Triparental inheritance in Dictyostelium.

Sex promotes the recombination and reassortment of genetic material and is prevalent across eukaryotes, although our knowledge of the molecular details of sexual inheritance is scant in several major lineages. In social amoebae, sex involves a promiscuous mixing of cytoplasm before zygotes consume the majority of cells, but for technical reasons, sexual progeny have been difficult to obtain and study. We report here genome-wide characterization of meiotic progeny in Dictyostelium discoideum We find that recombination occurs at high frequency in pairwise crosses between all three mating types, despite the absence of the Spo11 enzyme that is normally required to initiate crossover formation. Fusions of more than two gametes to form transient syncytia lead to frequent triparental inheritance, with haploid meiotic progeny bearing recombined nuclear haplotypes from two parents and the mitochondrial genome from a third. Cells that do not contribute genetically to the Dictyostelium zygote nucleus thereby have a stake in the next haploid generation. D. discoideum mitochondrial genomes are polymorphic, and our findings raise the possibility that some of this variation might be a result of sexual selection on genes that can promote the spread of individual organelle genomes during sex. This kind of self-interested mitochondrial behavior may have had important consequences during eukaryogenesis and the initial evolution of sex.

Two HAP2-GCS1 homologs responsible for gamete interactions in the cellular slime mold with multiple mating types: Implication for common mechanisms of sexual reproduction shared by plants and protozoa and for male-female differentiation.

Fertilization is a central event in sexual reproduction, and understanding its molecular mechanisms has both basic and applicative biological importance. Recent studies have uncovered the molecules that mediate this process in a variety of organisms, making it intriguing to consider conservation and evolution of the mechanisms of sexual reproduction across phyla. The social amoeba Dictyostelium discoideum undergoes sexual maturation and forms gametes under dark and humid conditions. It exhibits three mating types, type-I, -II, and -III, for the heterothallic mating system. Based on proteome analyses of the gamete membranes, we detected expression of two homologs of the plant fertilization protein HAP2-GCS1. When their coding genes were disrupted in type-I and type-II strains, sexual potency was completely lost, whereas disruption in the type-III strain did not affect mating behavior, suggesting that the latter acts as female in complex organisms. Our results demonstrate the highly conserved function of HAP2-GCS1 in gamete interactions and suggest the presence of additional allo-recognition mechanisms in D. discoideum gametes.

Comparative genome and transcriptome analyses of the social amoeba Acytostelium subglobosum that accomplishes multicellular development without germ-soma differentiation.

BACKGROUND: Social amoebae are lower eukaryotes that inhabit the soil. They are characterized by the construction of a starvation-induced multicellular fruiting body with a spore ball and supportive stalk. In most species, the stalk is filled with motile stalk cells, as represented by the model organism Dictyostelium discoideum, whose developmental mechanisms have been well characterized. However, in the genus Acytostelium, the stalk is acellular and all aggregated cells become spores. Phylogenetic analyses have shown that it is not an ancestral genus but has lost the ability to undergo cell differentiation. RESULTS: We performed genome and transcriptome analyses of Acytostelium subglobosum and compared our findings to other available dictyostelid genome data. Although A. subglobosum adopts a qualitatively different developmental program from other dictyostelids, its gene repertoire was largely conserved. Yet, families of polyketide synthase and extracellular matrix proteins have not expanded and a serine protease and ABC transporter B family gene, tagA, and a few other developmental genes are missing in the A. subglobosum lineage. Temporal gene expression patterns are astonishingly dissimilar from those of D. discoideum, and only a limited fraction of the ortholog pairs shared the same expression patterns, so that some signaling cascades for development seem to be disabled in A. subglobosum. CONCLUSIONS: The absence of the ability to undergo cell differentiation in Acytostelium is accompanied by a small change in coding potential and extensive alterations in gene expression patterns.

Root of Dictyostelia based on 213 universal proteins.

