Multiple forms of glucokinase from Dictyostelium discoideum.

A single form of glucokinase with an apparent Km value equal to 0.12 mM glucose was detectable in extracts prepared from aggregating cells, whereas kinetic and electrophoretic evidence indicated the presence of this form as well as a second glucose-phosphorylating enzyme with a Km value of about 0.01 mM glucose in extracts from culminating cells.     

Phosphodiesterase induction in Dictyostelium discoideum by inhibition of extracellular phosphodiesterase activity

Adenosine 3′,5′-monophosphate (cAMP) is a chemoattractant in Dictyostelium discoideum; it also induces phosphodiesterase activity. Recently it was shown (M. H. Juliani, J. Brusca, and C. Klein, (1981)Develop. Biol.83, 114–121) that N⁶-(aminohexyl)adenosine 3′,5′-monophosphate (hexyl-cAMP) effectively induced phosphodiesterase activity, while this compound was chemotactically inactive and did not effectively bind to the cell surface receptor for cAMP. It was suggested that hexyl-cAMP and cAMP induce phosphodiesterase activity via a chemoreceptor-independent mechanism. In another recent report (P. J. M. Van Haastert, R. C. Van der Meer, and T. M. Konijn (1981)J. Bacteriol.147, 170–175) investigation of induction of phosphodiesterase by several cAMP derivatives revealed that phosphodiesterase induction and chemotaxis had similar cyclic nucleotide specificity. Based on this result it was suggested that cAMP induces phosphodiesterase activity via activation of the chemotactic receptor. In this report we show that hexyl-cAMP transiently inhibits extracellular and cell surface phosphodiesterase. This transient inhibition of the inactivating enzyme and the permanent release of small amounts of cAMP by the cells leads to a transient increase of extracellular cAMP levels. Hexyl-cAMP does not inhibit beef heart phosphodiesterase, and is not degraded by this enzyme. Addition of hexyl-cAMP to a cell suspension containing beef heart phosphodiesterase does not result in an accumulation of extracellular cAMP, and phosphodiesterase induction is absent. We conclude that hexyl-cAMP inhibits phosphodiesterase activity which leads to the accumulation of cAMP; consequently cAMP binds to the chemotactic cAMP receptor resulting in the induction of phosphodiesterase activity.     

Induction by folate and folate analogs of extracellular and membrane-bound phosphodiesterase from Dictyostelium discoideum

Folate stimulation is known to enhance Dictyostelium discoideum differentiation. During early differentiation, D. discoideum cells possess two classes of folate receptors which can be distinguished by their difference in specificity (R. J. W. de Wit, FEBS Lett. 150, 445-448, 1982). We investigated the type of receptor by which folate affects cell differentiation. Two independently regulated developmental markers were used: the extracellular phosphodiesterase-inhibitor system and cell-surface phosphodiesterase activity. Our results indicate that the major effect of folate on development is mediated by the folate-specific receptor. The nonspecific folate receptor was only involved in a minor, transient enhancement of the extracellular phosphodiesterase activity very early in development.     

Purification and characterization of the extracellular cyclic AMP phosphodiesterase of Dictyostelium discoideum

Extracellular phosphodiesterase for adenosine 3':5'-monophosphate [EC 3.1.4.17] was purified from the supernatant of aggregation phase culture of Dictyostelium discoideum, and two types (type I and type II) of the enzyme were found. The type I enzyme was not absorbed on DEAE-Sephacel at pH 8.5 and had an apparent molecular weight of about 67,000 daltons. In contrast, the type II enzyme was adsorbed on DEAE-Sephacel and had an apparent molecular weight of about 120,000 daltons. The Km values of the two types were similar (2-4 microM). Upon SDS polyacrylamide gel electrophoresis analyses, however, both types produced the same bands with molecular weights of 55,000 and 57,000, indicating that they are two different forms composed of common constituents. During the growth phase, the two types of the enzyme were present in culture supernatant in roughly equal amounts, but type II accumulated predominantly in the aggregation phase, suggesting that the ratio of activity of the two forms is under developmental control. Rabbit antiserum prepared against purified type II enzyme cross-reacted with type I as well as membrane-bound enzyme, indicating that the three classes of the enzyme possess some common sequence.     

Supramolecular forms of actin from amoebae of Dictyostelium discoideum.

