Characterization of cDNA clones specific for sequences developmentally regulated during Dictyostelium discoideum spore germination

AT-rich upstream sequence elements regulate spore germination-specific expression of the Dictyostelium discoideum celA gene

Two members of a family of spore germination-specific cDNAs, celA and celB, are expressed coordinately, exclusively during spore germination. In the present study the regulatory sequence elements responsible for celA germination-specific expression have been identified. The very AT-rich 81 bp sequence between -664 and -584 upstream of the translation initiation site was required for proper temporal transcription of the celA gene. This sequence is comprised of two cis elements, each of which was active by itself in allowing celA expression. Electrophoretic mobility shift assays showed that a factor(s) in an extract prepared from germinating spores bound to the celA regulatory region. One of the three complexes formed was specific for the germinating spore extract. The results are consistent with the notion that the factor(s) that binds to this regulatory region is involved in expression of celA.

The Dictyostelium discoideum spore germination-specific cellulase is organized into functional domains

During Dictyostelium discoideum spore germination, degradation of the cellulose-containing spore wall is required to allow the amoeba to emerge. The CelA gene, which is transcribed and expressed exclusively during spore germination, codes for a 705-amino-acid protein that has cellulase activity [endo-(1,4)-beta-D-glucanase]. Amoebae transformed by a vector containing the CelA coding sequence or portions of it transcribed from a heterologous promoter expressed and secreted full-length or suitably truncated proteins during vegetative growth when, under normal conditions, these proteins are not made. The gene constructs divided the CelA protein into three domains: a 461-amino-acid N-terminal region that has significant similarity to those of other cellulases and that has been shown to be the catalytic domain; a contiguous 91-residue repeat containing the motif threonine-glutamic acid-threonine-proline, which is glycosylated; and, joined to the repeat, a C-terminal 153-amino-acid sequence that most probably defines a cellulose-binding domain.

Codon preference in Dictyostelium discoideum

Dictyostelium discoideum is of increasing interest as a model eukaryotic cell because its many attributes have recently been expanded to include improved genetic and biochemical manipulability. The ability to transform Dictyostelium using drug resistance as a selectable marker (1) and to gene target by high frequency homologous integration (2) makes this organism particularly useful for molecular genetic approaches to cell structure and function. Given this background, it becomes important to analyze the codon preference used in this organism. Dictyostelium displays a strong and unique overall codon preference. This preference varies between different coding regions and even varies between coding regions from the same gene family. The degree of codon preference may be correlated with expression levels but not with the developmental time of expression of the gene product. The strong codon preference can be applied to identify coding regions in Dictyostelium DNA and aid in the design of oligonucleotide probes for cloning Dictyostelium genes.

Structure of two developmentally regulated Dictyostelium discoideum ubiquitin genes

A previously isolated cDNA clone, pLK229, that is specific for mRNA developmentally expressed during Dictyostelium discoideum spore germination and multicellular development, was used to screen two genomic libraries. Two genomic sequences homologous to pLK229 were isolated and sequenced. Genomic clone p229 is identical to the cDNA clone pLK229 and codes for a polypeptide of 381 amino acids. This polypeptide is composed of five tandem repeats of the same 76-amino-acid sequence. Clone lambda 229 codes for a protein of 229 amino acids, containing three tandem repeats of the identical 76-amino-acid sequence. A computer search for homology to known proteins revealed that the 76-amino-acid repeat was identical to human and bovine ubiquitin except for two amino acid differences.

Structure of two developmentally regulated Dictyostelium discoideum ubiquitin genes

A previously isolated cDNA clone, pLK229, that is specific for mRNA developmentally expressed during Dictyostelium discoideum spore germination and multicellular development, was used to screen two genomic libraries. Two genomic sequences homologous to pLK229 were isolated and sequenced. Genomic clone p229 is identical to the cDNA clone pLK229 and codes for a polypeptide of 381 amino acids. This polypeptide is composed of five tandem repeats of the same 76-amino-acid sequence. Clone lambda 229 codes for a protein of 229 amino acids, containing three tandem repeats of the identical 76-amino-acid sequence. A computer search for homology to known proteins revealed that the 76-amino-acid repeat was identical to human and bovine ubiquitin except for two amino acid differences.

