Ammonia promotes accumulation of intracellular cAMP in differentiating amoebae of Dictyostelium discoideum

We used sporogenous mutants of Dictyostelium discoideum to investigate the mechanism(s) by which exogenous NH4Cl and high ambient pH promote spore formation during in vitro differentiation. The level of NH4Cl required to optimize spore formation is correlated inversely with pH, indicating that NH3 rather than NH4+ is the active species. The spore-promoting activity of high ambient pH (without exogenous NH4Cl) was eliminated by the addition of an NH3-scavenging cocktail, suggesting that high pH promotes spore differentiation by increasing the ratio of NH3:NH4+ secreted into the medium by developing cells. High ammonia levels and high pH stimulated precocious accumulation of intracellular cAMP in both sporogenous and wild-type cells. In both treatments, peak cAMP levels equaled or exceeded control levels and were maintained for longer periods than in control cells. In contrast, ammonia strongly inhibited accumulation of extracellular cAMP without increasing the rate of extracellular cAMP hydrolysis, indicating that ammonia promotes accumulation of intracellular cAMP by inhibiting cAMP secretion. These results are consistent with previous observations that factors that raise intracellular cAMP levels increase spore formation. Lowering intracellular cAMP levels with caffeine or progesterone inhibited spore formation, but simultaneous exposure to these drugs and optimal concentrations of NH4Cl restored both cAMP accumulation and spore formation to normal levels. These data suggest that ammonia, which is a natural Dictyostelium morphogen, favors spore formation by promoting accumulation or maintenance of high intracellular cAMP levels.     

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.     

Reversible inhibition of aggregation-related cohesivity in Dictyostelium discoideum by diffusible metabolites

Evidence presented elsewhere (G.B. Williams, E.M. Elder, and M. Sussman 1984, Dev. Biol. 105, 377-388) indicates that NH3 and certain carboxylic acids including propionate, succinate, and acetate modulate the cAMP relay in Dictyostelium discoideum. The former appears to act as a cAMP accumulation inhibitor, the latter as cAMP release inhibitors. The cohesive properties of aggregation competent cells have been assayed quantitatively in the presence of these modulators. The following results were obtained: (1) At pH 7.5, EDTA-resistant cohesivity was greatly inhibited by NH4C within the concentration range tested (30-3.8 mM). Even at the higher concentrations the effect was not immediate but required ca. 10 min for full expression. At the lower concentrations, the inhibitory level was only slightly reduced but the time for full expression progressively increased. At pH 6.5, the level of inhibition was marginal, indicating that NH3 is the active molecular species. By themselves, neither ambient pH nor ionic strength appeared to affect cohesive performance within the ranges employed. The inhibition was immediately and completely reversed upon removal of NH4Cl or a shift of ambient pH from 7.5 to 6.5. The presence of cycloheximide did not affect the recovery of cohesivity after NH4Cl removal. (2) The presence of 15 mM succinate, propionate, or acetate also reduced cell cohesivity. The timing and extent of the inhibition were identical at pH 7.5 and 6.5. The inhibition was expressed immediately and was reversible. Each of the acids acted synergistically with NH4Cl. The relative potencies of these metabolites acting singly or in combination as inhibitors of cohesivity corresponded roughly to their potencies as modulators of the cAMP relay (Williams et al., 1984). (3) The sensitivity to the metabolites was stage specific, being maximal during and shortly after aggregation and disappearing abruptly at 11-12 hr. This corresponds to the time at which this cohesive system, responsible for the end-to-end cell associations evident during aggregation (H. Beug, G. Gerisch, S. Kempff, V. Riedel, and G. Cremer, 1970, Exp. Cell. Res. 63, 147-158) is supplanted by a newly arisen, serologically and genetically distinct system which thereafter maintains the integrity of the aggregate (C. Steinemann and R.W. Parish, 1980, Nature (London) 286, 721-724; D.K. Wilcox and M. Sussman, 1981, Dev. Biol. 82, 102-112, and Proc. Natl. Acad. Sci. USA 78, 358-362; C.L. Saxe III and M. Sussman, 1982, Cell 29, 755-759). The activities of the metabolites, detailed above, are discussed in relation to their previously demonstrated activities as morphogens.     

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.     