Actin purified from amoebae of Dictyostelium discoideum polymerizes into filaments at 24 degrees upon addition of KCl, as judged by a change in optical density at 232 nm and by electron microscopy. The rate and extent of formation of this supramolecular assembly and the optimal KCl concentrations (0.1 M) for assembly are similar to those of striated muscle actin. The apparent equilibrium constant for the monomer-polymer transition is 1.3 muM for both Dictyostelium and muscle actin. Although assembly of highly purified Dictyostelium actin monomers into individual actin filaments resembles that of muscle actin, Dictyostelium actin but not muscle actin was observed to assemble into two-dimensional nets in 10 mM CaCl2. The Dictyostelium actin also forms filament bundles which are 0.1 mum in diameter and which assemble in the presence of 5 mM MgCl2. These bundles formed from partially purified Dictyostelium actin preparations but not from highly purified preparations, suggesting that their formation may depend on the presence of another component. These actin bundles reconstituted in vitro resemble the actin-containing bundles found in situ by microscopy in many non-muscle cells.     

Transient kinetics of a cGMP-dependent cGMP-specific phosphodiesterase from Dictyostelium discoideum

Chemotactic stimulation of Dictyostelium discoideum cells induces a fast transient increase of cGMP levels which reach a peak at 10 s. Prestimulation levels are recovered in approximately 30 s, which is achieved mainly by the action of a guanosine 3',5'-monophosphate cGMP-specific phosphodiesterase. This enzyme is activated about fourfold by low cGMP concentrations. The phosphodiesterase has two distinct cGMP-binding sites: a catalytic site and an activator site. cAMP does not bind to either site; inosine 3',5'-monophosphate (cIMP) binds only to the catalytic site, whereas 8-bromoguanosine 3',5'-monophosphate (c-b8-GMP) preferentially binds to the activator site. For detailed kinetical measurements we have used [3H]cIMP as the substrate and c-b8-GMP as the activator. c-b8-GMP activated the hydrolysis of [3H]cIMP by reducing the Km, whereas the Vmax was not altered. The hydrolysis of [3H]cIMP was measured at 5-s intervals by using a new method for the separation of 5'-nucleotides from cyclic nucleotides. The hydrolysis of [3H]cIMP by nonactivated enzyme or by preactivated enzyme was linear with time, which indicates that a steady state is reached at the catalytic site within 5 s after addition of the substrate. In contrast, the hydrolysis of [3H]cIMP immediately after activation by 0.1 microM c-b8-GMP was not linear with time, but increased in a quasi-exponential manner with a time constant of 21 s. This suggests that a steady state at the activator site is only reached in 30-45 s after addition of the activator. The on-rate of activation (k1) was 3 X 10(5) M-1s-1 for c-b8-GMP and 1.4 X 10(5) M-1s-1 for cGMP. The off-rate of activation (k-1) was 0.03 s-1 for both c-b8-GMP and cGMP. The significance of these kinetic constants for the chemoattractant-mediated cGMP response in vivo is discussed.     

The hydrophobic character of the membrane-bound phosphodiesterase from Dictyostelium discoideum

A phosphodiesterase activity is shown to copurify with the plasma membrane fraction prepared by the two-phase partition method. The enrichment in phosphodiesterase parallels that of alkaline phosphatase, which is thought to be a typical membranous enzyme. Up to 66% of the phosphodiesterase activity can be solubilized by a treatment with 0.2% Triton X-100. Higher doses were ineffective in solubilizing more activity. Analysis by native gel electrophoresis showed that an activity extracted by 2 M NaCl migrated at the same position as 'soluble' phosphodiesterase of cytosolic or extracellular origin. In contrast, the Triton-solubilized enzyme had an apparently higher molecular weight. When subjected to charge shift electrophoresis on agarose gels in the presence of an ionic detergent, the Triton-solubilized phosphodiesterase displayed a hydrophobic character. This behaviour contrasts with that of 'soluble' phosphodiesterases, the electrophoretic mobility of which is unaffected by the presence of an anionic detergent. The hydrophobic character of the membranous enzyme was lost after gentle hydrolysis by papain.     