Changes in the pattern of protein synthesis during zoospore germination in Blastocladiella emersonii

Using two-dimensional gel electrophoresis, we analyzed the pattern of proteins synthesized during Blastocladiella emersonii zoospore germination in an inorganic solution, in both the presence and absence of actinomycin D. During the transition from zoospore to round cells (the first 25 min), essentially no qualitative differences were noticeable, indicating that the earliest stages of germination are entirely preprogrammed with stored RNA. Later in germination (after 25 min), however, changes in the pattern of protein synthesis were found. Some of these proteins (a total of 6 polypeptides) correspond possibly to a selective translation of stored messages, whereas the majority of the changed proteins (22 polypeptides) corresponds to newly synthesized mRNA. Thus, multiple levels of protein synthesis regulation seem to occur during zoospore germination, involving both transcriptional and translational controls. We also analyzed the pattern of protein synthesis during germination in a nutrient medium; synthesis of specific polypeptides occurred during late germination. During early germination posttranslational control was also observed, several labeled proteins from zoospores being specifically degraded or charge modified.

Role of protein synthesis in decay and accumulation of mRNA during spore germination in the cellular slime mold Dictyostelium discoideum

Spore germination in Dictyostelium discoideum is a particularly suitable model for studying the regulation of gene expression, since developmentally regulated changes in both protein and mRNA synthesis occur during the transition from dormant spore to amoeba. The previous isolation of three cDNA clones specific for mRNA developmentally regulated during spore germination allowed for the quantitation of the specific mRNAs during this process. The three mRNAs specific to clones pLK109, pLK229, and pRK270 have half-lives much shorter (minutes) than those of constitutive mRNAs (hours). Using spore germination as a model, we studied the roles of ribosome-mRNA interactions and protein synthesis in mRNA degradation by using antibiotics that inhibit specific reactions in protein biosynthesis. Cycloheximide inhibits the elongation step of protein synthesis. Polysomes accumulate in inhibited cells because ribosomes do not terminate normally and new ribosomes enter the polysome, eventually saturating the mRNA. Pactamycin inhibits initiation, and consequently polysomes break down in the presence of this drug. Under this condition, the mRNA is essentially free of ribosomes. pLK109, pLK229, and pRK270 mRNAs were stabilized in the presence of cycloheximide, but pactamycin had no effect on their normal decay. Since it seems likely that stability of mRNA reflects the availability of sites for inactivation by nucleases, it follows that in the presence of cycloheximide, these sites are protected, presumably by occupancy by ribosomes. No ribosomes are bound to mRNA in the presence of pactamycin, and therefore mRNA degrades at about the normal rate. The data further indicate that a labile protein is probably not involved in mRNA decay or stabilization, since protein synthesis is inhibited equally by both antibiotics. We conclude that it may be important to use more than one type of protein synthesis inhibitor to evaluate whether protein synthesis is required for mRNA decay. The effect of protein synthesis inhibition on mRNA synthesis and accumulation was also studied. mRNA synthesis continues in the presence of inhibitors, albeit at a diminished rate relative to that of the uninhibited control.

Role of protein synthesis in decay and accumulation of mRNA during spore germination in the cellular slime mold Dictyostelium discoideum

Spore germination in Dictyostelium discoideum is a particularly suitable model for studying the regulation of gene expression, since developmentally regulated changes in both protein and mRNA synthesis occur during the transition from dormant spore to amoeba. The previous isolation of three cDNA clones specific for mRNA developmentally regulated during spore germination allowed for the quantitation of the specific mRNAs during this process. The three mRNAs specific to clones pLK109, pLK229, and pRK270 have half-lives much shorter (minutes) than those of constitutive mRNAs (hours). Using spore germination as a model, we studied the roles of ribosome-mRNA interactions and protein synthesis in mRNA degradation by using antibiotics that inhibit specific reactions in protein biosynthesis. Cycloheximide inhibits the elongation step of protein synthesis. Polysomes accumulate in inhibited cells because ribosomes do not terminate normally and new ribosomes enter the polysome, eventually saturating the mRNA. Pactamycin inhibits initiation, and consequently polysomes break down in the presence of this drug. Under this condition, the mRNA is essentially free of ribosomes. pLK109, pLK229, and pRK270 mRNAs were stabilized in the presence of cycloheximide, but pactamycin had no effect on their normal decay. Since it seems likely that stability of mRNA reflects the availability of sites for inactivation by nucleases, it follows that in the presence of cycloheximide, these sites are protected, presumably by occupancy by ribosomes. No ribosomes are bound to mRNA in the presence of pactamycin, and therefore mRNA degrades at about the normal rate. The data further indicate that a labile protein is probably not involved in mRNA decay or stabilization, since protein synthesis is inhibited equally by both antibiotics. We conclude that it may be important to use more than one type of protein synthesis inhibitor to evaluate whether protein synthesis is required for mRNA decay. The effect of protein synthesis inhibition on mRNA synthesis and accumulation was also studied. mRNA synthesis continues in the presence of inhibitors, albeit at a diminished rate relative to that of the uninhibited control.

