Zygote giant cell differentiation in Dictyostelium discoideum: biochemical markers of specific stages of sexual development.

Sexual development in Dictyostelium discoideum has many unique features making it an attractive eukaryotic model system for the study of biomembrane fusion and intercellular communication. The work presented here provides primary biochemical evidence for two distinct phases during early sexual development that appear to be defined by calcium-dependent gamete cell fusion. In addition, we introduce a novel procedure for the enrichment of zygote giant cells and use this method to define certain wheat-germ agglutinin binding glycoproteins which are specifically located in zygote giant cells and others which are markers for surrounding amoebae in the second phase of development. In addition, a G protein which is present in high amounts early in development is unique to giant cells in the second phase, suggesting a role in phagocytosis. Finally, alkaline phosphatase activity was found to mark the first phase of sexual development, suggesting a role in cell fusion. This contrasts with the patterns of alpha-mannosidase and beta-glucosidase activity that increase late in the second developmental phase, where they likely function in endocyte digestion during the cytophagic period. The developmental significance of these findings is discussed.     

In vitro fusion of newt macrophages

Spontaneous formation of multinucleate giant cells is often observed in in vitro cultures of peritoneal adherent macrophages from the newts, Notophthalmus viridescens and Taricha granulosa (urodele amphibians). The frequency of such giant cells in these cultures is increased by the addition of phorbol myristic acetate at the initiation of the cultures. This high frequency of multinucleate cells permitted us to evaluate whether multinucleate giant cells arise by cell fusion and/or by repeated nuclear division without cytokinesis. Cell fusion is readily detectable by scanning electron microscopy. To determine whether nuclear division without cytokinesis also occurs, some cultures were treated with colchicine to arrest mitotic figures; others were pulsed with tritiated thymidine to detect DNA synthesis. Mitotic figures were not seen in acridine orange-stained samples. In monolayers that were processed for autoradiography, only a few nuclei were marked with tritium. These observations suggest that nuclear division does not contribute significantly, if at all, to the formation of multinucleate giant cells from cultured newt peritoneal macrophages.     

The cytology of the gametes and fertilization of Allomyces macrogynus

The gametes and the process of fertilization were examined by light and electron microscopy in the lower eukaryote Allomyces macrogynus. Differences in gamete morphology included the overall larger size and the presence of a larger nuclear apparatus, along with the association of a side-body complex and many more mitochondria in the female gamete. In this species of Allomyces, fertilization was initiated by contact and fusion of specialized regions of the gamete plasma membranes resulting in a binucleate fusion cell surrounded by plasma membrane contributed by both partners. Following plasmogamy, nuclear fusion was initiated by multiple nuclear membrane contacts between adjacent outer membranes. Following inner membrane fusion, small nucleoplasmic bridges were observed which presumably fused with one another and resulted in a single bridge which widened, forming the mature diploid nucleus. After karyogamy, fusion of the nuclear caps did not always occur and zygotes with and without fused caps were observed. Coalescence of the nucleoli completed the events of fertilization, forming a zygote with a single nuclear apparatus (sometimes with two caps) and two flagella. These observations are discussed in relation to fertilization mechanisms and compared to fertilization in other organisms.     

Different developmental functions for calmodulin in Dictyostelium: trifluoperazine and R24571 both inhibit cell and pronuclear fusion but enhance gamete formation

The calmodulin antagonists trifluoperazine and compound R24571 were used to study the function of calmodulin during sexual development in Dictyostelium discoideum. Calmodulin activity is required for both cell fusion and pronuclear fusion. However, cell fusion and pronuclear fusion were each maximally inhibited at different concentrations of the same inhibitor suggesting differential calmodulin activity during these events. In contrast, trifluoperazine and R24571 were both found to enhance rather than inhibit the formation of gametes. This suggests an additional role for calmodulin as a negative regulator of gamete development. These results provide evidence of a role for calmodulin as both a positive (biomembrane fusion) and a negative (gamete development) regulator of developmental events in Dictyostelium. They also reveal calmodulin as a mediator of pronuclear fusion for zygote development in this eukaryote.     

