Changes during differentiation in requirements for cAMP for expression of cell-type-specific mRNAs in the cellular slime mold, Dictyostelium discoideum

A number of genes encoding developmentally regulated mRNAs in the cellular slime mold, Dictyostelium discoideum, have been described. Many of these are regulated by cAMP. Analysis of the earliest time at which elevated levels of cAMP can induce the expression of these mRNAs reveals a more complex pattern of regulation in which genes change in their ability to be induced in response to cAMP with developmental stage. A prestalk mRNA (C1/D11) previously thought not be regulated by elevated levels of cAMP is inducible by cAMP between aggregation and loose mound stage; later in development its expression becomes independent of elevated cAMP. The early prespore genes (prespore class I) also show two modes of regulation; early in development they are induced independently of continuous elevated levels of cAMP, while later in development their expression is dependent upon elevated cAMP. The period during development when the prestalk genes are cAMP inducible precedes by 2 hr the first time at which either the early prespore class I or late prespore class II mRNAs are inducible by continuous elevated levels of cAMP. Previous analysis of these mRNAs has been carried out using Dictyostelium cells grown axenically. In this report we have studied the developmental expression of these mRNAs in cells grown on bacteria. A substantial shutoff of the class I prestalk and early prespore (class I) mRNAs not seen in axenically grown cells is observed when bacterially grown cells are plated for development. Less than 10% of the maximal level of these mRNAs remains in the cells at the time of mature spore and stalk differentiation. Additionally, in the bacterially grown cells two distinct patterns of developmental regulation are observed for mRNAs which in axenically growing cells appear to be constitutively expressed throughout growth and development.     

A dedifferentiation-defective mutant of Dictyostelium that retains the capacity to aggregate in the absence of chemotaxis

During slime mold development, cells acquire the capacity to rapidly recapitulate morphogenesis in roughly a tenth the original time. When developing cells are disaggregated and refed, they completely loss this capacity in a rapid and synchronous step referred to as the “erasure event.” The erasure event sets in motion a program of dedifferentiation during which developmentally acquired functions are lost at different times. In this report, we describe the phenotype of HI4, which is a mutant partially defective in the dedifferentiation program but normal in all aspects of growth, morphogenesis, and rapid recapitulation. HI4 cells progress through the erasure event, losing in a relatively normal fashion (I) the capacity to rapidly recapitulate later stages of morphogenesis, (2) the capacity to release a cAMP signal, and (3) the capacity to respond chemotactically to a cAMP signal. However, erased HI4 cells abnormally retain the capacity to rapidly reaggregate, even though they have lost chemotactic functions. Erased HI4 cells also abnormally retain EDTA-resistant cohesion (contact sites A) and the surface glycoprotein gp80. It appears that erased HI4 cells rapidly reaggregate owing to random collisions followed by tight cell cohesion.     

Gene regulation during dedifferentiation in Dictyostelium discoideum

During development of Dictyostelium discoideum, cells acquire the capacity to rapidly recapitulate morphogenesis. Therefore, when cells at the loose aggregate stage are disaggregated and challenged to reaggregate, they do so in a tenth of the original time. If loose aggregate cells are disaggregated and resuspended in buffered dextrose solution (erasure medium), they retain the capacity of rapid recapitulation for 80 min, then completely lose this capacity in a single, synchronous step referred to as the "erasure event." The erasure event sets in motion a program of dedifferentiation during which cells lose developmentally acquired characteristics at different times. The erasure event is inhibited by the addition of 10(-4) M cAMP to erasure medium. The synthesis of 33 growth-associated polypeptides, the synthesis of 53 development-associated polypeptides, and the level of 2 development-associated RNAs have been monitored during the erasure program and in cultures inhibited from erasing by the addition of 10(-4) M cAMP. Growth-associated polypeptides begin to be resynthesized and development-associated polypeptides exhibit dramatic decreases in rate of synthesis at different times throughout the first 240 min in erasure medium. Inhibiting the erasure event with cAMP has no major effect in the resynthesis of the majority of growth-associated polypeptides. Only one growth-associated polypeptide, V28, is completely inhibited by cAMP, suggesting that it may play a role in the erasure process. In contrast, inhibiting the erasure event with cAMP has a marked effect on the synthesis of development-associated polypeptides, causing a dramatic reduction in the rate at which synthesis decreases for 6 polypeptides, and completely inhibits the decrease in the synthetic rate of 8 polypeptides. The two development-associated RNAs, 16G1 and 10C3, exhibit two distinctly different patterns of loss during erasure, but in both cases cAMP added at time zero of the erasure process dramatically retards or inhibits loss. In addition, when cAMP is added just prior to the erasure event, it inhibits the erasure event and stimulates a rapid increase in the level of 16G1 RNA back to the developmental level. The level of 16G1 RNA then remains at this level for at least 400 min. When cAMP is added after the erasure event, it causes a low, transient increase in the level of 16G1 RNA. These results are considered both in relation to the program of erasure, and in relation to the role of cAMP in the expression of developmental genes during the forward program of development.     

