium discoideum by tunicamycin is prevented by leupeptin

The carbohydrate requirement for cell adhesion of aggregation-competent cells of Dictyostelium discoideum has been examined by use of a selective glycosylation inhibitor of N-glycosyl protein, tunicamycin (TM). TM completely inhibited EDTA-stable cell adhesion and glycosylation of some membrane glycoproteins in aggregation-competent cells of D. discoideum (Yamada, H., et al. (1982) J. Biochem. 92, 399-406). The present study showed that the inhibition of EDTA-stable cell adhesion by TM was prevented significantly when the cells were treated with TM in the presence of a protease inhibitor, leupeptin (LP), whereas the inhibition of glycosylation by TM was not prevented. The cell extract of aggregation-competent cells contained acid proteases, and LP strongly inhibited acid protease from D. discoideum in vitro. On analysis by SDS-polyacrylamide gel electrophoresis (PAGE), many protein bands present in the membrane fraction of control cells disappeared or decreased on TM treatment of the cells in the absence of LP, however, some of these proteins were restored when the cells were treated with TM in the presence of LP. These results strongly support an idea that EDTA-stable cell adhesion characteristic to aggregation-competent cells is mediated by glycoproteins with asparagine-linked carbohydrate. However, the requirement for the carbohydrate moiety of the glycoprotein in cell adhesion appears to be indirect in that it acts to protect the protein moiety from proteolytic degradation.     

Correlates of developmental cell death in Dictyostelium discoideum

We have studied the correlates of cell death during stalk cell differentiation in Dictyostelium discoideum. Our main findings are four. (i) There is a gradual increase in the number of cells with exposed phosphatidyl serine residues, an indicator of membrane asymmetry loss and increased permeability. Only presumptive stalk cells show this change in membrane asymmetry. Cells also show an increase in cell membrane permeability under conditions of calcium-induced stalk cell differentiation in cell monolayers. (ii) There is a gradual fall in mitochondrial membrane potential during development, again restricted to the presumptive stalk cells. (iii) The fraction of cells showing caspase-3 activity increases as development proceeds and then declines in the terminally differentiated fruiting body. (iv) There is no internucleosomal cleavage of DNA, or DNA fragmentation, in D. discoideum nor is there any calcium- and magnesium-dependent endonucleolytic activity in nuclear extracts from various developmental stages. However, nuclear condensation and peripheralization does occur in stalk cells. Thus, cell death in D. discoideum shows some, but not all, features of apoptotic cell death as recognized in other multicellular systems. These findings argue against the emergence of a single mechanism of 'programmed cell death (PCD)' before multicellularity arose during evolution.     

Cell-type-specific responsiveness to cAMP in cell differentiation of Dictyostelium discoideum.

In Dictyostelium discoideum, both prespore and prestalk differentiation require extracellular cAMP. We investigated the difference in inducibility of the two cell types by cAMP. Previous studies indicate that cAMP added in the early stage of development inhibits prespore differentiation, and this was confirmed using three species of prespore specific mRNAs. By contrast, early treatment with cAMP did not inhibit, but induced the expression of prestalk-specific mRNA. These results indicate that differentiation pathways of the two cell types have different processes in the early stage of development.     

Ribosomal protein gene expression is cell type specific during development in Dictyostelium discoideum

Starvation for amino acids initiates the developmental cycle in the cellular slime mold, Dictyostelium discoideum. Upon starvation one of the earliest developmental events is the selective loss of the ribosomal protein mRNAs from polysomes. This loss depends upon sequences in the 5' non-translated leader of the ribosomal protein (r-protein) mRNAs. Here evidence is presented which indicates that those cells which will become prestalk cells express the ribosomal protein genes during development under starvation conditions. Cells which enter the prespore pathway shut off r-protein synthesis. The promoter and 5' non-translated leader sequences from two ribosomal protein genes, the rp-L11 and the rp-S9 genes, are fused to the Escherichia coli beta-galactosidase reporter gene. While beta-galactosidase enzyme activity is detected in situ in most growing cells, by 15 h of development beta-galactosidase enzyme activity is largely lost from the prespore cells although strong beta-galactosidase enzyme activity is present in the prestalk cells. These observations suggest the possibility that the ribosomal protein mRNAs are excluded from polysomes in a cell-type-specific manner.     

The COP9 signalosome regulates cell proliferation of Dictyostelium discoideum

Regulated protein destruction involving SCF (Skp1/Cullin/F-box, E3 ubiquitin ligase) complexes is required for multicellular development of Dictyostelium discoideum. Dynamic modification of cullin by nedd8 is required for the proper action of SCF. The COP9 signalosome (CSN), first identified in a signaling pathway for light response in plants, functions as a large multi-protein complex that regulates cullin neddylation in eukaryotes. Still, there is extreme sequence divergence of CSN subunits of the yeasts in comparison to the multicellular plants and animals. Using the yeast two-hybrid system, we have identified the CSN5 subunit as a potential interacting partner of a cell surface receptor of Dictyostelium. We further identified and characterized all 8 CSN subunits in Dictyostelium discoideum. Remarkably, despite the ancient origin of Dictyostelium, its CSN proteins cluster very closely with their plant and animal counterparts. We additionally show that the Dictyostelium subunits, like those of other systems are capable of multi-protein interactions within the CSN complex. Our data also indicate that CSN5 (and CSN2) are essential for cell proliferation in Dictyostelium, a phenotype similar to that of multicellular organisms, but distinct from that of the yeasts. Finally, we speculate on a potential role of CSN in cullin function and regulated protein destruction during multicellular development of Dictyostelium.     

