Aberrant folate response and premature development in a mutant of Dictyostelium discoideum

Growth and development are mutually exclusive in Dictyostelium discoideum. The transition between the two stages of the life cycle is regulated by the relative abundance of nutrients and proteins secreted by the cells which reflect population density. At the transition from growth to development, the discoidin genes--developmental markers--are induced by the "quorum" protein PSF. The effect of PSF is counteracted by food bacteria and by folate [8]. We show that folate treatment during growth delays morphologic development. Furthermore, we demonstrate that in a mutant of Dictyostelium discoideum (V188, renamed HBW3), which expresses discoidinI during growth and which develops rapidly [46], discoidinI expression is less sensitive to folate than in wild type cells. Finally, we present evidence that fragments of the discoidinI gamma promoter which are unresponsive to PSF and CM are sufficient for misregulation in the mutant. The only known regulator of these promoter elements is folate. Changes in the expression of other early developmental genes are also shown. Taken together, these data suggest that the reduced sensitivity to folate might be the cause for the "rapid development" phenotype of the mutant and that folate regulates developmental timing.     

repE--the Dictyostelium homolog of the human xeroderma pigmentosum group E gene is developmentally regulated and contains a leucine zipper motif.

We have cloned and characterized the Dictyostelium discoideum repE gene, a homolog of the human xeroderma pigmentosum (XP) group E gene which encodes a UV-damaged DNA binding protein. The repE gene maps to chromosome 4 and it is the first gene identified in Dictyostelium that is homologous to those involved in nucleotide excision repair and their related XP diseases in humans. The predicted protein encodes a leucine zipper motif. The repE gene is not expressed by mitotically dividing cells, and repE mRNA is first detected during the aggregation phase of development when the cells have ceased dividing and replicating genomic DNA. The mRNA level plateaus by the time the developing cells have entered multicellular aggregates and remains at the same steady-state level for the remainder of development. In addition, we have demonstrated that the level of mRNA is very low in developing cells. These observations suggest that repE may play a regulatory role in development. The data indicate that potential developmental roles for XP-related genes can be profitably studied in this system.     

Polyketide synthase genes and the natural products potential of Dictyostelium discoideum

MOTIVATION: The genome of the social amoeba Dictyostelium discoideum contains an unusually large number of polyketide synthase (PKS) genes. An analysis of the genes is a first step towards understanding the biological roles of their products and exploiting novel products. RESULTS: A total of 45 Type I iterative PKS genes were found, 5 of which are probably pseudogenes. Catalytic domains that are homologous with known PKS sequences as well as possible novel domains were identified. The genes often occurred in clusters of 2-5 genes, where members of the cluster had very similar sequences. The D.discoideum PKS genes formed a clade distinct from fungal and bacterial genes. All nine genes examined by RT-PCR were expressed, although at different developmental stages. The promoters of PKS genes were much more divergent than the structural genes, although we have identified motifs that are unique to some PKS gene promoters.     

Functional genomics of the social amoebae, Dictyostelium discoideum

Dictyostelium discoideum is one of the simplest organisms to form a multicellular structure, and it offers several advantages as a model. In order to understand the genetic basis of the multicellular development, a comprehensive analysis of cDNAs is being performed. To date, about 75,000 ESTs have been collected at different stages of development. They have been assembled into about 6,400 independent sequences that represent 70-80% of all of the expected genes in D. discoideum. The results are available on the Internet. In addition to structural analyses, functional analyses of the temporal and spatial expression patterns and gene targeting are being carried out. Furthermore, there are plans to combine the information that is obtained from the cDNA, Genome, and Proteome Projects, as well as the published results, into an integrated database, DictyBase.