Cell Patterning During Slug Migration and Early Culmination in Dictyostelium discoideum

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

Ultrastructural Changes During Germination of Dictyostelium discoideum Spores

Spores of Dictyostelium discoideum undergo significant changes in fine structure during germination. The mitochondria progressively become less dense and lose their peripherally attached ribosomes, and the tubuli become more pronounced as germination proceeds. During this period, the three-layered spore wall breaks down in two stages: first, the outer and middle layers are ruptured as a unit, and, second, the inner wall is breached. Crystals and dark (lipid) bodies disappear shortly before or during emergence of the myxamoebae. Autophagic vacuoles are found in dormant spores and throughout the entire germination process. The addition of cycloheximide to germinating spores inhibited the loss of the crystals and dark (lipid) bodies. In addition, the drug inhibited the breakdown of the inner wall layer. Cycloheximide did not prevent the formation of the water expulsion vesicle or the apparent function of the autophagic vacuoles.     

Changes in phospholipid composition during the development of Dictyostelium discoideum

The phospholipid composition of Dictyostelium discoideum cells was determined at various stages of development by two-dimensional, thin-layer chromatography and reaction thin-layer chromatography. Major phospholipids of D. discoideum which were detectable throughout all stages of development were ethanolamine phosphoglyceride and choline phosphoglyceride. Ethanolamine phosphoglyceride and choline phosphoglyceride were found as their plasmalogen forms at 45–58 and 10–24%, respectively. There were no qualitative changes in phospholipid composition during the development, but quantitative changes did occur. The relative content of ethanolamine phosphoglyceride in the total phospholipids gradually decreased from 60% at the vegetative stage to 44% at the 1-day-sorocarp stage. In contrast, choline phosphoglyceride gradually increased from 27% at the vegetative stage to 48% at the preculmination stage, and then gradually decreased to 43% during the culmination. The decrease in ethanolamine phosphoglyceride content during the middle and late development was due mainly to the decreased amount of its plasmalogen form but the increase of choline phosphoglyceride was independent of quantitative changes of its plasmalogen form. Other minor components of phospholipid did not show significant changes in their levels. The causes of these changes in contents of ethanolamine phosphoglyceride and choline phosphoglyceride were examined by label and chase experiments with [³H]ethanolamine and [¹⁴C]choline. It seems that one-third to one-half of the increased amount of choline phosphoglyceride was due to stepwise methylation of ethanolamine phosphoglyceride, and the remaining two-thirds to one-half was caused by de novo synthesis of choline phosphoglyceride from CDP-choline and diglyceride.     

Control of Late Development of Dictyostelium discoideum by Proteins Functioning at Early Stages

We examined two mutants of D. discoideum which are temperature-sensitive for development. At the nonpermissive temperature one mutant becomes arrested in development during the transition from the finger to the migrating slug. Temperature-shift experiment indicates that the temperature-sensitive period begins at considerably earlier tip-forming stage. The other mutant becomes arrested at the Mexican hat stage and the temperature-sensitive period coinsided with this stage. The analysis of protein synthesis by two-dimensional gels, however, showed specific changes at the nonpermissive temperature at an earlier finger-forming stage.
These results indicate the presence of a control of late development by proteins at early stages.     

The glycoproteins of Dictyostelium discoideum. Changes during development.

The glycoproteins of D. discoideum have been analyzed by direct binding of radio-iodinated lectins to SDS gels of the successive developmental stages. Compared with the total pattern of proteins, many changes are found in the glycoproteins during development. WGA reacts with few gel bands from the vegetative cells and most of these, including a very intense band at the top of the gel, are lost during the first few hours of development. Approximately half-way through the developmental cycle at least 14 new glycoproteins reacting with WGA begin to appear and progressively accumulate. In contrast, ConA labels many glycoproteins over the complete molecular weight range and most are unaffected during development. Lectins which bind fucose label a single component at the top of the gel of vegetative cells and this decreases rapidly as development begins. No other reactive gel bands are revealed by fucose-binding lectins until the final stages of spore and stalk formation, when four high molecular weight glycoproteins are detected. Lectins specific for terminal galactose residues and for N-acetyl-galactosamine, including the intrinsic lectins produced by D. discoideum during its development, failed to reveal any reactive glycoproteins.     