Dictyostelia are common soil microbes that can aggregate when starved to form multicellular fruiting bodies, a characteristic that has also led to their long history of study and widespread use as model systems. Ribosomal RNA phylogeny of Dictyostelia identified four major divisions (Groups 1-4), none of which correspond to traditional genera. Group 1 was also tentatively identified as sister lineage to the other three Groups, although not consistently or with strong support. We tested the dictyostelid root using universal protein-coding genes identified by exhaustive comparison of six completely sequenced dictyostelid genomes, which include representatives of all four major molecular Groups. A set of 213 genes are low-copy number in all genomes, present in at least one amoebozoan outgroup taxon (Acanthamoeba castellanii or Physarum polycephalum), and phylogenetically congruent. Phylogenetic analysis of a concatenation of the deduced protein sequences produces a single topology dividing Dictyostelia into two major divisions: Groups 1+2 and Groups 3+4. All clades in the tree are fully supported by maximum likelihood and Bayesian inference, and all alternative roots are unambiguously rejected by the approximately unbiased (AU) test. The 1+2, 3+4 root is also fully supported even after deleting clusters with strong individual support for this root, or concatenating all clusters with low support for alternative roots. The 213 putatively ancestral amoebozoan proteins encode a wide variety of functions including 21 KOG categories out of a total of 25. These comprehensive analyses and consistent results indicate that it is time for full taxonomic revision of Dictyostelia, which will also enable more effective exploitation of its unique potential as an evolutionary model system.

Temporal and non-permanent division of labor during sorocarp formation in the social amoeba Acytostelium subglobosum.

Somatic cell differentiation is crucial for the development of multicellular organisms. While the development of a fruiting body in Dictyostelium discoideum represents a simple model of this process with separation of stalk cells from the spore lineage, that of Acytostelium subglobosum is not accompanied by cell type separation. This species produces acellular stalks and, seemingly, all aggregated amoebae become spores; however, it possesses homologs for the stalk-cell marker genes of D. discoideum. In this study, we analyzed the spatio-temporal expression of A. subglobosum orthologs for D. discoideum stalk- or spore-lineage markers to clarify the developmental process of A. subglobosum. We first found that the prespore vesicles, which contained spore coat proteins, started to accumulate in the tip region and were observed in the entire sorogen throughout later development, confirming that all A. subglobosum cells became spores. The expression of a stalk-lineage gene ortholog, As-ecmA, started at the mound stage and was prominent in the protruding sorogen. Although two spore-lineage gene orthologs, As-cotD1 and -cotD2, were likewise detected shortly after cell aggregation and increased in intensity until tip formation, their expression diminished in the protruding sorogen. Double-fluorescence staining of these prestalk and prespore marker genes revealed that the expression of these marker genes was mutually exclusive and that expression switching occurred in the early tip. Our results indicate that A. subglobosum cells become committed to the spore lineage first, and then, while keeping this commitment intact, participate in stalk formation. Instead of the permanent division of labor observed in D. discoideum, A. subglobosum produces fruiting bodies by all cells contributing to the formation of the stalk as well as forming spores.

Cross-species functional complementation of cellulose synthase during the development of cellular slime molds.

Cellulose is a major and important component of the extracellular matrix during the development of Dictyostelium discoideum. Upon starvation, solitary amoebae of D. discoideum gather and form fruiting bodies in which cells differentiate into stalk cells and spores. The stalk tubes and walls of spores and stalk cells are made of cellulose. In the genus Acytostelium, however, all cells are destined to become spores and the stalks comprise only a cellulose tube, suggesting species-specific regulation of cellulose synthesis. In this study, we cloned a putative cellulose synthase gene (cesA) of Acytostelium subglobosum and performed comparative analyses with the D. discoideum cellulose synthase gene (dcsA). Although the deduced amino acid sequences were highly conserved between cesA and dcsA, the numbers of transmembrane spans preceding the catalytic domain were dissimilar; 2 and 3, respectively. Since ectopic expression of cesA in dcsA(-) null cells failed to restore the developmental defects of the mutant, we constructed a series of chimerical genes for complementation analyses and found that the catalytic domain of cesA was functional in D. discoideum cells if the preceding transmembrane region was swapped with dcsA. The non-functional products that contained the cesA-derived transmembrane region were localized to lysosomes. These results indicate that the transmembrane region of cellulose synthase is essential for proper accumulation of cellulose during the development of D. discoideum and that its differential localization in A. subglobosum may be related to the characteristic morphogenesis in this species.

Analysis of phenotypic evolution in Dictyostelia highlights developmental plasticity as a likely consequence of colonial multicellularity.

Colony formation was the first step towards evolution of multicellularity in many macroscopic organisms. Dictyostelid social amoebas have used this strategy for over 600 Myr to form fruiting structures of increasing complexity. To understand in which order multicellular complexity evolved, we measured 24 phenotypic characters over 99 dictyostelid species. Using phylogenetic comparative methods, we show that the last common ancestor (LCA) of Dictyostelia probably erected small fruiting structures directly from aggregates. It secreted cAMP to coordinate fruiting body morphogenesis, and another compound to mediate aggregation. This phenotype persisted up to the LCAs of three of the four major groups of Dictyostelia. The group 4 LCA co-opted cAMP for aggregation and evolved much larger fruiting structures. However, it lost encystation, the survival strategy of solitary amoebas that is retained by many species in groups 1-3. Large structures, phototropism and a migrating intermediate 'slug' stage coevolved as evolutionary novelties within most groups. Overall, dictyostelids show considerable plasticity in the size and shape of multicellular structures, both within and between species. This probably reflects constraints placed by colonial life on developmental control mechanisms, which, depending on local cell density, need to direct from 10 to a million cells into forming a functional fructification.