Substrate specificity of cyclic nucleotide phosphodiesterase from beef heart and from Dictyostelium discoideum

The substrate specificity of beef heart phosphodiesterase activity and of the phosphodiesterase activity at the cell surface of the cellular slime mold Dictyostelium discoideum has been investigated by measuring the apparent Km and maximal velocity (V) of 24 derivatives of adenosine 3',5'-monophosphate (cAMP). Several analogs have increased Km values, but unaltered V values if compared to cAMP; also the contrary (unaltered Km and reduced V) has been observed, indicating that binding of the substrate to the enzyme and ring opening are two separate steps in the hydrolysis of cAMP. cAMP is bound to the beef heart phosphodiesterase by dipole-induced dipole interactions between the adenine moiety and an aromatic amino acid, and possibly by a hydrogen bond between the enzyme and one of the exocyclic oxygen atoms; a cyclic phosphate ring is not required to obtain binding. cAMP is bound to the slime mold enzyme via a hydrogen bond at the 3'-oxygen atom, and probably via a hydrogen bond with one of the exocyclic oxygen atoms. A cyclic phosphate ring is necessary to obtain binding to the enzyme. A specific interaction (polar or hydrophobic) between the base moiety and the enzyme has not been demonstrated. A negative charge on the phosphate moiety is not required for binding of cAMP to either enzyme. The catalytic reaction in both enzymes is restricted to the phosphorus atom and to the exocyclic oxygen atoms. Substitution of the negatively charged oxygen atom by an uncharged dimethylamino group in axial or equatorial position renders the compound non-hydrolyzable. Substitution of an exocyclic oxygen by a sulphur atom reduces the rate of the catalytic reaction about 100-fold if sulphur is placed in axial position and more than 10000-fold if sulphur is placed in equatorial position. A reaction mechanism for the enzymatic hydrolysis of cAMP is proposed.     

Cellulose-binding modules from extracellular matrix proteins of Dictyostelium discoideum stalk and sheath.

Cellulose-binding modules (CBMs) of two extracellular matrix proteins, St15 and ShD, from the slime mold Dictyostelium discoideum were expressed in Escherichia coli. The expressed proteins were purified to > 98% purity by extracting inclusion bodies at pH 11.5 and refolding proteins at pH 7.5. The two refolded CBMs bound tightly to amorphous phosphoric acid swollen cellulose (PASC), but had a low affinity toward xylan. Neither protein exhibited cellulase activity. St15, the stalk-specific protein, had fourfold higher binding affinity toward microcrystalline cellulose (Avicel) than the sheath-specific ShD CBM. St15 is unusual in that it consists of a solitary CBM homologous to family IIa CBMs. Sequence analysis of ShD reveals three putative domains containing: (a) a C-terminal CBM homologous to family IIb CBMs; (b) a Pro/Thr-rich linker domain; and (c) a N-terminal Cys-rich domain. The biological functions and potential role of St15 and ShD in building extracellular matrices during D. discoideum development are discussed.     

Characterization of a cAMP-stimulated cAMP phosphodiesterase in Dictyostelium discoideum

A cyclic nucleotide phosphodiesterase, PdeE, that harbors two cyclic nucleotide binding motifs and a binuclear Zn(2+)-binding domain was characterized in Dictyostelium. In other eukaryotes, the Dictyostelium domain shows greatest homology to the 73-kDa subunit of the pre-mRNA cleavage and polyadenylation specificity factor. The Dictyostelium PdeE gene is expressed at its highest levels during aggregation, and its disruption causes the loss of a cAMP-phosphodiesterase activity. The pdeE null mutants show a normal cAMP-induced cGMP response and a 1.5-fold increase of cAMP-induced cAMP relay. Overexpression of a PdeE-yellow fluorescent protein (YFP) fusion construct causes inhibition of aggregation and loss of the cAMP relay response, but the cells can aggregate in synergy with wild-type cells. The PdeE-YFP fusion protein was partially purified by immunoprecipitation and biochemically characterized. PdeE and its Dictyostelium ortholog, PdeD, are both maximally active at pH 7.0. Both enzymes require bivalent cations for activity. The common cofactors Zn(2+) and Mg(2+) activated PdeE and PdeD maximally at 10 mm, whereas Mn(2+) activated the enzymes to 4-fold higher levels, with half-maximal activation between 10 and 100 microm. PdeE is an allosteric enzyme, which is approximately 4-fold activated by cAMP, with half-maximal activation occurring at about 10 microm and an apparent K(m) of approximately 1 mm. cGMP is degraded at a 6-fold lower rate than cAMP. Neither cGMP nor 8-Br-cAMP are efficient activators of PdeE activity.     

The relationship of phosphodiesterase to the developmental cycle of Dictyostelium discoideum.