Changes in the polyadenylated messenger RNA population during development of Dictyostelium discoideum

The program of gene expression during the life cycle of Dictyostelium discoideum has been assessed by molecular hybridization of cDNA probes with polysomal RNA extracted at the following different stages of development: vegetative growth, interphase (2.5 hr), aggregation (8 hr), postaggregation (12 hr), and preculmination (18 hr). Several different cDNA probes were used. Two probes were prepared from vegetative stage poly(A⁺) RNA, one representing all species present and the other enriched for abundant species. A third cDNA probe was prepared from preculmination stage polysomal RNA and a fourth probe consisted of the preculmination stage cDNA depleted in those species also present at the vegetative stage. Hybridization of the various probes with the different polysomal RNA preparations has revealed developmental changes in the mRNA populations. These changes were not detected in an aggregation less mutant under similar conditions of starvation. Abundant RNA species of vegetative cells were found to drop to low levels, especially during the aggregation period. Fifty percent by mass of the RNA present in polysomes at 18 hr is not present during vegetative growth. Some of the new RNA species appeared during interphase and the remaining during the postaggregation period. A gradual increase in the number of copies per cell of certain RNA species comprising both new species as well as some shared with vegetative cells was observed throughout development. Other results indicated that the composition of polysomal and cytoplasmic RNA is similar during vegetative growth but differs markedly at 18 hr of development. Also, cytoplasmic RNA at 18 hr contained, in addition to polysomal RNA, a large proportion by mass of nonpolysomal RNA similar to vegetative RNA. The number of polysomal RNA species detected by this analysis during vegetative growth and during the preculmination stage were estimated to be 3000 and 3700, respectively. The number of copies of these RNA species ranged between 30 and 2000 per cell during vegetative growth and 3 to 300 per cell in polysomes at 18 hr. Developmentally induced RNAs which were preferentially distributed among abundant and intermediate classes were estimated to number 700–900 species.     

Changes of plasma membrane proteins during prespore differentiation in Dictyostelium discoideum

By the use of a shake culture system, we have previously shown (Oyama, M., Okamoto, K., & Takeuchi, I. (1982) J. Cell Sci. 56, 223-232) that both cAMP and cAMP-dependent cell contact are required for prespore differentiation in Dictyostelium discoideum. The present study was undertaken to examine changes of the plasma membrane proteins during prespore differentiation in the shake culture system. Rabbit antibodies prepared against the plasma membrane fraction of the differentiated cells inhibited the reaggregation of the differentiated cells but not that of aggregation-competent cells. This result indicates that new contact sites are formed in the differentiated cells. By the combined use of the antibody-conjugated immuno-adsorbent with sodium dodecyl sulfate-polyacrylamide gel electrophoresis, changes of membrane proteins were analyzed with the cells incubated under various conditions. Three proteins were found to be present specifically in the differentiated cells only in the presence of cAMP, one of which (105K protein) appeared when cells became adhesive, but before prespore specific proteins were detected. Two others (80K and 58K proteins) appeared during prespore differentiation after cells formed agglomerates.     

Changes in cellular adhesiveness during the development of the slime mold Dictyostelium discoideum

A method was devised to measure the adhesiveness to the substratum of the amoebae of the cellular slime mold, Dictyostelium discoideum, and measurements were conducted with the cells at various stages of development. The adhesiveness of the vegetative amoebae was low, and remained unchanged as long as they fed on bacteria. During the transition from the vegetative stage to the interphase (due to the cessation of feeding), the adhesiveness increased rapidly, and afterwards continued to rise, as development proceeded. The adhesiveness of the interphase amoebae was greatly decreased by the treatment with proteolytic enzymes, lipase, and acid phosphatase. These indicate that accumulation of some substance(s) such as lipoprotein on the cell surface is responsible for the increase in adhesiveness during the interphase. EDTA and periodic acid had no noticeable effect on the adhesiveness of the interphase amoebae. EDTA, however, decreased the adhesiveness in co-operation with trypsin or lipase. The cells disaggregated from the anterior part of the migrating slug showed higher adhesiveness than those from the posterior part. The adhesiveness of either cells was higher than that of the interphase amoebae.     

Phagocytosis and Exocytosis by Differentiating Dictyostelium discoideum Cells

While vegetative cells of the cellular slime mold Dictyosteliumdiscoideum engage in active phagocytosis, cells isolated frommigrating slugs of this organism were found to be almost lackingin this activity. However, when incubated under sparsely populatedconditions, these cells regained the phagocytic ability as theylost prespore specific antigen and dedifferentiated. Changesin phagocytic activity during the development were quantitativelyexamined. After cessation of feeding, phagocytic activity ofcells first increased but shortly afterward decreased rapidly,together with the initiation of aggregation. The loss of phagocyticability of a cell was accompanied by a change in cell shapefrom an isodiametric to an elongate form, as the cell becameaggregation competent. During such a transition, polystyrenebeads which had been ingested and retained by the cell wereexocytized. ¹ This paper is dedicated to the memory of Prof. Joji Ashida. (Received December 17, 1982; Accepted February 18, 1983)     

