Ca(2+) signalling is not required for chemotaxis in Dictyostelium.

Dictyostelium cells can move rapidly towards a source of cyclic-AMP (cAMP). This chemoattractant is detected by G-protein-linked receptors, which trigger a signalling cascade including a rapid influx of Ca(2+). We have disrupted an inositol 1,4,5-trisphosphate (InsP(3)) receptor-like gene, iplA, to produce null cells in which Ca(2+) entry in response to chemoattractants is abolished, as is the normal increase in free cytosolic Ca(2+) ([Ca(2+)](c)) that follows chemotactic stimulation. However, the resting [Ca(2+)](c) is similar to wild type. This mutant provides a test for the role of Ca(2+) influx in both chemotaxis and the signalling cascade that controls it. The production of cyclic-GMP and cAMP, and the activation of the MAP kinase, DdERK2, triggered from the cAMP receptor, are little perturbed in the mutant; mobilization of actin into the cytoskeleton also follows similar kinetics to wild type. Mutant cells chemotax efficiently towards cAMP or folic acid and their sensitivity to cAMP is similar to wild type. Finally, they move at similar speeds to wild-type cells, with or without chemoattractant. We conclude that Ca(2+) signalling is not necessary for chemotaxis to cAMP.

The RdeA-RegA system, a eukaryotic phospho-relay controlling cAMP breakdown.

The regA and rdeA gene products of Dictyostelium are involved in the regulation of cAMP signaling. The response regulator, RegA, is composed of an N-terminal receiver domain linked to a C-terminal cAMP-phosphodiesterase domain. RdeA may be a phospho-transfer protein that supplies phosphates to RegA. We show genetically that phospho-RegA is the activated form of the enzyme in vivo, in that the predicted site of aspartate phosphorylation is required for full activity. We show biochemically that RdeA and RegA communicate, as evidenced by phospho-transfer between the two proteins in vitro. Phospho-transfer is dependent on the presumed phospho-accepting amino acids, histidine 65 of RdeA and aspartate 212 of RegA, and occurs in both directions. Phosphorylation of RegA by a heterologous phospho-donor protein activates RegA phosphodiesterase activity at least 20-fold. Our results suggest that the histidine phosphotransfer protein, RdeA, and the response regulator, RegA, constitute two essential elements in a eukaryotic His-Asp phospho-relay network that regulates Dictyostelium development and fruiting body maturation.

Taking the plunge. Terminal differentiation in Dictyostelium.

During the last stage of Dictyostelium development a motile, cylindrical slug transforms into an immotile, stalked fruiting body and the constituent cells change from amoebae to either refractile spores or vacuolated stalk cells. Analysis of this process using genetics and simple culture techniques is becoming a powerful way of investigating a number of conserved signal transduction processes. A common pathway activating cAMP-dependent protein kinase (PKA) triggers the maturation of spore cells and those stalk cells forming the stalk. It uses a eukaryotic version of the 'bacterial' two-component phospho-relay system to control cAMP breakdown. A second pathway, inhibiting the GSK3 protein kinase, might control the maturation of a distinct set of stalk cells at the base of the fruiting body.

An intersection of the cAMP/PKA and two-component signal transduction systems in Dictyostelium.

Terminal differentiation of both stalk and spore cells in Dictyostelium can be triggered by activation of cAMP-dependent protein kinase (PKA). A screen for mutants where stalk and spore cells mature in isolation produced three genes which may act as negative regulators of PKA: rdeC (encoding the PKA regulatory subunit), regA and rdeA. The biochemical properties of RegA were studied in detail. One domain is a cAMP phosphodiesterase (Km approximately 5 microM); the other is homologous to response regulators (RRs) of two-component signal transduction systems. It can accept phosphate from acetyl phosphate in a reaction typical of RRs, with transfer dependent on Asp212, the predicted phosphoacceptor. RegA phosphodiesterase activity is stimulated up to 8-fold by the phosphodonor phosphoramidate, with stimulation again dependent on Asp212. This indicates that phosphorylation of the RR domain activates the phosphodiesterase domain. Overexpression of the RR domain in wild-type cells phenocopies a regA null. We interpret this dominant-negative effect as due to a diversion of the normal flow of phosphates from RegA, thus preventing its activation. Mutation of rdeA is known to produce elevated cAMP levels. We propose that cAMP breakdown is controlled by a phosphorelay system which activates RegA, and may include RdeA. Cell maturation should be triggered when this system is inhibited.

Differential regulation of types-1 and -3 inositol trisphosphate receptors by cytosolic Ca2+.