Loss and resynthesis of a developmentally regulated membrane protein (gp80) during dedifferentiation and redifferentiation in Dictyostelium

When developing cultures of Dictyostelium discoideum are disaggregated and resuspended in nutrient medium, they lose the capacity to rapidly reaggregate after 90 min, in a rapid and synchronous step referred to as the "erasure event." They then proceed to lose remaining developmentally acquired functions in a program of dedifferentiation culuminating with the loss of EDTA-resistant cohesion roughly 5 hr later. Immediately following the erasure event, cells can be stimulated to reenter the developmental program even though they still possess a number of developmentally acquired functions. These cells therefore appear to undergo dedifferentiation and redifferentiation simultaneously (D. R. Soll and L. H. Mitchell, 1982, Dev. Biol. 91, 183-190). In this report, we have employed an antiserum made against a developmentally acquired membrane glycoprotein, gp80, to examine whether gp80 is lost during dedifferentiation and whether it is either reutilized or resynthesized during redifferentiation. Results are presented which demonstrate that (1) when 9-hr developing cells are disaggregated and resuspended in nutrient medium, gp80 continues to accumulate for several hours after the erasure event, then is lost at roughly the same time as EDTA-resistant cohesion; (2) when cells are stimulated to reenter the developmental program immediately after the erasure event, both gp80 and EDTA-resistant cohesion are still lost according to the program of dedifferentiation, but are then reacquired soon afterwards according to the program of redifferentiation; (3) during redifferentiation, cells do not reutilize gp80 which had been synthesized during initial development; rather they synthesize gp80 de novo; and (4) developing cells of a dedifferentiation-defective variant, HI4, when disaggregated and resuspended in nutrient medium, retain gp80, EDTA-resistant cohesion, and the capacity to rapidly reinitiate aggregation for at least 12 hr. This last result indicates that the loss of gp80 is regulated by the dedifferentiation process and is not an independent response to disaggregation or the reintroduction of nutrients. Together, these results reinforce the conclusion that dedifferentiation and redifferentiation can function independently and simultaneously in the same cells.     

Cyclic AMP levels and turnover during development of the cellular slime mold Dictyostelium discoideum.

Changes in intracellular and extracellular cAMP levels are reported for the cellular slime mold Dictyostelium discoideum during its development on filter supports. Examined were axenically and bacterially grown strain A3 and bacterially grown NC-4. In each case a major peak in cAMP occurred during aggregation. In addition, axenically grown A3 showed minor rises in cAMP at 16 hr and during culmination; in contrast, NC-4 showed no increase at 16 hr but gave a very large increase at culmination. Both cell-associated phosphodiesterase and the extracellular phosphodiesterase present in the top filter were measured throughout development. Both showed activity peaks during aggregation with much lower plateau values thereafter. At aggregation about 80% of the activity per filter was contributed by the cell-associated phosphodiesterase. The rate of cAMP turnover during aggregation was estimated by following the hydrolysis of applied [³H]cAMP. A minimum rate of about 7% turnover/sec was obtained. From this turnover rate a minimum value for the stimulated activity of the adenylate cyclase was estimated as 224 pmoles/min-mg. Although this level is already over threefold greater than the highest value obtained in vitro, other experiments indicate that the in vivo adenylate cyclase activity may exceed 700 pmoles/min-mg.     

Characterization of DNA from the cellular slime mould Dictyostelium discoideum after growth of the amoebae in different media

Amoebae of the cellular slime mould Dictyostelium discoideum Ax2 grown on Aerobacter aerogenes as food source have a DNA content (36.0 ± 0.9 × 10⁻¹⁴ g/cell) approximately twice that of the same amoebae grown axenically (16.8 ± 0.4 × 10⁻¹⁴ g/cell). Isolation and characterization of DNA from amoebae grown either axenically or on bacteria, by several methods (melting curve, density gradient centrifugation, DNA/DNA hybridization) suggests that not more than 16% of the DNA content of bacterially grown amoebae is of bacterial origin. Studies of the rate of reannealing of DNA samples isolated from amoebae grown either axenically or on bacteria and of the degree to which they hybridize with ribosomal RNA, suggests that the ‘extra’ DNA that bacterially grown cells contain is biologically similar to that contained in axenically grown cells. It is therefore concluded that amoebae growing exponentially on bacteria have, on average, 2.4 to 2.7 genome equivalents per cell and amoebae growing exponentially in axenic medium have 1.3 to 1.4 genome equivalents per cell. Since it is believed that amoebae of this strain growing on bacteria are haploid and since these differences in DNA content persist during their subsequent differentiation, it is concluded that axenically grown amoebae differentiate whilst in the G1 phase of the cell cycle and bacterially grown amoebae differentiate whilst in the G2 phase of the cell cycle.     