Determination of the rate of total phosphodiesterase production by Dictyostelium discoideum shows that a dramatic rise in enzyme production occurs after 3 hours of cell starvation. Use of imposed cAMP pulses indicate that this increase is related to the developmental program of the amoebae and is probably due to a stimulation of adenyl cyclase.     

Multiple cysteine proteinase forms during the life cycle of Dictyostelium discoideum revealed by electrophoretic analysis.

Proteinases of the cellular slime mould Dictyostelium discoideum have been analysed using electrophoresis on polyacrylamide gels containing gelatin (gelatin/PAGE). Multiple proteinase forms were apparent in vegetative myxamoebae, but the presence of individual enzyme forms depended on the manner in which the cells were grown. Axenic cells had a characteristic A-pattern of proteinases consisting of six bands, the most active enzymes having apparent Mr values of 51,000 and 45,000 (these have been named ddCP51 and ddCP45, respectively). Some of the proteinases were also present in the medium, the major extracellular form was ddCP42, a 42,000-Mr enzyme. Cells grown in association with bacteria had a distinct B-pattern with three main enzymes that had apparent Mr values of 48,000, 43,000 and 38,000. All of the A- and B-pattern proteinases were most active at acid pH in the presence of dithiothreitol and were inhibited by various agents such as trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane (E64), leupeptin and chymostatin, which inactivate cysteine proteinases. One of the enzymes, ddCP30, was identified as cysteine proteinase B which had been purified and characterized previously [North, M.J. & Whyte, A. (1984) J. Gen. Microbiol. 130, 123-134]. During starvation of axenic cells in shaken suspensions some of the vegetative proteinases disappeared, ddCP42 was released from the cells and one new enzyme with an apparent Mr of 48,000 appeared. Addition of cyclic AMP had little effect on these changes. When the axenically grown myxamoebae underwent development on filters, similar changes in band pattern were observed and the aggregation stage was characterized by the presence of three cysteine proteinase bands (apparent Mr values of 48,000, 45,000 and 43,000). Proteinases, especially ddCP42, were released from the cells and could be collected from the buffer-saturated pads which supported the filters. The results demonstrate that cysteine proteinases are present throughout growth and development of D. discoideum and that the forms present are subject to nutritional and developmental regulation.     

Extracellular cyclic-amp phosphodiesterase regulation in agar plate cultures of Dictyostelium discoideum.

Extracellular cyclic-AMP phosphodiesterase and the inhibitor of this enzyme is tested in agar plate cultures of two Dictyostelium discoideum wild-type strains and in a mutant which lacks the inhibitor. Under the conditions used, the phosphodiesterase inhibitor is formed in both wild-type strains either before or in an early stage of cell aggregation. During aggregation of one strain the phosphodiesterase activity is extremely low, excluding a necessary function of the enzyme in the aggregation process.     

Induction of stalk cell differentiation by cyclic-AMP in a susceptible variant of Dictyostelium discoideum.

The P-4 variant of Dictyostelium discoideum (DdH) was found to produce a great excess of stalk cells compared to the wild type DdH. If the vegetative cells of P-4 were repeatedly washed, the variant changed back to the wild type phenotype, and if cyclic-AMP was added to the washed P-4 cells, the variant character was restored. Furthermore, if the concentration of added cyclic-AMP was increased, it was possible to induce 100% stalk cells in P-4. Phosphodiesterase would cause the variant to change to the wild type, while 5-AMP and cyclic-nucleotides other than cyclic-AMP have no effect at all. Therefore it was concluded that cyclic-AMP plays a key role in stalk cell differentiation.A comparison between wild type DdH and the variant P-4 showed that DdH is ten times less sensitive to cyclic-AMP induction. They both produce the same amount of cyclic-AMP and extracellular phosphodiesterase, but the specific activity of P-4 cell-bound phosphodiesterase during development is significantly less than that in the DdH. One hypothesis that accounts for the P-4-DdH difference is that because of the lack of cell-bound phosphodiesterase, more cyclic-AMP enters the variant cells and hence more stalk cell differentiation.     

