Changes during differentiation in requirements for cAMP for expression of cell-type-specific mRNAs in the cellular slime mold, Dictyostelium discoideum

Ndm, a coiled-coil domain protein that suppresses macropinocytosis and has effects on cell migration

The ampA gene has a role in cell migration in Dictyostelium discoideum. Cells overexpressing AmpA show an increase in cell migration, forming large plaques on bacterial lawns. A second-site suppressor of this ampA-overexpressing phenotype identified a previously uncharacterized gene, ndm, which is described here. The Ndm protein is predicted to contain a coiled-coil BAR-like domain-a domain involved in endocytosis and membrane bending. ndm-knockout and Ndm-monomeric red fluorescent protein-expressing cell lines were used to establish a role for ndm in suppressing endocytosis. An increase in the rate of endocytosis and in the number of endosomes was detected in ndm(-) cells. During migration ndm(-) cells formed numerous endocytic cups instead of the broad lamellipodia structure characteristic of moving cells. A second lamellipodia-based function-cell spreading-was also defective in the ndm(-) cells. The increase in endocytosis and the defect in lamellipodia formation were associated with reduced chemotaxis in ndm(-) cells. Immunofluorescence results and glutathione S-transferase pull-down assays revealed an association of Ndm with coronin and F-actin. The results establish ndm as a gene important in regulating the balance between formation of endocytic cups and lamellipodia structures.

Evidence of an evolutionarily conserved LMBR1 domain-containing protein that associates with endocytic cups and plays a role in cell migration in dictyostelium discoideum

The ampA gene plays a role in Dictyostelium discoideum cell migration. Loss of ampA function results in reduced ability of growing cells to migrate to folic acid and causes small plaques on bacterial lawns, while overexpression of AmpA results in a rapid-migration phenotype and correspondingly larger plaques than seen with wild-type cells. To help understand how the ampA gene functions, second-site suppressors were created by restriction enzyme-mediated integration (REMI) mutagenesis. These mutants were selected for their ability to reduce the large plaque size of the AmpA overexpresser strain. The lmbd2B gene was identified as a suppressor of an AmpA-overexpressing strain. The lmbd2B gene product belongs to the evolutionarily conserved LMBR1 protein family, some of whose known members are endocytic receptors associated with human diseases, such as anemia. In order to understand lmbd2B function, mRFP fusion proteins were created and lmbd2B knockout cell lines were established. Our findings indicate that the LMBD2B protein is found associated with endocytic cups. It colocalizes with proteins that play key roles in endocytic events and is localized to ruffles on the dorsal surfaces of growing cells. Vegetative lmbd2B-null cells display defects in cell migration. These cells have difficulty sensing the chemoattractant folic acid, as indicated by a decrease in their chemotactic index. lmbd2B-null cells also appear to have difficulty establishing a front/back orientation to facilitate migration. A role for lmbd2B in development is also suggested. Our research gives insight into the function of a previously uncharacterized branch of the LMBR1 family of proteins. We provide evidence of an LMBR1 family plasma membrane protein that associates with endocytic cups and plays a role in chemotaxis.

A novel Dictyostelium gene encoding multiple repeats of adhesion inhibitor-like domains has effects on cell-cell and cell-substrate adhesion

The Dictyostelium protein AmpA (adhesion modulation protein A) is encoded by the gene originally identified by the D11 cDNA clone. AmpA contains repeated domains homologous to a variety of proteins that influence cell adhesion. The protein accumulates during development, reaching a maximal level at the finger stage. Much of the AmpA protein is found extracellularly during development, and in culminants, AmpA is found in association with anterior-like cells. Characterization of an ampA- strain generated by gene replacement reveals a significant increase in cell-cell clumping when cells are starved in nonnutrient buffer suspensions. Developing ampA- cells are also more adhesive to the underlying substrate and are delayed in developmental progression, with the severity of the delay increasing as cells are grown in the presence of bacteria or on tissue culture dishes rather than in suspension culture. Reintroduction of the ampA gene rescues the developmental defects of ampA- cells; however, expression of additional copies of the gene in wild-type cells results in more severe developmental delays and decreased clumping in suspension culture. We propose that the AmpA protein functions as an anti-adhesive to limit cell-cell and cell-substrate adhesion during development and thus facilitates cell migration during morphogenesis.

A gene encoding a novel anti-adhesive protein is expressed in growing cells and restricted to anterior-like cells during development of Dictyostelium

The Dictyostelium gene ampA, initially identified by the D11 cDNA, encodes a novel anti-adhesive-like protein. The ampA gene product inhibits premature cell agglutination during growth and modulates cell-cell and cell-substrate adhesion during development. Analysis of the promoter indicates that cap site-proximal sequence directs ampA expression during both growth and early development. Expression following tip formation is controlled by more distal sequence, which contains TTGA repeats known to regulate prestalk cell gene expression in other promoters. Comparison of reporter gene expression and endogenous mRNA accumulation indicates that during growth the ampA gene is expressed in an increasing number of cells as a function of density. The number of cells expressing the ampA gene drops as development initiates, but the cells that continue to express the gene do so at high levels. These cells are initially scattered throughout the entire aggregate. By the tip formation stage, however, the majority of ampA-expressing cells are localized to the mound periphery, with only a few cells remaining scattered in the upper portion of the mound. In the final culminant, ampA is expressed only in the upper cup, lower cup, and basal disc. Although reporter expression is observed in cells that migrate anteriorly to a banded region just posterior to the tip, expression is rarely observed in the extreme tip. AmpA protein however, is localized to the tip as well as to ALCs during late development. The results presented here suggest that ampA gene expression is shut off in ALCs that continue along the prestalk differentiation pathway before they are added to the primordial stalk.

cAMP and DIF-1 repress the expression of the Dictyostelium MADS-box gene srfA at early stages of development

The MADS-box-containing gene srfA from Dictyostelium discoideum codes for a putative transcription factor that plays multiple roles in the development of this social amoeba. We have investigated the regulation of srfA gene expression after disaggregation of the cells from developing structures. The steady-state level of srfA mRNA was strongly and transiently induced shortly after disaggregation. srfA is maximally expressed 20 min after cell disaggregation and decreases thereafter. Induction was not dependent on protein synthesis, PKA, the kinase SplA and SrfA itself. This phenomena does not occur when cells are disaggregated in a small volume of buffer, suggesting the presence of extracellular molecules that repress srfA gene expression. To test this hypothesis, several well-known extracellular signaling molecules were studied. We found that srfA mRNA induction can be efficiently repressed by addition of exogenous cAMP and DIF-1 to the buffer in which the cells were disaggregated. Addition of other extracellular compounds such as ammonia, adenosine, SDF-1, and SDF-2 had no effect. srfA promoter P2, specifically induced during slug migration, was responsible for this regulation by extracellular compounds.