Ammonium sulfate modifies adenylate cyclase and the chemotactic receptor of Dictyostelium discoideum. Evidence for a G protein effect

(NH4)2SO4 was found to activate adenylate cyclase in Dictyostelium discoideum membranes. The effect of (NH4)2SO4 on the enzyme was observed after pretreatment of membranes but could not be observed if the salt was added to the assay mixture. Activation was seen when membranes were pretreated with 0.16 M (NH4)2SO4 and was maximal at 0.6-1.0 M. The maximal activation of the enzyme was observed within 3 min of pretreatment and was not readily reversible. The effect was specific for the NH+4 ion since pretreatment of membranes with other NH+4 salts could activate the enzyme, whereas pretreatment with NaCl or KCl could not. Pretreatment of plasma membranes with (NH4)2SO4 eliminated the sensitivity of the enzyme to the inhibitory effect of guanine nucleotides. (NH4)2SO4 pretreatment also significantly attenuated the inhibition by guanine nucleotides of cAMP binding to its plasma membrane receptor. The effect of (NH4)2SO4 on GTP inhibition of cAMP binding to its receptor was even more dramatic when the salt was present in the binding assay. (NH4)2SO4 also increased the ADP-ribosylation by cholera toxin of a 39,000-Da membrane protein. The data support the hypothesis that (NH4)2SO4-induced changes in adenylate cyclase and the cAMP receptor are due to an alteration of a putative G protein.     

Pertussis toxin inhibits cAMP surface receptor-stimulated binding of [35S]GTP gamma S to Dictyostelium discoideum membranes

GTP-binding activity to Dictyostelium discoideum membranes was investigated using various guanine nucleotides. Rank order of binding activities was: GTP gamma S greater than GTP greater than 8-N3-GTP; the binding of GTP gamma S and GTP, but not of 8-N3-GTP, was stimulated by receptor agonists. [3H]GTP binding to D. discoideum membranes has been described previously by a single binding type (Kd = 2.6 microM, Bmax = 85 nM). More detailed studies with [35S]GTP gamma S showed heterogeneous binding composed of two forms of binding sites with respectively high (Kd = 0.2 microM) and low (Kd = 6.3 microM) affinity. cAMP derivatives enhanced GTP gamma S binding by increasing the affinity and the number of the high-affinity sites, while the low-affinity sites were not affected by cAMP. The specificity of cAMP derivatives for stimulation of GTP gamma S binding showed a close correlation with the specificity for binding to the cell surface cAMP receptor. Pretreatment of D. discoideum cells with pertussis toxin did not affect basal GTP and GTP gamma S binding, but eliminated the cAMP stimulation of GTP and GTP gamma S binding. These results indicate that D. discoideum cells have a pertussis toxin-sensitive GTP-binding protein that interacts with the surface cAMP receptor, suggesting the functional interaction of surface receptor with a G-protein in D. discoideum.     

Dual role of cAMP and involvement of both G-proteins and ras in regulation of ERK2 in Dictyostelium discoideum.

Dictyostelium discoideum expresses two Extracellular signal Regulated Kinases, ERK1 and ERK2, which are involved in growth, multicellular development and regulation of adenylyl cyclase. Binding of extracellular cAMP to cAMP receptor 1, a G-protein coupled cell surface receptor, transiently stimulates phosphorylation, activation and nuclear translocation of ERK2. Activation of ERK2 by cAMP is dependent on heterotrimeric G-proteins, since activation of ERK2 is absent in cells lacking the Galpha4 subunit. The small G-protein rasD also activates ERK2. In cells overexpressing a mutated, constitutively active rasD, ERK2 activity is elevated prior to cAMP stimulation. Intracellular cAMP and cAMP-dependent protein kinase (PKA) are essential for adaptation of the ERK2 response. This report shows that multiple signalling pathways are involved in regulation of ERK2 activity in D.discoideum.     

Involvement of cyclic AMP cell surface receptors and G-proteins in signal transduction during slug migration of Dictyostelium discoideum.

The presence of G-proteins, interacting with cAMP surface receptors, was investigated in vegetative cells, aggregation-competent cells, and migrating slugs of Dictyostelium discoideum. Our results indicate that G-proteins are present in all stages. In vegetative cells there is a limited number of cAMP receptors but no effect of GTP tau S on cAMP binding could be detected; in addition, no effect of cAMP on GTP tau S binding or GTPase activity was observed. In both aggregation-competent cells and slugs GTP tau S inhibits cAMP binding, while cAMP stimulates GTP tau S binding and high-affinity GTPase. Since the presence of G-proteins coupled to cAMP receptors could be demonstrated in slugs, the involvement of the effector enzymes adenylate cyclase and phospholipase C was investigated. The results show that adenylate cyclase activity is stimulated by GTP tau S in both stages and that in cells from migrating slugs the Ins(1,4,5)P3 production is increased upon stimulation with cAMP. The possible involvement of G-proteins in signal transduction during the slug stage of D. discoideum is discussed.     