A surface glycoprotein indispensable for gamete fusion in the social amoeba Dictyostelium discoideum.

Sexual reproduction is essential for the maintenance of species in a wide variety of multicellular organisms, and even unicellular organisms that normally proliferate asexually possess a sexual cycle because of its contribution to increased genetic diversity. Information concerning the molecules involved in fertilization is accumulating for many species of the metazoan, plant, and fungal lineages, and the evolutionary consideration of sexual reproduction systems is now an interesting issue. Macrocyst formation in the social amoeba Dictyostelium discoideum is a sexual process in which cells become sexually mature under dark and submerged conditions and fuse with complementary mating-type cells. In the present study, we isolated D. discoideum insertional mutants defective in sexual cell fusion and identified the relevant gene, macA, which encodes a highly glycosylated, 2,041-amino-acid membrane protein (MacA). Although its overall similarity is restricted to proteins of unknown function within dictyostelids, it contains LamGL and discoidin domains, which are implicated in cell adhesion. The growth and development of macA-null mutants were indistinguishable from those of the parental strain. The overexpression of macA using the V18 promoter in a macA-null mutant completely restored its sexual defects. Although the macA gene encoded exactly the same protein in a complementary mating-type strain, it was expressed at a much lower level. These results suggest that MacA is indispensable for gamete interactions in D. discoideum, probably via cell adhesion. There is a possibility that it is controlled in a mating-type-dependent manner.

Evolutionary linkage between eukaryotic cytokinesis and chloroplast division by dynamin proteins.

Chloroplasts have evolved from a cyanobacterial endosymbiont and been retained for more than 1 billion years by coordinated chloroplast division in multiplying eukaryotic cells. Chloroplast division is performed by ring structures at the division site, encompassing both the inside and the outside of the two envelopes. A part of the division machinery is derived from the cyanobacterial cytokinetic activity based on the FtsZ protein. In contrast, other parts of the division machinery involve proteins specific to eukaryotes, including a member of the dynamin family. Each member of the dynamin family is involved in the division or fusion of a distinct eukaryotic membrane system. To gain insight into the kind of ancestral dynamin protein and eukaryotic membrane activity that evolved to regulate chloroplast division, we investigated the functions of the dynamin proteins that are most closely related to chloroplast division proteins. These proteins in the amoeba Dictyostelium discoideum and Arabidopsis thaliana localize at the sites of cell division, where they are involved in cytokinesis. Our results suggest that the dynamin for chloroplast division is derived from that involved in eukaryotic cytokinesis. Therefore, the chloroplast division machinery is a mixture of bacterial and eukaryotic cytokinesis components, with the latter a key factor in the synchronization of endosymbiotic cell division with host cell division, thus helping to establish the permanent endosymbiotic relationship.

Developmental biology of the social amoeba: history, current knowledge and prospects.

The cellular slime molds are known as the social amoebae because they conditionally construct multicellular forms in which cell differentiation takes place. Among them, Dictyostelium discoideum has many advantages as an experimental system and is widely used as a model organism. This review aims to reconsider how it has contributed to the understanding of developmental mechanisms and what should be done in the future. Chemotaxis, cell differentiation, genome and transcriptome, and the ecological and evolutionary implications of development are discussed.

Genes involved in Dictyostelium discoideum sexual reproduction.

Macrocyst formation in the cellular slime moulds is a sexual process induced under dark and humid conditions. Normal development life cycle in these organisms involves proliferation by cell division and, upon starvation, formation of multicellular aggregates and fruiting bodies, consisting of spores and stalk cells. Macrocyst formation, cell division by binary fission and spore formation are thus three alternative modes of reproduction, for which it is of interest to understand how a choice is made. The genetic basis of asexual development and fruiting body formation is well known, by contrast information on the genetic control of sexual reproduction during macrocyst formation is scarce. In Dictyostelium discoideum, the most widely used species, several cell-surface proteins relevant to sexual cell fusion have been identified using cell fusion-blocking antibodies, but isolation of the relevant genes has been unsuccessful. Analysis of sexually deficient mutants, some of which are normal for asexual development, has shown that sexual reproduction is regulated by both specific genes and genes that are also involved in asexual development. Reverse genetic analysis of 24 genes highly enriched in a gamete-specific subtraction library has revealed four genes involved in the regulation of sexual cell interactions. One of them was found to be a novel regulator of the cAMP signalling pathway specific to sexual development. Studies on the molecular genetic control of the sexual cycle will be reviewed and their contribution to our understanding of the organization and function of the D. discoideum genome as a whole discussed.

