ATP, trehalose, glucose and ammonium ion localization in the two cell types of Dictyostelium discoideum

A cell number counting factor alters cell metabolism

It is still not clear how organisms regulate the size of appendages or organs during development. During development, Dictyostelium discoideum cells form groups of approximately 2 x 10(4) cells. The cells secrete a protein complex called counting factor (CF) that allows them to sense the local cell density. If there are too many cells in a group, as indicated by high extracellular concentrations of CF, the cells break up the group by decreasing cell-cell adhesion and increasing random cell motility. As a part of the signal transduction pathway, CF decreases the activity of glucose-6-phosphatase to decrease internal glucose levels. CF also decreases the levels of fructose-1,6-bisphosphate and increases the levels of glucose-6-phosphate and fructose-6-phosphate. In this report, we focus on how a secreted signal used to regulate the size of a group of cells regulates many basic aspects of cell metabolism, including the levels of pyruvate, lactate, and ATP, and oxygen consumption.

A model for cell type localization in the migrating slug of Dictyostelium discoideum based on differential chemotactic sensitivity to cAMP and differential sensitivity to suppression of chemotaxis by ammonia

The three basic cell types in the migrating slug of Dictyostelium discoideum show differential chemotactic response to cyclic AMP (cAMP) and differential sensitivity to suppression of the chemotaxis by ammonia.The values of these parameters indicate a progressive maturation of chemotactic properties during the transdifferentiation of slug cell types.We present a model that explains the localization of the three cell types within the slug based on these chemotactic differences and on the maturation of their chemotactic properties.

Functional genomics in Dictyostelium: MidA, a new conserved protein, is required for mitochondrial function and development

Genomic sequencing has revealed a large number of evolutionary conserved genes of unknown function. In the absence of characterized functional domains, the discovery of the role of these genes must rely on experimental approaches. We have selected 30 Dictyostelium discoideum genes of unknown function that showed high similarity to uncharacterized human genes and were absent in the complete proteomes from Saccharomyces cerevisiae and S. pombe. No putative functional motifs were found in their predicted encoded proteins. Eighteen genes were successfully knocked-out and three of them showed obvious phenotypes. A detailed analysis of one of them, midA, is presented in this report. Disruption of midA in Dictyostelium leads to pleiotropic defects. Cell size, growth rate, phagocytosis and macropinocytosis were affected in the mutant. During development, midA- cells showed an enhanced tendency to remain at the slug stage, and spore viability was compromised. The expression of MidA fused to GFP in midA- strain rescued the phenotype and the fused protein was located in the mitochondria. Although cellular oxygen consumption, mitochondrial content and mitochondrial membrane potential were similar to wild type, the amount of ATP was significantly reduced in the mutant suggesting a mitochondrial dysfunction. Metabolomic analysis by natural-abundance 13C-nuclear magnetic resonance has shown the lack of glycogen accumulation during growth. During starvation, mutant cells accumulated higher levels of ammonia, which inhibited normal development. We hypothesize that the lack of MidA reduces mitochondrial ATP synthetic capacity and this has an impact in some but not all energy-dependent cellular processes. This work exemplifies the potential of Dictyostelium as a model system for functional genomic studies.

Unusual properties of the prespore-specific enzyme, UDPgalactose:polysaccharide galactosyl transferase, of Dictyostelium discoideum

UDPgalactose:polysaccharide galactosyl-transferase is the enzyme that is specifically localized in prespore cells of Dictyostelium discoideum and its activity sharply changes in response to differentiation and dedifferentiation. To clarify the nature of this enzyme, we first developed an improved assay method for the enzyme, and by using this method, we partially purified the enzyme through DEAE-sepharose, phenyl-sepharose and ATP-sepharose chromatography. The apparent molecular mass of the enzyme was ca. 200 KDa (by non-denaturing polyacrylamide gel gradient analysis) and the isoelectric point was around pH 7. The enzyme exhibited a hitherto undescribed property, that is the reaction proceeds faster at 0 degrees C than at 21 degrees C, with a smaller K(m) value and an unchanged V(max) value. This low-temperature resistant property of the enzyme is consistent with the previous observation (Maeda 1984, J. Cell Sci. 69, 159-165) that prespore differentiation is favored at low temperatures. The reaction appears to proceed in a double displacement manner. ATP reversibly inhibited the enzyme with a K(i) value of 2 mM, suggesting the possibility that ATP regulates its activity in vivo.

