MACROCYSTS IN THE LIFE CYCLE OF THE DICTYOSTELIACEAE. II. GERMINATION OF THE MACROCYSTS

Macrocyst germination was demonstrated in the five species of the Dictyosteliaceae known to produce these structures. The morphological changes that occurred during germination appeared to be identical in all of the strains examined, showing the following stages: (1) swelling of the dark, contracted content of the dormant cysts, (2) gradual loss of color and reappearance of cells within what previously appeared as a homogeneous protoplasmic mass, and (3) rupture of the heavy cellulosic cyst wall to liberate the myxamoebae. The age of the macrocyst appeared to be the most critical factor in determining whether or not germination would occur, since the cysts in many of the strains needed to age for several weeks or months before germination could be demonstrated. In Dictyostelium mucoroides strain DM-7, upon which the current study was centered, light was necessary to stimulate germination of young macrocysts—a requirement that gradually diminished as the cysts aged. The rate of germination and the temperature permitting germination were also age dependent: older macrocysts germinated more rapidly and at considerably higher temperatures than did young cysts. Although light was not essential for germination in every strain, the results obtained with strain DM-7 seem to be generally applicable to the germination process.     

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.     

ENZYMATIC DISSOCIATION OF NASCENT MACROCYSTS AND PARTITION OF THE LIBERATED CYTOPHAGIC GIANT CELLS IN DICTYOSTELIUM MUCOROIDES*

Nascent macrocysts of the cellular slime mold Dictyostelium mucoroides were dissociated enzymatically and the liberated cytophagic giant cells were partitioned by dextrin density gradient centrifugation. Enzymatic and cytochemical studies revealed that the primary wall is composed mainly of cellulose (β-1,4-glucan) associated with polysaccharides including hemicellulose, pectic substances and á-1,4-glucan. The buoyant density of the liberated cytophagic giant cells and peripheral cells was determined by density gradient centrifugation, and partitioning of the cells was possible due to the difference in this property. The process of macrocyst reconstitution was investigated using dissociated cells. The isolated cytophagic giant cell has a specific affinity for other cytophagic giant cells and predominantly ingests them by phagocytosis, while it retains the ability to ingest peripheral cells. The present study provides a clue for investigating the differentiation and development of sexual cells, since only the cytophagic giant cell gives rise to a zygote in macrocyst formation.     

THE EFFECTS OF LIGHT ON THE DEVELOPMENT OF THE CELLULAR SLIME MOLD ACRASIS ROSEA

No fruiting of the NC-18 isolate of Acrasis rosea occurs in cultures maintained in continuous light or in continuous dark. The use of different food organisms does not alter the aforementioned behavior. The time at which fruiting occurs in this isolate can be regulated by administering stimulatory light followed by a dark period. Mature sorocarps are formed approximately 14 hr after the termination of light and the start of darkness. Within this 14-hr interval aggregation and sorocarp development occur. After about 6 hr of dark incubation, NC-18 amebae, previously stimulated by light, form a few weak aggregation centers. After 8 hr of dark incubation there are numerous aggregation areas, large in size and deep rose in color. By 10 hr the aggregations are quite compact and firm in appearance, and between 12 and 14 hr late aggregations, sorogens and, finally, mature sorocarps are formed. The minimum dark period, i.e., the minimum time that is required in darkness (for cultures previously stimulated with light) to obtain at least some fruiting within the 14-hr developmental period, is 7–8 hr for NC-18 and 5–6 hr for Tu-26. Maximum numbers of sorocarps form when cultures are given 10–11 hr of uninterrupted dark. Light-stimulated cultures of NC-18 placed in darkness and interrupted by a 10- or 30-min exposure to wide-spectrum blue or cool white fluorescent light an hour prior to the minimal dark period exhibit a 4–5 hr-delay in fruiting when returned to darkness and inspected at intervals following the second irradiation. Growth and fruiting of NC-18 occurred with purified food sources of each of five different species of Chlorella and with the alga Stichococcus bacillaris. This is apparently the first report of the utilization of algae as food sources by a cellular slime mold. Fruiting of NC-18 was readily arrested by lowering the relative humidity to 40–45%. This change in the moisture content of the surrounding air induced microcyst formation. Growth on buffered medium occurred in the entire pH range tested, 3.5–7.6, but fruiting occurred only between pH 5.0 and 6.6.     

