Morphogenetic cell movement in Dictyostelium

Dictyostelium morphogenesis starts with the chemotactic aggregation of starving individual cells. The cells move in response to propagating waves of the chemoattractant cyclic AMP initiated by cells in the aggregation centre. During aggregation the cells begin to differentiate into several types with different signalling and chemotactic properties. These cell types sort out from each other to form an axial pattern in the slug. There is now good evidence that periodic chemotactic signals not only control aggregation, but also later stages of morphogenesis. These signals take the form of target patterns, spirals, multi-armed spirals and scroll waves. I will discuss their role in the control of cell movement during mound and slug formation and in the formation of the fruiting body.     

A model for cell type localization in the migrating slug of <Emphasis Type="Italic">Dictyostelium discoideum</Emphasis> 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.     

Calcium,cyclic GMP and the control of myosin II during chemotactic signal transduction ofDictyostelium

Evidence is presented for Ca²⁺ and cyclic GMP being involved in signal transduction between the cell surface cyclic AMP receptors and cytoskeletal myosin II involved in chemotactic cell movement. Ca²⁺ is shown to be required for chemotactic aggregation of amoebae. The evidence for uptake and/or eflux of this ion being regulated by the nucleotide cyclic GMP is discussed. The connection between Ca²⁺, cyclic GMP and chemotactic cell movement has been explored using “streamer F” mutants. The primary defect in these mutants is in the structural gene for the cyclic GMP-specific phosphodiesterase which results in the mutants producing an abnormally prolonged peak of accumulation of cyclic GMP in response to stimulation with the chernoattractant cyclic AMP. While events associated with production and relay of cyclic AMP signals are normal, certain events associated with movement are (like the cyclic GMP response) abnormally prolonged in the mutants. These events include Ca²⁺ uptake, myosin II association with the cytoskeleton and inhibition of myosin heavy and light chain phosphorylation. These changes can be correlated with the amoebae becoming elongated and transiently decreasing their locomotive speed after chemotactic stimulation. Other mutants studied in which the accumulation of cyclic GMP in response to cyclic AMP stimulation was absent produced no myosin II responses. Models are described in which cyclic GMP (directly or indirectly via Ca²⁺) regulates accumulation of myosin II on the cytoskeleton by inhibiting phosphorylation of the myosin heavy and light chain kinases.     

Streamers: chemotactic mutants of Dictyostelium discoideum with altered cyclic GMP metabolism

Mutants of Dictyostelium discoideum that developed huge aggregation streams in expanding clones were investigated using optical and biochemical techniques. Representatives of the six complementation groups previously identified (stmA-stmF) were found to be similar to the parental wild-type strain XP55 in both the extent and timing of their ability to initiate and relay chemotactic signals and in the formation of cyclic AMP receptors and phosphodiesterases. The mutants differed from the wild-type in producing an abnormal chemotactic (movement) response visible using both dark-field optics with synchronously aggregating amoebae on solid substrata and light scattering techniques with oxygenated cell suspensions. Mutants of complementation group stmF showed chemotactic movement responses lasting up to 520 s, rather than 100 s as seen in the parental and other strains. Measurements of cyclic GMP formed intracellularly in response to chemotactic pulses of cyclic AMP in stmF mutants showed that abnormally high concentrations of this nucleotide were formed within 10 s and were not rapidly degraded. A causal correlation between defective cyclic GMP metabolism and the altered chemotactic response is suggested, and a model is proposed that accounts for the formation of huge aggregation streams in clones of these mutants.U     

Streamer F mutants and chemotaxis of Dictyostelium.

Streamer F mutants have been found to be useful tools for studying the pathway of signal transduction leading to chemotactic cell movement. The primary defect in these mutants is in the structural gene for the cyclic GMP specific phosphodiesterase. This defect allows a larger and prolonged peak of cyclic GMP to be formed in response to the chemotactic stimulus, cyclic AMP. This characteristic aberrant pattern of cyclic GMP accumulation in the streamer F mutants has been correlated with similar patterns of changes in the influx of calcium from the medium, myosin II association with the cytoskeleton, myosin phosphorylation and a decrease in speed of movement of the amoebae. From these studies a sequence of events can be deduced that leads from cell surface cyclic AMP stimulation to cell polarization prior to movement of the amoebae in response to the chemotactic stimulus.     

