Redundant regulatory elements account for the developmental control of a ribosomal protein gene of Dictyostelium discoideum

Cell-cycle checkpoint for transition from cell division to differentiation

In general, growth and differentiation are mutually exclusive, but they are cooperatively regulated during the course of development. Thus, the process of a cell's transition from growth to differentiation is of general importance for the development of organisms, and terminally differentiated cells such as nerve cells never divide. Meanwhile, the growth rate speeds up when cells turn malignant. The cellular slime mold Dictyostelium discoideum grows and multiplies as long as nutrients are supplied, and its differentiation is triggered by starvation. A critical checkpoint (growth/differentiation transition or GDT point), from which cells start differentiating in response to starvation, has been precisely specified in the cell cycle of D. discoideum Ax-2 cells. Accordingly, integration of GDT point-specific events with starvation-induced events is needed to understand the mechanism regulating GDTs. A variety of intercellular and intracellular signals are involved positively or negatively in the initiation of differentiation, making a series of cross-talks. As was expected from the presence of the GDT point, the cell's positioning in cell masses and subsequent cell-type choices occur depending on the cell's phase in the cell cycle at the onset of starvation. Since novel and multiple functions of mitochondria in various respects of development including the initiation of differentiation have been directly realized in Dictyostelium cells, they are also reviewed in this article.

SrfB, a member of the Serum Response Factor family of transcription factors, regulates starvation response and early development in Dictyostelium

The Serum Response Factor (SRF) is an important regulator of cell proliferation and differentiation. Dictyostelium discoideum srfB gene codes for an SRF homologue and is expressed in vegetative cells and during development under the control of three alternative promoters, which show different cell-type specific patterns of expression. The two more proximal promoters directed gene transcription in prestalk AB, stalk and lower-cup cells. The generation of a strain where the srfB gene has been interrupted (srfB⁻) has shown that this gene is required for regulation of actin–cytoskeleton-related functions, such as cytokinesis and macropinocytosis. The mutant failed to develop well in suspension, but could be rescued by cAMP pulsing, suggesting a defect in cAMP signaling. srfB⁻ cells showed impaired chemotaxis to cAMP and defective lateral pseudopodium inhibition. Nevertheless, srfB⁻ cells aggregated on agar plates and nitrocellulose filters 2 h earlier than wild type cells, and completed development, showing an increased tendency to form slug structures. Analysis of wild type and srfB⁻ strains detected significant differences in the regulation of gene expression upon starvation. Genes coding for lysosomal and ribosomal proteins, developmentally-regulated genes, and some genes coding for proteins involved in cytoskeleton regulation were deregulated during the first stages of development.

Cloning of Dictyostelium eIF6 (p27BBP) and mapping its nucle(ol)ar localization subdomains

Eukaryotic translation initiation factor 6 (eIF6), also termed p27BBP, is an evolutionary conserved regulator of ribosomal function. The protein is involved in maturation and/or export from the nucleus of the 60S ribosomal subunit. Regulated binding to and release from the 60S subunit also regulates formation of 80S ribosomes, and thus translation. The protein is also found in hemidesmosomes of epithelial cells expressing beta4 integrin and is assumed to regulate cross-talk between beta4 integrin, intermediate filaments and ribosomes. In the present study we show that the Dictyostelium eIF6 (also called p27BBP) gene is expressed during growth, down-regulated during the first hours of starvation, and up-regulated again at the end of aggregation. Phagocytosis, and to a lesser extent pinocytic uptake of axenic medium, stimulate gene expression in starving cells. The eIF6 gene is present in single copy and its ablation is lethal. We utilized the green fluorescent protein (GFT) as fusion protein marker to investigate sequences responsible for eIF6 subcellular localization. The protein is found both in cytoplasm and nucleus, and is enriched in nucleoli. Deletion sequence analysis shows that nucle(ol)ar localization sequences are located within the N- and C-terminal subdomains of the protein.

Regulation of growth and differentiation in Dictyostelium

In general, growth and differentiation are mutually exclusive, but they are cooperatively regulated during the course of development. Thus, the process of a cell's transition from growth to differentiation is of general importance not only for the development of organisms but also for the initiation of malignant transformation, in which this process is reversed. The cellular slime mold Dictyostelium, a wonderful model organism, grows and multiplies as long as nutrients are supplied, and its differentiation is triggered by starvation. A strict checkpoint (growth/differentiation transition or GDT point), from which cells start differentiating in response to starvation, has been specified in the cell cycle of D. discoideum Ax-2 cells. Accordingly, integration of GDT point-specific events with starvation-induced events is needed to understand the mechanism regulating GDTs. A variety of intercellular and intracellular signals are involved positively or negatively in the initiation of differentiation, making a series of cross-talks. As was expected from the presence of GDT points, the cell's positioning in cell masses and subsequent cell-type choices occur depending on the cell's phase in the cell cycle at the onset of starvation. Since novel and somewhat unexpected multiple functions of mitochondria in cell movement, differentiation, and pattern formation have been well realized in Dictyostelium cells, they are reviewed in this article.

