A mutation in the cAMP signaling pathway affects sexual development of Dictyostelium discoideum

Amoebae of cellular slime molds have two developmental modes, asexual fruiting body formation and sexual macrocyst formation. How developmental choice is made is an interesting subject of wide importance. Light exposure and dry conditions are favorable for asexual development, while conditions of darkness and high humidity are so for sexual development. In Dictyostelium discoideum , the latter conditions enhance zygote formation, which determines the fate of surrounding cells for sexual development. Here, a mutant (TMC1) defective in the post-fusion aggregation of cells during sexual development is described. This mutant is also aggregationless in asexual development, and the level of cyclic adenosine monophosphate (cAMP) receptor is reduced. Correspondingly, a series of existing mutants with defects in cAMP signaling pathways showed the same sexual phenotype as TMC1. These results suggest that molecular mechanisms of development are shared by the two alternative developmental modes.     

Cystein proteinase changes during macrocyst formation in Dictyostelium mucoroides

Cysteine proteinases were detected in vegetative myxamoebae of Dictyostelium mucoroides DM7 using chromogenic substrates and by electrophoretic analysis (gelatin-SDS-PAGE) which revealed three enzymes, dmCP30, dmCP35 and dmCP46 (a minor form). During the initial stages of macrocyst formation the cysteine proteinaes were secreted and disappeared almost completely from the cells. High extracellular levels of activity towards N-benzoyl-L-prolyl-L-phenylalanyl-L-arginine 4-nitroanilide and of dmCP30 persisted throughout macrocyst development. Three new intracellular proteinases, dmCP31, dmCP36 and dmCP40, were produced as macrocysts formed but their activity was only detected by gelatin-SDS-PAGE. Their appearance was specific to the developmental pathway leading to macrocyst formation. This is the first direct evidence for the accumulation of cysteine proteinases during a developmental process in a cellular slime mould.     

Induction of Heterothallic and Homothallic Zygotes in Dictyostelium discoideum by Ethylene

Dictyostelium mucoroides -7 (Dm7) and a mutant (MF1) derived from it exhibit homothallic macrocyst formation in the sexual process. As previously shown, the zygote formation during macrocyst formation is induced by a potent plant hormone, ethylene. The present work was undertaken to know if ethylene is also involved in heterothallic and homothallic macrocyst formation in D. discoideum. In heterothallic macrocyst formation between NC4 and V12M2 cells, ethionine, an analogue of methionine, inhibits macrocyst formation through arresting specifically the acquisition process of fusion competence. Such an inhibitory effect of ethionine was almost completely cancelled by co-application of ACC (1-aminocyclopropane-1-carboxylic acid), the immediate precursor of ethylene. Essentially the same effects of ethionine and ACC were also noticed on homothallic macrocyst formation in D. discoideum AC4. Thus it seems most likely that ethylene is required for the acquisition of fusion competence during macrocyst formation, and that in a variety of strains examined there is a common mechanism regulated by ethylene, beyond the difference of sexual modes.     

Locomotion of Physarum polycephalum amoebae is guided by a short range interaction with E. coli

Studies of the behavior of Physarum polycephalum amoebae have shown that locomotion of these cells is guided by surfaces composed of aggregated bacteria. Amoebae move readily on both E. coli and agar surfaces. However, when a cell migrating on bacteria encounters an edge of the bacterial surface, the orientation of cell movement changes so that the cell maintains contact with bacteria. Time-lapse cinemicrographic studies employing wild type and mutant cells show that this behavior involves short range interactions between amoebae and bacteria, that it is not dependent on variations in the rate of phagocytosis, and that it is not a simple result of constraints on cell movement imposed by adhesive bonds between amoebae and bacteria. These results provide evidence that guidance of cell locomotion depends on active regulation of the cellular force generating system as the amoebae contact surfaces of varying characteristics and, therefore, suggest that this system is amenable to detailed studies of process involved both in cell-cell recognition and in linking such recognition to regulation of cell movement.     