Ribosomal protein gene expression is cell type specific during development in Dictyostelium discoideum

Starvation for amino acids initiates the developmental cycle in the cellular slime mold, Dictyostelium discoideum. Upon starvation one of the earliest developmental events is the selective loss of the ribosomal protein mRNAs from polysomes. This loss depends upon sequences in the 5' non-translated leader of the ribosomal protein (r-protein) mRNAs. Here evidence is presented which indicates that those cells which will become prestalk cells express the ribosomal protein genes during development under starvation conditions. Cells which enter the prespore pathway shut off r-protein synthesis. The promoter and 5' non-translated leader sequences from two ribosomal protein genes, the rp-L11 and the rp-S9 genes, are fused to the Escherichia coli beta-galactosidase reporter gene. While beta-galactosidase enzyme activity is detected in situ in most growing cells, by 15 h of development beta-galactosidase enzyme activity is largely lost from the prespore cells although strong beta-galactosidase enzyme activity is present in the prestalk cells. These observations suggest the possibility that the ribosomal protein mRNAs are excluded from polysomes in a cell-type-specific manner.

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].

Analysis of mRNA levels for developmentally regulated prespore specific glutamine synthetase in Dictyostelium discoideum

The enzyme glutamine synthetase (GS) of Dictyostelium discoideum is developmentally regulated, preferentially localized in prespore cells and is likely to play an important role in controlling the levels of ammonia, a known morphogen, in this organism. To further investigate the regulation of GS, a portion of the GS gene was isolated and used as a probe to examine the changes in GS mRNA throughout development and the level of GS mRNA in the two precursor cell types. The amino acid sequence of the cloned DNA fragment isolated is highly homologous to other eukaryotic GS genes. DNA blot analysis demonstrated that the GS gene exists as a single copy in D. discoideum. Analysis of RNA indicated that there is a single 1.7 kb GS transcript that increased during development to peak at the initial stages of culmination. Furthermore, GS mRNA was highly localized in prespore cells, which is consistent with a proposed source-sink model for ammonia assimilation in this organism.

Analysis of a novel cyclic Amp inducible prespore gene in Dictyostelium discoideum: evidence for different patterns of cAMP regulation

The D7 cDNA clone hybridizes to a 2.8 kb mRNA which first appears at the mound stage of development in the cellular slime mold Dictyostelium discoideum. This gene which is cyclic AMP (cAMP) inducible and is expressed specifically in the prespore cells contains an open reading frame interrupted by only one intron. The predicted amino acid sequence indicates a novel prespore protein which differs from all of the previously described prespore proteins in that it contains no internal repeats and does not share any homology with any of the other prespore genes. The amino acid sequence predicts a protein of 850 amino acids with a molecular weight of 95,343 daltons and an isoelectric point of 4.25. The protein is very rich in glutamine (13.8%), asparagine (10.6%) and glutamic acid (10.4%) with one potential glycosylation site and 28 possible sites for phosphorylation. The amino terminus is hydrophobic with characteristics of a signal sequence while the entire carboxyl half of the protein is notable for its hydrophilicity. Comparison of cAMP regulation of the D7 gene with the regulation of two other cAMP regulated prespore genes, the PL3(SP87) gene and the Psa(D19), reveals some striking differences. Disaggregation in the presence of cAMP results in transient degradation of mRNA for all three genes. The transcription rate for the D7 and PsA(D19) genes remains relatively unaffected by disaggregation but there is a rapid although transient decline in the transcription rate of the PL3(SP87) gene. Although the accumulation of all three mRNAs is first detectable at mound stage, transcription of the D7 and PsA(D19) genes is detected earlier in development, at rippling aggregate stage several hours prior to the earliest time when transcription of the PL3(SP87) gene is detected. Analysis of the promoter region of the D7 gene reveals three CA like boxes flanked by direct repeats as well as four G rich regions that may serve as regulatory elements.

Pure populations of Dictyostelium discoideum prespore and prestalk cells obtained by flow cytometry have different redevelopment characteristics at their cell surfaces

The multicellular slug stage of Dictyostelium discoideum consists of two major differentiated cell types: prespore and prestalk cells, which become, respectively, the spores and the stalk of the fruiting body. It is known that these cells, although expressing cell-type-specific proteins, remain totipotent, and experimental disruption of slugs results in redifferentiation taking place. We looked at what happens to cell-type-specific surface molecules when a cell changes from one type of another. Using monoclonal antibodies and flow cytometry we were able for the first time to obtain pure populations of single cells of each cell type. These were analysed during redevelopment. The initial hypothesis was that a proportion of each cell type would redifferentiate to reestablish the original proportions. However, it was found that the two cell types responded quite differently. Whereas almost all prestalk cells retained their prestalk surface antigen, in contrast, all prespore cells redifferentiated. During this process redifferentiating prespore cells simultaneously expressed surface determinants of both cell types, an event not seen in normal development.

Cell-type-specific responsiveness to cAMP in cell differentiation of Dictyostelium discoideum

In Dictyostelium discoideum, both prespore and prestalk differentiation require extracellular cAMP. We investigated the difference in inducibility of the two cell types by cAMP. Previous studies indicate that cAMP added in the early stage of development inhibits prespore differentiation, and this was confirmed using three species of prespore specific mRNAs. By contrast, early treatment with cAMP did not inhibit, but induced the expression of prestalk-specific mRNA. These results indicate that differentiation pathways of the two cell types have different processes in the early stage of development.

