Half-lives of messenger RNA species during growth and differentiation of Dictyostelium discoideum

Specific cell-cell contacts are essential for induction of gene expression during differentiation of Dictyostelium discoideum

Postaggregation Dictyostelium discoideum cells contain 2000-3000 mRNA species that are absent from pre-aggregation cells. These aggregation-dependent sequences compose 30% of the mass of the late mRNA and represent the transcription products of an additional 11% of the single-copy genome. By analysis of mutants that are blocked at different stages of differentiation, we show that induction of expression of these genes is correlated with the formation of tight cell-cell contacts that resist EDTA. In particular, mutants that exhibit chemotaxis and aggregate to form loose mounds but do not form cell-cell contacts that resist EDTA fail to induce these late mRNA and protein species. By contrast, mutants that form normal contacts but progress no further through development do express the late mRNA species. Thus, interactions at the cell surface are involved in developmental induction of a large group of coregulated mRNAs. We have employed two independent assays for these developmentally regulated mRNAs: hybridization of gel-separated RNAs to cloned nuclear DNAs and hybridization of mRNA to a cDNA probe specific for the population of 2000-3000 regulated sequences.

Dictyostelium discoideum gene family contains a long internal amino acid repeat

Two different cDNA clones denoted pTO270-6 and pTO270-11 represent two mRNAs that are developmentally regulated during spore germination in Dictyostelium discoideum. The respective mRNAs are found only during early germination and are not present in other stages of growth or multicellular development. Four different genomic clones that hybridize to sequences that are common to both of the 270 cDNA clones were isolated from Dictyostelium libraries and sequenced. Two are the genes for the two cDNAs, and the other two represent genes that do not seem to be transcribed. All four genomic sequences possess a very unusual internal feature in the deduced protein sequences composed of a monotonous repeat of the tetrapeptide threonine-glutamic acid-threonine-proline. The other portions of the proteins have no homology among themselves. The deduced protein corresponding to the 270-6 gene is very similar to avocado (Persea americana) cellulase. Since cellulose in the spore wall has to be digested during spore germination this suggests that this protein may function as an endo-(1,4)-beta-D-glucanase during germination.

Differential regulation of glycoprotein sulfation and fucosylation during growth of Dictyostelium discoideum

During early starvation-induced development, amoebae of Dictyostelium discoideum have been previously shown to increase sulfation and fucosylation of glycoprotein-linked oligosaccharides to levels above those observed in axenically growing cells. We report here that the axenic broth culture itself induces generation of high levels of fucosylated glycoprotein-linked oligosaccharides at all stages in the growth curve. However, when grown on bacteria, amoebae of both the axenic strain and the wild type show dramatic depression in fucose incorporation during early exponential growth. In mid- and late-exponential stages of growth, fucosylation rises to the levels found at all stages of axenic culture. Sulfation also increases during early development, but, in contrast to fucosylation, oligosaccharide sulfation is not altered by growth in axenic medium and does not increase during growth on bacteria. Starvation of bacterially grown cells results in increased sulfation and a further rise in fucosylation, as is also characteristic of broth-grown cells. The ability of axenic culture to uncouple control of these two classes of glycan-modification steps suggests that the synchronous increases during early development actually reflect responses to different regulatory signals, even though they participate in the same metabolic process. The increase in in vivo fucosyltransferase activity, which can act on many substrate glycoproteins, may alter many characteristics of the cells.

mRNA decay rates in late-developing Dictyostelium discoideum cells are heterogeneous, and cyclic AMP does not act directly to stabilize cell-type-specific mRNAs