Altered cyclic-AMP receptor activity and morphogenesis in a chemosensory mutant of Dictyostelium discoideum

The functional properties of the cell-surface cyclic-AMP receptor that controls chemotaxis were found to be altered in an aggregation mutant of Dictyostelium discoideum. The mutant aggregated without stream formation and had a tenfold increased cell-density requirement for the initiation of aggregation. After aggregation, mounds formed multiple tips and subsequently subdivided to give multiple fruits that were small and abnormally proportioned. Cyclic-AMP-induced light-scattering changes in cell suspensions indicated that the mutant had a diminished response to external cyclic-AMP signals. Associated with these altered functional responses was a physical change in the cyclic-AMP sensory system. Cyclic-AMP-binding studies showed that the parent had two classes of cyclic-AMP binding sites, i.e., Kd = 32 and 110 nM. In contrast, the mutant had two- to threefold or more high-affinity sites (Kd = 25 nM) and altered low-affinity sites (Kd less than 3 microM). These results indicate that both affinity classes of binding site are independently mutable. This observation suggests that the two affinity classes can be interconverted by mutation, or the mutation alters a single molecular species and its equilibrium between binding sites with different affinities for cyclic AMP, as postulated in receptor cycling models.     

Purification and properties of a cyclic-AMP phosphodiesterase that is active in only one cell type during the multicellular development of Dictyostelium discoideum

Cyclic-AMP phosphodiesterase (PDE) accumulates during the aggregation stage of Dictyostelium where it functions in maintaining extracellular levels of cyclic AMP (cAMP). The activity decreases during the subsequent multicellular slug stage and then accumulates again during sorocarp construction, but the enzyme is active only in the developing stalk. Because of the possible significance of this localized activity in only one of the two cell types, we have purified the enzyme from the multicellular stage in order to understand its mode of regulation in vivo. We find that the enzyme which is localized in the prestalk cells is similar in many respects to the extracellular PDE which is active at the aggregation stage. The enzyme from both stages is inhibited by a low molecular weight protein. The mechanism of this inhibition is through a shift in the apparent Km for cAMP from micromolar to millimolar levels. The inhibited form of the enzyme can be activated by preincubation with MgSO4 and dithiothreitol (DTT). This activation treatment releases the inhibitor from the enzyme, thus restoring the low Km form, changes the molecular weight of the culmination stage enzyme from 95 000-100 000 to 68 000 by releasing the Mr 35 000-40 000 inhibitor protein, and causes irreversible loss of inhibitor activity. Although the inhibitor could be obtained in high yield from the aggregation stage by simply heating the extracellular fluid, it could not be detected from culmination stage extracts when prepared by this method. However, inclusion of calcium in the extraction buffer resulted in release of inhibitor from both heated and nonheated samples. The results indicate that the stalk cell specific PDE is regulated similarly to the aggregation stage PDE and opens the possibility of differential regulation of PDE in the two cell types.     

Altered cyclic-AMP receptor activity and morphogenesis in a chemosensory mutant of Dictyostelium discoideum

Abstract. The functional properties of the cell-surface cyclic-AMP receptor that controls chemotaxis were found to be altered in an aggregation mutant of Dictyostelium discoideum. The mutant aggregated without stream formation and had a tenfold increased cell-density requirement for the initiation of aggregation. After aggregation, mounds formed multiple tips and subsequently subdivided to give multiple fruits that were small and abnormally proportioned. Cyclic-AMP-induced light-scattering changes in cell suspensions indicated that the mutant had a diminished response to external cyclic-AMP signals. Associated with these altered functional responses was a physical change in the cyclic-AMP sensory system. Cyclic-AMP-binding studies showed that the parent had two classes of cyclic-AMP binding sites, i.e., Kd = 32 and 110 nM. In contrast, the mutant had two- to threefold or more high-affinity sites (Kd = 25n M ) and altered low-affinity sites (Kd < 3μ M ). These results indicate that both affinity classes of binding site are independently mutable. This observation suggests that the two affinity classes can be interconverted by mutation, or the mutation alters a single molecular species and its equilibrium between binding sites with different affinities for cyclic AMP, as postulated in receptor cycling models.     

The cyclic nucleotide phosphodiesterase inhibitory protein of Dictyostelium discoideum. Purification and characterization

We have purified the glycoprotein inhibitor of the extracellular cyclic nucleotide phosphodiesterase of Dictyostelium discoideum to apparent homogeneity. The inhibitor has a molecular weight of 47,000 measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The interaction of the inhibitor and the cyclic nucleotide phosphodiesterase occurs with 1:1 stoichiometry and with a dissociation constant of about 10(-10) M. Periodate oxidation of the inhibitor or of the enzyme destroys concanavalin A binding ability but does not affect the formation of the enzyme-inhibitor complex. Inhibitor is not produced by cells during logarithmic growth but appears in quantity during stationary phase and after transfer from growth medium to phosphate buffer.