Self- and non-self-recognition in bisexual mating of Dictyostelium discoideum

Cell recognition plays a central part in the sexual process. Although cell-surface molecules involved in gamete recognition have been identified in several organisms, our knowledge of the molecular basis of sexual cell recognition is still limited. We have been studying molecular mechanisms of sexual cell fusion using the lower eukaryote Dictyostelium discoideum . There are homothallic, heterothallic, bisexual and asexual strains in D. discoideum , and how they distinguish between each other to find out proper partners is an interesting and important question. However, analytical studies of sexuality in D. discoideum have been carried out mostly on heterothallic strains, and the polymorphism of the mating system has not yet been thoroughly investigated. In the present study, we extended our analysis to the bisexual mating phenomenon paying special attention to the mechanism of self-incompatibility. We showed that a bisexual strain WS2162 was self-incompatible at the step of sexual cell fusion. Results of antibody inhibition of cell fusion and detection of gp138, a cell-fusion-related protein found in heterothallic strains, suggest that a molecular basis for bisexual and heterothallic mating are common. We propose two models to clarify the mechanisms of self- and non-self discrimination in bisexual mating patterns of D. discoideum .     

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.     

Cell fusion, nuclear fusion, and zygote differentiation during sexual development of Dictyostelium discoideum

The fluorescent nuclear stain Hoechst 33258 was used to study the nuclear events during mating of Dictyostelium discoideum in liquid culture. These studies revealed that cell fusion begins about 11 hr after the sexually compatible cultures are mixed and continues until 26 hr. Approximately 37% of the cells fuse during this 15-hr period. At first the fused cells are relatively small, but by 20 hr the fusion products become evident as morphologically distinct giant cells. Starting at 22 hr these giant cells are transformed into true zygotes as nuclear fusion begins. Both the fusion of amebae and the differentiation of zygote giant cells are Ca²⁺-dependent events as revealed by studies using EGTA. The nuclear events of zygote differentiation involve nuclear swelling, migration, and fusion. The precise timing of these events has been detailed. Of particular interest for genetic analyses via the macrocyst is the presence of a small population of multinucleate cells (maximum level is 1.67% of the cell population) which usually possess 3 or 4 nuclei but may have as many as 10 or more. Although these multinucleate cells contain many nuclei, our evidence suggests that only one is a zygote nucleus. The genetic implications of these data and the potential value of using the mating system for the analysis of cell fusion are discussed.     

In vitro double fertilization in Nicotiana tabacum (L.): fusion behavior and gamete interaction traced by video-enhanced microscopy

In vitro double fertilization in tobacco was carried out with attention to fusion behavior and gamete interaction. Structural and cytological events indicating possible reaction to the fusion of sperm-egg and especially sperm-central cell were recorded by video-enhanced microscopy. Generative cells were fused with the egg cell or central cell as a control system to better understand gamete interaction. As early as adherence of the male cell, the female cell showed response by means of cytoplasm strand formation. After gamete fusion, cytoplasm activation in the egg cell was observed as long distance movement of organelles. In fertilized central cells, however, fusion did not result in notable cytological change within 30 min. Male nuclear movement recorded in the female cell illustrated two different patterns of movement which showed similarity to organelle movement. The dynamics of male and female nuclear fusion after in vitro fertilization was also recorded in the central cell. It revealed that the fusion process requires only a few seconds and is similar to that of gamete fusion in vitro. This may offer a new clue for understanding how female and male nuclei attract, adhere and finally fuse each other. Received: 13 October 1999 / Revision accepted: 6 December 1999     

Cellular events during sexual development from amoeba to plasmodium in the slime mould Physarum polycephalum

Time-lapse cinematography and immunofluorescence microscopy were used to study cellular events during amoebal fusions and sexual plasmodium development in Physarum polycephalum. Amoebal fusions occurred frequently in mixtures of strains heteroallelic or homoallelic for the mating-type locus matA, but plasmodia developed only in the matA-heteroallelic cultures. These observations confirmed that matA controls development of fusion cells rather than cell fusion. Analysis of cell pedigrees showed that, in both types of culture, amoebae fused at any stage of the cell cycle except mitosis. In matA-heteroallelic fusion cells, nuclear fusion occurred in interphase about 2 h after cell fusion; interphase nuclear fusion did not occur in matA-homoallelic fusion cells. The diploid zygote, formed by nuclear fusion in matA-heteroallelic fusion cells, entered an extended period of cell growth which ended in the formation of a binucleate plasmodium by mitosis without cytokinesis. In contrast, no extension to the cell cycle was observed in matA-homoallelic fusion cells and mitosis was always accompanied by cytokinesis. In matA-homoallelic cultures, many of the binucleate fusion cells split apart without mitosis, regenerating pairs of uninucleate amoebae; in the remaining fusion cells, the nuclei entered mitosis synchronously and spindle fusion sometimes occurred, giving rise to a variety of products. Immunofluorescence microscopy showed that matA-heteroallelic fusion cells possessed two amoebal microtubule organizing centres, and that most zygotes possessed only one; amoebal microtubule organization was lost gradually over several cell cycles. In matA-homoallelic cultures, all the cells retained amoebal microtubule organization.     