We reevaluated the use of 32PO4 pulse-chases for analyzing mRNA decay rates in late-developing Dictyostelium cells. We found that completely effective PO4 chases could not be obtained in developing cells and that, as a consequence, the decay rates exhibited by some mRNAs were influenced by the rates at which they were transcribed. In developing cells disaggregated in the presence of cyclic AMP, the poly(A)+ mRNA population turned over with an apparent half-life of 4 h, individual mRNA decay rates were heterogeneous, and some prestalk and prespore mRNAs appeared to decay with biphasic kinetics. In cells disaggregated in the absence of cyclic AMP, all prestalk and prespore mRNAs decayed with biphasic kinetics. During the first 1 to 1.5 h after disaggregation in the absence of cyclic AMP, the cell-type-specific mRNAs were selectively degraded, decaying with half-lives of 20 to 30 min; thereafter, the residual prestalk and prespore mRNA molecules decayed at rates that were similar to those measured in the presence of cyclic AMP. This short-term labilization of cell-type-specific mRNAs was observed even for those species not requiring cyclic AMP for their accumulation in developing cells. The observation that cell-type specific mRNAs can decay at similar rates in disaggregated cells with or without cyclic AMP indicates that this compound does not act directly to stabilize prestalk and prespore mRNAs during development and that its primary role in the maintenance of cyclic-AMP-dependent mRNAs is likely to be transcriptional.

mRNA decay rates in late-developing Dictyostelium discoideum cells are heterogeneous, and cyclic AMP does not act directly to stabilize cell-type-specific mRNAs

We reevaluated the use of 32PO4 pulse-chases for analyzing mRNA decay rates in late-developing Dictyostelium cells. We found that completely effective PO4 chases could not be obtained in developing cells and that, as a consequence, the decay rates exhibited by some mRNAs were influenced by the rates at which they were transcribed. In developing cells disaggregated in the presence of cyclic AMP, the poly(A)+ mRNA population turned over with an apparent half-life of 4 h, individual mRNA decay rates were heterogeneous, and some prestalk and prespore mRNAs appeared to decay with biphasic kinetics. In cells disaggregated in the absence of cyclic AMP, all prestalk and prespore mRNAs decayed with biphasic kinetics. During the first 1 to 1.5 h after disaggregation in the absence of cyclic AMP, the cell-type-specific mRNAs were selectively degraded, decaying with half-lives of 20 to 30 min; thereafter, the residual prestalk and prespore mRNA molecules decayed at rates that were similar to those measured in the presence of cyclic AMP. This short-term labilization of cell-type-specific mRNAs was observed even for those species not requiring cyclic AMP for their accumulation in developing cells. The observation that cell-type specific mRNAs can decay at similar rates in disaggregated cells with or without cyclic AMP indicates that this compound does not act directly to stabilize prestalk and prespore mRNAs during development and that its primary role in the maintenance of cyclic-AMP-dependent mRNAs is likely to be transcriptional.

Determinants of mRNA stability in Dictyostelium discoideum amoebae: differences in poly(A) tail length, ribosome loading, and mRNA size cannot account for the heterogeneity of mRNA decay rates

As an approach to understanding the structures and mechanisms which determine mRNA decay rates, we have cloned and begun to characterize cDNAs which encode mRNAs representative of the stability extremes in the poly(A)+ RNA population of Dictyostelium discoideum amoebae. The cDNA clones were identified in a screening procedure which was based on the occurrence of poly(A) shortening during mRNA aging. mRNA half-lives were determined by hybridization of poly(A)+ RNA, isolated from cells labeled in a 32PO4 pulse-chase, to dots of excess cloned DNA. Individual mRNAs decayed with unique first-order decay rates ranging from 0.9 to 9.6 h, indicating that the complex decay kinetics of total poly(A)+ RNA in D. discoideum amoebae reflect the sum of the decay rates of individual mRNAs. Using specific probes derived from these cDNA clones, we have compared the sizes, extents of ribosome loading, and poly(A) tail lengths of stable, moderately stable, and unstable mRNAs. We found (i) no correlation between mRNA size and decay rate; (ii) no significant difference in the number of ribosomes per unit length of stable versus unstable mRNAs, and (iii) a general inverse relationship between mRNA decay rates and poly(A) tail lengths. Collectively, these observations indicate that mRNA decay in D. discoideum amoebae cannot be explained in terms of random nucleolytic events. The possibility that specific 3'-structural determinants can confer mRNA instability is suggested by a comparison of the labeling and turnover kinetics of different actin mRNAs. A correlation was observed between the steady-state percentage of a given mRNA found in polysomes and its degree of instability; i.e., unstable mRNAs were more efficiently recruited into polysomes than stable mRNAs. Since stable mRNAs are, on average, "older" than unstable mRNAs, this correlation may reflect a translational role for mRNA modifications that change in a time-dependent manner. Our previous studies have demonstrated both a time-dependent shortening and a possible translational role for the 3' poly(A) tracts of mRNA. We suggest, therefore, that the observed differences in the translational efficiency of stable and unstable mRNAs may, in part, be attributable to differences in steady-state poly(A) tail lengths.