Agonist-stimulated high-affinity GTPase in Dictyostelium membranes

GTP hydrolysis in Dictyostelium discoideum membranes is caused by a low (Km greater than 1 mM) and a high affinity (Km 6.5 microM) GTPase. cAMP enhances GTP hydrolysis apparently by increasing the affinity of the high affinity GTPase (stimulated Km 4.5 microM); the low affinity GTPase was not affected by cAMP. Stimulation of GTP hydrolysis by cAMP was maximal at early time points and declined thereafter. A half-maximal stimulation of GTPase occurred at 3 microM cAMP and the specificity of cAMP derivatives for stimulation of GTPase activity showed a close correlation with the specificity for binding to the cell surface cAMP receptor. Treatment of D. discoideum cells with pertussis toxin decreased the cAMP-induced stimulation of GTPase from 42 +/- 6% in control cells to 17 +/- 9% in pertussis toxin-treated cells. These results suggest that the interaction of cAMP with its surface receptor leads to stimulation of high affinity GTPase in D. discoideum membranes. At least one of those enzymes may represent a guanine nucleotide-binding protein sensitive to pertussis toxin.     

Guanylate Cyclase Activity in Dictyostelium discoideum and Its Increase during Cell Development

Following consumption of the food supply, cells of the cellular slime mould Dictyostelium discoideum aggregate and form a multicellular organism. The mechanism for cell aggregation is chemotaxis. The chemotactic signal in D. discoideum is released periodically from aggregation centers and propagated from cell to cell. cAMP mediates cell aggregation by acting as chemotactic attractant and as propagator of the signal. cAMP signals are measured by cell-surface receptors. Recent evidence indicates a role for cGMP during cAMP-mediated cell aggregation in D. discoideum .
During cell differentiation to aggregation competence, cAMP binding sites appear at the cell surface, and the activity of the enzymes adenylate cyclase and phosphodiesterase increases several-fold. In the present work we investigate the synthesis of cGMP in D. discoideum . Conditions for the assay of guanylate cyclase in cell homogenates are described. Guanylate cyclase activity was followed during cell differentiation to aggregation competence and found to increase fourfold. These results indicate that cGMP is involved in cell differentiation of D. discoideum . In contrast to adenylate cyclase, which is activated by cAMP, guanylate cyclase was under our conditions activated neither by cAMP, nor by folic acid.     

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)     

The actin-binding protein comitin (p24) is a component of the Golgi apparatus

Comitin (p24) was first identified in Dictyostelium discoideum as a membrane-associated protein which binds in gel overlay assays to G and F actin. To analyze its actin-binding properties we used purified, bacterially expressed comitin and found that it binds to F actin in spin down experiments and increases the viscosity of F actin solutions even under high-salt conditions. Immunofluorescence studies, cell fractionation experiments and EM studies of vesicles precipitated with comitin-specific monoclonal antibodies showed that comitin was present in D. discoideum on: (a) a perinuclear structure with tubular or fibrillary extensions; and (b) on vesicles distributed throughout the cell. In immunofluorescence experiments using comitin antibodies NIH 3T3 fibroblasts showed a similar staining pattern as D. discoideum cells. Using bona fide Golgi markers the perinuclear structure was identified as the Golgi apparatus. The results were supported by an electron microscopic study using cryosections. Based on these data we propose that also in Dictyostelium the stained perinuclear structure is the Golgi apparatus. In vivo the perinuclear structure was found to be attached to the actin and the microtubule network. Alteration of the actin network or depolymerization of the microtubules led to its dispersal into vesicles distributed throughout the cell. These results suggest that the Golgi apparatus in D. discoideum is connected to the actin network by comitin. This protein seems also to be present in mammalian cells.     