Developmental regulation of the alpha-mannosidase gene in Dictyostelium discoideum: control is at the level of transcription and is affected by cell density

In Dictyostelium discoideum, there is a group of genes that are expressed following starvation and when exponentially growing cells reach high densities. We have examined the expression of one of these genes, alpha-mannosidase. Using an alpha-mannosidase cDNA probe in Northern (RNA) blot analysis, we have shown that the previously observed increase in alpha-mannosidase enzyme-specific activity during development is due to an increase in the levels of alpha-mannosidase mRNA. mRNA levels reach a maximum by 8 h of development and then begin to decline by 14 to 22 h. Using nuclear run-on analysis, we have found that this gene is regulated at the level of transcription. We also examined the effects of cell-cell contacts, cyclic AMP levels, and protein synthesis on expression of this gene and found that they were not critical in regulating its expression. However, cell density did play a major role in the expression of alpha-mannosidase. High cell density or the presence of buffer conditioned by high-density cells was sufficient to induce expression of alpha-mannosidase, indicating that this is one of the prestarvation response genes. Finally, the alpha-mannosidase gene was not expressed in aggregation-negative mutant strain HMW 404.

Developmental regulation of the alpha-mannosidase gene in Dictyostelium discoideum: control is at the level of transcription and is affected by cell density

In Dictyostelium discoideum, there is a group of genes that are expressed following starvation and when exponentially growing cells reach high densities. We have examined the expression of one of these genes, alpha-mannosidase. Using an alpha-mannosidase cDNA probe in Northern (RNA) blot analysis, we have shown that the previously observed increase in alpha-mannosidase enzyme-specific activity during development is due to an increase in the levels of alpha-mannosidase mRNA. mRNA levels reach a maximum by 8 h of development and then begin to decline by 14 to 22 h. Using nuclear run-on analysis, we have found that this gene is regulated at the level of transcription. We also examined the effects of cell-cell contacts, cyclic AMP levels, and protein synthesis on expression of this gene and found that they were not critical in regulating its expression. However, cell density did play a major role in the expression of alpha-mannosidase. High cell density or the presence of buffer conditioned by high-density cells was sufficient to induce expression of alpha-mannosidase, indicating that this is one of the prestarvation response genes. Finally, the alpha-mannosidase gene was not expressed in aggregation-negative mutant strain HMW 404.

Dictyostelium discoideum lipids modulate cell-cell cohesion and cyclic AMP signaling

During Dictyostelium discoideum development, cell-cell communication is mediated through cyclic AMP (cAMP)-induced cAMP synthesis and secretion (cAMP signaling) and cell-cell contact. Cell-cell contact elicits cAMP secretion and modulates the magnitude of a subsequent cAMP signaling response (D. R. Fontana and P. L. Price, Differentiation 41:184-192, 1989), demonstrating that cell-cell contact and cAMP signaling are not independent events. To identify components involved in the contact-mediated modulation of cAMP signaling, amoebal membranes were added to aggregation-competent amoebae in suspension. The membranes from aggregation-competent amoebae inhibited cAMP signaling at all concentrations tested, while the membranes from vegetative amoebae exhibited a concentration-dependent enhancement or inhibition of cAMP signaling. Membrane lipids inhibited cAMP signaling at all concentrations tested. The lipids abolished cAMP signaling by blocking cAMP-induced adenylyl cyclase activation. The membrane lipids also inhibited amoeba-amoeba cohesion at concentrations comparable to those which inhibited cAMP signaling. The phospholipids and neutral lipids decreased cohesion and inhibited the cAMP signaling response. The glycolipid/sulfolipid fraction enhanced cohesion and cAMP signaling. Caffeine, a known inhibitor of cAMP-induced adenylyl cyclase activation, inhibited amoeba-amoeba cohesion. These studies demonstrate that endogenous lipids are capable of modulating amoeba-amoeba cohesion and cAMP-induced activation of the adenylyl cyclase. These results suggest that cohesion may modulate cAMP-induced adenylyl cyclase activation. Because the complete elimination of cohesion is accompanied by the complete elimination of cAMP signaling, these results further suggest that cohesion may be necessary for cAMP-induced adenylyl cyclase activation in D. discoideum.

Structure, expression, and regulation of members of the developmentally controlled V and H gene classes from Dictyostelium

We have examined the expression and structure of vegetative specific genes belonging to the V and H gene classes. Both classes of genes are deactivated at the onset of development by a reduction in the rate of transcription. Thus, the genes must be reactivated when the terminally differentiated spores germinate and the resulting amebae return to the vegetative state. During germination, activation of expression of most members of the V gene class was found to parallel the emergence of amoebae from the spore coats. The activation of the V genes did not occur when protein synthesis was inhibited. The timing of activation of the H genes was more heterogeneous and did not parallel emergence. H gene activation occurred even when protein synthesis was inhibited. V4 was found to be the only vegetative specific gene that was responsive to the presence of bacteria. V4 expression was induced by 25-100 fold via transcriptional activation when bacteria were added to amebae growing axenically. Isolation and sequence analysis of the corresponding genomic clones revealed that two V genes, V18 and V1, encode ribosomal proteins. Promoter analysis has delineated the sequences necessary for expression and regulation for several of the V and H genes. In all cases, expression was determined by sequences within the first several hundred base pairs of the transcription start site. For V18 and V14, a positive constitutive element was identified in addition to the sequences involved in regulation. Finally, all of the characterizations and findings are discussed in terms of postulated models for V and H gene expression and regulation.