Determinants of mRNA stability in Dictyostelium discoideum amoebae: differences in poly(A) tail length, ribosome loading, and mRNA size cannot account for the heterogeneity of mRNA decay rates

As an approach to understanding the structures and mechanisms which determine mRNA decay rates, we have cloned and begun to characterize cDNAs which encode mRNAs representative of the stability extremes in the poly(A)+ RNA population of Dictyostelium discoideum amoebae. The cDNA clones were identified in a screening procedure which was based on the occurrence of poly(A) shortening during mRNA aging. mRNA half-lives were determined by hybridization of poly(A)+ RNA, isolated from cells labeled in a 32PO4 pulse-chase, to dots of excess cloned DNA. Individual mRNAs decayed with unique first-order decay rates ranging from 0.9 to 9.6 h, indicating that the complex decay kinetics of total poly(A)+ RNA in D. discoideum amoebae reflect the sum of the decay rates of individual mRNAs. Using specific probes derived from these cDNA clones, we have compared the sizes, extents of ribosome loading, and poly(A) tail lengths of stable, moderately stable, and unstable mRNAs. We found (i) no correlation between mRNA size and decay rate; (ii) no significant difference in the number of ribosomes per unit length of stable versus unstable mRNAs, and (iii) a general inverse relationship between mRNA decay rates and poly(A) tail lengths. Collectively, these observations indicate that mRNA decay in D. discoideum amoebae cannot be explained in terms of random nucleolytic events. The possibility that specific 3'-structural determinants can confer mRNA instability is suggested by a comparison of the labeling and turnover kinetics of different actin mRNAs. A correlation was observed between the steady-state percentage of a given mRNA found in polysomes and its degree of instability; i.e., unstable mRNAs were more efficiently recruited into polysomes than stable mRNAs. Since stable mRNAs are, on average, "older" than unstable mRNAs, this correlation may reflect a translational role for mRNA modifications that change in a time-dependent manner. Our previous studies have demonstrated both a time-dependent shortening and a possible translational role for the 3' poly(A) tracts of mRNA. We suggest, therefore, that the observed differences in the translational efficiency of stable and unstable mRNAs may, in part, be attributable to differences in steady-state poly(A) tail lengths.

Regulation of mRNA stability and the poly(A) problem in Dictyostelium discoideum

This paper reviews our studies of three aspects of post-transcriptional regulation in Dictyostelium discoideum: 1) the determinants of mRNA stability in vegetative amoebae; 2) the effects of disaggregation and cyclic AMP on the decay rates of cell-type-specific mRNAs in late developing cells; and 3) the cytoplasmic function of the 3' poly(A) tracts present on most mRNAs. We find that: 1) mRNA stability in vegetative amoebae is not dependent on mRNA size, ribosome loading, or poly(A) tract length, but may be determined by specific 3'-untranslated sequences within a given mRNA; 2) mRNA decay rates in late developing cells are heterogeneous, and cyclic AMP does not act directly to stabilize cell-type-specific mRNAs; and 3) poly(A) is most likely involved in the initiation of protein synthesis via an interaction with cytoplasmic poly(A)-binding proteins.

Organization of the actin multigene family of Dictyostelium discoideum and analysis of variability in the protein coding regions

There are 17 to 20 actin genes in the genome of the cellular slime mold Dictyostelium discoideum. Genomic clones of 15 of the genes have been isolated. Extensive nucleotide sequence within the protein-coding regions has been determined, including the complete nucleotide sequence of four genes representing the three distinct evolutionary groups of Dictyostelium actin genes. All are similar to mammalian cytoplasmic actins at diagnostic amino acid positions, and there is generally less variability among Dictyostelium actin genes than among Drosophila actin genes. Two genes, Actins 3-sub 1 and 3-sub 2 differ substantially from all the rest in terms of replacement amino acid substitutions and probably encode actin-related proteins rather than bona fide actins. Each contains several amino acid substitutions that should alter the secondary structure of the resulting proteins, and Actin 3-sub 2 encodes four additional amino acids at the C terminus. This gene is as divergent from other Dictyostelium actin genes as is the yeast or a soybean actin gene. At present, evidence suggests that all 15 genes examined are expressed, except the previously identified Actin 2-sub 2. We suggest that Dictyostelium might maintain a high number of functional actin genes for the purpose of regulating the level of actin synthesis within narrow limits, rather than because most genes perform different functions.