Techniques and Marker Genes for Use in Macrocyst Genetics with POLYSPHONDYLIUM PALLIDUM

Previous work has shown that genetic exchange occurs in the macrocyst of Polysphondylium pallidum, as in species of Dictyostelium. These studies are extended here. Mutants resistant to six different poisons have been isolated for use as genetic markers. A replica-plating technique has been engineered whereby 14 progeny clones growing on a master plate may be simultaneously transferred to test plates containing individual poisons. Germination percent of macrocysts has been greatly increased by the presence of a growing fungus during the resting stage. These means have been used to analyze crosses showing that: (1) Vegetative amebae are haploid, at least at the three marker loci tested. (2) Amebae emerging from a single macrocyst are identical about 90% of the time. (3) Any single combination of parental markers may emerge from a given macrocyst, and all combinations appear in approximately equal frequencies. These findings suggest that normally one of four nuclei produced by meiosis survives in every macrocyst and that all markers examined are unlinked. (4) About 10% of the macrocysts germinate to give two or more classes of progeny. These may result from the presence of a second zygote in the macrocyst or from the survival of two nuclei after meiosis. (5) If genetic exchange occurs during spore formation or microcyst formation, its frequency is low (<0.01%).     

Social amoebae mating types do not invest unequally in sexual offspring

Unequal investment by different sexes in their progeny is common and includes differential investment in the zygote and differential care of the young. The social amoeba Dictyostelium discoideum has a sexual stage in which isogamous cells of any two of the three mating types fuse to form a zygote which then attracts hundreds of other cells to the macrocyst. The latter cells are cannibalized and so make no genetic contribution to reproduction. Previous literature suggests that this sacrifice may be induced in cells of one mating type by cells of another, resulting in a higher than expected production of macrocysts when the inducing type is rare and giving a reproductive advantage to this social cheat. We tested this hypothesis in eight trios of field‐collected clones of each of the three D. discoideum mating types by measuring macrocyst production at different pairwise frequencies. We found evidence that supported differential contribution in only two of the 24 clone pairs, so this pattern is rare and clone‐specific. In general, we did not reject the hypothesis that the mating types contribute cells relative to their proportion in the population. We also found a significant quadratic relationship between partner frequency and macrocyst production, suggesting that when one clone is rare, macrocyst production is limited by partner availability. We were also unable to replicate previous findings that macrocyst production could be induced in the absence of a compatible mating partner. Overall, mating type‐specific differential investment during sex is unlikely in microbial eukaryotes like D. discoideum.     

Aggregation during sexual development in Dictyostelium discoideum.

A microcinematographic analysis of the behaviour and movements of cells and cell masses in mated cultures (NC4 X VI2) of Dictyostelium discoideum indicates that a chemotactic process directs cell aggregation during macrocyst development. Zygote giant cells form before aggregation begins and act as the aggregation centres. Young multicellular macrocyst stages are sources of cyclic AMP, and amoebae from macrocyst cultures orient chemotactically to cyclic AMP. The data, coupled with other characteristics such as pulsatile streaming, suggest that the aggregation process leading to macrycyst development is the same as that occurring during fruit construction. Other aspects of sexual development are also discussed. Based upon these data, we propose a model for the sequence of events leading to macrocyst development in D. discoideum.     

Induction of Macrocyst Formation by Factors Secreted by Giant Cells in Dictyostelium discoideum

The fusion of cells of complementary mating types to produce giant cells has been shown to be the critical event to induce macrocyst formation in Dictyostelium discoideum. We have examined the way in which giant cells use diffusible factors to influence the developmental mode of nearby cells using an experimental design in which NC4 cells are allowed to develop on a dialysis membrane above a suspension of giant cells. We have observed that giant cells are able to inhibit independent aggregation and stream formation in the upper cells and become the dominant aggregation centers. In addition giant cells are able to redirect local amoeba away from the fruiting-body and toward the macrocyst mode of development. We show that these effects are mediated by diffusible factors of under 2,000 MW. and discuss possible mechanisms of action.     

Nuclear fusion in multinucleated giant cells during the sexual development of Dictyostelium discoideum

Macrocyst development in Dictyostelium discoideum, is generally considered a sexual phase. This development is initiated by the formation of a giant cell, the result of the fusion of two different mating type haploid cells, such as NC4 and HM1. The giant cell engulfs unfused surrounding cells to develop into a macrocyst. Therefore, if the macrocyst is a sexual structure, the giant cell must be a diploid zygote. However, under certain conditions, a very large multinucleated giant cell containing several dozens of nuclei is formed, followed by normal development into a macrocyst. In such a multinucleated giant cell, it was found that only two nuclei fuse together to produce a diploid zygote and all others disappear at the early stage of development. The diploid nucleus undergoes meiosis and subsequently subdivides into a number of haploid progeny cells later released from the macrocyst to initiate new life cycles.     