Cell-cell contact mediates cAMP secretion in Dictyostelium discoideum

Cyclic adenosine 3':5' monophosphate (cAMP) and cell-cell contact regulate developmental gene expression in Dictyostelium discoideum. Developing D. discoideum amoebae synthesize and secrete cAMP following the binding of cAMP to their surface cAMP receptor, a response called cAMP signaling. We have demonstrated two responses of developing D. discoideum amoebae to cell-cell contact. Cell-cell contact elicits cAMP secretion and alters the amount of cAMP secreted in a subsequent cAMP signaling response. Depending upon experimental conditions, bacterial-amoebal contact and amoebal-amoebal contact can enhance or diminish the amount of cAMP secreted during a subsequent cAMP signaling response. We have hypothesized that cell-cell contact regulates D. discoideum development by altering cellular and extracellular levels of cAMP. To begin testing this hypothesis, these responses were further characterized. The two responses to cell-cell contact are independent, i.e., they can each occur in the absence of the other. The responses to cell-cell contact also have unique temperature dependences when compared to each other, cAMP signaling, and phagocytosis. This suggests that these four responses have unique steps in their transduction mechanisms. The secretion of cAMP in response to cell-cell contact appears to be a non-specific response; contact between D. discoideum amoebae and Enterobacter aerogenes, latex beads, or other amoebae elicits cAMP secretion. Despite the apparent similarities of the effects of bacterial-amoebal and amoebal-amoebal contact on the cAMP signaling response, this contact-induced response appears to be specific. Latex beads addition does not alter the magnitude of a subsequent cAMP signaling response.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental protein synthesis is required for the transcription of Dictyostelium prespore genes

It has been established previously that the maintenance of expression of prespore-specific genes of Dictyostelium discoideum is prevented by the translational inhibitor cycloheximide. The drug had no effect upon the level of transcripts of the other genes examined, prestalk-specific or cell type-nonspecific. However, the interpretation of this result is open to question, because of possible nonspecific effects of cycloheximide. We have now characterized the cellular specificity and temporal profiles of mRNA accumulation of additional Dictyostelium cDNA clones, and have examined other inhibitors of in vivo protein synthesis. Four structurally and mechanistically distinct translational inhibitors each prevented the reaccumulation of prespore transcripts in cyclic AMP-primed, disaggregated amoebae. These results establish the importance of developmental protein synthesis in the accumulation of prespore gene transcripts. Nuclear run-on transcription assays were used to learn whether protein synthesis is required primarily for mRNA synthesis or transcript stability. A transcriptional time course first demonstrated that the abundance of these cell-specific transcripts during development mirrors their rates of synthesis. Significantly, the protein synthesis requirement of the prespore genes examined also occurs at the level of mRNA transcription, implying the existence of one or more developmentally regulated transcriptional activators.

Gene expression and chromatin structure in the cellular slime mold, Dictyostelium discoideum

Micrococcal nuclease digestion of chromatin from growing cells reveals a structural organization which differs for genes transcribed at diverse rates. The late cAMP dependent prespore genes which are not transcribed in growing cells are found in growing cells in a regular nucleosomal repeat with an average spacing of 168 nucleotides. By contrast genes expressed at a low level in growing cells show an irregular pattern of bands with an average distance between bands of 80 nucleotides. The sizes of the bands generated from the transcribed genes are consistent with the concept that transcription results in the loss of the linker region histone H1 with concomitant sliding of nucleosomes to generate close packed ("slipped") di, tri, and tetra nucleosomes lacking the linker region. Further analysis of dinucleosomes released by micrococcal nuclease digestion reveals that transcriptionally active genes are found associated with dinucleosomes species which may be lacking histone H1. The length of DNA protected by these dinucleosomes is heterogeneous, ranging from 250 to 300 nucleotides. Methodology is described which has been adapted to allow two dimensional hybridization mapping of nucleoprotein complexes on single copy Dictyostelium genes.

Dictyostelium discoideum lipids modulate cell-cell cohesion and cyclic AMP signaling

During Dictyostelium discoideum development, cell-cell communication is mediated through cyclic AMP (cAMP)-induced cAMP synthesis and secretion (cAMP signaling) and cell-cell contact. Cell-cell contact elicits cAMP secretion and modulates the magnitude of a subsequent cAMP signaling response (D. R. Fontana and P. L. Price, Differentiation 41:184-192, 1989), demonstrating that cell-cell contact and cAMP signaling are not independent events. To identify components involved in the contact-mediated modulation of cAMP signaling, amoebal membranes were added to aggregation-competent amoebae in suspension. The membranes from aggregation-competent amoebae inhibited cAMP signaling at all concentrations tested, while the membranes from vegetative amoebae exhibited a concentration-dependent enhancement or inhibition of cAMP signaling. Membrane lipids inhibited cAMP signaling at all concentrations tested. The lipids abolished cAMP signaling by blocking cAMP-induced adenylyl cyclase activation. The membrane lipids also inhibited amoeba-amoeba cohesion at concentrations comparable to those which inhibited cAMP signaling. The phospholipids and neutral lipids decreased cohesion and inhibited the cAMP signaling response. The glycolipid/sulfolipid fraction enhanced cohesion and cAMP signaling. Caffeine, a known inhibitor of cAMP-induced adenylyl cyclase activation, inhibited amoeba-amoeba cohesion. These studies demonstrate that endogenous lipids are capable of modulating amoeba-amoeba cohesion and cAMP-induced activation of the adenylyl cyclase. These results suggest that cohesion may modulate cAMP-induced adenylyl cyclase activation. Because the complete elimination of cohesion is accompanied by the complete elimination of cAMP signaling, these results further suggest that cohesion may be necessary for cAMP-induced adenylyl cyclase activation in D. discoideum.

Induction of gene expression in Dictyostelium by prestarvation factor, a factor secreted by growing cells

During growth, Dictyostelium cells continuously secrete a factor, PSF, that accumulates in proportion to cell density. At sufficient concentration, it triggers the production of discoidin I and certain lysosomal enzymes. Our earlier studies demonstrated these effects of PSF on protein and enzyme levels [Clarke et al., Differentiation 34:79-87, 1987; Clarke et al., Dev Genet 9: 315-326, 1988]. In the present study, we have examined whether PSF induces increased mRNA levels. By Northern blot analysis, we have found that discoidin I mRNA accumulates in exponentially growing NC4 cells as the cells reach high density; significant levels of mRNA are detectable in cells growing either on plates or in suspension, beginning about four generations before the end of exponential growth. High levels of discoidin I mRNA are also found in low-density cells grown in the presence of buffer conditioned by high-density cells. These results indicate that PSF induces the accumulation of discoidin I mRNA. Other "early developmental" genes, pCZ22 and the early I genes (16, 18, and 111), are also expressed in exponentially growing cells at high density or in the presence of conditioned buffer. We conclude that several genes previously found to be preferentially expressed very early in development are actually induced during late exponential growth by PSF.