Ammonia differentially suppresses the cAMP chemotaxis of anterior-like cells and prestalk cells in Dictyostelium discoideum

A drop assay for chemotaxis to cAMP confirms that both anterior-like cells (ALC) and prestalk cells (pst cells) respond to cAMP gradients. We present evidence that the chemotactic response of both ALC and pst cells is suppressed by ammonia, but a higher concentration of ammonia is required to suppress the response in pst cells. ALC show a chemotactic response to cAMP when moving on a substratum of prespore cells in isolated slug posteriors incubated under oxygen. ALC chemotaxis on a prespore cell substratum is suppressed by the same concentration of ammonia that suppresses ALC chemotaxis on the agar substratum in drop assays. Chemotaxis suppression is mediated by the unprotonated (NH3) species of ammonia. The observed suppression, by ammonia, of ALC chemotaxis to cAMP supports our earlier hypothesis that ammonia is the tip-produced suppressor of such chemotaxis. We discuss implications of ammonia sensitivity of pst cells and ALC with regard to the movement and localization of ALC and pst cells in the slug and to the roles played by ALC in fruiting body formation. In addition, we suggest that a progressive decrease in sensitivity to ammonia is an important part of the maturation of ALC into pst cells.

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.

Effect of the glutamine synthetase inhibitor, methionine sulfoximine, on the growth and differentiation of Dictyostelium discoideum

To examine further the role of the enzyme glutamine synthetase in Dictyostelium discoideum we report here the effects of a specific glutamine synthetase inhibitor, methionine sulfoximine, on the growth and differentiation of this organism. Vegetative AX3 cells grown in the presence of methionine sulfoximine did not complete culmination in the normal time but were blocked at the finger stage. In these cells glutamine synthetase activity was almost completely abolished. However, methionine sulfoximine did not affect the level of glutamine synthetase mRNA, suggesting that there is no link between glutamine synthetase activity and mRNA transcription. Eventually glutamine synthetase activity reappeared and at the time culmination occurred. These results suggest that glutamine synthetase plays an important role in the assimilation of ammonia during the later stages of development in D. discoideum and that this assimilation is necessary for the completion of culmination.

Possible role of isoaspartyl methyltransferase towards regulation of acid trehalase activity in Saccharomyces cerevisiae

Logarithmically growing cells of S. cerevisiae contained high neutral trehalase (NT) activity while stationary-phase cells had high acid trehalase (AT) activity. Change in activity profile of AT and NT were different during growth under different conditions, particularly during growth in acetate medium and up to 1 h of germination period, but that for AT and isoaspartyl methyltransferase (IMT) were found to be almost identical. Concomitant increase in NT activity as well as increase in cAMP level was noticed at the onset of spore germination. Increase in AT and IMT activities as well as decrease in S-adenosyl-L-methionine (AdoMet) level were noticed during stationary phase of growth. Acidic polyacrylamide gel electrophoresis and subsequent autoradiography revealed that substrate of IMT was a protein of molar mass around 82 kDa which could be an AT. Methylated AT was found to be more active while non-methylated AT was relatively less active in comparison to the untreated sample. Since AT existed as an equilibrium mixture of protomer and oligomer, it was suggested that IMT catalysed carboxyl methylation might have some contribution towards the regulation of AT activity.

Construction of kinetic models to understand metabolism in vivo

This review describes increasingly complex kinetic models that simulate carbohydrate metabolism in a simple eucaryotic system which undergoes differentiation. Dynamic models of complex metabolic networks serve to organize and analyze the many interdependent variables involves and to define the rate-limiting events controlling metabolism in vivo. Since the ultimate justification for and test of any model are its predictive values, a series of predictions and related experiments will be described.