Gene-specific expression of the actin multigene family of Dictyostelium discoideum

We have investigated the expression of 14 cloned genes of the 20-member actin multigene family of Dictyostelium discoideum using gene-specific mRNA complementary probes and an RNase protection assay. Actin gene expression was studied in vegetative cells and in cells at a number of developmental stages chosen to represent the known major shifts in actin mRNA and protein synthesis. At least 13 of these genes are expressed. A few genes are expressed very abundantly at 10% or more of total actin mRNA; however, the majority are maximally expressed at 1 to 5% of actin message. Although all of the genes are transcribed in vegetative cells, most genes appear to be independently regulated. Actin 8 appears to be transcribed at constant, high levels throughout growth and development. Actin 12 mRNA is maximally expressed in vegetative cells but the level is reduced appreciably by the earliest stage of development examined, while Actin 7 mRNA is specifically induced approximately sevenfold at this time. The rest of the genes appear to be induced 1.5 to 2-fold early in development, coincident with the increase in total actin mRNA. Since 12 of the genes code for extremely homologous proteins, it is possible that the large number of actin genes in Dictyostelium is utilized for precise regulation of the amount of actin produced at any stage of development, even though individual gene expression appears in some cases to be very stage-specific. In addition to these 13 actin genes, at least two and possibly four more genes are known to be expressed, because they are represented by complementary DNA clones, and an additional one or two expressed genes are indicated by primer extension experiments. Only one known gene, Actin 2-sub 2, is almost certainly a pseudogene. Thus the vast majority of Dictyostelium actin genes are expressed.

Differential stability of Drosophila embryonic mRNAs during subsequent larval development

The relative stabilities of specific embryonic mRNAs that persist in Drosophila melanogaster larvae were determined using an approach that combined RNA density labeling with cell-free translation. Unlike the other methods commonly used to measure the decay of individual mRNAs, the density labeling approach does not depend on the use of transcriptional inhibitors or on the measurement of precursor pool specific activities. Using this approach, we have determined that different embryonic mRNA species persist for varying periods during subsequent development, with half-lives ranging from approximately 2 to approximately 30 h. The embryonic histone mRNAs are relatively unstable; they are no longer detectable by 9 h of larval development. By 41 h of larval development, 90% of the nonhistone mRNAs assayed have decayed considerably; computerized scanning densitometry of translation products indicates that these transcripts are not decaying as members of discrete half-life classes. The persisting mRNAs that remain are very long-lived; their in vitro translation products can still be detected after 91 h of larval development. We have tentatively identified the mRNAs that encode actin, tropomyosin, and tubulin as members of this stable mRNA population. Although embryonic mRNAs do fall into these three broad classes of stability, they appear to decay with a continuum of half-lives. Because the range of half-lives is so great, mRNA stability is probably an important factor controlling mRNA abundance during Drosophila development.

Organization of the Dictyostelium discoideum actin multigene family. Flanking sequences show subfamily homologies and unusual dyad symmetries