Cyclic AMP and calcium exchange in a cellular slime mold

Cyclic AMP is known to be an effective chemotactic agent for amebae of the cellular slime mold D. discoideum. A large amount of information from experiments on metazoa suggested that one cellular effect of cyclic AMP might be to alter the permeability of the cell membrane to Calcium or Sodium ions. On the basis of this information experiments were designed to test the effect of cyclic AMP on outflow of labeled Calcium or Sodium ions from amebae of D. discoideum. It was found that addition of cyclic AMP at 10^?4M resulted in a large increase of Ca⁴⁵ outflow from cells at the pre-aggregative or aggregative stage of development. No effect was found on Na²² outflow. It is suggested that this effect on Calcium permeability of the membrane is related to the chemotactic influence of ATP by some action on the contractile mechanism for ameboid movement. The phenomenon may be distinct from the enzyme inductive activity of cyclic AMP known for bacteria, and perhaps occurring in the cellular slime molds as well.     

Local and spatially coordinated movements in Dictyostelium discoideum amoebae during chemotaxis

We have studied chemotaxis by individual Dictyostelium discoideum amoebae using strong, local gradients of the chemoattractant cyclic AMP. Gradients were provided by diffusion of cyclic AMP from a microneedle, which could be positioned at various points around the cell. Responses to changes in the gradient indicate how the cell is structurally organized for chemotactic movement. There is a polarity in the responsiveness of the surface to stimulation by cyclic AMP along the length of the amoeba. Furthermore, two aspects of chemotactic movement can be distinguished. The first response to cyclic AMP is a locally generated extension of a hyaline pseudopod from the region of the surface nearest the stimulus. The second response, the flow of cytoplasm in the direction of the stimulus, is coordinated and separate from the first response. The coordination appears to depend on the nucleus or on the microtubule-organizing center.     

Suppression of cyclic AMP-induced cell excitation in Dictyostelium discoideum by inhibitors of eicosanoid oxidation

Abstract Receptor-mediated stimulation of Dictyostelium cells by the aggregative chemoattractant cyclic AMP leads to a complex excitatory response resulting in chemotaxis and the synthesis and release of cyclic AMP as the relayed chemotactic signal. However, the mechanism of this stimulus-response coupling is not well understood. In this study, we show that a number of compounds, best known as inhibitors of cyclooxygenase activity in mammalian cells, prevent cyclic AMP receptor-mediated cell excitation and cyclic AMP accumulation in aggregation-competent Dictyostelium cells. These observations suggest that some eicosanoid-like compound(s) may be involved in stimulus-response coupling in this organism, as is the case in higher eukaryotic cells.     

Histamine modulation of eosinophil migration.

Preincubation of eosinophils with 10(-5) M or higher concentrations of histamine inhibited the eosinophil chemotactic response to endotoxin-activated serum whether by using the nucleopore filter assay and counting the cells migrating through the filter, or by using the Zigmond-Hirsch assay and counting the cells at each 10-mum interval. When the H2-receptor sites on the eosinophils were blocked by metiamide, the inhibitory capacity of histamine was prevented. Preincubation of eosinophils with 10(-6) M histamine increased the number of responding eosinophils to endotoxin-activated serum and this enhancement was blocked by an H1-receptor antagonist. Isoproteronol and aminophylline inhibited eosinophil movement and increasing concentrations of dibutryl cyclic AMP inhibited eosinophil migration. Concentrations of histamine that consistently resulted in inhibition of eosinophil movement stimulated an increase in cyclic AMP that was prevented by blocking the H2-receptor but not the H1-receptor. Thus, histamine-dependent inhibition of the eosinophil chemotactic response to other agents is mediated through the H2-receptor and is associated with an increase in the intracellular level of cyclic AMP whereas histamine dependent enhancement of eosinophil migration to other agents appears to be mediated through the H1-receptor. Eosinophils behave as a heterogeneous population as assessed by the ability of histamine to augment or inhibit cell migration. This may reflect differences in H1 to H2 receptor density or cell responsiveness to receptor stimulation. The chemoattractant activity of histamine itself is not influenced by H1 or H2 receptor antagonists, thus it is possible that an eosinophil has a third type of histamine receptor.     

