Monoclonal antibodies block cell-cell adhesion in Dictyostelium discoideum

Of 39 monoclonal antibodies that bind the cell surface of aggregating Dictyostelium discoideum, 4 block 76-98% of cell-cell adhesion measured in an in vitro assay. The active antibodies all bind in the range of 10(6) antigenic sites/cell surface and react with more than one material on nitrocellulose blots prepared after polyacrylamide gel electrophoresis of whole aggregating cells in sodium dodecyl sulfate. Active antibodies can by grouped into two classes, each with two very similar members. Class I binds several molecules that are prominent in aggregating cells but scarce or undetectable in vegetative cells, blocks cell adhesion only in the presence of EDTA, and has no detectable effect on cell morphology. Class II binds a wide range of molecules present in both vegetative and aggregating cells, inhibits adhesion as well in the absence as in the presence of EDTA, and reversibly alters cell shape.     

Plasma membrane proton pump inhibition and stalk cell differentiation in Dictyostelium discoideum

The choice of the stalk cell differentiation pathway in Dictyostelium is promoted by an endogenous substance, DIF-1, which is 1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)-1-hexanone. It is also favoured by weak acids and two inhibitors of the plasma membrane proton pumps of fungi and plants, diethylstilbestrol (DES) and zearalenone, and antagonised by ammonia and other weak bases, which promote spore differentiation. These observations led to the proposal that the choice of differentiation pathway is regulated by intracellular pH. They also prompted the conjecture that DIF-1 itself is a plasma membrane proton pump inhibitor. We report here experiments showing that DIF-1 is not a plasma membrane proton pump inhibitor. We demonstrate that diethylstilbestrol and zearalenone do inhibit the plasma membrane proton pump of Dictyostelium and we show that there is an excellent qualitative and quantitative correlation between the inhibitory activity of these agents, and of a number of other substances, and their ability to divert differentiation from the spore to the stalk pathway. We conclude that inhibition of the plasma membrane proton pump does shift the choice of differentiation pathway in Dictyostelium towards the stalk pathway, but that DIF does not act by this route, and we propose a model for the actions of DIF and plasma membrane proton pump inhibitors in which the differentiation pathway is controlled by the pH of intracellular vesicles rather than by intracellular pH itself. The model invokes a DIF- and proton-activated vesicular chloride channel whose opening permits acidification of the vesicles and lowers cytosolic Ca++ concentration.     

Cyclic AMP is an inhibitor of stalk cell differentiation in Dictyostelium discoideum

Cyclic AMP and DIF-1 (1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)-1-hexanone) together induce stalk cell differentiation in vitro in Dictyostelium discoideum strain V12M2. The induction can proceed in two stages: in the first, cyclic AMP brings cells to a DIF-responsive state; in the second, DIF-1 alone can induce stalk cell formation. We report here that during the DIF-1-dependent stage, cyclic AMP is a potent inhibitor of stalk cell differentiation. Addition of cyclic AMP at this stage to V12M2 cells appreciably delays, but does not prevent, stalk cell formation. In contrast, stalk cell differentiation in the more common strain NC4 is completely suppressed by the continued presence of cyclic AMP. This fact explains earlier failures to induce stalk cells in vitro in NC4. We now consistently obtain efficient stalk cell induction in NC4 by removing cyclic AMP in the DIF-1-dependent stage. Cyclic AMP also inhibits the production of a stalk-specific protein (ST310) in both NC4 and a V12M2 derivative. Adenosine, a known antagonist of cyclic AMP action, does not relieve this inhibition by cyclic AMP and does not itself promote stalk cell formation. Finally, stalk cell differentiation of NC4 cells at low density appears to require factors in addition to cyclic AMP and DIF-1, but their nature is not yet known. The inhibition of stalk cell differentiation by cyclic AMP may be important in establishing the prestalk/prespore pattern during normal development, and in preventing the maturation of prestalk into stalk cells until culmination.     