Apparent Positive Cooperativity at a Surface cAMP Receptor in Dictyostelium

In the large species of the cellular slime mold Dictyostelium , cell aggregation is regulated by extracellular cAMP. During aggregation, cAMP is released in pulses from cells in the aggregation centers and these rhythmic signals are propagated through the population by a signal relay system. In addition to triggering the relay response, the pulsatile signals also regulate the chemotactic movement of the cells and early cell differentiation. These different cellular responses to exogenous cAMP are thought to be mediated via cAMP receptors, which appear on the cell surface shortly after starvation.
Using a sensitive assay, the equilibrium binding properties of these receptors were analyzed at low cAMP concentrations. As reported earlier, Scatchard plots of cAMP binding to preaggregative amoebae of D. discoideum strain NP187 in the concentration range 2–500 nM were curvilinear suggesting either receptor heterogeneity or negative cooperative interactions. However, at cAMP concentrations below approximately 1.5 nM, the affinity of the receptors was found to decline as a function of decreasing receptor occupancy. This apparent positive cooperativity was observed with binding sites on crude plasma membranes as well as on intact cells, and it occurred at both 0°C and 22°C. Moreover, apparent positive cooperativity was a property of the receptors on all strains of D. discoideum examined and on one strain of D. purpureum . Unlike preaggregative cells, receptors on postaggregative cells often lacked this property.
The lowest concentration of cAMP pulses that can appreciably stimulate membrane differentiation in strain NP187 was found to be 0.15–1.5 nM. Since similar concentrations of exogenous cAMP have been reported to trigger minimal chemotactic and relay responses in D. discoideum , the apparent positive cooperative behavior of the cAMP receptor might function to generate a steep cellular response threshold.     

Evolution of self-organisation in Dictyostelia by adaptation of a non-selective phosphodiesterase and a matrix component for regulated cAMP degradation

Dictyostelium discoideum amoebas coordinate aggregation and morphogenesis by secreting cyclic adenosine monophosphate (cAMP) pulses that propagate as waves through fields of cells and multicellular structures. To retrace how this mechanism for self-organisation evolved, we studied the origin of the cAMP phosphodiesterase PdsA and its inhibitor PdiA, which are essential for cAMP wave propagation. D. discoideum and other species that use cAMP to aggregate reside in group 4 of the four major groups of Dictyostelia. We found that groups 1-3 express a non-specific, low affinity orthologue of PdsA, which gained cAMP selectivity and increased 200-fold in affinity in group 4. A low affinity group 3 PdsA only partially restored aggregation of a D. discoideum pdsA-null mutant, but was more effective at restoring fruiting body morphogenesis. Deletion of a group 2 PdsA gene resulted in disruption of fruiting body morphogenesis, but left aggregation unaffected. Together, these results show that groups 1-3 use a low affinity PdsA for morphogenesis that is neither suited nor required for aggregation. PdiA belongs to a family of matrix proteins that are present in all Dictyostelia and consist mainly of cysteine-rich repeats. However, in its current form with several extensively modified repeats, PdiA is only present in group 4. PdiA is essential for initiating spiral cAMP waves, which, by organising large territories, generate the large fruiting structures that characterise group 4. We conclude that efficient cAMP-mediated aggregation in group 4 evolved by recruitment and adaptation of a non-selective phosphodiesterase and a matrix component into a system for regulated cAMP degradation.     

Induction of post-aggregative differentiation in Dictyostelium discoideum by cAMP: Evidence of involvement of the cell surface cAMP receptor

Exogenous cAMP is known to induce post-aggregative differentiation in Dictyostelium discoideum under conditions that normal development is blocked. We have analysed the cyclic nucleotide specificity, the effect of modulation of the cAMP signal and the dose-response relationship of the induction of two independent markers of post-aggregative differentiation, i.e., a prespore cell-specific antigen detected by a monoclonal antibody, and the activity of glycogen phosphorylase. Our results confirm that high concentrations of cAMP (10(-6)-10(-3)M) are required for the induction of these markers. The cells are shown not to adapt to the cAMP signal. The cyclic nucleotide specificity of induction agrees with the specificity of the cell surface cAMP receptor, but is very dissimilar to the specificity of the intracellular cAMP-dependent protein kinase. It is thus unlikely that cAMP leaks into the cell and activates the cAMP-dependent protein kinase directly. Instead, the induction of post-aggregative differentiation by cAMP seems to be mediated by cell surface cAMP receptors.     