Chemotaxis to cAMP and slug migration in Dictyostelium both depend on migA, a BTB protein.

Chemotaxis in natural aggregation territories and in a chamber with an imposed gradient of cyclic AMP (cAMP) was found to be defective in a mutant strain of Dictyostelium discoideum that forms slugs unable to migrate. This strain was selected from a population of cells mutagenized by random insertion of plasmids facilitated by introduction of restriction enzyme (a method termed restriction enzyme-mediated integration). We picked this strain because it formed small misshapen fruiting bodies. After isolation of portions of the gene as regions flanking the inserted plasmid, we were able to regenerate the original genetic defect in a fresh host and show that it is responsible for the developmental defects. Transformation of this recapitulated mutant strain with a construct carrying the full-length migA gene and its upstream regulatory region rescued the defects. The sequence of the full-length gene revealed that it encodes a novel protein with a BTB domain near the N terminus that may be involved in protein-protein interactions. The migA gene is expressed at low levels in all cells during aggregation and then appears to be restricted to prestalk cells as a consequence of rapid turnover in prespore cells. Although migA- cells have a dramatically reduced chemotactic index to cAMP and an abnormal pattern of aggregation in natural waves of cAMP, they are completely normal in size, shape, and ability to translocate in the absence of any chemotactic signal. They respond behaviorally to the rapid addition of high levels of cAMP in a manner indicative of intact circuitry connecting receptor occupancy to restructuring of the cytoskeleton. Actin polymerization in response to cAMP is also normal in the mutant cells. The defects at both the aggregation and slug stage are cell autonomous. The MigA protein therefore is necessary for efficiently assessing chemical gradients, and its absence results in defective chemotaxis and slug migration.     

The role of cyclic AMP in the chemotactic responsiveness and spontaneous motility of rabbit peritoneal neutrophils. The inhibition of neutrophil movement and the elevation of cyclic AMP levels by catecholamines, prostaglandins, theophylline and cholera toxin.

Agents known to affect intracellular levels of cyclic AMP in many diverse systems have been tested for their effect on the chemotaxis induced by Escherichia coli culture filtrates, spontaneous motility and cyclic AMP levels of rabbit peritoneal neutrophils. Prostaglandin E1 and A1 but not prostaglandin F2alpha increased neutrophil cyclic AMP levels and, correspondingly, only the former two prostaglandins inhibited chemotaxis. Nevertheless, a quantitative relationship between prostaglandin stimulation of cyclic AMP and inhibition of chemotaxis could not be found. Epinephrine, isoproterenol, and, to a much lesser extent, norepinephrine increased neutrophil cyclic AMP through beta adrenergic stimulation. Only epinephrine and isoproterenol inhibited chemotaxis, but the inhibition was variable and not related to the ability of these catecholamines to increase intracellular cyclic AMP. Cholera toxin increased neutrophil cyclic AMP after a 30-min lag period which paralled its inhibitory effect on chemotaxis and spontaneous motility. However, the effect on chemotaxis require 50 ng/ml of toxin whereas the effect on cyclic AMP was manifested at 2 ng/ml of toxin. Prior to 30-min preincubation there was no effect of even 1250 ng/ml of toxin on either cyclic AMP or chemotaxis. Choleragenoid prevented the effects of toxin on both cyclic AMP and chemotaxis. The bacterial chemotactic factor obtained from E. coli culture filtrates did not effect a measurable change in levels of neutrophil cyclic AMP. The data indicate that even though cyclic AMP is not, in the main sequence of events, triggering the chemotactic response, increases in neutrophil cyclic AMP may modulate the movement and thus the chemotactic responsiveness of the neutrophil.     

Chemotaxis and binding of cyclic AMP in cellular slime molds.

