Developmental regulation of the cyclic-nucleotide-phosphodiesterase mRNA of Dictyostelium discoideum. Analysis by cell-free translation and immunoprecipitation

Sequence and expression analysis of a cAMP-responsive gene regulated during late development of Dictyostelium discoideum

The 7E gene is expressed late in normal development of Dictyostelium discoideum after pseudoplasmodium formation. After disaggregation of the developing cells, transcription of this gene depends entirely on exogenous 3'5' cyclic AMP (cAMP). The 5' flanking region of the 7E gene contains two TATA box-oligo (dT) promoter motifs but analysis of 7E gene expression by primer extension shows only a single primary transcript with transcription initiating immediately after the most proximal promoter motif during development or in disaggregated cells in the presence of exogenous cAMP. Four C-rich sequences lie within 350bp upstream of the cap site, analogous to the upstream elements implicated in the cAMP regulation of several other Dictyostelium genes expressed in development.

Cyclic nucleotide phosphodiesterase of Dictyostelium discoideum and its glycoprotein inhibitor: structure and expression of their genes

The genes coding for the cyclic nucleotide phosphodiesterase (PD) and the PD inhibitory glycoprotein (PDI) have been cloned and characterized. The PDI gene was isolated as a 1.6 kb genomic fragment, which included the coding sequence containing two small introns and 510 nucleotides of non-translated 5' sequence. From the deduced amino acid sequence we predict a protein with a molecular weight (MW) of 26,000 that, in agreement with previous data, contains 15% cysteine residues. Genomic Southern blot analysis indicates that only one gene encodes the inhibitor. Northern blot analysis shows a single transcript of 0.95 kb. The PDI gene is expressed early in development with little transcript remaining following aggregation. The appearance of PDI mRNA is prevented by the presence of cAMP, but when cAMP is removed the transcript appears within 30 minutes. When cAMP is applied to cells expressing PDI the transcript disappears with a half-life of less than 30 minutes. The PD gene of D. discoideum is transcribed into three mRNAs: a 1.9 kb mRNA specific for growth, a 2.4 kb mRNA specific for aggregation, and a 2.2 kb mRNA specific for late development. The 2.2 kb mRNA is also specific for prestalk cells, and is induced by differentiation-inducing factor. All three mRNAs contain the same coding sequence, and differ only in their 5' non-coding sequences. Each mRNA is transcribed from a different promoter, and by using the chloramphenicol acyltransferase gene as a reporter, we have shown that each promoter displays the same regulation as its cognate mRNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Cell-type-specific genes expressed late in Dictyostelium development show markedly different responses to 3'5' cyclic AMP

The maintenance of late gene expression by 3'5' cyclic AMP was re-examined using several newly isolated cell-type-specific genes. Expression of all the prespore-enriched genes ceased immediately upon disaggregation of developing cells and pre-existing mRNA was rapidly degraded. For most genes, cAMP had little or no effect either alone or in combination with conditioned medium factors. The expression of the non-cell-type-specific genes 7E and 2C also ceased upon cell disaggregation but cAMP triggered a full re-induction of expression although the timing of the response differed markedly between these two genes. In contrast to earlier interpretations, these data argue that for none of these late prespore genes is cAMP alone sufficient for the maintenance of expression. The responses of the two prestalk mRNAs examined were gene-specific. Prestalk 5D mRNA decayed slowly upon disaggregation and was partially stabilized by cAMP whereas prestalk 5G mRNA increased upon disaggregation and was inhibited by cAMP.

cAMP regulation of early gene expression in signal transduction mutants of Dictyostelium