Biphasic regulation of inositol trisphosphate (IP3)-stimulated Ca2+ mobilization by cytosolic Ca2+ is believed to contribute to regenerative intracellular Ca2+ signals. Since cells typically express several IP3 receptor isoforms and the effects of cytosolic Ca2+ are not mediated by a single mechanism, it is important to resolve the properties of each receptor subtype. Full-length rat types-1 and -3 IP3 receptors were expressed in insect Sf9 cells at levels 10-40-fold higher than the endogenous receptors. The expressed receptors were glycosylated and assembled into tetramers, and binding of [3H]IP3 to each subtype was regulated by cytosolic Ca2+. The effects of increased [Ca2+] on native cerebellar and type-1 receptors expressed in Sf9 cells were indistinguishable. A maximally effective increase in [Ca2+] reversibly inhibited [3H]IP3 binding by approx. 50% by decreasing the number of IP3-binding sites (Bmax) without affecting their affinity for IP3. The effects of Ca2+ on type-3 receptors were more complex: increasing [Ca2+] first stimulated [3H]IP3 binding by increasing Bmax, and then inhibited it by causing a substantial decrease in the affinity of the receptor for IP3. The different effects of Ca2+ on the receptor subtypes were not a consequence of limitations in the availability of accessory proteins or of artifactual effects of Ca2+ on membrane structure. We conclude that Ca2+ can inhibit IP3 binding to types-1 and -3 IP3 receptors although by different mechanisms, and that IP3 binding to type-3 receptors is stimulated at intermediate [Ca2+]. A consequence of these differences is that, at resting cytosolic [Ca2+], type-3 receptors are more sensitive than type-1 receptors to IP3, but the situation reverses at higher cytosolic [Ca2+]. Such differences may be important in generating the spatially and temporally complex changes in cytosolic [Ca2+] evoked by receptors linked to IP3 formation.

The initiation of basal disc formation in Dictyostelium discoideum is an early event in culmination.

We have analysed expression of the ecmA and ecmB genes of Dictyostelium by enzymatic double staining using beta-galactosidase and beta-glucuronidase reporter gene constructs. Cells expressing the ecmA gene first appear as scattered cells at the mound stage of development and we show that this is also true for cells expressing the ecmB gene. During tip formation the ecmA-expressing cells move to the apex of the mound, while the ecmB-expressing cells accumulate in the base. The ecmB-expressing cells constitute part of the basal disc if the culminant is formed in situ but are discarded if a migratory slug is formed. During slug migration they are replaced by a band of ecmB-expressing cells, situated in the front half of the prespore zone and tightly apposed to the substratum. When culmination is triggered these cells rapidly move to the back half of the prestalk zone, possibly acting as a point of attachment to the substratum. Ultimately, they are joined by cells at the back of the slug, the rearguard cells, to form the basal disc. Thus, contrary to previous belief, basal disc formation is initiated very early during culmination and occurs by the forward movement of cells located in the anterior of the prespore zone.

The proximal pathway of metabolism of the chlorinated signal molecule differentiation-inducing factor-1 (DIF-1) in the cellular slime mould Dictyostelium.

Stalk cell differentiation during development of the slime mould Dictyostelium is induced by a chlorinated alkyl phenone called differentiation-inducing factor-1 (DIF-1). Inactivation of DIF-1 is likely to be a key element in the DIF-1 signalling system, and we have shown previously that this is accomplished by a dedicated metabolic pathway involving up to 12 unidentified metabolites. We report here the structure of the first four metabolites produced from DIF-1, as deduced by m.s., n.m.r. and chemical synthesis. The structures of these compounds show that the first step in metabolism is a dechlorination of the phenolic ring, producing DIF metabolite 1 (DM1). DM1 is identical with the previously known minor DIF activity, DIF-3. DIF-3 is then metabolized by three successive oxidations of its aliphatic side chain: a hydroxylation at omega-2 to produce DM2, oxidation of the hydroxy group to a ketone group to produce DM3 and a further hydroxylation at omega-1 to produce DM4, a hydroxyketone of DIF-3. We have investigated the enzymology of DIF-1 metabolism. It is already known that the first step, to produce DIF-3, is catalysed by a novel dechlorinase. The enzyme activity responsible for the first side-chain oxidation (DIF-3 hydroxylase) was detected by incubating [3H]DIF-3 with cell-free extracts and resolving the reaction products by t.l.c. DIF-3 hydroxylase has many of the properties of a cytochrome P-450. It is membrane-bound and uses NADPH as co-substrate. It is also inhibited by CO, the classic cytochrome P-450 inhibitor, and by several other cytochrome P-450 inhibitors, as well as by diphenyliodonium chloride, an inhibitor of cytochrome P-450 reductase. DIF-3 hydroxylase is highly specific for DIF-3: other closely related compounds do not compete for the activity at 100-fold molar excess, with the exception of the DIF-3 analogue lacking the chlorine atom. The Km for DIF-3 of 47 nM is consistent with this enzyme being responsible for DIF-3 metabolism in vivo. The two further oxidations necessary to produce DM4 are also performed in vitro by similar enzyme activities. One of the inhibitors of DIF-3 hydroxylase, ancymidol (IC50 67 nM) is likely to be particularly suitable for probing the function of DIF metabolism during development.