RNAi in Dictyostelium: the role of RNA-directed RNA polymerases and double-stranded RNase

We show that in Dictyostelium discoideum an endogenous gene as well as a transgene can be silenced by introduction of a gene construct that is transcribed into a hairpin RNA. Gene silencing was accompanied by the appearance of sequence-specific RNA about 23mers and seemed to have a limited capacity. The three Dictyostelium homologues of the RNA-directed RNA polymerase (RrpA, RrpB, and DosA) all contain an N-terminal helicase domain homologous to the one in the dicer nuclease, suggesting exon shuffling between RNA-directed RNA polymerase and the dicer homologue. Only the knock-out of rrpA resulted in a loss of the hairpin RNA effect and simultaneously in a loss of detectable about 23mers. However, about 23mers were still generated by the Dictyostelium dsRNase in vitro with extracts from rrpA(-), rrpB(-), and DosA(-) cells. Both RrpA and a target gene were required for production of detectable amounts of about 23mers, suggesting that target sequences are involved in about 23mer amplification.

Gene identification by shotgun antisense

Shotgun antisense is a technique to make a random set of mutant cells or organisms in such a way that one can select an interesting mutant and then sequence part of the mutated gene within a day. In addition to the fantastic rapidity with which one can identify the mutated gene, there are more advantages of this technique over other mutagenesis techniques: (1) one can identify genes that when completely repressed are lethal; (2) one can select which sets of genes will be mutated; and (3) genes that are expressed from multiple copies can be repressed and thus identified.

Dictyostelium ribosomal protein genes and the elongation factor 1B gene show coordinate developmental regulation which is under post-transcriptional control

Starvation for amino acids initiates the developmental program in the cellular slime mold, Dictyostelium discoideum [19, 20]. One of the earliest developmental events is the decline in ribosomal protein synthesis [2, 17, 29, 30]. The ribosomal protein mRNAs are excluded from polysomes with 20 min to 1 h following the removal of nutrients, and their mRNA levels decline sharply at about 9 h into the 24-h developmental cycle [28, 31, 35, 36]. It has been generally assumed that the decline in r-protein mRNA levels during late development reflected a decline in the transcription rate [12, 32, 43]. Here we demonstrate that this is not the case. The transcription rates of three ribosomal protein genes, rpL11, rpL23 and rpS9 as well as an elongation factor 1B gene have been determined during growth and development in Dictyostelium. Throughout growth and development the transcription rate of the ribosomal protein genes remains relatively constant at 0.2%-0.5% of the rate of rRNA transcription while the elongation factor 1B gene is transcribed at 0.4%-0.6% of the rRNA rate. This low but constant transcription rate is in contrast to a spore coat protein gene Psp D, which is transcribed at 6% of the rRNA rate in late developing cells. The elongation factor 1B gene appears to be co-regulated with the ribosomal protein genes both in terms of its transcription rate and mRNA accumulation. Dictyostelium has been a popular model for understanding signal transduction and the growth to differentiation transition, thus it is of significance that the regulation of ribosome biosynthesis in Dictyostelium resembles that of higher eukaryotes in being regulated largely at the post-transcriptional level in response to starvation as opposed to yeasts where the regulation is largely transcriptional [27].

Mutagenesis and gene identification in Dictyostelium by shotgun antisense

We have developed a mutagenesis technique that uses antisense cDNA to identify genes required for development in Dictyostelium discoideum. We transformed Dictyostelium cells with a cDNA library made from the mRNA of vegetative and developing cells. The cDNA was cloned in an antisense orientation immediately downstream of a vegetative promoter, so that in transformed cells the promoter will drive the synthesis of an antisense RNA transcript. We find that individual transformants typically contain one or occasionally two antisense cDNAs. Using this mutagenesis technique, we have generated mutants that fail to aggregate, aggregate but fail to form fruiting bodies, or aggregate but form abnormal fruiting bodies. The individual cDNA molecules from the mutants were identified and cloned using PCR. Initial sequence analysis of the PCR products from 35 mutants has identified six novel Dictyostelium genes, each from a transformant with one antisense cDNA. When the PCR-isolated antisense cDNAs were ligated into the antisense vector and the resulting constructs transformed into cells, the phenotypes of the transformed cells matched those of the original mutants from which each cDNA was obtained. We made homologous recombinant gene disruption transformants for three of the novel genes, in each case generating mutants with phenotypes indistinguishable from those of the original antisense transformants. Shotgun antisense thus is a rapid way to identify genes in Dictyostelium and possibly other organisms.

Sequence and developmental regulation of the gene that encodes the Dictyostelium discoideum L3 ribosomal protein

We have isolated and characterized genomic and cDNA recombinant plasmids that encode the Dictyostelium discoideum (Dd) ribosomal protein L3 (rpL3). Genomic plasmids were identified using a probe derived from the Saccharomyces cerevisiae TCM1 gene, that encodes the yeast rpL3. The DdL3 gene contains two introns and encodes a protein 398 amino acids in length that shows a high degree of homology to the conserved rpL3 protein of both lower and higher eukaryotes. During development, both the pattern of accumulation of DdL3 mRNA and changes in its translational activity are identical to those observed for other r-protein mRNAs.