The effect of cyclic AMP on the growth of Toxoplasma gondii in vitro

To assess the role of cAMP on the growth and proliferation of Toxoplasma in HL-60 cells we tested the effect of exogenous cAMP and cAMP analogues to the co-culture system of Toxoplasma and HL-60 cells. cAMP, dbcAMP, and br-cAMP stimulated the growth of Toxoplasma at a specific concentration, i.e., 10(0) mM, 10(0) mM, and 10(-1) mM, respectively. There were differences in growth induction kinetics and in the rate of promotion. These results were further verified by treating the co-culture with adenylate cyclase activator, pNHppG, cAMP phosphodiesterase activators, imidazole and A23187, and cAMP phosphodiesterase inhibitors, IBMX, compound 48/80, and theophylline, separately. When the cytosolic cAMP levels increased by the reagents mentioned above, Toxoplasma in the cytoplasm of HL-60 cells stimulated to proliferate more rapidly with concentration-dependent modes compared to the control, and vice versa. It is suggested that some mechanisms are activated by the high levels of cAMP in the cytoplasm, which result in the stimulation of Toxoplasma proliferation.

Developmental regulation of cell-type-enriched mRNAs in Dictyostelium discoideum

We describe sixteen new families of cDNA clones representing mRNAs that are expressed preferentially in either prespore or prestalk cells during development of Dictyostelium discoideum and two new mRNAs that are expressed in a non-cell-type-specific manner. None of the prespore-enriched mRNAs are detectable in Dictyostelium cells until 13-15 h of development but then they increase dramatically and peak at 18-22 h. Upon dissociation of developing aggregates, all these mRNAs rapidly decay to low levels. In marked contrast to data presented for prespore genes by other workers, cyclic AMP either has no effect on the mRNA levels in dissociated cells or is only weakly effective in restoring normal expression. A prestalk-enriched mRNA examined, 5G mRNA, is similarly expressed late in development but is also expressed in vegetative cells. The level of 5G mRNA is only moderately affected by cell disaggregation.

Identification of a signal transduction response sequence element necessary for induction of a Dictyostelium discoideum gene by extracellular cyclic AMP

The signal transduction pathways that lead to gene induction are being intensively investigated in Dictyostelium discoideum. We have identified by deletion and transformation analysis a sequence element necessary for induction of a gene coding for uridine diphosphoglucose pyrophosphorylase (UDPGP1) of D. discoideum in response to extracellular cyclic AMP (cAMP). This regulatory element is located 380 base pairs upstream of the transcription start site and contains a G+C-rich partially palindromic sequence. It is not required for transcription per se but is required for induction of the gene in response to the stimulus of extracellular cAMP. The cAMP response sequence is also required for induction of the gene during normal development. A second A+T-rich cis-acting region located immediately downstream of the cAMP response sequence appears to be essential for the basal level of expression of the UDPGP1 gene. The position of the cAMP response element coincides with a DNase I-hypersensitive site that is observed when the UDPGP1 gene is actively transcribed.

Primary structure and regulation of vegetative specific genes of Dictyostelium discoideum

We have examined the expression and structure of several genes belonging to two classes of vegetative specific genes of the simple eukaryote, Dictyostelium discoideum. In amebae grown on bacteria, deactivation of all vegetative specific genes occurred at the onset of development and very little mRNA exists by 8 to 10 hours. In contrast, when cells were grown in axenic broth, the mRNA levels remained constant until a dramatic drop occurred around 10 to 12 hours. Thus, regulation of both classes of genes during the first several hours of development is dependent upon the prior growth conditions. Analysis of genomic clones has resulted in the identification of two V genes, V1 and V18, as ribosomal protein genes. Several other V genes were not found to be ribosomal protein genes, suggesting that in Dictyostelium non-ribosomal protein genes may be coordinately regulated with the ribosomal protein genes. Finally, using deletion analysis we show that the promoters of two of the V genes are composed of a constitutive positive element(s) located upstream of sequences involved in the regulated expression of these genes and within the first 545 upstream bp for V18 and 850 bp for V14. The regions involved in regulated expression were localized between -7 and -222 for V18 and -70 and -368 for V14. The sequences conferring protein synthesis sensitivity were shown to reside between -502 and -61 of the H4 promoter.

Identification of a signal transduction response sequence element necessary for induction of a Dictyostelium discoideum gene by extracellular cyclic AMP

The signal transduction pathways that lead to gene induction are being intensively investigated in Dictyostelium discoideum. We have identified by deletion and transformation analysis a sequence element necessary for induction of a gene coding for uridine diphosphoglucose pyrophosphorylase (UDPGP1) of D. discoideum in response to extracellular cyclic AMP (cAMP). This regulatory element is located 380 base pairs upstream of the transcription start site and contains a G+C-rich partially palindromic sequence. It is not required for transcription per se but is required for induction of the gene in response to the stimulus of extracellular cAMP. The cAMP response sequence is also required for induction of the gene during normal development. A second A+T-rich cis-acting region located immediately downstream of the cAMP response sequence appears to be essential for the basal level of expression of the UDPGP1 gene. The position of the cAMP response element coincides with a DNase I-hypersensitive site that is observed when the UDPGP1 gene is actively transcribed.

Identification of sequences regulating the transcription of a Dictyostelium gene selectively expressed in prespore cells

There has been considerable debate about the relative contributions of transcriptional and post-transcriptional mechanisms to the regulation of prespore gene expression in Dictyostelium. We have determined the DNA sequence upstream of D19, the Dictyostelium gene encoding PsA, a prespore-specific, cell surface protein of unknown function. Our analysis of gene fusions, in which D19 upstream sequences are placed adjacent to a heterologous reporter gene, indicates that transcriptional signals alone are sufficient for the correct temporal and cell-type specific expression of this gene. We also show that the 5' and 3' boundaries of the minimal sequences necessary for correct developmental regulation lie within the region 338 to 122 nucleotides upstream of the start site of transcription but that flanking sequences seem to be necessary for optimal expression.