Electron microscopy of sexual reproduction in Nephroselmis olivacea (Prasinophyceae, Chlorophyta)

The electron microscopy of zygote formation and the early stages of zygote germination in Nephroselmis olivacea Stein are presented. Although the gametes differ behaviorally during the early stages of gamete fusion, the alga is isogamous. The minus gamete settled on the substrate, and attached with its left side. The plus gamete swam to the minus gamete, attached ventral to the right side of the minus gamete, while slightly on its left side, and plasmogamy started. No specialized organelle for gamete fusion was seen using either scanning or transmission electron microscopy. Gametic fusion was uniform; the right side of the minus gamete always fused with the ventral, slightly left side of the plus gamete, which suggests the participation of the d‐rootlets of the flagellar apparatus of the two gametes. Body scales were retained throughout the entire sexual process. Before karyogamy, a network of endoplasmic reticulum developed between the nuclei. This position corresponded to the contractile vacuole of the plus gamete. Fusion proceeded as the minus gamete was drawn to the plus gamete and resulted in a hemispherical zygote. Fibrous material appeared on the cell surface, embedding the body scales to form a layer that thickened and contributed to the strong adhesion of the zygote to the substrate. During this stage, karyogamy was completed. A thick zygotic wall composed of two layers, an electron‐dense outer layer and a straticulate electron‐lucent inner layer developed beneath the layer of fibrous material and scales. Zygote germination was induced. After the first meiotic division, the layer of fibrous material and scales ruptured and the inner layer of the zygotic wall thinned, allowing the emergence of two germ cells. They had newly formed scales and two starch grains, but no typical pyrenoid.     

Gamete fusion site on the egg cell and autonomous establishment of cell polarity in the zygote

Gamete fusion activates the egg in animals and plants, and the gamete fusion site on the zygote might provide a possible cue for zygotic development and/or embryonic patterning. In angiosperms, a zygote generally divides into a two-celled proembryo consisting of an apical and a basal cell with different cell fates. This is a putative step in the formation of the apical-basal axis of the proembryo. We observed the positional relationship between the gamete fusion site and the division plane formed by zygotic cleavage using an in vitro fertilization system with rice gametes. There was no relationship between the gamete fusion site and the division plane leading to the two-celled proembryo. Thus, the gamete fusion site on the rice zygote does not appear to function as a determinant for positioning the zygote division plane, and the zygote apparently possesses autonomous potential to establish cell polarity along the apical-basal axis for its first cleavage.Key words: asymmetric division, egg cell, fertilization, gamete fusion, rice, sperm cell, two-celled proembryo, zygote     

Phagocytic specificity during sexual development in Dictyostelium discoideum

During the sexual cycle of Dictyostelium discoideum, zygote giant cells develop and serve as foci for further development by chemoattracting and cannibalizing hundreds of local amoebae. Previous work has shown that the phagocytic process bears similarities to and differences from asexual endocytosis. In the present study, sexual phagocytosis in D. discoideum was found to be species and developmental stage specific. It was inhibited selectively by glucose and concanavalin A. Although a partial, inhibitory effect of mannose on phagocytosis was not statistically significant, alpha-methylmannosamine, like alpha-methyl-glucose, significantly restored the phagocytic competence of giant cells treated with concanavalin A. Other sugars (N-acetyl-glucosamine, N-acetylgalactosamine, and galactose) and lectins (wheat germ agglutinin, Ulex europus type I, and Ricinis communis agglutinin type I) had no significant effect on sexual phagocytosis. Together these data indicate that a glucose-type receptor is involved in selective uptake of D. discoideum amoebae by giant cells.     