Sequences flanking the protein-coding regions of 15 of the 17 to 20 actin genes in the cellular slime mold Dictyostelium discoidium have been determined. Comparison of sequences among genes shows that they contain extensive homologies at both the 5' and 3' ends of the coding regions. On the basis of these homologies, actin genes fall into three groups. Group I consists of Actin 8 alone. Group II consists of the two closely linked genes Actin 3-sub1 and Actin 3-sub2. These two genes differ from all other actin genes in the location of their TATA box and oligo(dT) run, and diverge substantially in their coding sequence as well. Group III contains all the rest of the genes we have studied. Within this group, there are two subgroups of genes, IIIA (Actins 5, 9 and 10) and IIIB (Actins M6, 2-sub1 and 2-sub2, 4, 6, 7, 11 and 12). Two actin cDNA clones, ITL-1 and III-12/A1, which have no cloned genomic counterparts, are members of groups IIIA and IIIB, respectively. Homologies at the 3' ends of genes do not extend beyond a short genomic poly(A) sequence, the probable termination of transcription. Homologies at the 5' ends may extend about 300 base-pairs 5' to the ATG but, in most cases, extend only about 150 base-pairs 5' to the ATG. We have identified a group of short, relatively G + C-rich sequences within the extremely A + T-rich sequence at the 5' ends of actin-coding regions, which are shared among different actin genes. Many of these sequences exhibit dyad symmetry, and their general location and order is conserved among the different actin genes. We suggest that they may have a role in regulation of the transcriptional patterns of individual actin genes.

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.

Expression of a spore-specific gene in Dictyostelium discoideum

The expression of a previously cloned Dictyostelium discoideum spore-specific gene (Julien et al., EMBO J. 1, 1089-1093 (1982)) was investigated in wild type and mutant strains. In vitro translation of this spore-specific mRNA gave a protein of a molecular weight consistent with the mRNA size. Expressed at a low level during vegetative growth development and in stalk cells, the accumulation of this mRNA reached high values only in spore cells.

Cyclic AMP stabilizes a class of developmentally regulated Dictyostelium discoideum mRNAs

The stability of mRNA is an important facet of the regulation of protein synthesis. In mammalian cells most mRNAs have long half-lives (5-15 hours) but a substantial fraction are much less stable. There are few examples where the stability of a particular mRNA or class of mRNAs is specifically affected by environmental or developmental stimuli. Certain hormones cause specific stabilization of mRNAs species and preferential mRNA stability is important in the accumulation of globin and myosin mRNAs during the terminal stages of erythropoesis or myogenesis, respectively. Disaggregation of Dictyostelium discoideum aggregates induces the specific destabilization of a large class of developmentally regulated mRNAs; thus, this system is an excellent one in which to determine how such controls are effected. Here we show that addition of cyclic AMP to disaggregated cells specifically prevents the destabilization of these mRNAs.

Messenger RNA half-life in Dictyostelium discoideum

Messenger RNA half-life in vegetatively growing cells of Dictyostelium discoideum was determined using a uridine pulse-chase procedure. In these experiments, mRNA decayed in a complex fashion, and consisted of at least two major components, one with a half-life of about 50 min and a second with a half-life of about 10 hr. These results independently confirm our previous studies on the decay of mRNA extracted from actinomycin D-treated cells. Since these results were in apparent conflict with half-life determinations obtained with a combination of actinomycin D and daunomycin (J. P. Margolskee and H. F. Lodish, 1980a, Dev. Biol. 74, 37-49), we have also studied mRNA half-life in cells treated with a combination of both drugs and found that simultaneous use of both drugs leads to accelerated mRNA decay and other noticeable side effects. In light of our observations, we have suggested an alternative to conclusions drawn by others with respect to mRNA synthesis and stability in Dictyostelium development.

Differential expression and 5' end mapping of actin genes in Dictyostelium

Using a modification of the Berk and Sharp S1 nuclease mapping procedure and by analyzing actin cDNA clones, we have examined the expression of several members of the 17-member multigene family encoding actin in Dictyostelium. The mapping procedure, which takes advantage of the fact that the actin genes are homologous in the protein-coding region but are very divergent in the proposed 5' untranslated region has enabled us to quantitate the relative expression of several genes during the Dictyostelium life cycle. We have shown that at least six of the 17 potential actin-coding sequences are expressed. One is not expressed at levels of more than 0.5--1% of total actin mRNA at the developmental times examined and appears to be a pseudogene. By quantitating the amount of actin mRNA in mRNA populations isolated from cells at various times in development, we have shown that four of the actin genes show different patterns of expression. Interestingly, three of the four genes appear to encode the same protein. We have also taken advantage of the S1 mapping procedure to identify the 5' ends of the actin mRNAs from four genes and have compared the sequences outside the 5' ends on these genes with the nucleotide sequences of seven other actin genes. We have identified homologous sequences in most of these genes that may be involved in initiation of transcription.