Ca++ antagonists distinguish different requirements for cAMP-mediated gene expression in the cellular slime mold, Dictyostelium discoideum

Cyclic AMP is essential for the accumulation of many prespore mRNAs and can advance the time of appearance of mRNAs specifically enriched in prestalk cells. Additionally, when late-developing cells are washed free of cAMP, a number of growth phase mRNAs reaccumulate. This reaccumulation can be suppressed by cAMP. These effects of cAMP are all mediated through the cell surface cAMP receptor and can occur under conditions where the receptor-associated adenylate cyclase is inactive, indicating that the initial intracellular transduction event necessary for expression of these mRNAs does not depend upon cAMP synthesis. The dihydropyridine derivatives, nifedipine and nitrendipine, are highly specific Ca++ channel blockers. They are shown here to prevent the influx of Ca++ from the external medium that occurs in response to cAMP binding to the cell surface receptor during development. These two compounds as well as another Ca++ antagonist, 8-N,N-diethylamino)octyl-3,4,5-trimethoxy-benzoate (TMB-8) and a calmodulin inhibitor, N-(6-amino-hexyl)-5-chloro-1-naphthalene sulfonamide (W7), all specifically decrease cAMP-mediated prespore mRNA accumulation in a dose-dependent manner. They also prevent cAMP from suppressing the expression of the growth phase genes. The growth phase mRNAs reaccumulate in cAMP-treated cells in the presence of increasing concentrations of these drugs. By contrast, cAMP induction of the pre-stalk-enriched mRNA is not as significantly affected by these agents. These results raise the possibility that the cell surface cAMP receptor can couple to different signal transduction systems and thereby induce or suppress the expression of different sets of cAMP-regulated genes during development.

Prespore gene expression in Dictyostelium requires concomitant protein synthesis

It has been established previously that the maintenance of expression of prespore-specific genes of Dictyostelium discoideum is prevented by the translational inhibitor cycloheximide. The drug had no effect upon the level of transcripts of the other genes examined, prestalk-specific or cell type non-specific (Mehdy, M., Ratner, D. and Firtel, R., (1983) Cell 32, 763-771). We have now characterized the cellular specificity and temporal profiles of mRNA accumulation of additional Dictyostelium cDNA clones. Other inhibitors of in vivo protein synthesis have been examined, with emetine shown to be a particularly effective but reversible agent. Four structurally and mechanistically distinct translational inhibitors each prevented the reaccumulation of prespore transcripts in cyclic AMP-primed disaggregated amoebae. These results establish a role for protein synthesis in the transcription or transcript stability of prespore genes.

Complementation of a Dictyostelium discoideum thymidylate synthase mutation with the mouse gene provides a new selectable marker for transformation

A cDNA encoding mouse thymidylate synthase has been inserted 3' to the Dictyostelium discoideum actin 15 promoter in an E. coli-D.discoideum shuttle vector. When this construct was introduced into a D.discoideum thymidylate synthase mutant strain HPS400, stable transformants were obtained at high frequency. These transformants grew in standard axenic medium without requiring exogenous thymidine. This construct provides a second selectable marker for use in transformation of D.discoideum.

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.

Structural characterization of Dictyostelium discoideum prespore-specific gene D19 and of its product, cell surface glycoprotein PsA

The Dictyostelium discoideum cell surface antigen PsA is a glycoprotein which first appears in the multicellular stage soon after tip formation and is selectively expressed on prespore cells. The D19 gene encodes an mRNA sequence which is highly enriched in prespore over prestalk cells in the slug stage. We have determined 81 amino acid residues of N-terminal sequence from immunoaffinity-purified PsA protein and shown this sequence to be identical to the predicted sequence of the D19 gene. There are several short repeat elements close to the C terminus, and unequal crossing-over within these is proposed to account for the size polymorphism observed in PsA protein isolated from different D. discoideum strains. The repeats are proline rich and show similarity to the C-terminal region of the D. discoideum cell adhesion molecule, contact sites A. The extreme C terminus, which is also homologous to contact sites A, is characteristic of proteins attached to the plasma membrane via a glycosyl-phosphatidylinositol link. We have marked the PsA gene by insertion of an oligonucleotide encoding an epitope of the human c-myc protein. A construct containing this gene and 990 base pairs of 5'-flanking region directed correct temporal and spatial mRNA accumulation. We found the marked PsA protein, detected with the human c-myc antibody, to be correctly localized on the surface of 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.

Structural characterization of Dictyostelium discoideum prespore-specific gene D19 and of its product, cell surface glycoprotein PsA

The Dictyostelium discoideum cell surface antigen PsA is a glycoprotein which first appears in the multicellular stage soon after tip formation and is selectively expressed on prespore cells. The D19 gene encodes an mRNA sequence which is highly enriched in prespore over prestalk cells in the slug stage. We have determined 81 amino acid residues of N-terminal sequence from immunoaffinity-purified PsA protein and shown this sequence to be identical to the predicted sequence of the D19 gene. There are several short repeat elements close to the C terminus, and unequal crossing-over within these is proposed to account for the size polymorphism observed in PsA protein isolated from different D. discoideum strains. The repeats are proline rich and show similarity to the C-terminal region of the D. discoideum cell adhesion molecule, contact sites A. The extreme C terminus, which is also homologous to contact sites A, is characteristic of proteins attached to the plasma membrane via a glycosyl-phosphatidylinositol link. We have marked the PsA gene by insertion of an oligonucleotide encoding an epitope of the human c-myc protein. A construct containing this gene and 990 base pairs of 5'-flanking region directed correct temporal and spatial mRNA accumulation. We found the marked PsA protein, detected with the human c-myc antibody, to be correctly localized on the surface of cells.

Developmental consequences of the lack of myosin heavy chain in Dictyostelium discoideum

Two different Dictyostelium discoideum cell lines that lack myosin heavy chain protein (MHC A) have been previously described. One cell line (mhcA) was created by antisense RNA inactivation of the endogenous mRNA and the other (HMM) by insertional mutagenesis of the endogenous myosin gene. The two cell lines show similar developmental defects; they are delayed in aggregation and become arrested at the mound stage. However, when cells that lack myosin heavy chain are mixed with wild-type cells, some of the mutant cells are capable of completing development to form mature spores. The pattern of expression of a number of developmentally regulated genes has been examined in both mutant cell lines. Although morphogenesis becomes aberrant before aggregation is completed, all of the markers that we have examined are expressed normally. These include genes expressed prior to aggregation as well as prespore genes expressed later in development. It appears that the signals necessary for cell-type differentiation are generated in the aborted structures formed by cells lacking MHC A. The mhcA cells have negligible amounts of MHC A protein while the HMM cells express normal amounts of a fragment of the myosin heavy chain protein similar to heavy meromyosin (HMM). The expression of myosin light chain was examined in these two cell lines. HMM cells accumulate normal amounts of the 18,000-D light chain, while the amount of light chain in mhcA cells is dramatically reduced. It is likely that the light chains assemble normally with the HMM fragment in HMM cells, while in cells lacking myosin heavy chain (mhcA) the light chains are unstable.