Two distinct populations of prestalk cells within the tip of the migratory Dictyostelium slug with differing fates at culmination.

The ecmA gene of Dictyostelium encodes an extracellular matrix protein and is selectively expressed in prestalk cells. We show that its promoter contains discrete elements that direct expression in different subpopulations of prestalk cells. Prestalk(pst)A cells occupy the front half of the prestalk region. Expression in pstA cells requires DNA sequences close to the cap site of the gene and a separate, upstream region that acts in combination with the gene proximal sequences. PstO cells are situated in the rear half of the prestalk region and at least two separate and redundant promoter regions direct expression within them. All constructs that are expressed in pstO cells are also expressed in anterior-like cells (ALCs); cells that resemble prestalk cells but which are scattered throughout the prespore region. This observation suggests that pstO cells and ALCs may be very similar in their properties. If development occurs under conditions in which a migratory slug is not formed, there is an ordered movement of cells into the stalk tube. PstA cells enter the stalk tube first, followed by a proportion of the pstO cells. The remainder of the pstO cells contribute to the upper cup, an ALC-derived subpopulation of prestalk cells which is located at the apex of the spore head. After prolonged slug migration, a discrete pstO zone appears not to be maintained and, at culmination, pstO cells are found scattered throughout the stalk.

Interacting signalling pathways regulating prestalk cell differentiation and movement during the morphogenesis of Dictyostelium.

Analysis of the expression patterns of two genes encoding extracellular matrix proteins shows there to be an unexpectedly complex pattern of prestalk cell differentiation and movement during the morphogenesis of Dictyostelium. The organism employs both cell sorting and positional differentiation to generate a patterned structure but these two mechanisms are used at different times during development. During slug formation prestalk cells arise at scattered positions within the aggregate and then move to its apex to form the tip. In contrast, during culmination, stalk cell differentiation occurs in a positionally localized manner at the entrance to the stalk tube. Two interacting signalling pathways regulate the differentiation of prestalk and stalk cells. Prestalk cell differentiation is induced by DIF, a chlorinated hexaphenone, and a repression mechanism prevents DIF acting to induce premature stalk cell differentiation during slug migration. At culmination intracellular cAMP levels rise, the cAMP dependent protein kinase (PKA) is activated and the block to stalk cell differentiation is lifted. Activation of PKA is also necessary in order that prestalk cells move to the entrance of the stalk tube at culmination. Thus, in Dictyostelium, PKA plays a role both in the regulation of cellular differentiation and in morphogenetic cell movement.

A localized differentiation-inducing-factor sink in the front of the Dictyostelium slug.

Differentiation-inducing factor 1 [DIF-1; 1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)-hexan-1-one] induces stalk cell differentiation during Dictyostelium development. It is present as a gradient in the multicellular slug, its lowest concentration being in the anterior. Here we demonstrate the existence of a localized sink for DIF-1, also in the anterior of the slug, which could be responsible for generating the DIF-1 gradient. DIF-1 is metabolized extensively by developing cells, initially by a mono-dechlorination. We used an enzyme assay for DIF-1 dechlorinase to examine its distribution in the slug. DIF-1 dechlorinase activity is 30-fold higher in prestalk cells (largely anterior) compared with prespore cells (posterior) when these are separated from each other on Percoll density gradients. Dissection experiments showed that DIF-1 dechlorinase is 25-fold enriched in the anterior 13% of the slug compared with the rest. These experiments also showed that DIF-1 dechlorinase is more anterior-enriched than the standard prestalk markers, the ecmA and ecmB mRNAs. When cut from a slug, both prestalk and prespore fragments regulate to restore the missing cell type. Prespore fragments rapidly regain (by 30 min) a DIF-1 sink in their anteriors, and prestalk fragments restore a posterior zone with low DIF-1 dechlorinase by 4 hr after cutting. The reappearance of the DIF-1 sink in the anterior of prespore fragments is accomplished without detectable cell sorting and may, therefore, be in response to positional signals. Finally, a localized sink may provide a general way of producing a gradient of a signal substance in a developing embryo.