Reverse genetic analyses of gamete-enriched genes revealed a novel regulator of the cAMP signaling pathway in Dictyostelium discoideum.

Sexual development in Dictyostelium discoideum is initiated by the fusion of opposite mating type cells to form zygote giant cells, which subsequently gather and phagocytose surrounding cells for nutrition to form macrocysts. Here we performed the targeting of 24 highly gamete-enriched genes we previously isolated, and successfully generated knockout mutants for 16 genes and RNAi mutants for 20 genes including 6 genes without disruptants. In the knockout mutants of two genes, cell aggregation toward the giant cells was much less extensive and many cells remained around poorly formed macrocysts. We named these genes tmcB and tmcC. Although macrocyst formation of wild type cells was suppressed by the addition of exogenous cAMP, that of knockout mutants of tmcB was much less sensitive. The mRNA level of phosphodiesterase (pde) was higher and that of its inhibitor (pdi) was lower in the latter cells compared to the parental strains during sexual development. Thus, tmcB appeared to be a novel regulator of the cAMP signaling pathway specific to sexual development. Knockout mutants of tmcC were indistinguishable from the wild type cells with respect to the cAMP response, suggesting that this gene is relevant to other processes.

Cultivation, spore production, and mating.

Dictyostelium discoideum proliferates as solitary amoebae, constitutes multicellular structures called fruiting bodies, and mates to form macrocysts depending on environmental conditions. All of these processes can be easily induced in the laboratory. The amoebae are normally cultured with food bacteria, but the strains with mutations in axe loci can proliferate in nutrient media without bacteria. The strains can be stored either as spores or amoebae. Synchronous development of fruiting bodies is initiated by depleting the culture media or food bacteria. Synchronous development of macrocysts is achieved by mixing the cells of heterothallic strains separately cultured in darkness to induce the sexual maturation.

The cDNA sequencing project.

The Dictyostelium discoideum cDNA sequencing project started in 1995, preceding the genome sequencing project. Altogether, 14 cDNA libraries, including full-length ones, were constructed from five different stages of growth and asexual and sexual development, from which nearly 100,000 randomly chosen clones were sequenced to yield over 150,000 expressed sequence tags (ESTs). The data have been publicized online to facilitate clone distribution and collaboration using the whole clone set for microarray analyses. The EST reads were assembled to 6700 independent genes, which constitute about 55% of the total estimated Dictyostelium genes. Utilization of wet and dry resources have contributed to the understanding of the genetic system controlling the multicellular development in Dictyostelium.

PCR-mediated generation of a gene disruption construct without the use of DNA ligase and plasmid vectors.

We introduce a PCR-based procedure for generating a gene disruption construct. This method depends on DNA fragment fusion by the PCR technique and requires only two steps of PCR to obtain a sufficient amount of the gene disruption construct for one transformation experiment. The first step involves three separate PCR syntheses of a selectable marker cassette and the 5'- and 3'-regions of a target gene. Of the four primers used in amplification of the 5'- and 3'-regions of the target gene, two primers placed proximal to the site of the marker cassette are designed to have sequence tags complementary to the 5'- or 3'-side of the marker cassette. The two primers used in PCR synthesis of the marker cassette are complementary to the tagged primers. By fusion PCR, the 5' and 3' PCR products are linked to the marker cassette via the regions of tagged primers that overlap. A sufficient amount of the disruption construct can be directly amplified with the outermost primers. This method is simple, rapid and relatively inexpensive. In addition, there is the freedom of attaching long flanking regions to any selectable marker cassette.

Analyses of cDNAs from growth and slug stages of Dictyostelium discoideum.