Constraints on the models of carbohydrate metabolism in the two cell types of Dictyostelium discoideum

The constraints in the parameters in models of the spore and stalk cells in Dictyostelium discoideum have been examined. It was found that the relative sizes of the two cellular glucose pools are not very critical, i.e. they can be varied in the models over a fairly wide range and still allow simulations which are compatible with the data. In contrast, the following model parameters are highly constrained, and must fall within narrow limits: flux through the glycogen cycle; the fraction of glycogen present which actually participates in glycogen turnover; the net rate of glycogen degradation; the concentration of exogenous labelled glucose which actually participates in cellular metabolism; the rates of exchange of this exogenous glucose with the two cellular glucose pools; the concentration of the spore glucose-6-phosphate pool, and the rate of exchange of stalk glucose-1-phosphate and stalk glucose-6-phosphate.

Modulation of the cAMP relay in Dictyostelium discoideum by ammonia and other metabolites: possible morphogenetic consequences

Using a perfusion technique (P.N. Devreotes, P.L. Derstine, and T.L. Steck, 1979, J. Cell Biol. 80, 291-299), it has been shown that cAMP secretion by aggregation-competent cells in response to an exogenous cAMP signal is significantly reduced by exposure to NH4Cl or any of a set of carboxylic acids that includes propionate, succinate, pyruvate, and acetate. The effects of NH4Cl and any of the carboxylic acids are additive and the combinations restrict cAMP secretion to barely detectable or insignificant levels. The inhibitions are rapidly expressed, and are reversible. The activity of NH4Cl is marked at pH 7.2 and undetectable at pH 6.2. Hence, NH3 is presumably the active molecular species. Propionate activity is significantly greater at pH 6.2 than 7.2, indicating that the un-ionized acid is the active species. The data presented herein indicate that these effects are exerted via two separate and independent routes. During exposure of cAMP-stimulated cells to NH4Cl, the decrease in intracellular cAMP accumulation was even greater than the decrease in extracellular accumulation. Hence, NH3 appears to act as a cAMP accumulation inhibitor (CAI). In contrast, exposure to carboxylic acid concentrations that drastically reduce extracellular cAMP accumulation can actually enhance or, at worst, only slightly reduce intracellular accumulation. Hence, the carboxylic acids appear to act as cAMP release inhibitors (CRI). Stationary phase cells incubated on solid substratum in the presence of NH4Cl plus succinate (or propionate) for 18 hr failed to exhibit even the earliest signs of aggregation. If then harvested and redeposited in the absence of the metabolites, they proceeded through the morphogenetic sequence with approximately normal kinetics, suggesting that no significant morphogenetic competence had been achieved during their previous tenure. The morphogenetic implications of cAMP relay modulation are discussed.

The distribution of ammonia between hepatocytes and extracellular fluid

1. Some factors determining the distribution of ammonia between hepatocytes and the suspension medium and between mitochondria and cell cytosol were examined. 2. Intracellular [ammonia] of isolated hepatocytes was similar to that in freeze-clamped rat liver. The intra- to extracellular [ammonia] ratio ('ammonia ratio') of cells incubated without added substrates was as great as 70. 3. High ammonia ratios were found only within the physiological range of extracellular [ammonia] i.e. 0.03 mM. At higher external [NH4Cl] the ammonia ration decreased until at 20 mM it approached 1.0. 4. On addition of NH4Cl (10.0 mM) ammonia entered hepatocytes rapidly until at about 2.5 min internal and external ammonia concentration were similar. The final steady state distribution of ammonia was not reached until 60 min, when the internal concentration was slightly higher than that externally. 5. Intracellular [K+] decreased when intracellular [ammonia] increased. The sum of intracellular [K+] plus [NH4(+)] remained approximately constant. 6. In anaerobic cells the high endogenous ammonia ratio was not maintained. 7. The high physiological ammonia ratio was not abolished by ouabain. Thus the (Na+ + K+)-ATPase does nt appear to be responsible for the maintenance of the ammonia ratio. 8. A high ammonia ratio also existed between hepatocyte cytosol and mitochondria. 9. On addition of fructose, which depletes the cells of Pi and adenine nucleotides, the ammonia content of the cells decreased parallel with Pi and ATP. In the presence of fructose much ammonia was removed by the formation of alanine. However, when pyruvate was added to stimulate alanine formation there was no effect on the ammonia distribution. This showed that alanine formation alone was not responsible for decreased intracellular [ammonia] with fructose. 10. Incubation with adenosine led to a large increase in intracellular ATP and ammonia content as well as in the ammonia ratio. Incubation with alanine also led to increased intracellular ammonia production but in this case ammonia was released into the medium and high ammonia ratios did not occur. 11. Some mechanisms for maintenance of a high ammonia ratio between cells and medium are discussed.