Signaling molecules involved in the transition of growth to development of Dictyostelium discoideum

The social amoeba Dictyostelium discoideum, a powerful paradigm provides clear insights into the regulation of growth and development. In addition to possessing complex individual cellular functions like a unicellular eukaryote, D. discoideum cells face the challenge of multicellular development. D. discoideum undergoes a relatively simple differentiation process mainly by cAMP mediated pathway. Despite this relative simplicity, the regulatory signaling pathways are as complex as those seen in metazoan development. However, the introduction of restriction-enzyme-mediated integration (REMI) technique to produce developmental gene knockouts has provided novel insights into the discovery of signaling molecules and their role in D. discoideum development. Cell cycle phase is an important aspect for differentiation of D. discoideum, as cells must reach a specific stage to enter into developmental phase and specific cell cycle regulators are involved in arresting growth phase genes and inducing the developmental genes. In this review, we present an overview of the signaling molecules involved in the regulation of growth to differentiation transition (GDT), molecular mechanism of early developmental events leading to generation of cAMP signal and components of cAMP relay system that operate in this paradigm.     

Reduced cAMP secretion in Dictyostelium discoideum mutant HB3

Extracellular cAMP induces the intracellular synthesis and subsequent secretion of cAMP in Dictyostelium discoideum (relay). cAMP relay was strongly diminished in mutant HB3 which shows abnormal development by making very small fruiting bodies. Extracellular cAMP binds to receptors on the surface of mutant cells and induces the rapid activation of adenylate cyclase. Intracellular cAMP rises to a concentration as high as that in wild-type cells but only a very small amount of cAMP is secreted. cAMP secretion in wild-type cells starts immediately after cAMP production, and is proportional to the intracellular cAMP concentration. In the mutant cells cAMP secretion starts a few minutes after cAMP production; by that time most of the intracellular cAMP is already degraded by phosphodiesterase and little cAMP is available for secretion. We conclude that mutant HB3 has a defect in the mechanism by which Dictyostelium cells secrete cAMP.     

Developmental regulation of the Inositol 1,4,5-trisphosphate phosphatases in Dictyostelium discoideum

The cellular slime mold Dictyostelium discoideum is a microorganism in which growth and development are strictly separated. Starvation initiates a developmental program in which extracellular cAMP plays a major role as a signal molecule. In response to cAMP several second messengers are produced, including cAMP, cGMP and inositol 1,4,5-trisphosphate, (Ins(1,4,5)P3). Ins(1,4,5)P3 levels are controlled by the activation of phosphoinositidase C and the activity of the Ins(1,4,5)P3-degrading phosphatases. In Dictyostelium discoideum two major routes for the dephosphorylation of Ins(1,4,5)P3 are present: a 5-phosphatase, which hydrolyses Ins(1,4,5)P3 at the 5-position producing Ins(1,4)P2 as in vertebrate cells, and a 1-phosphatase which removes the 1-phosphate, giving Ins(4,5)P2, as in plants. In this paper we show that at the onset of development both the 1-phosphatase and the 5-phosphatase are present in equal amounts. During development the 5-phosphatase disappears leaving the 1-phosphatase as the single enzyme to remove Ins(1,4,5)P3. We conclude that during development Dictyostelium discoideum switches from a mixed type of Ins(1,4,5)P3 degradation to a more plant-like degradation pathway.     

A serpentine receptor-dependent, Gbeta- and Ca(2+) influx-independent pathway regulates mitogen-activated protein kinase ERK2 in Dictyostelium.

Ca(2+) influx and mitogen-activated protein (MAP) kinase activation are important phenomena in signal transduction, which are often interconnected. We investigated whether serpentine receptor-dependent, Gbeta-independent activation of MAP kinase ERK2 by chemoattractant cyclic AMP (cAMP) is mediated by Ca(2+) influx in the social amoeba Dictyostelium discoideum. We generated a D. discoideum double mutant, which harbours a temperature-sensitive Gbeta subunit and expresses the apoaequorin protein. Utilizing this mutant, we demonstrate that cAMP induced Ca(2+) influx into intact D. discoideum cells can be blocked completely at both the permissive and the restrictive temperature, by using either gadolinium ions or Ruthenium Red. Under the same experimental conditions, these substances do not abolish cAMP stimulation of ERK2 at either temperature. We conclude that there is a Gbeta- and Ca(2+) influx-independent pathway for the receptor-dependent activation of MAP kinase ERK2 in D. discoideum.