Actin-binding protein G (AbpG) participates in modulating the actin cytoskeleton and cell migration in Dictyostelium discoideum

Cell migration is involved in various physiological and pathogenic events, and the complex underlying molecular mechanisms have not been fully elucidated. The simple eukaryote Dictyostelium discoideum displays chemotactic locomotion in stages of its life cycle. By characterizing a Dictyostelium mutant defective in chemotactic responses, we identified a novel actin-binding protein serving to modulate cell migration and named it actin-binding protein G (AbpG); this 971–amino acid (aa) protein contains an N-terminal type 2 calponin homology (CH2) domain followed by two large coiled-coil regions. In chemoattractant gradients, abpG⁻ cells display normal directional persistence but migrate significantly more slowly than wild-type cells; expressing Flag-AbpG in mutant cells eliminates the motility defect. AbpG is enriched in cortical/lamellipodial regions and colocalizes well with F-actin; aa 401–600 and aa 501–550 fragments of AbpG show the same distribution as full-length AbpG. The aa 501–550 region of AbpG, which is essential for AbpG to localize to lamellipodia and to rescue the phenotype of abpG⁻ cells, is sufficient for binding to F-actin and represents a novel actin-binding protein domain. Compared with wild-type cells, abpG⁻ cells have significantly higher F-actin levels. Collectively our results suggest that AbpG may participate in modulating actin dynamics to optimize cell locomotion.     

Cytoplasmic pH and glycolysis in the Dictyostelium discoideum cell cycle

Lactate production measurements during the cell cycle of synchronized populations of Dictyostelium discoideum cells reveal cyclic variations in glycolysis which correspond with pH_i oscillations which were discovered by us previously [(1985) Cell, in press]. Aerobic lactate production varies about 6-fold during the cell cycle and the lactate maxima correlate with (~ 0.25 pH unit) cyclic increases in pH. However, artificially altering pH_i using weak acids or bases does not influence the rate of lactate production in asynchronous cell populations. This result suggests that the cyclic variations in pH_i and those in glycolytic rate are not causally related events.     

Dynamics of antigenic membrane sites relating to cell aggregation in Dictyostelium discoideum

Membrane interaction in aggregating cells of Dictyostelium discoideum can be blocked by univalent antibodies directed against specific membrane sites. Using a quantitative technique for measuring cell association, two classes of target sites for blocking antibodies were distinguished and their developmental dynamics studied. One class of these sites is specific for aggregation-competent cells, their quantity rising from virtually 0-level during growth, with a steep increase shortly before cell aggregation. The serological activity of these structures is species specific; they are not detectable in a nonaggregating mutant, but present in a revertant undergoing normal morphogenesis. Patterns of cell assembly in the presence of antibodies show that selective blockage of these membrane sites abolishes the preference for end-to-end association which is typical for aggregating cells. A second class of target sites is present in comparable quantities in particle fractions from both growth-phase and aggregation-competent cells. Blockage of these sites leads to aggregation patterns in which the side-by-side contacts of aggregating cells are abolished. The target sites of aggregation-inhibiting antibodies are suggested to be identical or associated with the molecular units of the cell membrane that mediate cell-to-cell contacts during aggregation. The results indicate that in one cell, two independent classes of contact sites can be simultaneously active.     

Naringenin is a novel inhibitor of Dictyostelium cell proliferation and cell migration

Naringenin is a flavanone compound that alters critical cellular processes such as cell multiplication, glucose uptake, and mitochondrial activity. In this study, we used the social amoeba, Dictyostelium discoideum, as a model system for examining the cellular processes and signaling pathways affected by naringenin. We found that naringenin inhibited Dictyostelium cell division in a dose-dependent manner (IC(50) approximately 20 microM). Assays of Dictyostelium chemotaxis and multicellular development revealed that naringenin possesses a previously unrecognized ability to suppress amoeboid cell motility. We also found that naringenin, which is known to inhibit phosphatidylinositol 3-kinase activity, had no apparent effect on phosphatidylinositol 3,4,5-trisphosphate synthesis in live Dictyostelium cells; suggesting that this compound suppresses cell growth and migration via alternative signaling pathways. In another context, the discoveries described here highlight the value of using the Dictyostelium model system for identifying and characterizing the mechanisms by which naringenin, and related compounds, exert their effects on eukaryotic cells.