Regulation of the developmental modes in Dictyostelium mucoroides by cAMP and ethylene

The cellular slime mold Dictyostelium mucoroides-7 (Dm7) and a mutant (MF1) derived from it exhibit clear dimorphism in development depending upon environmental conditions: macrocyst formation occurs during the sexual cycle, and sorocarp formation during the asexual process. As previously reported, exposure of cells to ethylene gas is favorable to macrocyst formation, while exogenously added 3',5'-cyclic adenosine monophosphate (cAMP) induces sorocarp formation. The significance of ethylene and cAMP for the mechanism involved in selection of the developmental pathways was further confirmed by determining the amounts of these substances in macrocyst- or sorocarp-forming cells. Aminooxy-acetic acid (AOA), an inhibitor of ethylene synthesis, was found to switch development of Dm7 and MF1 cells from macrocyst to sorocarp formation by decreasing ethylene production. The cAMP content was shown to be always higher in cells destined for sorocarp formation than in those destined for macrocyst formation, particularly at the aggregation stage. All of the results obtained strongly suggested that the amounts of cAMP and ethylene present, and possibly the ratio between them, may be of great importance for determining which mode of development will be realized.     

Protein Synthesis Initiated by Cell Fusion in Dictyostelium discoideum

D. discoideum has two alternative developmental pathways. If cells of two complement mating-type strains, NC4 and HM1, fuse sexually, a giant cell is produced which subsequently develops into a macrocyst, the sexual structure of this organism. However, if fusion fails to occur and cells are starved, a fruiting-body is produced instead of a macrocyst. In this paper, a two-dimensional polypeptide gel electrophoresis study showed that giant cells produce specific polypeptides which may possibly be involved in macrocyst development. Out of total 497 polypeptides which appeared in a giant cell during an incubation period of 13 hr, 92 were the specific for giant cells. Four of these polypeptides were appeared within only 1 hr after the cell fusion. The other 405 were non-specific polypeptides which appeared in both giant cells and NC4 or/and HM1 cells. However, the patterns and the rates of production of each polypeptide during the incubation period were different between these cells.     

Ethylene as a potent inducer of sexual development

A novel and critical function of ethylene, a potent plant hormone, has been well documented in Dictyostelium, because it leads cells to the sexual development (macrocyst formation) by inducing zygote formation. Zygote formation (sexual cell fusion) and the subsequent nuclear fusion are the characteristic events occurring during macrocyst formation. A novel gene, zyg1 was found to be predominantly expressed during the sexual development, and its enforced expression actually induces zygote formation. As expected, the zygote inducer, ethylene enhances the expression of zyg1. Thus the function of ethylene has been verified at all of individual (macrocyst formation), cellular (zygote formation), and molecular levels (zyg1 expression). Based on our recent studies concerning the behavior and function of the zyg1 product (ZYG1 protein), the signal transduction pathways involved in zygote formation are proposed in this review.     

Lectin binding and inhibition studies reveal the importance of D-glucose, D-mannose and N-acetylglucosamine during early sexual development of Dictyostelium discoideum

Fluorescein-conjugated and non-conjugated lectins were used to determine which surface sugars are involved in the early events of sexual (macrocyst) development in Dictyostelium discoideum. Only zygote giant cells showed unique binding of FITC-WGA and FITC-PNA while all cell types (amoebae, gametes, binucleates, giant cells) showed identical patterns of FITC-Con A, -Gorse and -RCA II binding. In spite of its non-selective labelling of all cell types, Con A inhibited macrocyst formation. The temporal addition of Con A with and without specific hapten sugars indicates the importance of both D-mannose and D-glucose in phagocytosis and, possibly, cell fusion. WGA also inhibited macrocyst formation. Varying the time of addition of the lectin plus/minus its primary hapten sugar implicates N-acetylglucosamine as being important in cell fusion. Neither Gorse, RCA II nor PNA had any detectable inhibitory effects on macrocyst development leaving the appearance of increased PNA receptors at the giant cell surface as an enigma.     

Synthesis of specific proteins for sexual development in Dictyostelium discoideum

The development of Dictyostelium discoideum may proceed by two pathways, macrocyst or fruiting-body formation, the former being the sexual and the latter the asexual cycle. The pathway of development depends on the presence or absence of zygote giant cells which are produced through fusion of opposite mating-type cells in a population, in heterothallic strains. During the early stages of macrocyst development the patterns of developmentally regulated proteins were noted to differ considerably from those during fruiting-body development. Furthermore, the haploid cells around zygote giant cells synthesized a large number of specific proteins for macrocyst development through the influence of giant cells.     