Involvement of cytoplasmic pH in the production of ethylene,a potent inducer of sexual development inDictyostelium mucoroides

Summary Dictyostelium mucoroides-7 (Dm 7) and a mutant MF 1 derived from it exhibit two developmental pathways: sorocarp formation occurs during the asexual process, and macrocyst formation during the sexual cycle. The two developmental pathways are mainly regulated by two chemical substances: 3,5-cyclic adenosine monophosphate (cAMP) and ethylene. Recently, we have demonstrated that cytoplasmic pH (pH_i) has a critical role for the choice of developmental pathways, higher pH_i being favourable to macrocyst formation. Thereupon, attention was riveted to the relation of pH_i to biosynthesis of cAMP and ethylene. Effect of pH_i on the production and release of ethylene, a potent inducer of macrocyst formation, was examined, using the two facing culture method. The result showed that lowered pH_i inhibits ethylene production, thus resulting in a failure of cells to form macrocysts. The accumulation of cAMP, an inhibitor of macrocyst formation, was found to vary depending on extracellular pH (pH_o), but diethylstilbestrol (DES) that is a proton pump inhibitor and also an inhibitor of macrocyst formation had no significant effect on the accumulation. Taken together these results indicate that higher pH_i may induce macrocyst formation through enhancement of ethylene production rather than inhibition of cAMP synthesis.Abbreviations cAMP 3,5-cyclic adenosine monophosphate - pH_i cytoplasmic pH - pH_o extracellular pH - ACC 1-1-aminocyclopropane-1-carboxylic acid     

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.     

ENVIRONMENTAL FACTORS AND THE GROWTH OF NATIVE ORCHIDS

The environments in which native orchids grow were examined in terms of factors which might determine the survival and reproduction of the various species. Soil tests were made for 34 species now known to be growing in Rhode Island. Soil reaction appears to be related to growth of orchids, but other factors in the environment were found to be of equal if not greater importance. These include light, moisture, temperature and destruction by animals. Fertility was not found to be limiting under the conditions observed.     

STUDIES ON THE ECOLOGICAL AND PHYSIOLOGICAL SIGNIFICANCE OF AMPHICARPY IN GYMNARRHENA MICRANTHA (COMPOSITAE)

The 2 types of fruit (aerial and subterranean) borne by the dwarf desert annual Gymnarrhena micrantha were compared with regard to their responses to factors affecting their formation, dispersal, germination and seedling mortality. The 2 types of fruit differed markedly in several respects. In comparison with the subterranean fruits, the aerial ones are much smaller and more numerous, but the formation of the inflorescence in which they develop is more dependent on a favorable supply of soil moisture. The aerial fruits are dispersed by wind, after becoming detached by a complex series of hygroscopic movements which involve several organs and tissues, while the subterranean fruits never leave the dead parent plant, germinating right through its tissues. Germination of the subterranean fruits starts after a shorter incubation period and is less temperature-dependent in both light and dark. Light stimulated germination of both types of fruit, increasing their germination rates and final percentages, but not affecting the duration of the incubation period. In the subterranean fruits, the rate of germination was equally stimulated by light over the entire temperature range, with a well-defined optimum at 15 C in both light and dark. In the aerial fruits, the same optimum was found only in the light, rates in darkness increasing with decreasing temperatures. In the aerial fruits, alternations of light and dark were more favorable to germination than either continuous light or dark, the full effect being obtained with a single 8-hr or 16-hr light period, provided it was preceded by 16 or 8 hr of darkness, respectively. Similar reactions to combinations of light and dark were not observed in the subterranean fruits. Seedlings developing from the subterranean fruits were much larger, but grew at a relatively much slower rate than those from aerial fruits. The former were distinctly more tolerant of unfavorable soil-moisture regimes, such as low moisture supply and drought. It was concluded that the 2 types of fruit serve 2 distinct functions in the biology of the plant. The aerial fruits are adapted to the function of increasing the distribution of the species within suitable habitats, while the subterranean fruits are adapted to increasing the probability of the survival of the species.     

