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.

Total tetra knockout of GP138 multigene family implicated in cell interactions in Dictyostelium discoideum

The cellular slime mold Dictyostelium discoideum reproduces sexually under submerged and dark conditions. A cell surface glycoprotein gp138 has been identified as a target molecule for cell fusion-blocking antibodies, and is considered to be indispensable for the sexual cell fusion in this organism. Currently, four isoforms of gp138, DdFRP1alpha, DdFRP1beta, DdFRP2, and DdFRP3, are known. Genes encoding the latter three isoforms, GP138C, GP138A, and GP138B, have been isolated, comprising a GP138 multigene family. Here we isolated the fourth GP138 gene, GP138D, encoding DdFRP1alpha. These GP138 genes were found to cluster in a tandem array on chromosome 5, being bordered by two GP138-like sequences highly homologous to them but truncated. To clarify functional relationships among the GP138 family members, the entire GP138 region was deleted by a single knockout. Northern hybridization and western immuno-blotting analyses confirmed complete losses of GP138 mRNA and DdFRPs in the knockout strains, indicating that there are no more GP138 genes. Unexpectedly, however, the GP138-null mutants were fully potent for both sexual cell fusion and subsequent development. In addition, the original fusion-blocking antibodies detected a cell surface protein of close electrophoretic mobility to gp138 in the knockouts, suggesting the possibility that the actual target molecule of the fusion-blocking antibodies was not DdFRPs but this unidentified component. Since GP138-null mutants exhibited no obvious defects either in growth or asexual development, the real function of the GP138 family is unknown. Nevertheless, the expression levels of other developmental genes such as acaA, csaA, cotA-C, and spiA appeared to be altered in the GP138-null mutants. Therefore, it seems to have a non-critical but some role(s) during asexual development.

Identification and characterization of two flavohemoglobin genes in Dictyostelium discoideum

Flavohemoglobins are being identified in an expanding number of prokaryotes and unicellular eukaryotes. These molecules consist of an N-terminal hemoglobin domain and a C-terminal oxidoreductase domain, and are considered to function in storage or as sensors for O2, and in defense against oxidative stress and/or NO. However, their physiological significance has not yet been determined. Here, we isolated and analyzed two flavohemoglobin genes of Dictyostelium discoideum, DdFHa and DdFHb, which lie close to each other in the genome. DdFHs were induced by submerged conditions, and enriched in the sexually mature cells of D. discoideum. Although they were not essential for growth or development under standard laboratory conditions, disruption of both genes caused an increase in number of large but uninuclear cells, and hypersensitivity to higher concentrations of glucose and to NO releasers. These results indicate that DdFHs are responsible for transducing NO signals to maintain normal cellular conditions against environmental stresses.

A new member of the GP138 multigene family implicated in cell interactions in Dictyostelium discoideum

The cellular slime mold Dictyostelium discoideum reproduces sexually under submerged and dark conditions. Its mating system is polymorphic and particularly interesting with respect to mechanisms of cell recognition. The cell-surface glycoprotein gp138 has been implicated in sexual cell interactions, as it was identified as a target molecule for the antibodies that block sexual cell fusion in D. discoideum. Two mutually homologous genes, GP138A and GP138B, have been cloned, but gene disruption experiments to clarify their functional relationships suggested that there is at least one more gene for gp138. Further protein analysis including peptide mapping also revealed that gp138 exists as three isoforms, DdFRP1, DdFRP2, and DdFRP3. GP138A encodes DdFRP2 and GP138B, DdFRP3, and the presence of a third gp138 gene encoding DdFRP1 was suggested. Here, we isolated and characterized a third GP138 gene, GP138C. Although the deduced amino acid sequences of GP138C matched completely with those of peptide fragments of DdFRP1 in the N-terminal half, the rest did not give complete matches. Overexpression of GP138C caused an increase in the intensity of DdFRP1, but disruption of this gene did not diminish DdFRP1. Our results indicate that GP138C encodes a protein very similar to but distinct from DdFRP1. The GP138 multigene family is thus composed of more members than previously expected, and their functional relationships are of special interest.

A Dictyostelium discoideum homologue to Tcp-1 is essential for growth and development

Tcp-1 (t-complex polypeptide 1 gene) was first identified in the mouse as relevant for tail-less and embryonic lethal phenotypes. Since then, its homologous sequences have been isolated in several other species, and the yeast Tcp-1 has been shown to encode a molecular chaperon for actin and tubulin. In a random sample of genes expressed in the gamete of Dictyostelium discoideum (Dd), we encountered a sequence containg the TCP1 motifs. The complete ORF of the gene (DdTcp-1) showed more than 60% similarity to TCP-1 of several organisms, including human. DdTcp-1 was found to be expressed in both sexually mature and immature cells at the growth phase. Although the sexual process itself was not affected, antisense interference of this gene resulted in severe retardation of cell growth, leading to the complete cessation of division. In addition, the antisense transformants stopped asexual development at the finger stage. These results suggest an important function of DdTcp-1 in growth and development of this organism.

Localization of a DNA topoisomerase II to mitochondria inDictyostelium discoideum: Deletion mutant analysis and mitochondrial targeting signal presequence

DNA topoisomerase II ofDictyostelium discoideum (TopA), the gene (topA) encoding which we cloned, was shown to have an additional N-terminal region which contains a putative mitochondrial targeting signal presequence. We constructed overexpression mutants which expressed the wild-type or the N-terminally deleted enzyme, and examined its localization by immunofluorescence microscopy and proteinase K digestion experiment. These experiments revealed that the enzyme is located in the mitochondria by virtue of the additional N-terminal region. Furthermore, in the cell extract depleted the enzyme by immunoprecipitation, nuclear DNA topoisomerase II activity was not decreased. These results confirmed that TopA is located in the mitochondria, even through its amino acid sequence is highly similar to those of nuclear type topoisomerase II of other organisms. Thus, this report is the first to establish the location of the mitochondrial targeting signal presequence in DNA topoisomerase II and in proteins ofD. discoideum directly by analyzing deletion mutants.