The immediate induction of extensive cell fusion by Ca2+ addition in Dictyostelium discoideum

In mated cultures (NC4 X V12) of Dictyostelium discoideum containing 1.0 mM CaCl2, cell fusion generates large numbers of binucleate cells which develop into zygote giant cells. In the absence of Ca2+, binucleate formation does not occur. When 1.0 mM CaCl2 is added to Ca2+-deficient cultures at 18 h, 50% of the cells fuse within 45 min producing large multinucleate syncytia. Small, presumptive gametes appear in Ca2+-deficient cultures and reach a peak of about 20% of the cell population by 10 h, but they maintain this plateau and do not fuse. Upon the addition of CaCl2, the presumptive gametes immediately fuse, producing binucleate cells which develop rapidly into morphologically distinct giant cells. Cell fusion continues, resulting in the formation of extremely large (40-80 microns diameter) multinucleate syncytia by 45 min. The induction of this extensive, synchronous cell fusion does not occur in the presence of other chloride salts and EGTA inhibits it, revealing that Ca+ is the regulatory ion.     

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.     

Development of polyspermic zygote and possible contribution of polyspermy to polyploid formation in angiosperms

Fertilization is a general feature of eukaryotic uni- and multicellular organisms to restore a diploid genome from female and male gamete haploid genomes. In angiosperms, polyploidization is a common phenomenon, and polyploidy would have played a major role in the long-term diversification and evolutionary success of plants. As for the mechanism of formation of autotetraploid plants, the triploid-bridge pathway, crossing between triploid and diploid plants, is considered as a major pathway. For the emergence of triploid plants, fusion of an unreduced gamete with a reduced gamete is generally accepted. In addition, the possibility of polyspermy has been proposed for maize, wheat and some orchids, although it has been regarded as an uncommon mechanism of triploid formation. One of the reasons why polyspermy is regarded as uncommon is because it is difficult to reproduce the polyspermy situation in zygotes and to analyze the developmental profiles of polyspermic triploid zygotes. Recently, polyspermic rice zygotes were successfully produced by electric fusion of an egg cell with two sperm cells, and their developmental profiles were monitored. Two sperm nuclei and an egg nucleus fused into a zygotic nucleus in the polyspermic zygote, and the triploid zygote divided into a two-celled embryo via mitotic division with a typical bipolar microtubule spindle. The two-celled proembryos further developed and regenerated into triploid plants. These suggest that polyspermic plant zygotes have the potential to form triploid embryos, and that polyspermy in angiosperms might be a pathway for the formation of triploid plants.     

Photographs of Fertilization in the Smaller Species of Trichonympha

SYNOPSIS. The photographs illustrate male and female gametes before fertilization, several progressive stages in the entrance of the male gamete into the cytoplasm of the female, cytoplasmic fusion of gametes, loss of extranuclear organelles of male gamete, retention of extranuclear organelles of female gamete, movement of pronucleus of male gamete to that of female, progressive stages in fusion of pronuclei, and the formation of the zygote which possesses the extranuclear organelles of the female gamete. Some abortive attempts at fertilization, resulting from failure of gametes to differentiate, are shown.     

SEXUAL REPRODUCTION AND MEIOSIS IN PERIDINIUM INCONSPICUUM LEMMERMANN (DINOPHYCEAE)

In Peridinium inconspicuum Lemmermann, sexual reproduction occurs in both nitrogen-enriched and nitrogen-deficient media. In this homothallic strain, protoplasmic fusion begins between two thecate gametes; but zygote formation is completed in a space outside the fusing pair. This diploid cell can form a plated theca which is shed as the cell enlarges. This spherical zygote then forms a new non-plated theca. The process of ecdysis and the formation of a new non-plated theca is repeated several times. During this process the zygote gradually elongates and by cytoplasmic infurrowing becomes peanut-shaped. Eventually two cells are formed. The first and second meiotic divisions are greatly separated in time. The first meiotic division occurs in the spherical non-thecate zygote. The second meiotic division can occur in the peanut-shaped zygote before it completes cytokinesis. This meiotic division may not be synchronous, occasionally resulting in a trinucleate stage. Eventually four flagellated, haploid products are produced.