Ultraviolet Irradiation of the Vegetative Cells of Dictyostelium discoideum

Experiments on the effect of ultraviolet (UV) light on the survival of vegetative Dictyostelium discoideum cells indicate that this is a relatively UV-resistant organism. Several factors suggest the presence of some type of repair process. Experiments to test for liquid-holding recovery and simple photoreactivation yielded negative results. Acriflavine and caffeine were utilized to possibly interfere with dark repair. Acriflavine produced no UV sensitization, but caffeine did cause a concentration-dependent decrease in survival of irradiated cells. When UV-irradiated cells were illuminated with photoreactivating light while suspended in caffeine, the survival increased above that for cells treated with caffeine alone, suggesting an overlap between lesions repaired by photorepair and dark repair. Growth experiments showed that UV light induced a dose-dependent division delay, followed by a period of retarded growth characterized by the presence of a constant fraction of nonviable cells in the irradiated population. The delayed exposure of cells to caffeine after irradiation showed that the magnitude of the caffeine sensitization diminished throughout the division-delay period. An action spectrum indicated probable nucleoprotein involvement in the induction of division delay. UV light retarded ribonucleic acid and protein synthesis and temporarily blocked deoxyribonucleic acid synthesis. However, synthesis of all three accelerated prior to the end of the division-delay period and then closely paralleled the increase in cell number.     

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.     

Changes in the Cell Surface Level of GP126 during Development of Dictyostelium discoideum

The developmental regulation of the vegetative cohesion molecule, gp 126, has been monitored in the cellular slime mould Dictyostelium discoideum. As judged by immunoprecipitation using an anti-vegetative cell, cohesion blocking antibody, gp126 persisted until at least the grex stage of development although a decline in the level of the molecule was observed thereafter. Further, after the grex stage, cells showed an increasing loss of ability to absorb the cohesion-blocking effect of an anti-vegetative cell Fab. Therefore, the decline of gp 126 could be ascribed to a loss from the cell surface. By radio-iodination of vegetative cells followed by liquid-scintillation counting of gp 126, developmental-regulation could be determined quantitatively.
At the grex stage of development, whole aggregates were embedded in wax. Longitudinal sections were then stained with a monospecific anti-gp 126 Fab, followed by a fluorescent sheep anti-rabbit IgG. Fluorescence was observed only at the tip (the prestalk) region, thereby showing that gp 126 is a prestalk marker.
To confirm the above result, grexes were dissociated and cells were separated into prespore and prestalk populations on a gradient of Percoll. Prestalk but not prespore cells were able to absorb the cohesion-blocking effect of an anti-vegetative cell Fab.
To examine the biosynthesis of gp 126, cells were pulsed with radioactive glucosamine, mannose or acetate. The pattern of incorporation of radioactivity suggested that the de novo synthesis of gp 126 ceases upon commencement of development.     

盘基网柄菌(Dictyostelium discoideum)吞噬作用中肌动蛋白多聚化及其调节

肌动蛋白是盘基网柄菌(Dictyostelium discoideum)细胞吞噬过程中的关键组分,通过其细胞内的定位和多聚化形式在确定的时间和地点连接特定的分子,使吞噬过程得以完成。profilin是肌动蛋白多聚化的重要调节分子,在磷脂酰肌醇信号转导与细胞骨架相交处起关键作用。许多小分子G蛋白参与细胞骨架调节,CAP蛋白是两者间重要连接分子。所以,吞噬作用是细胞内诸分子协同作用的结果。     

Changes of Endocytotic Activities during the Cell Cycle of Dictyostelium Cells

Changes of endocytotic activities during the cell cycle of the cellular slime mould Dictyostelium discoideum Ax-2 were examined using the temperature-shift method for inducing synchronous growth. The activity of fluid-phase pinocytosis (FPP) was altered Ca²⁺-dependently and stimulated by EGTA. On the other hand, pinocytosis was greatly enhanced by addition of Bacteriological-peptone(BP) to the growth medium for Ax-2 cells, irrespective of the extracellular Ca²⁺-concentration. The maximal pinocytotic activity was attained in the presence of EGTA plus BP, the effects of the two substances being additive. The FPP activity was found to be high in cells in and just after the S phase, when the BP-induced fraction of pinocytosis was rather low. Thus the total activity for pinocytosis in the growth medium remained almost constant throughout the cell cycle, indicating that the rate of nutrient uptake through pinocytosis was not a limiting factor for cell cycle regulation. The change of phagocytotic activity during the cell cycle was somewhat similar to that of the FPP activity. Possible mechanisms of such cell-cycle related changes are discussed in relation to cytoskeletal proteins in the cell cortex. Some properties of BP-induced pinocytosis are also described.