To obtain more information about how cyclic AMP mediates cell aggregation as found in some species of the cellular slime molds, we determined the maximal binding activity of cyclic AMP in different species under various environmental conditions. The binding of cyclic AMP is limited to amoebae using this cyclic nucleotide as chemotactic agent. Maximal binding activity proved to coincide with a maximal chemotactic response and to be related to the length of the period between the vegetative and the aggregative phase. Of the species studied, Dictyostelium discoideum has the highest cellular density of cyclic AMP receptors and is the most sensitive to cyclic AMP as attractant. At 15 degrees C, aggregation begins later, chemotaxis takes effect over a greater distance, and the maximal binding activity is higher than 22 degrees C. The number of cyclic AMP receptors is independent of temperature. The delay in the onset of aggregation and the increased chemotactic response in darkness is not due to a change in the maximal binding activity. The binding of cyclic AMP and its inactivation is discussed in the light of cell aggregation.     

CYCLIC AMP IN THE RAT CEREBRAL CORTEX AFTER ACTIVATION OF NORADRENALINE NEURONS OF THE LOCUS COERULEUS

The levels of cyclic AMP in the rat brain were studied in vivo following destruction or stimulation of the noradrenergic pathway originating in the locus coeruleus. After chronic lesion of the locus coeruleus no alterations in cyclic AMP content were found. Electrical stimulation of the locus coeruleus produced an elevation of cyclic AMP in the cerebral cortex of chloral hydrate anaesthetized rats of 30%. Maximal increases were found after 15–60 s stimulation at a frequency of 30–100 Hz. This maximal response was slightly inhibited by phenoxybenzamine, an α-adrenergic blocking agent, and by the β-blocker propranolol. When the α and β blockers were administered together a highly significant decrease in cyclic AMP response was observed. Pretreatment of the rats with reserpinc +α methyl-p-tyrosine prevented the cyclic AMP response. In addition to the effect in the cerebral cortex, cyclic AMP-levels were also enhanced in the hippocampus, in the striatum and in the hypothalamus. These results suggest that the locus coeruleus regulates a small fraction of cerebral cyclic AMP levels, by both α- and β-adrenergic receptors.     

Chemotaxis and binding of cyclic AMP in cellular slime molds

To obtain more information about how cyclic AMP mediates cell aggregation as found in some species of the cellular slime molds, we determined the maximal binding activity of cyclic AMP min different species under various environmental conditions. The binding of cyclic AMP is limited to amoebae using this cyclic nucleotide as chemotactic agent. Maximal binding activity proved to coincide with a maximal chemotactic response and to be related to the lenght of the period between the vegetative and the aggregative phase. Of the species studied, Dictyostelium discoideum has the highest cellular density of cyclic AMP receptors and is the most sensitive to cyclic AMP as attractant.At 15°C, aggregation begins later, chemotaxis takes effect over a greater distance, and the maximal binding activity is higher than at 22°C. The number of cyclic AMP receptors is independent of temperature. The delay in the onset of aggregation and the increased chemotactic response in darkness is not due to a change in the maximal binding activity. The binding of cyclic AMP and its inactivation is discussed in the light of cell aggregation.     

Signal transduction and motility ofDictyostelium

This review is concerned with the roles of cyclic GMP and Ca²⁺ ions in signal transduction for chemotaxis ofDictyostelium. These molecules are involved in signalling between the cell surface cyclic AMP receptors and cytoskeletal myosin II involved in chemotactic cell movement. Evidence is presented for uptake and/or eflux of Ca²⁺ being regulated by cyclic GMP. The link between Ca²⁺, cyclic GMP and chemotactic cell movement has been explored using streamer F mutants whose primary defect is in the structural gene for the cyclic GMP-specific phosphodiesterase. This mutation causes the mutants to produce an abnormally prolonged peak of cyclic GMP accumulation in response to stimulation with the chemoattractant cyclic AMP. The production and relay of cyclic AMP signals is normal in these mutants, but certain events associated with movement are (like the cyclic GMP response) abnormally prolonged in the mutants. These events include Ca²⁺ uptake, myosin II association with the cytoskeleton and regulation of both myosin heavy and light chain phosphorylation. These changes can be correlated with changes in the shape of the amoebae after chemotactic stimulation. Other mutants in which the accumulation of cyclic GMP in response to cyclic AMP stimulation was absent produced no myosin II responses.A model is described in which cyclic GMP (directly or indirectly via Ca²⁺) regulates accumulation of myosin II on the cytoskeleton by regulating phosphorylation of the myosin heavy and light chain kinases.     