The induction of stalk cell differentiation in submerged monolayers of Dictyostelium discoideum

Abstract. Differentiation of Dictyostelium discoideum cells in submerged monolayers was studied and compared with in vivo development. The accumulation patterns of three developmentally regulated enzymes in cells of strain V12M2 differentiating in vivo on Millipore Filters or in vitro in monolayers at high cell-densities were found to be similar. Moreover, stalk cell formation occurred at approximately the same time in high or low cell density monolayers as it did during normal differentiation. These observations suggest that the timing of differentiation in vitro and in vivo is similar.
In vitro stalk cell formation requires exogenous cyclic AMP, and in its absence, the accumulation patterns of the three developmentally regulated enzymes are alterd. At low cell densities, in vitro stalk cell induction also requires a differentiation-inducing factor (DIF). The addition or removal of cyclic AMP or DIF during development under these conditions revealed the sequence of these two requirements. Cyclic AMP is not required for stalk cell induction for the first 8 hours of incubation, but thereafter, a gradually increasing proportion of cells are induced by cyclic AMP. After a brief delay there is a period of induction by DIF, and this period corresponds approximately to the period of DIF accumulation during in vivo development. The two induction events are clearly separate, in that each inducer can act in the absence of the other, as long as cyclic AMP induction precedes DIF induction. Cyclic AMP is only required at a concentration of 40 μM when added 8 hours after the beginning of the differentiation period.     

Dictyopyrones, novel alpha-pyronoids isolated from Dictyostelium spp., promote stalk cell differentiation in Dictyostelium discoideum

Dictyopyrones A and B (DpnA and B), whose function(s) is not known, were isolated from fruiting bodies of Dictyostelium discoideum. In the present study, to assess their function(s), we examined the effects of Dpns on in vitro cell differentiation in D. discoideum monolayer cultures with cAMP. Dpns at 1-20 microM promoted stalk cell formation to some extent in the wild-type strain V12M2. Although Dpns by themselves could hardly induce stalk cell formation in a differentiation-inducing factor (DIF)-deficient strain HM44, both of them dose-dependently promoted DIF-1-dependent stalk cell formation in the strain. In the sporogenous strain HM18, Dpns at 1-20 microM suppressed spore formation and promoted stalk cell formation in a dose-dependent manner. Analogs of Dpns were less effective in affecting cell differentiation in both HM44 and HM18 cells, indicating that the activity of Dpns should be chemical structure specific. It was also shown that DpnA at 2-20 microM dose-dependently suppressed spore formation induced with 8-bromo cAMP and promoted stalk cell formation in V12M2 cells. Interestingly, it was shown by the use of RT-PCR that DpnA at 10 microM slightly promoted both prespore- and prestalk-specific gene expressions in an early phase of V12M2 and HM18 in vitro differentiation. The present results suggest that Dpns may have functions (1) to promote both prespore and prestalk cell differentiation in an early stage of development and (2) to suppress spore formation and promote stalk cell formation in a later stage of development in D. discoideum.     

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.     

Continuous requirement of cAMP for pre-spore differentiation in Dictyostelium discoideum

Abstract Using a shaking culture system, we have previously shown that both cell contact and cAMP are required for pre-spore differentiation in Dictyostelium discoideum [2]. In the present study, cAMP was removed from the medium by the use of a hydrolysing enzyme after cells had formed agglomerates. This treatment left the agglomerates unchanged, but caused a rapid decrease in the activity of UDP galactose transferase, a pre-spore-specific enzyme. This result indicates that cAMP is required even after agglomerate formation to maintain pre-spore differentiation.     

Developmental regulation of a stalk cell differentiation-inducing factor in Dictyostelium discoideum

Previous work has shown that cells developing at high density release a low-molecular-weight factor that can induce isolated Dictyostelium discoideum amoebae of strain V12M2 to differentiate into stalk cells in the presence of cyclic AMP. We now show that this differentiation-inducing factor, called DIF, can be extracted from cells during normal development and that its production is strongly developmentally regulated. DIF is not detectable in vegetative cells but rises dramatically after aggregation to reach a peak during slug migration. DIF levels are very low in two mutants defective in aggregation. The postaggregative synthesis of DIF is stimulated by the addition of extracellular cyclic AMP. We propose that DIF is a morphogen controlling prestalk cell differentiation.     