Chemotactic sorting to cAMP in the multicellular stages of Dictyostelium development.

Dictyostelium transformants that overproduce the extracellular form of cyclic nucleotide phosphodiesterase and so accumulate a reduced amount of cAMP are blocked in development after aggregation in the form of a tight mound, prior to formation of the apical tip. In such mounds, prespore cell differentiation is repressed, and the apical accumulation of prestalk cells is greatly retarded. When a source of cAMP is placed below the arrested mounds, prestalk cells that would normally migrate in an apical direction instead sort downwards to the substratum. Thus, by acting as the chemoattractant that draws prestalk cells to the apex, cAMP signaling directs the formation of a patterned structure.

Chlorine-containing compounds produced during Dictyostelium development. Detection by labelling with 36Cl.

DIF-1 [Differentiation-Inducing Factor 1; 1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)hexan-1-one] is a novel chlorinated signal molecule that induces stalk-cell differentiation during development of Dictyostelium discoideum. Here we introduce the use of the radioisotope 36Cl to label DIF-1 and other low-Mr chlorinated compounds produced during development. H.p.l.c. and t.l.c. were used to resolve the labelled compounds. We find the following. (1) At least 14 dialysable 36Cl-labelled compounds are released into the medium by cells labelled continuously through development with Na36Cl. (2) The compounds can be classified into two major groups according to their times of accumulation in development. The early group of compounds starts accumulating at the end of aggregation, co-ordinately with DIF-1; the late group is only made at the end of development, by mature fruiting bodies. There may also be an intermediate group made during culmination. (3) The early group of compounds has been identified as comprising DIF-1 and seven of its metabolites by co-chromatography with the authentic compounds. These metabolites had previously only been recognized in suspensions of living cells incubated with exogenous DIF-1. Their detection here, from cells undergoing normal development, suggests that endogenous DIF-1 is metabolized in normal development in much the same way as is DIF-1 added to cells in suspension. (4) The intermediate and late groups of compounds are not obvious DIF-1 metabolites. They may have some role unconnected with DIF signalling. (5) A group of 36Cl-labelled late compounds remain cell-associated after washing of the fruiting bodies, and these are greatly enriched in stalk, compared with spore, cells. (6) Other slime-mould species were labelled with 36Cl. All three tested, namely D. mucoroides, D. vinaceo-fuscum and P. violaceum, also produced chloro compounds. D. mucoroides produced DIF-1 by the criterion of h.p.l.c. co-elution with authentic DIF-1. A developmentally regulated metabolism of chlorinated compounds may therefore be widespread amongst slime moulds. To our knowledge, labelling with 36Cl in vivo has not been reported before and provides a powerful general method for investigating chlorinated compounds in diverse organisms.

The DIF-1 signaling system in Dictyostelium. Metabolism of the signal.

DIF-1 is a novel, chlorinated alkyl phenone from Dictyostelium which, at very low concentrations, induces amoebae to differentiate into stalk cells and may act as a morphogen in the formation of the prestalkprespore pattern during development. We report here the existence of a developmentally regulated metabolic pathway which inactivates DIF-1. Radioisotopically labeled DIF-1 was synthesized, incubated with developing cells, the metabolites recovered, and then analyzed by high pressure liquid chromatography and TLC. At least 12 metabolites are produced and the early steps of a complex metabolic pathway have been deduced by following the flow of counts from one metabolite to another and by determining the fate of purified metabolites when they are incubated with cells. The first metabolite, DM1, is largely cell-associated whereas the more distal ones are found mainly in the medium. Metabolism inactivates DIF-1, since DM1 retains only 7% of the specific activity of DIF-1 in the stalk cell differentiation bioassay and later metabolites possess even less activity. Metabolism is developmentally regulated, increasing toward the end of aggregation to reach maximal levels at the tipped mound stage, as endogenous DIF-1 levels are themselves rising. Cells at this stage of development possess the capacity to metabolize their endogenous DIF-1 with a half-life of a few minutes. We suggest that DIF-1 metabolism is important to prevent the DIF-1 receptor system from becoming saturated by excess ligand, thus allowing cells to respond to changes in DIF-1 production. Metabolism may also produce other effector molecules from DIF-1 or produce DIF-1 gradients in the aggregate by the localized destruction of DIF-1.