Dictyostelium is a favored model for studying problems in cell and developmental biology. To comprehend the genetic potential and networks that direct growth and multicellular development, we are performing a large-scale analysis of Dictyostelium cDNAs. Here, we newly determine 7720 nucleotide sequences of cDNAs from the multicellular, slug stage (S) and 10 439 from the unicellular, vegetative stage (V). The combined 26 954 redundant ESTs were computer assembled using the PHRAP program to yield 5381 independent sequences. These 5381 predicted genes represent about half of the estimated coding potential of the organism. One-third of them were classified into 12 functional categories. Although the overall classification patterns of the V and S libraries were very similar, stage-specific genes exist in every category. The majority of V-specific genes function in some aspect of protein translation, while such genes are in a minority in the S-specific and common populations. Instead, genes for signal transduction and multicellular organization are enriched in the population of S-specific genes. Genes encoding the enzymes of basic metabolism are mainly found in the common gene population. These results therefore suggest major differences between growing and developing Dictyostelium cells in the nature of the genes transcribed.

Identification of a second member of the ponticulin gene family and its differential expression pattern.

We have identified a homologue (ponB) of the ponticulin gene (ponA), an F-actin binding protein, in the expressed sequence tag library generated to mRNA isolated from fusion-competent cells of Dictyostelium discoideum. PonB is predicted to have many of the same characteristics as ponticulin. Both proteins are predicted to possess a cleaved signal peptide, a glycosyl anchor, an amphipathic beta-strand structure and six conserved cysteines. Because of the sequence similarity and predicted conserved structures, this gene constitutes the second member of a ponticulin gene family. Unlike ponticulin, ponB is not expressed in axenically grown cells or during the asexual reproductive phase of D. discoideum. PonB is expressed by cells grown on bacterial lawns and by cells induced to be fusion-competent, i.e., gametes. The expression of ponB correlates with the appearance of a new F-actin binding activity in cell lysates of bacterially grown ponA(-) cells. By immunofluorescence microscopy, ponB appears to be localized to vesicles and to the plasma membrane of bacterially grown cells. Because ponticulin is the major high-affinity link between the plasma membrane and the cytoskeleton, the ponticulin gene family is likely to be part of the redundant system of proteins involved in connecting the cytoskeleton to the plasma membrane.

A comparative sequence analysis reveals a common GBD/FH3-FH1-FH2-DAD architecture in formins from Dictyostelium, fungi and metazoa.

BACKGROUND: Formins are multidomain proteins defined by a conserved FH2 (formin homology 2) domain with actin nucleation activity preceded by a proline-rich FH1 (formin homology 1) domain. Formins act as profilin-modulated processive actin nucleators conserved throughout a wide range of eukaryotes. RESULTS: We present a detailed sequence analysis of the 10 formins (ForA to J) identified in the genome of the social amoeba Dictyostelium discoideum. With the exception of ForI and ForC all other formins conform to the domain structure GBD/FH3-FH1-FH2-DAD, where DAD is the Diaphanous autoinhibition domain and GBD/FH3 is the Rho GTPase-binding domain/formin homology 3 domain that we propose to represent a single domain. ForC lacks a FH1 domain, ForI lacks recognizable GBD/FH3 and DAD domains and ForA, E and J have additional unique domains. To establish the relationship between formins of Dictyostelium and other organisms we constructed a phylogenetic tree based on the alignment of FH2 domains. Real-time PCR was used to study the expression pattern of formin genes. Expression of forC, D, I and J increased during transition to multi-cellular stages, while the rest of genes displayed less marked developmental variations. During sexual development, expression of forH and forI displayed a significant increase in fusion competent cells. CONCLUSION: Our analysis allows some preliminary insight into the functionality of Dictyostelium formins: all isoforms might display actin nucleation activity and, with the exception of ForI, might also be susceptible to autoinhibition and to regulation by Rho GTPases. The architecture GBD/FH3-FH1-FH2-DAD appears common to almost all Dictyostelium, fungal and metazoan formins, for which we propose the denomination of conventional formins, and implies a common regulatory mechanism.

Construction of a gamete-enriched gene pool and RNAi-mediated functional analysis in Dictyostelium discoideum.

Macrocysts in Dictyostelium discoideum possess prototypic features of sexual reproduction and are useful for understanding the basic mechanisms of the reproductive process. Here, we randomly analyzed 1,071 gamete cDNAs, and then constructed a gamete-specific subtraction library, FC-IC. Nucleotide sequences of all 903 FC-IC clones were determined and clustered into 272 independent genes. Expression analysis based on real-time RT-PCR revealed 67 gamete-enriched genes, among which those involved in 'signal transduction' and 'multicellular organization' are prevalent. One of them, FC-IC0003, appeared also to be mating-type specific, and was named gmsA. RNAi-mediated silencing as well as disruption of gmsA reduced the cellular competency for sexual cell fusion, indicating the involvement of this gene in the sexual development of D. discoideum.