A DEVELOPMENTAL STUDY OF GUTTULINOPSIS VULGARIS (ACRASIALES)

The cellular slime mold, Guttulinopsis vulgaris E. W. Olive, is a common and widely distributed species. Its myxamoebae have lobose pseudopodia and aggregate, not by streaming, but by movement singly or in small groups into the aggregation center. The resulting shield-shaped pseudoplasmodium gives rise to one (or possibly more on occasion) whitish, simple or compound sorocarp. Sorocarps are 95–465 μ in height, typically with relatively short, stout stalks and with mucilaginous spore heads that measure 75–350 μ broad. The spores are mostly irregular, with flattened or concave sides, and are surrounded by a thin spore wall. They measure 3.8–9.2 μ diam., or 2.6–7.8 × 3.9–9.2 μ. During sorocarp development the myxamoebae become grouped within membranous compartments both in the sorocarp and pseudoplasmodium. In the upper part of the sorocarp they develop almost entirely into spores, while in the lower stalk region of the sorocarp and in the pseudoplasmodium, some myxamoebae develop into spores while others degenerate. The phylogenetic position of Guttulinopsis is unclear, but the genus is probably not closely related to the Dictyosteliaceae. This investigation has been supported by National Science Foundation Grants G–44263 and GB-501. The writer is grateful to Miss Carmen Stoianovitch for her assistance.     

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.     

A NATURALLY OCCURRING DEVELOPMENTAL SYNERGISM BETWEEN THE CELLULAR SLIME MOLD,DICTYOSTELIUM MUCOROIDES AND THE FUNGUS,MUCOR HIEMALIS

We here report the second record of a developmentally aberrant strain of a cellular slime mold from natural populations and demonstrate that this Dictyostelium mucoroides variant is capable of undergoing normal morphogenesis in the presence of the phycomycete fungus, Mucor hiemalis. The synergism is induced by an extracellular product(s) which is diffusable through thin agar membranes and is released by the fungus. The presence of the fungus not only induces stalk formation in this stalkless variant, but also increases the rate of sorocarp formation in 3 of 5 additional species of cellular slime molds assayed.     

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%).     

Polysphondylium multicystogenum sp. nov., a new dictyostelid species from Sierra Leone, West Africa

Polysphondylium multicystogenum, a new heterothallic species of dictyostelids, is described based on three isolates collected from soils in Sierra Leone, West Africa. This species is characterized by sorophores with a combination of clavate base and ovoid to oblong tip cell, smaller spores and abundant microcyst production under the usual culture conditions for sorocarp formation at 20 C. This is the first report of Polysphondylium producing such abundant microcysts.     

The Possible Involvement of Cyclic AMP and Volatile Substance (s) in the Development of a Macrocyst-Forming Strain of Dictyostelium mucoroides

A mutant MF1 previously isolated from Dictyostelium mucoroides -7 (Dm7) formed macrocysts with or without light when plated on agar at high cell dinsities. At lower cell densities, however, the MF1 cells formed only fruiting bodies. This failure to form macrocysts was shown to be due to the subthreshfold concentration of a volatile substance(s) required for macrocyst formation. Although ammonia is a volatile substance produced by both the Dm7 and MF1 cells, no evidence of its involvement in macrocyst formation was obtained. Mixing the Dm7 and MF1 in a one-to-one ratio resulted only in fruiting body formation suggesting that the Dm7 cells produced a factor which allowed MF1 cells to form fruiting bodies. This factor may be cyclic AMP (cAMP) since addition of cAMP to the medium directed development of MF1 cells to fruiting body formation. The effect of cAMP was exhibited most conspicuously when MF1 cells were exposed at the aggregation stage. Based on these results it is suggested that developmental pathway of the D. mucoroides macrocystforming strain Dm7 and its mutant MF1 may be determined by the relative concentrations of the volatile, macrocyst-inducing substance(s) and cAMP at the aggregation stage.     

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.     

环境因子对荒漠沙蜥种群密度影响的研究

本文研究人类改造荒漠的活动,植被,潜在的可利用的食物资源,竞争种的密度,土壤理化性质等坏境因子对荒漠沙蜥种群密度的影响。结果说明：人类的活动对沙蜥种群密度没有显著影响;决定沙蜥种群密度的主导因子是潜在的可利用的食物资源,植被,土壤含水量,竞争种的密度。这些因子的任何改变都能改变沙蜥的种群密度,均具有调节种群的作用。     

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.     