Effect of protein synthesis inhibition on gene expression during early development of Dictyostelium discoideum

Several genes which are deactivated on the initiation of development of Dictyostelium discoideum were identified by differential screening of various cDNA libraries. These genes have in common a decrease in the steady-state levels of their corresponding mRNAs on the onset of development and as development proceeds. When development was carried out in the absence of protein synthesis by inhibition with cycloheximide, the decrease in mRNA levels for most genes (V genes) was normal or slightly accelerated. For about 5% of the genes (H genes), however, cycloheximide caused an apparent induction of expression, as revealed by a slight or dramatic increase in mRNA levels, instead of the normal decrease. This effect was due to inhibition of protein synthesis and not to cycloheximide per se. The induction was found to be due to an enhancement of the transcription rate; normal rates of transcription for the H genes were dependent on continued protein synthesis during vegetative growth and development. Thus, two general regulatory classes exist for deactivation of gene expression on initiation of development, one of which is dependent on and one of which is independent of protein synthesis. Analysis of expression of these genes in mutant strains which are aggregation deficient allowed the classes to be subdivided further. Taken together, these characterizations allow several distinct regulatory mechanisms to be identified that are involved in the deactivation of gene expression on the onset of development in D. discoideum.

A Ca2+-dependent signal transduction system participates in coupling expression of some cAMP-dependent prespore genes to the cell surface receptor

Elevated levels of cAMP are essential for the expression of many postaggregation prespore and prestalk mRNA species and for the suppression of some growth phase mRNAs. Here we review evidence that this regulation is mediated by cAMP interacting at the cell surface receptor. These effects of cAMP on gene expression can occur under conditions where the receptor-associated adenylate cyclase is inactivated and in concentrations that are consistent with receptor-binding. A number of differences are noted in the mechanism by which cAMP regulates prespore and prestalk genes. Finally, evidence is reviewed for the role of a Ca2+-dependent signal transduction system in coupling the expression of some of the prespore mRNAs to the cAMP receptor. This signal transduction system does not appear to be involved in the expression of the cAMP-dependent prestalk gene.

Analysis of the prestarvation response in growing cells of Dictyostelium discoideum

We have previously shown that growing cells of Dictyostelium discoideum (strains NC4 and AX3) produce a soluble substance that accumulates in the medium in proportion to cell density; this substance regulates the production of certain proteins previously thought to be induced by starvation [Clarke et al., 1987]. We suggest the name PSF (prestarvation factor) for this substance. During growth, Dictyostelium cells monitor the relative concentrations of PSF and food bacteria. When PSF reaches a sufficiently high level relative to the concentration of bacteria, synthesis of PSF-regulated proteins is induced. We propose the name prestarvation response for this induction, which takes place in exponentially growing cells several generations before the food bacteria are depleted. We have explored the mechanism by which the food bacteria inhibit the response of Dictyostelium cells to PSF. We find that the bacteria do not inactivate PSF or inhibit its production; instead, they affect the ability of NC4 cells to detect PSF, possibly by binding to the same cell surface receptor. In the absence of bacteria, as during axenic growth of AX3 cells, the prestarvation response occurs at much lower cell densities, probably accounting for the presence of certain developmentally regulated mRNAs and proteins in axenic cultures.

Effect of protein synthesis inhibition on gene expression during early development of Dictyostelium discoideum

Several genes which are deactivated on the initiation of development of Dictyostelium discoideum were identified by differential screening of various cDNA libraries. These genes have in common a decrease in the steady-state levels of their corresponding mRNAs on the onset of development and as development proceeds. When development was carried out in the absence of protein synthesis by inhibition with cycloheximide, the decrease in mRNA levels for most genes (V genes) was normal or slightly accelerated. For about 5% of the genes (H genes), however, cycloheximide caused an apparent induction of expression, as revealed by a slight or dramatic increase in mRNA levels, instead of the normal decrease. This effect was due to inhibition of protein synthesis and not to cycloheximide per se. The induction was found to be due to an enhancement of the transcription rate; normal rates of transcription for the H genes were dependent on continued protein synthesis during vegetative growth and development. Thus, two general regulatory classes exist for deactivation of gene expression on initiation of development, one of which is dependent on and one of which is independent of protein synthesis. Analysis of expression of these genes in mutant strains which are aggregation deficient allowed the classes to be subdivided further. Taken together, these characterizations allow several distinct regulatory mechanisms to be identified that are involved in the deactivation of gene expression on the onset of development in D. discoideum.

Analysis of cis and trans elements involved in cAMP-inducible gene expression in Dictyostelium discoideum

Expression of the Dictyostelium discoideum pst-cath (CP2) gene is transcriptionally regulated during multicellular development, and the gene is inducible in competent single cells following administration of exogenous cAMP. The 5' flanking region of pst-cath (CP2) that extends from -313 to the Cap site (+1) has previously been shown to contain sufficient cis-acting regulatory elements for proper developmental and cAMP-inducible expression of a foreign gene [Datta and Firtel, 1987, Mol Cell Biol 7:149-159]. The -283 to -201 region includes two exceptional "G-boxes" centered at -233 and -217 respectively, and this approximately 80 bp region is essential for basal as well as regulated expression of the pst-cath (CP2) gene. Here we summarize results obtained from a detailed analysis of a series of linker-scanner mutants and mutants that carry small internal deletions within the essential 80-bp region. Insertion of a synthetic oligonucleotide that includes the downstream G-box is demonstrated to rescue a low level of cAMP-inducible expression following insertion into cassette mutants. The effect of introducing a change in the relative spacing between regulatory elements has also been investigated. We have analyzed nuclear extracts for the presence of DNA-binding proteins that interact specifically with the pst-cath (CP2) regulatory region and identified two such putative trans-acting factors: 1) the AT-factor that is observed within a few hours following the onset of starvation and that binds tightly to stretches of alternating adenine-thymine residues (poly(dA-dT]; and 2) the AG-factor that is present in nuclear extracts of aggregated cells. Competition studies have demonstrated significant differences in the affinity that characterizes the binding of the two factors to G-box-containing sequences. The binding specificities of these DNA-binding proteins have been analyzed using gel mobility-shift and DNaseI footprinting assays.