Genetics of phototaxis in a model eukaryote,Dictyostelium discoideum

The life cycle of Dictyostelium discoideum offers a unique opportunity to study signal transduction in eukaryotic cells at both the unicellular and multicellular levels of organization. Adding to the already extensive knowledge of the unicellular stages, classical and molecular genetics have begun to unravel transduction of signals controlling morphogenesis and behaviour (phototaxis and thermotaxis) in the multicellular ‘slug’ stage of the life cycle. Distributed over all seven genetic linkage groups are probably about 20, but possibly as many as 55, genes of importance for slug behaviour. The encoded proteins appear from pharmacological studies and mutant phenotypes to govern transduction pathways involving the intracellular second messengers cyclic AMP, cyclic GMP, IP₃ and Ca²⁺. Pathways from the photo- and thermoreceptors converge first with each other and thence, at the level of the second messengers, with those from extracellular tip activation (cyclic AMP) and inhibition (Slug Turning Factor and/or ammonia and/or adenosine) signals that control slug movement and morphogenesis.     

Membrane potentials of Dictyostelium discoideum cells at the pseudoplasmodial stage

Abstract The difference in membrane potentials between prestalk cells and prespore cells has been examined with reference to the formation of cellular pattern in the pseudoplasmodium (slug) of D. discoideum . Each cell at a different concentration of cAMP had a characteristic membrane potential. In addition, differences in and reversal of membrane potentials occurred between the two types of cell. The results indicate that the changes in membrane potential in both types of cell are closely correlated with the changes in chemotactic movement in response to cAMP.     

DEDIFFERENTIATION OF THE DISAGGREGATED SLUG CELL OF THE CELLULAR SLIME MOLD DICTYOSTELIUM DISCOIDEUM

It was previously shown that differentiation of the prespore cell in the pseudoplasmodium (slug) of the cellular slime molds is characterized by the synthesis of a specific substance which is detectable by a heteroplastic antispore serum (T akeuchi , 1963). When a prespore cell which was already differentiated was disaggregated from a slug of Dictyostelium discoideum and was incubated in salt solution under a sparsely populated condition, it gradually lost its specific substance and dedifferentiated. The dedifferentiation proceeded without accompanying cell growth and was completed within 5 hr of incubation. This process was inhibited at a low temperature and also in the presence of cyclohexamide, actinomycin D, and cyclic AMP. The dedifferentiation was induced and proceeded at a normal rate in the absence of bacteria. When a disaggregated slug cell was incubated in the presence of bacteria, however, every prestalk and prespore cell was able to grow and underwent its first cell division after about 9–10 hr of incubation, and then multiplied with the generation time of 3 hr. The relationship between the dedifferentiation and the growth of a disaggregated slug cell was discussed.     

Ammonia differentially suppresses the cAMP chemotaxis of anterior-like cells and prestalk cells indictyostelium 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.     

Distribution of cAMP-dependent protein kinase during development in Dictyostelium discoideum

During the developmental cycle of Dictyostelium discoideum cyclic AMP functions as both a chemotactic signal for aggregation and a regulatory molecule during later events of differentiation. Morphological and biochemical data suggest that cAMP may direct cells during morphogenesis and differentiation. We utilized microtechniques to determine the stage- and cell-specific levels of the cAMP-dependent protein kinase, the probable intracellular cAMP receptor. Kinase activity was low and non-cAMP-dependent in amoebae and early aggregates but increased and became cAMP-dependent in aggregates after the formation of tight cell contacts. Maximum kinase activity and cAMP dependency occurred during the slug and culmination stages. The only differential distribution of the kinase within a single stage occurred during culmination when the activity in the stalks was approximately one-fourth of that in the prespore mass. Preliminary evidence indicates that this difference is not due to an inhibitor. In all other stages tested cAMP-dependent protein kinase activity was equal in prespore and prestalk cells.