Localization of cyclic nucleotide phosphodiesterase in the multicellular stages of Dictyostelium discoideum

Cyclic 3',5'-adenosine monophosphate (cAMP) is secreted as the chemotactic signal by aggregating amoebae of the cellular slime mold Dictyostelium discoideum. We have used ultramicrotechniques in the biochemical analysis of cyclic nucleotide phosphodiesterase (PD) distribution in individual aggregates at various stages of development. With handmade constriction pipettes in microliter volumes, sections of lyophilized individuals weighing 20-100 ng could be assayed in a reaction coupled to 5'-nucleotidase. Phosphodiesterase activity was measured at pH 7.5 with 12 microM cAMP, cAMP-PD activity in aggregates ranged from 20-40 mmol/h/kg. In the pseudoplasmodium it had dropped to 5-10 mmol/h/kg and a difference in activity between the anterior prestalk cells and posterior prespore cells began to appear. The utmost posterior sections showed elevated phosphodiesterase from this stage onward. During culmination, activity rose to 40-60 mmol/h/kg associated with the developing stalk, while it declined in the spore mass. The papilla remained constant at 5-10 mmol/h/kg. The pattern of localization in the stalk was the same when cGMP was used as substrate. Extracellular phosphodiesterase inhibitor produced at the aggregation stage was found to reduce the localized activity in the culmination stage by 50-80%, with the most marked inhibition occurring in the center of the papilla. We found no evidence of endogenous heat-stable phosphodiesterase inhibitor within the culminating sorocarp.

The prestalk-prespore pattern in cellular slime molds

In cellular slime molds the slugs become divided into two regions with different properties, and anterior prestalk-zone and a posterior prespore zone. Although the cells in these zones are normally destined to form the stalk cells and spores of the fruiting body, respectively, they are not irreversibly committed to one sort of differentiation or the other during the slug stage. The volume ratio of the two zones remains almost constant over a wide range of slug sizes. If the prestalk-prespore pattern is distrubed by removing tissue from the slug, conversion of tissue from prestalk to prespore or vice versa occurs as necessary to restore a normal pattern with normal proportions. Conversions also occur in both directions during normal development. The initial formation of the prestalk-prespore pattern may well involve sorting-out, but other mechanisms must be invoked to account for regulation. We describe three different models of the generation of the prestalk-prespore pattern, the'cell-contact model' of McMahon, in which pattern is created by interactions of cells with their immediate neighbors, the 'positional-information model' of various authors, in which pattern formation involves an overall gradient and a gradient-reading mechanism, and the 'activator-inhibitor model' of Gierer and Meinhardt, in which the prestalk-prespore pattern is formed by a system of diffusible substances that affect one another's production. The activator-inhibitor model is the most successful of the models at describing the known features of the prestalk-prespore pattern. The various models lead to a number of distinctive predictions. According to the cell-contact model, small transplants may cause gross changes in the prestalk-prespore pattern, and mutants may exist which severely disrupt pattern formation even if diluted with a large excess of wild-type cells. Positional-information models predict the existence of 'gradient-reading mutants'; slugs that are a mixture of such mutants and wild-type cells would show two prestalk-prespore boundaries, one at the mutant and one at the normal position. Both the activator-inhibitor model and some versions of the positional-information model predict that small transplants will sometimes induce accessory prestalk or prespore zones; the quantitative characteristics of these effects may allow one to make a case in favor of one or other of the two models. Finally, the activator-inhibitor model leads one to expect that mutants may be isolated which normally show accessory prestalk or prespore zones. A search for these phenomena may help determine whether the activator-inhibitor model will continue to enjoy its present preeminent position.