Contact alters cAMP metabolism in aggregation-competent Dictyostelium amoebae

cAMP and cell-cell contact are involved in the coordination of differentiation and morphogenesis in Dictyostelium discoideum. The experiments described in this paper establish a relationship between cAMP and cell-cell contact. Contact between Enterobacter aerogenes and aggregation-competent Dictyostelium amoebae and contact between Dictyostelium amoebae themselves results in the transient secretion of cAMP and an alteration in the amount of cAMP secreted in response to subsequent stimulation by cAMP, i.e., an alteration in magnitude of a cAMP relay response. The subsequent cAMP relay response can be enhanced or diminished depending upon the number of contacts formed and the concentration of cAMP present at the time of contact. Latex beads are capable of evoking cAMP secretion. However, the bead/amoebal contact is unable to alter the magnitude of a subsequent response to cAMP. This suggests that a nonspecific interaction via cell-cell contact elicits transient cAMP secretion in aggregation-competent Dictyostelium amoebae. The two responses to cell-cell contact are distinct from each other and distinct from the cAMP relay response. 1) The dose-response curves for the responses to Enterobacter contact are clearly different. 2) Contact with latex beads can elicit cAMP secretion but not alter the magnitude of a subsequent cAMP relay response. 3) The temperature dependences of the contact-induced responses and the cAMP relay response show that only the contact-induced cAMP secretion is inhibited at 12 and 15 degrees C, while only the cAMP relay response is inhibited at 28 degrees C. A 4-second application of cAMP at the time that contact is initiated enhances both contact-induced responses. Whether the relationship between these two developmental regulators is important for the regulation of Dictyostelium development has yet to be established.

Density-dependent induction of discoidin-I synthesis in exponentially growing cells of Dictyostelium discoideum

The synthesis of the lectin, discoidin I, by vegetative cells of Dictyostelium discoideum (strain NC4) was monitored using immunoblot analysis and indirect immunofluorescence. Suspension cultures were used, so that the D. discoideum cell density and the concentration of bacteria could be controlled. Discoidin-I production was found to be a function of the relative densities of D. discoideum cells and food bacteria. Synthesis was initiated in exponentially growing D. discoideum cells approximately three generations before depletion of the food supply. In the growth medium of cells producing discoidin I, a soluble activity was detected that caused low-density cells to begin discoidin-I synthesis. This activity was not dialyzable and was destroyed by heat. A similar activity was produced by AX3 cells during axenic growth. Density-dependent induction of other 'early developmental' proteins was also detected in wild-type cells. These findings suggest that the expression of several 'early developmental' genes is regulated by a mechanism that measures cell density relative to food supply, not by starvation per se.

Two vectors which facilitate gene manipulation and a simplified transformation procedure for Dictyostelium discoideum

We have constructed and characterized two Dictyostelium transformation vectors (pB10TP1 and pB10TP2) designed for the facile sequence determination, mutagenesis and functional analysis of Dictyostelium genes. The vectors incorporate the B10 neomycin-resistance (neo) gene [Nellen et al., Mol. Cell. Biol. 4 (1984) 2890-2898] and sequences derived pEMBL18+ [Dente et al., Nucl. Acids Res. 11 (1983) 1645-1655], enabling the production of single-stranded template and increasing the yield of double-stranded DNA. A new multiple cloning site (MCS) has been inserted adjacent to the M13 sequence primer binding site so that single-stranded template DNA isolated from recombinants prepared using these vectors is suitable for sequence analysis and site-directed mutagenesis. The linker incorporates restriction sites suitable for the preparation of a directed deletion series and useful in cloning, including some sites with recognition sequences frequent in the extremely A + T-rich Dictyostelium genome. A Dictyostelium genomic fragment has been included to provide transcription termination signals for the neo gene. One of the two vectors (pB10TP1) contains the 3'-proximal portion of a constitutively expressed mRNA of unknown function. It is located downstream from the MCS so that 5'-proximal fragments of genes, cloned into the MCS, generate fusion transcripts which are distinguishable from transcripts of the corresponding endogenous genes. The complete nucleotide sequence of the two vectors has been established and a comprehensive restriction map deduced. We also describe a modification of the published transformation system, which allows it to be applied to the commonly used strain Ax-2, and another generally applicable modification which greatly reduces the time required to obtain stable transformants.

Cyclic AMP and NH3/NH4+ both regulate cell-type-specific mRNA accumulation in the cellular slime mold, Dictyostelium discoideum

Dictyostelium discoideum cells plated for development until aggregation stage, and then dissociated into media containing glucose, albumin, and cAMP will form into clumps and undergo prespore and prestalk differentiation. Differentiation in this in vitro system is dependent on three components: cAMP, multicellularity, and the acquisition of "differentiation competence" which the cells acquire in a period between interphase and aggregation stage when plated on Millipore filters. We have used this system to explore aspects of the multicellular environment which are involved in regulation the accumulation of the different prespore- and prestalk-specific messenger RNAs. Two classes of prespore messenger RNA, as well as a prestalk-specific messenger RNA, all require the acquisition of differentiation competence in order to be expressed in response to cAMP. Additionally, all of these messenger RNAs require agglomerate formation for maximal expression. The addition of 33 mM ammonium sulfate (NH4)2SO4, however, can entirely replace the requirement for agglomerate formation for expression of the prestalk-specific messenger RNA, and can partially substitute for agglomerate formation in inducing the expression of both classes of prespore-specific messenger RNAs. In this system, cAMP is essential for the initial induction of expression of all three classes of messenger RNAs. In this system, cAMP is essential for the initial induction of expression of all three classes of messenger RNAs while agglomerate formation or elevated NH3/NH+4 is essential only for the maintenance of the elevated levels of the messenger RNAs.