We have examined the regulation of three early developmentally regulated genes in Dictyostelium. Two of these genes (D2 and M3) are induced by pulses of cAMP and the other (K5) is repressed. Expression of these genes has been examined in a number of developmental mutants that are specifically blocked in various aspects of the signal transduction/cAMP relay system involved in aggregation and control of early development. The mutant strains include Synag mutants, which are blocked in receptor-mediated activation of adenylate cyclase and do not relay cAMP pulses; FrigidA mutants, which are blocked in receptor-mediated activation of both adenylate cyclase and the putative phosphoinositol bisphosphate (PIP2) turnover pathway and appear to be mutations in the gene encoding one of the G alpha protein subunits; and a StreamerF allele, which lacks cGMP-specific cGMP phosphodiesterase. From the analysis of the developmental expression of these genes under a variety of conditions in these mutant strains, we have drawn a number of conclusions concerning the modes of regulation of these genes. Full induction of D2 and M3 genes requires cAMP interaction with the cell surface receptor and an "oscillation" of the receptor between active and adapted forms. Induction of these genes does not require activation of the signal transduction pathway that leads to adenylate cyclase activation and cAMP relay, but does require activation of other receptor-mediated intracellular signal transduction pathways, possibly that involving PIP2 turnover. Likewise, repression of the K5 gene requires pulses of cAMP. Expression of this gene is insensitive to cAMP pulses in FrigidA mutants, suggesting that a signal transduction pathway is necessary for its repression. Results using the StreamerF mutant suggest that the rise in cGMP in response to cAMP/receptor interactions may not be directly related to control of the pulse-induced genes. In addition, we have examined the effect of caffeine, which M. Brenner and S.D. Thomas (1984, Dev. Biol., 101, 136-146) showed preferentially blocks the cAMP relay system by blocking receptor-mediated activation of adenylate cyclase. We show that in many of the mutants and in an axenic wild-type strain, caffeine causes the induction of pulse-induced gene expression to almost wild-type levels or in some cases to higher than wild-type levels. Our data suggest that caffeine works by activating some step in the signal transduction pathway that must lie downstream from both the receptor and at least one of the G proteins and thus has effects other than simply blocking the receptor-mediated cAMP relay system.

Two divergently transcribed genes of Dictyostelium discoideum are cyclic AMP-inducible and coregulated during development

The cysteine proteinase 1 (CP1) gene of Dictyostelium discoideum encodes a developmentally regulated sulfhydryl proteinase. We characterized the DNA sequences upstream of the CP1 gene and found a second developmentally regulated gene, which we term DG17. The translational open reading frame of the DG17 gene encoded a 458-amino-acid cysteine- and lysine-rich protein of unknown function. In several regions, the cysteine and lysine residues were arranged in a manner characteristic of the zinc-binding domains found in proteins which interact with nucleic acids. During normal development, the DG17 and CP1 genes are coordinately activated late in aggregation. The addition of exogenous cyclic AMP (cAMP) induced the premature expression of both mRNAs. By measuring the rate of specific mRNA synthesis in isolated nuclei, we showed that cAMP acted at the transcriptional level to activate both genes. The two genes were separated by 910 nucleotides and were divergently transcribed. The intergenic region was predominantly composed of A + T residues except for four short G-rich regions. These sequences coincided with the positions of four nuclease-hypersensitive sites, which appear during aggregation when the DG17 and CP1 genes are transcribed (J. Pavlovic, E. Banz, and R. W. Parish, Nucleic Acids Res. 14:8703-8722, 1986). Two of the G-rich regions formed the core of two almost identical 80-nucleotide repeats located 220 and 320 nucleotides upstream of the CP1 gene. Using the Dictyostelium transformation system, we showed that a restriction fragment containing the intergenic region was capable of directing bidirectional transcription in a cAMP-dependent manner.

Genetics of early Dictyostelium discoideum development

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Characterization of two divergently transcribed Dictyostelium gene pairs and identification of G-rich sequence element lying between them with the characteristics of a basal promoter element

The cysteine proteinase 1 (CP1) and cysteine proteinase 2 (CP2) genes of Dictyostelium discoideum encode coordinately expressed mRNA sequences that are inducible by extracellular cAMP. Both genes form part of divergently transcribed gene pairs. The gene proximal to CP1 is coordinately regulated and encodes a protein containing several potential zinc binding domains of the kind found in DNA binding proteins. The gene proximal to CP2 is a constitutively transcribed gene of unknown function. There are multiple, short, G-rich sequence elements between both gene pairs, and deletion of the pair of elements 200 nucleotides upstream from the CP2 gene abolishes cAMP-inducibility. A synthetic oligonucleotide, containing two copies of the G-rich element from the CP1 gene, will reconstitute cAMP-inducibility in the deletion mutant of the CP2 gene. This shows that the elements in the two genes are functionally homologous. Efficient induction requires at least two copies of the CP1 element, but their relative orientation is unimportant. Two copies in an inverted orientation are, however, inactive when moved upstream of their normal position and are incapable of conferring cAMP-inducibility on a heterologous gene. These observations suggest that these sequences are either essential promoter elements, not themselves interacting with the inducer, or that their interaction with a separate class of control sequences is necessary for inducible expression.