Locomotion and feeding of Acanthamoeba at the water-air interface of ponds

Acanthamoeba trophozoites attach to and effect amoeboid locomotion at the water-air interface of ponds. Their locomotory rate (approximately 0.8 microm s(-1)) and manner of independent movement at this interface is similar to that over solid substrata. Adhesion forces developed between amoebae and the water-air interface are greater than gravity and thus amoebae are also transported passively without detachment. Amoebae docked with the water-air interface remain and flourish here as they are shown, by using green fluorescent protein-labelled Aeromonas hydrophila, to feed on bacteria that occur at the interface, digesting them intracellularly.     

The developmental capacity of various stages of a macrocyst-forming strain of the cellular slime mold, Dictyostelium mucoroides.

Vegetative cells of certain strains of Dictyostelium mucoroides form fruiting bodies on an agar surface and macrocysts when placed under saline. This study sought to determine whether the aggregation and pseudoplasmodial stages of fruiting body formation could be induced to form macrocysts when placed under saline. Likewise, different stages in macrocyst formation were put on an agar surface to determine their potential to switch to fruiting body formation. It was found that 78% of the aggregates and 21% of the pseudoplasmodia placed under saline formed macrocysts indicating that as fruiting body development proceeds, there is a restriction of the capability of cells to respond to environmental conditions favoring macrocyst formation. Stages in macrocyst development prior to the formation of precysts always formed fruiting bodies when put on agar. Once precysts had formed, surrounded by their acellular sheath, they always developed as macrocysts on agar. Peripheral cells isolated from precysts and put on agar quickly aggregated; the aggregates became surounded by a sheath and developed as macrocysts. If isolated peripheral cells were allowed to proliferate on the agar surface, the resulting cells aggregated and formed fruiting bodies.     

The effect of light on morphogenesis of Dictyostelium mucoroides

The effect of light on the production of macrocysts and sorocarps of Dictyostelium mucoroides, strain DM-7, has been studied with surface cultures grown on dilute lactose-peptone agar at 22 degrees C with Escherichia coli, strain B/r, as food bacteria. The production of sorocarps or macrocysts can be controlled by altering the light component of the environment. Far red light had no effect on macrocyst production, whereas visible light from 440 to 700 nm inhibited macrocyst production with production decreasing with increasing light intensity. Fluence response curves for macrocyst production were determined for twelve wavelengths of light between 400 and 700 nm. An action spectrum calculated from the fluence response curves shows a single major peak at about 425-430 nm.     

A novel cyclic AMP metabolism exhibited by giant cells and its possible role in the sexual development of Dictyostelium discoideum

In Dictyostelium discoideum cyclic AMP (cAMP) metabolism during macrocyst development, i.e., the sexual cycle of this organism, and in giant cells, i.e., fusion products from opposite mating-type cells, was investigated. The pattern of change in cAMP levels during macrocyst development differed considerably from that observed during fruiting-body formation, i.e., the asexual cycle. Giant cells produced and excreted considerable amounts of cAMP. Adenylate cyclase activity catalyzing cAMP production in giant cells was comparable to that of unfused cells. However, the activity of membrane-bound phosphodiesterase in giant cells was extremely low, and no extracellular phosphodiesterase was excreted. A phosphodiesterase inhibitory protein was secreted in excess by giant cells.     

Motory effects of perforating peripheral cell layers ofAmoeba proteus

Summary Perforation of peripheral cell layers ofA. proteus in any place provokes immediate endoplasm efflux, what supports the view that the hydrostatic pressure is higher in the cell interior than outside. The local effusion of endoplasm results in the reversal of flow in formerly advancing pseudopodia, in agreement with the pressure gradient theories of protoplasmic streaming. Amoebae with destroyed frontal zones squeeze all their endoplasm out through the breach, what disproves the frontal contraction hypothesis of amoeboid movement, but supports the concept of a general contraction of cell cortex.Study supported by the Research Project II.1 of the Polish Academy of Science.     

MACROCYSTS IN THE LIFE CYCLE OF THE DICTYOSTELIACEAE. I. FORMATION OF THE MACROCYSTS

Macrocysts, a morphogenetic phase that is alternative to sorocarp formation in the life cycle of some cellular slime molds, are known for two genera and five species of the Dictyosteliaceae. In all of these macrocyst formation was found to be strongly affected by four factors: light, temperature, moisture, and the composition of the medium. In general, macrocyst formation was suppressed and sorocarp formation was enhanced by exposure to light, by incubation at temperatures lower than 20 C, by buffering nutrient media with phosphates, and by reducing atmospheric moisture through the use of clay covers on Petri dishes. The extent to which these environmental factors, singly or in combination, inhibited the production of macrocysts varied among the different strains and species.