The ethylene action in the development of cellular slime molds: an analogy to higher plants

Summary The cellular slime moldDictyostelium mucoroides-7 (Dm 7) and its mutant (MF 1) exhibit sexual or asexual development depending upon culture conditions. During the sexual cycle macrocyst formation occurs, whereas sorocarps containing spores and stalk cells are asexually formed. As previously reported, the macrocyst formation is marked by the emergence of true zygotes, and is induced by a potent plant hormone, ethylene. The concentration of ethylene required for macrocyst induction was determined to establish the similarity of ethylene action between this organism and higher plants. Macrocysts are induced by low (1 l/l) exogenous concentrations of ethylene. Higher concentrations (10–1,000 ul/l) also gave essentially the same inductive activity. Ethionine, an analogue of methionine, was found to inhibit zygote formation during sexual development through its interference with ethylene production by Dm 7 and MF 1 cells. In fact, the inhibitory effect of ethionine was mostly nullified by the application of ethylene, S-adenosyl-L-methionine, or 1-aminocyclopropane-1-carboxylic acid. Taken together these results suggest that both the effective concentration of ethylene and the pathway of ethylene biosynthesis inD. mucoroides may be similar to those in higher plants. Ethylene was also found to be produced in various species and strains of cellular slime molds, even during the asexual process. The possible functions of ethylene in the asexual development are discussed in relation to cell aggregation and differentiation.Abbreviations SAM S-adenosyl-L-methionine - ACC 1-aminocyclopropane-1-carboxylic acid - AOA (aminooxy) acetic acid - BSS Bonner's salt solution - DAPI 4,6-diamidino-2-phenylindole     

Early seedling growth of pine (Pinus densiflora) and oaks (Quercus serrata,Q. mongolica,Q. variabilis) in response to light intensity and soil moisture

In climatic chambers seed germination and seedling growth of Pinus densiflora Sieb. et Zucc., Quercus serrata Thunb., Quercus mongolica Fisch. ex Turcz. and Quercus variablilis Bl. were investigated as functions of light intensity and soil moisture. In Korea these tree species occur widely and form mixed forests with different distributions. Species clearly differed in the pattern of germination and early seedling growth between light and soil treatments. The germination of pine did not differ between the experimental treatments until the breaking of the primary buds. After that, light intensity was the deciding factor for further development. In the most moist treatment (approx. field capacity) growth of the pine seedlings was strongly inhibited. For the three oak species, differences between experimental treatments first occurred after complete formation of primary leaves. Seed development strongly correlated with the weight of the acorn. The large seeded Q. variabilis (acorns with mean weight of 4.7 g) developed faster and reached larger dimensions towards the end of the experiment than Q. mongolica (2.8 g per acorn) and Q. serrata (0.9 g per acorn). Regarding height and biomass growth, the oak species showed a higher shade tolerance than pine. The proleptic shoot growth was clearly influenced by the light intensity. Root formation was favoured by a high exposure to light. In case of the oak species reduction of soil moisture increased the length of primary roots and the number of secondary roots.     

Possible existence of a light-inducible protein that inhibits sexual cell fusion in Dictyostelium discoideum.

Sexual cell fusion is an initial step of macrocyst formation in Dictyostelium discoideum and requires environmental conditions such as darkness, plenty of water and the presence of calcium ions. We have been analyzing the mechanism of sexual cell fusion between HM1 and NC4, heterothallic strains in D. discoideum. Cells of these strains have been shown to be fusion competent when cultured in a liquid medium in darkness, but not so when cultured on agar plates or in a liquid medium in the light. Two cell-surface proteins, gp70 and gp138, have been identified as target molecules for fusion-blocking antibodies and therefore as relevant to sexual cell fusion. In the present study, gp70 was shown to be present in HM1 cells cultured in the light, and fusion incompetent. Intact HM1 cells cultured in the light were unable to absorb the fusion-blocking activity of antibodies against membrane components of fusion-competent HM1 cells, whose activity had been shown to be absorbed by gp70, but they did so after separation of proteins in the SDS-PAGE. In addition, fusion-competent HM1 cells were found to lose their fusion competence by subsequent cultivation in the light. This loss of competence was cycloheximide sensitive, indicating that de novo synthesis of proteins was necessary for this inhibition. From these results, we presume that light induces a protein that hinders the interaction of gp70 in HM1 cells with its receptor on the NC4 cell surface and thereby inhibits the sexual process between these strains.