Two divergently transcribed genes of Dictyostelium discoideum are cyclic AMP-inducible and coregulated during development

The cysteine proteinase 1 (CP1) gene of Dictyostelium discoideum encodes a developmentally regulated sulfhydryl proteinase. We characterized the DNA sequences upstream of the CP1 gene and found a second developmentally regulated gene, which we term DG17. The translational open reading frame of the DG17 gene encoded a 458-amino-acid cysteine- and lysine-rich protein of unknown function. In several regions, the cysteine and lysine residues were arranged in a manner characteristic of the zinc-binding domains found in proteins which interact with nucleic acids. During normal development, the DG17 and CP1 genes are coordinately activated late in aggregation. The addition of exogenous cyclic AMP (cAMP) induced the premature expression of both mRNAs. By measuring the rate of specific mRNA synthesis in isolated nuclei, we showed that cAMP acted at the transcriptional level to activate both genes. The two genes were separated by 910 nucleotides and were divergently transcribed. The intergenic region was predominantly composed of A + T residues except for four short G-rich regions. These sequences coincided with the positions of four nuclease-hypersensitive sites, which appear during aggregation when the DG17 and CP1 genes are transcribed (J. Pavlovic, E. Banz, and R. W. Parish, Nucleic Acids Res. 14:8703-8722, 1986). Two of the G-rich regions formed the core of two almost identical 80-nucleotide repeats located 220 and 320 nucleotides upstream of the CP1 gene. Using the Dictyostelium transformation system, we showed that a restriction fragment containing the intergenic region was capable of directing bidirectional transcription in a cAMP-dependent manner.

The expression of two transcripts of the phosphodiesterase gene during the development of Dictyostelium discoideum

One of the earliest events in the development of Dictyostelium discoideum is the induction of the cyclic nucleotide phosphodiesterase gene. During vegetative growth a small amount of secreted phosphodiesterase is synthesized. The phosphodiesterase transcript which is responsible for the vegetative enzyme has a size of 1800 nucleotides. Soon after starvation begins a more abundant mRNA with a size of 2200 nucleotides is synthesized by the developing cells. The induction of the 2200-nucleotide mRNA is dependent on protein synthesis and takes place under all regimens of growth and starvation. When growth is in axenic medium and development is in phosphate buffer, the appearance of the larger transcript is very rapid, occurring within 30 min after the onset of starvation. The initial burst of phosphodiesterase mRNA synthesis is followed by a decline in mRNA abundance unless the cells are stimulated by cAMP. When cells are grown on bacteria and development takes place on filter paper, the larger transcript appears after 4 hr, reaches a peak at 10-12 hr of development, and then slowly disappears. When prestalk and prespore cells from migrating slugs are separated, a small amount of transcript can be found only in the prestalk cells. A series of mutants blocked early in development make very little phosphodiesterase transcript or are otherwise abnormal in expression of the phosphodiesterase mRNA. Together these mutants define five independent genetic loci which affect the accumulation of the phosphodiesterase mRNA. These are the pdsA, fgdA, fgdC, fgdD, and fgdE genes.

The regulatory subunit of cAMP-dependent protein kinase from Dictyostelium discoideum: cellular localization and developmental regulation analyzed by immunoblotting

The level of the regulatory subunit of the cAMP-dependent protein kinase from Dictyostelium discoideum was analyzed in subcellular fractions of cells at various stages of development by Western blotting. The protein was found only in the cytosolic fraction. A small amount of regulatory subunit was present in vegetative cells, and its level increased sharply during the first hours of aggregation; a further increase also occurred during culmination. Analysis of mature spores and of the stalky mutant HL 65 revealed that the protein is present only in prespore cells.