Synthesis of specific proteins for sexual development in Dictyostelium discoideum

The development of Dictyostelium discoideum may proceed by two pathways, macrocyst or fruiting-body formation, the former being the sexual and the latter the asexual cycle. The pathway of development depends on the presence or absence of zygote giant cells which are produced through fusion of opposite mating-type cells in a population, in heterothallic strains. During the early stages of macrocyst development the patterns of developmentally regulated proteins were noted to differ considerably from those during fruiting-body development. Furthermore, the haploid cells around zygote giant cells synthesized a large number of specific proteins for macrocyst development through the influence of giant cells.     

Acquisition process of differentiation competence in Dictyostelium discoideum

It was previously shown [K. Okamoto, J. Gen. Microbiol. 127, 301 (1981)] that Dictyostelium discoideum cells dissociated from early aggregates, but not aggregation competent cells obtained in a suspension culture, undergo prespore differentiation, when transferred into a medium containing glucose, albumin, and cAMP. Therefore, the former, but not the latter, is considered to have been acquired "differentiation competence." In the present work, the requirements for cells to acquire the differentiation competence are investigated with D. discoideum NC4 strain. On solid substratum, the incubation above a threshold density is absolutely required for this process, while cell aggregation itself is not essential. In suspension cultures, the competence is acquired only under hypertonic conditions. Inhibition of protein synthesis or depletion of cAMP does not affect the acquisition process of the competence. The requirement of hypertonic treatment was also investigated with several other D. discoideum strains.     

The timing of cell-type-specific differentiation in Dictyostelium discoideum

We have used two-dimensional gel electrophoresis to identify over 30 proteins which are specific to one or other of the two cell types of Dictyostelium discoideum, either at the slug stage or in mature fruiting bodies. Our results support the idea that there is a continuous developmental program that begins in prespore cells at the hemispherical mound stage (10-12 hr) and results in spore differentiation (24 hr). Prestalk differentiation, on the other hand, appeared largely unrelated to stalk differentiation, which was first detectable at the onset of culmination (18 hr). We have also used this approach to study the differentiation of stalk-only mutants and have found that the cells can switch from spore to stalk differentiation as late as 2 hr before the end of the wild-type developmental program.     

Cell specific activity of trehalose-6-phosphate synthetase during differentiation of Dictyostelium discoideum.

Trehalose-6-P synthetase activity was low at the beginning of the life cycle of Dictyostelium discoideum, reached maximum activity at 20 h, and decreased at late sorocarp. Enzyme activity in developing spore cells increased 10-fold during differentiation from myxamoebae (0 h) to the culmination stage (20 h) and decreased slightly at sorocarp (24 h). Activity was similar in spore cells at the apex of the stalk. The activities in the stalk cells were dependent upon their position in the developing stalk. There was a decreasing gradient of activity from the apex to the base of the stalk.     

Monoclonal antibodies against discoidin I and discoidin II of the cellular slime mold, Dictyostelium discoideum

The preparation and properties of monoclonal antibodies against carbohydrate-binding proteins (discoidin I and discoidin II) in the cellular slime mold, Dictyostelium discoideum are described. Monoclonal antibody (mAb) ndI,II-1 bound both discoidins I and II specifically. mAb nI-1 and mAb dI-1 bound only discoidin I but their binding specificities were different: nI-1 recognized the native form and dI-1 the denatured form. mAb dII-1 bound only denatured discoidin II. In preliminary work mAbs dII-1 and nI-1 were found to be useful for localizing discoidins I and II immunohistochemically.     