Diffusible signal molecules controlling cell differentiation and patterning in Dictyostelium.

Slime moulds, such as Dictyostelium discoideum, have biochemical, physiological and probably developmental features in common with both plants and animals. During development separate Dictyostelium amoebae first aggregate into collecting centers to form small multicellular organisms which, in their slug form, can migrate over the substratum toward light. Eventually a slug culminates to form a fruiting body consisting of a cellular stalk supporting a mass of spores. Development is highly regulative, indicating that it is controlled by signalling between the cells. A number of diffusible signal molecules have been discovered, including cyclic AMP, the chemoattractant in aggregation, and DIF-1, a novel chlorinated phenyl alkanone, which acts as a specific inducer of stalk cell differentiation. The migrating slug contains three types of precursor cell: prespore, prestalk A and prestalk B cells. Differentiation of these cells from uncommitted amoebae can be brought about in cell cultures by cyclic AMP and DIF-1 acting in combination: cyclic AMP alone favours prespore, DIF-1 alone favours prestalk B, cyclic AMP and DIF-1 together favour prestalk A cell differentiation. There is evidence suggesting that these signals act in the same way in the intact aggregate. A cytoplasmic DIF-1 binding protein has been discovered, whose level increases as cells become sensitive to DIF-1 and which binds DIF-1 with an affinity and specificity suggestive of a receptor. At the same time, cells are able to inactivate DIF-1 by a metabolic pathway involving at least 12 metabolites. Metabolism may also serve to produce gradients of DIF-1 in the aggregate or other signal molecules from DIF-1.(ABSTRACT TRUNCATED AT 250 WORDS)

Origins of the prestalk-prespore pattern in Dictyostelium development.

Using cell-autonomous markers we have traced the origins of prespore cells and two types of prestalk cells (pstA and pstB cells) during slug formation. We show that cell sorting and positional information both contribute to Dictyostelium morphogenesis. The initial pattern established at the mound stage is topologically quite different from that of the slug. Confirming previous studies, we find that prespore cells occupy most of the aggregate but are absent from a thin layer at the base and from the emerging tip. PstB cells are almost entirely localized to the basal region during the early stages of tip formation. Thus prespore and pstB cell differentiation appear to occur in response to localized morphogenetic signals. In the case of pstB cells, these signals presumably emanate from the base and not, as might be expected, from the tip. When first detectable, pstA cells are scattered throughout the aggregate. They then appear to migrate to the apex, where the tip forms.

Morphogen hunting in Dictyostelium.

A highly regulative pattern of prestalk and prespore tissue is formed during Dictyostelium development, starting from separate amoebae. Potential morphogens controlling this process have been hunted biochemically, using bioassays to monitor activity. All those discovered to date are low MW diffusible compounds: cAMP, adenosine, NH3 and DIFs 1-3. The DIFs are assayed by their ability to induce isolated amoebae to differentiate into stalk cells and have been identified as a family of chlorinated phenyl alkanones. The diversification of amoebae into prestalk and prespore cells seems to be brought about by cAMP and DIF-1. cAMP is necessary for both pathways of differentiation but DIF-1 specifically induces the differentiation of prestalk cells while suppressing that of prespores. When DIF-1 is added to intact slugs, it causes a substantial enlargement of the prestalk tissue at physiological concentrations in the time previously shown to be required for pattern regulation. DIF-1 is a dynamic molecule and we have found that it is metabolized along a pathway involving at least 8 compounds. Metabolism is developmentally regulated and may be important in producing DIF gradients or other effector molecules from DIF. Although we almost certainly have some of the central actors, it is difficult to formulate a satisfactory theory of pattern formation in Dictyostelium at the moment. We suspect that at least one important actor is missing.

Phase I trial of a new nitrosourea, CGP 6809, given every 2 weeks.

A phase I study was carried out on a new water-soluble nitrosourea, 6-deoxy-3,5 di-O-methyl 6-(3 methyl-3-nitrosoureido)-alpha-D-glucofuranoside (EDMN, CGP 6809), given every 2 weeks. A total of 18 patients received doses of 1, 2, 3, and 3.75 g/m2 as a 2- to 5-h infusion. Toxicity principally involved nausea and vomiting, hepatotoxicity, and abdominal pain. There was no evidence of cumulative toxicity. The dose of 3.75 g/m2 was not exceeded because in a previous phase I study, 4.5 g/m2 every 6 weeks was not tolerated; the recommended dose for phase II studies is 3.75 g/m2 every 2 weeks.