Dictyostelium discoideum mRNAs developmentally regulated during spore germination have short half-lives

mRNA decay was studied during spore germination in Dictyoselium discoideum by the use of three previously isolated cDNA clones, pLK109, pLK229, and pRK270, which are specific for mRNAs developmentally regulated during spore germination. The half-life of a constitutive mRNA, pLK125, which is present throughout germination, growth, and development, as also determined. Nogalamycin, a DNA-intercalating compound, was used to inhibit RNA synthesis. Total RNA was isolated at intervals after addition of the drug, and the decay of mRNAs specific for the cDNA clones was determined by both Northern blot and RNA dot hybridization. If nogalamycin was added immediately after activation of dormant spores, neither pLK229 nor pLK109 mRNA decayed, but pLK125 mRNA did decay. Although pLK109 mRNA did not decay under these conditions, the RNA was smaller 1 h after activation than in dormant spores, indicating that it was processed normally. At 1 h after activation, pLK229-, pLK125-specific mRNAs decayed exponentially, with half-lives of 24, 39, and 165 min, respectively. Under the same conditions, decay of pLK109-specific mRNA was biphasic. Thirty-eight percent of the mRNA decayed with a half-life of 5.5 min, and the remainder decayed with a half-life of 115 min. It seems likely that nogalamycin inhibits the synthesis of an unstable component of the mRNA degradative pathway which is needed continuously for the decay of pLK109 mRNA. By extrapolating the curve representing the rapidly decaying component, a half-life of 18 min was calculated for pLK109-specific mRNA. The mRNAs developmentally regulated during spore germination have half-lives shorter than that of the constitutive messenger and shorter than the average half-life of 3 to 4 h previously determined for total Dicyostelium polyadenylated mRNA.

Dictyostelium discoideum mRNAs developmentally regulated during spore germination have short half-lives

mRNA decay was studied during spore germination in Dictyoselium discoideum by the use of three previously isolated cDNA clones, pLK109, pLK229, and pRK270, which are specific for mRNAs developmentally regulated during spore germination. The half-life of a constitutive mRNA, pLK125, which is present throughout germination, growth, and development, as also determined. Nogalamycin, a DNA-intercalating compound, was used to inhibit RNA synthesis. Total RNA was isolated at intervals after addition of the drug, and the decay of mRNAs specific for the cDNA clones was determined by both Northern blot and RNA dot hybridization. If nogalamycin was added immediately after activation of dormant spores, neither pLK229 nor pLK109 mRNA decayed, but pLK125 mRNA did decay. Although pLK109 mRNA did not decay under these conditions, the RNA was smaller 1 h after activation than in dormant spores, indicating that it was processed normally. At 1 h after activation, pLK229-, pLK125-specific mRNAs decayed exponentially, with half-lives of 24, 39, and 165 min, respectively. Under the same conditions, decay of pLK109-specific mRNA was biphasic. Thirty-eight percent of the mRNA decayed with a half-life of 5.5 min, and the remainder decayed with a half-life of 115 min. It seems likely that nogalamycin inhibits the synthesis of an unstable component of the mRNA degradative pathway which is needed continuously for the decay of pLK109 mRNA. By extrapolating the curve representing the rapidly decaying component, a half-life of 18 min was calculated for pLK109-specific mRNA. The mRNAs developmentally regulated during spore germination have half-lives shorter than that of the constitutive messenger and shorter than the average half-life of 3 to 4 h previously determined for total Dicyostelium polyadenylated mRNA.