Dictyostelium discoideum: a model system for differentiation and patterning

In Dictyostelium, development begins with the aggregation of free living amoebae, which soon become organized into a relatively simple organism with a few different cell types. Coordinated cell type differentiation and morphogenesis lead to a final fruiting body that allows the dispersal of spores. The study of these processes is having increasing impact on our understanding of general developmental mechanisms. The availability of biochemical and molecular genetics techniques has allowed the discovery of complex signaling networks which are essential for Dictyostelium development and are also conserved in other organisms. The levels of cAMP (both intracellular and extracellular) play essential roles in every stage of Dictyostelium development, regulating many different signal transduction pathways. Two-component systems, involving histidine kinases and response regulators, have been found to regulate intracellular cAMP levels and PKA during terminal differentiation. The sequence of the Dictyostelium genome is expected to be completed in less than two years. Nevertheless, the available sequences that are already being released, together with the results of expressed sequence tags (ESTs), are providing invaluable tools to identify new and interesting genes for further functional analysis. Global expression studies, using DNA microarrays in synchronous development to study temporal changes in gene expression, are presently being developed. In the near future, the application of this type of technology to the complete set of Dictyostelium genes (approximately 10,000) will facilitate the discovery of the effects of mutation of components of the signaling networks that regulate Dictyostelium development on changes in gene expression.     

Extracellular cyclic AMP-phosphodiesterase accelerates differentiation in Dictyostelium discoideum.

Extracellular cyclic AMP-phosphodiesterase accelerates the development of aggregation competence in Dictyostelium discoideum when present during the preaggregation stage. The effect on development appears to depend only on hydrolysis of extracellular cyclic AMP and not on other properties of the phosphodiesterase molecule. Extracellular cyclic AMP-phosphodiesterase, as a promoter of differentiation, acts mainly throughout the first half of interphase. Our evidence supports the proposal that cyclic AMP oscillations control the rate and possibly the initiation of development. Since extracellular cyclic AMP-phosphodiesterase acts from the beginning of interphase cyclic AMP oscillations may also occur from early interphase, at least in the presence of this enzyme. This would imply that the cyclic AMP oscillator is a determinant, but not a product, of the developmental programme.     

Enzyme activity changes during cyclic AMP-induced stalk cell differentiation in P4, a variant of Dictyostelium discoideum.

The P4 variant of Dictyostelium discoideum is characterized by the production of fruiting structures in which the overall proportion of stalk to spore material is increased, relative to the wild type. The altered morphology of the mutant is due to increased sensitivity to cyclic AMP which promotes stalk cell differentiation. In the presence of 10-4 M-cyclic AMP the entire population of P4 amoebae forms clumps of stalk cells on the surface of the dialysis membrane support. Measurement of changes in activity of a range of developmentally-regulated enzymes during the development of P4 in the presence and absence of cyclic AMP has allowed us to identify three classes of enzyme: (i) Those, such as beta-glucosidase II, trehalose-6-phosphate synthetase and uridine diphosphogalactose-4-epimerase, which are required for the production of spores. (ii) Enzymes, primarily but perhaps not exclusively, required during stalk cell formation. Typical of these are N-acetylglucosaminidase and alkaline phosphatase. (iii) General enzymes, such as threonine dehydrase, alpha-mannosidase and uridine diphosphoglucose pyrophyosphorylase, which are present inboth pre-stalk and pre-spore cells and appear to be necessary for the development of both cell types.     

Monoclonal antibodies specific for beta-adrenergic ligands

After somatic cell fusion between splenocytes of immunized BALB/c mice and NS-1 myeloma cells, eight clones were obtained secreting anti-alprenolol antibodies as characterized by means of an ELISA. Four of these were subcloned and were studied further. The association constant for alprenolol ranged from 1.9 X 10(6) M-1 to 24 to 10(6) M-1. Competitive inhibition of [3H]-l-dihydroalprenolol binding revealed cross-reactivity with beta-adrenergic ligands, with a higher avidity for antagonists than for agonists. Two of the antibodies had a higher affinity for the l-isomer than for the d-isomer. The most stereospecific of these antibodies showed only affinity for beta-adrenergic antagonists and for the agonist isoproterenol. The other recognized both beta-adrenergic antagonists and agonists; it also showed an increase in tryptophan fluorescence after ligand binding. This property was used for the physicochemical study of the hapten-antibody interaction.