Synthesis and stability of developmentally regulated dictyostelium mRNAs are affected by cell--cell contact and cAMP

Postaggregation Dictyostelium discoideum cells contain 3000 mRNA species that are absent from preaggregation cells; these aggregation-dependent sequences comprise 30% of the mass of mRNA in these cells. We show that the synthesis and stability of these regulated mRNA sequences are affected by both cell--cell contact and cAMP. Three independent assays are used to quantitate these mRNAs: in vitro translation followed by two-dimensional gel analysis of the protein products; hybridization of gel-separated RNAs to cloned DNAs; and hybridization of mRNA to a cDNA probe specific for the population of regulated sequences. In postaggregation cells, the half-life of both the developmentally regulated mRNAs and the constitutive mRNAs present throughout growth and differentiation is the same--about 4 hr. Following disaggregation, all of the late mRNA sequences are degraded and decay with a half-life of 25 to 45 min. The constitutive species are unaffected; 2.5 hr after disaggregation, the ratio of late to constitutive mRNAs is about 6% that of normal plated cells. Addition of cAMP to cells that have been disaggregated for 2.5 hr (or longer) restores the level of most late mRNAs within 3 hr. We conclude that cAMP stimulates the synthesis of these mRNAs and may also act to stabilize them in the cytoplasm. This effect of cAMP is dependent on the cells having been in contact with other cells; cAMP has no effect on the levels of mRNA in suspension-starved, aggregation-competent cells that have never formed cell--cell aggregates.

Nogalamycin inhibits ribonucleic acid synthesis in growing and developing cells of the slime mold Dictyostelium discoideum

Nogalamycin, an anthracycline antibiotic that intercalates into deoxyribonucleic acid, is a potent inhibitor of ribonucleic acid (RNA) synthesis in the slime mold Dictyostelium discoideum. The antibiotic inhibits RNA synthesis in growing cells and in inactivated spores, and in this way inhibits spore germination. Protein synthesis is much less inhibited. Nogalamycin inhibits ribosomal RNA, transfer RNA, and messenger RNA equally. Polysomes break down in the presence of the drug with a half-life of 220 min, and messenger RNA decays with a half-life of 290 min. The data show that nogalamycin can be employed to inhibit messenger RNA synthesis and is useful in determining messenger RNA decay rates in the slime mold.

A change in the rate of transcription of a eukaryotic gene in response to cyclic AMP

The plasmid pDd812 contains the DNA copy of an mRNA sequence from Dictyostelium discoideum that undergoes first an increase and then a decrease in concentration during the first few hours of differentiation. We have recently shown that the mRNA sequence complementary to pDd812 encodes discoidin I, a developmentally regulated lectin that may play a role in cellular cohesion. By using pDd812 as a hybridization probe, we found that addition of cyclic AMP during the first few hours of development inhibited the accumulation of discoidin I mRNA. By measuring the rate of transcription in isolated nuclei, we showed that, at least in part, this inhibition results from a rapid and specific reduction in the rate of transcription of the discoidin I gene. Addition of cyclic AMP during the first few hours of development inhibited the accumulation of discoidin I mRNA. By measuring the rate of transcription in isolated nuclei, we showed that, at least in part, this inhibition results from a rapid and specific reduction in the rate of transcription of the discoidin I gene. Addition of cyclic AMP during the first few hours of development inhibited the accumulation of discoidin I mRNA. By measuring the rate of transcription in isolated nuclei, we showed that, at least in part, this inhibition results from a rapid and specific reduction in the rate of transcription of the discoidin I gene. Addition of high external concentrations of cAMP is known to increase the intracellular concentration to a level normally found later in development. This natural increase in cAMP concentration occurs at the time during development when transcription of the discoidin I gene ceases. We suggest, therefore, that changes in the intracellular concentration of cAMP act at the level of transcription to control gene expression during development. This hypothesis is supported by our observation that several poly(A)+RNA sequences that normally accumulate after transcription of the discoidin I gene has ceased are synthesized prematurely in cells exposed to exogenous cAMP.