Differentiation and dedifferentiation can function simultaneously and independently in the same cells in Dictyostelium discoideum

When developing cultures of Dictyostelium discoideum are disaggregated and morphogenesis is reinitiated, cells recapitulate the stages they had progressed through prior to disaggregation in a fraction of the original time. If developing cultures are disaggregated and the cells resuspended in nutrient medium, they retain this capacity for 1.5 hr and then synchronously and rapidly revert to the slow timing of log phase cells. Loss of the capacity to recapitulate morphogenesis rapidly is referred to as the “erasure event.” Following the erasure event, cells systematically lose developmentally acquired functions in a defined temporal sequence of dedifferentiation. Cells which have just passed through the erasure event can be stimulated to reenter the developmental program, even though they still possess several aggregation-associated functions acquired during the initial developmental program. In this report, we have tested whether cells stimulated to reenter the developmental program immediately after the erasure event progress along the same rate-limiting pathway leading to aggregation as they did during initial development and whether this rate-limiting pathway can run simultaneously with and independently of the sequence of dedifferentiation. Results are presented which demonstrate (1) that the erasure event resets the rate-limiting pathway for development back to zero and that erased cells reentering development progress along the same rate-limiting pathway as naive log phase cells, (2) that the loss of an aggregation-associated function late in the sequence of dedifferentiation is completely blocked by the addition of cycloheximide, but not cAMP, just prior to the expected time of loss, and (3) that differentiation and dedifferentiation can function simultaneously and independently in the same cells, even though the former leads to the acquisition and the latter to the loss of the same aggregation-associated functions (in this case EDTA-resistant adhesion and cAMP-stimulated motility).     

Chemoresponsiveness to cAMP and folic acid during growth, development, and dedifferentiation in Dictyostelium discoideum

Chemoresponsiveness to cAMP and to folic acid are monitored in growing, developing, and dedifferentiating amebae of the cellular slime mold Dictyostelium discoideum. Two semiquantitative assays are employed, one measuring the directed movement of cells up a gradient of chemoattractant ('chemotaxis' assay) and the other measuring the outward spreading of cells in response to a chemical stimulant distributed equally throughout the substratum ('spreading' assay). Vegetative amebae possess relatively insignificant levels of chemotactic responsiveness to cAMP. Six h after the initiation of development, at approximately the same time as the onset of aggregation, cells rapidly acquire chemotactic responsiveness to cAMP. During 'erasure', a dedifferentiation induced by resuspending aggregating cells in fresh nutrient medium, chemotactic responsiveness to cAMP is lost just after the erasure event. By the same chemotactic assay, it is demonstrated that vegetative amebae possess a significant level of chemotactic responsiveness to folic acid. Two h after the initiation of development, cells completely lose chemotactic responsiveness to folic acid. During erasure, cells reacquire chemotactic responsiveness to folic acid at approximately the same time that they lose responsiveness to cAMP. Dramatically different results are obtained by the spreading assay. When cells lose chemotactic responsiveness to folic acid early in development and when erasing cells lose chemotactic responsiveness to cAMP, they retain the spreading response to the two stimulants, respectively. The different results obtained for chemoreception employing the two assays are discussed in terms of molecular mechanisms, and a testable hypothesis is proposed for the possible roles of chemoresponsiveness and erasure in late morphogenesis.     

MFE1, a member of the peroxisomal hydroxyacyl coenzyme A dehydrogenase family,affects fatty acid metabolism necessary for morphogenesis in Dictyostelium spp

Beta-oxidation of long-chain fatty acids and branched-chain fatty acids is carried out in mammalian peroxisomes by a multifunctional enzyme (MFE) or D-bifunctional protein, with separate domains for hydroxyacyl coenzyme A (CoA) dehydrogenase, enoyl-CoA hydratase, and steroid carrier protein SCP2. We have found that Dictyostelium has a gene, mfeA, encoding MFE1 with homology to the hydroxyacyl-CoA dehydrogenase and SCP2 domains. A separate gene, mfeB, encodes MFE2 with homology to the enoyl-CoA hydratase domain. When grown on a diet of bacteria, Dictyostelium cells in which mfeA is disrupted accumulate excess cyclopropane fatty acids and are unable to develop beyond early aggregation. Axenically grown mutant cells, however, developed into normal fruiting bodies composed of spores and stalk cells. Comparative analysis of whole-cell lipid compositions revealed that bacterially grown mutant cells accumulated cyclopropane fatty acids that remained throughout the developmental stages. Such a persistent accumulation was not detected in wild-type cells or axenically grown mutant cells. Bacterial phosphatidylethanolamine that contains abundant cyclopropane fatty acids inhibited the development of even axenically grown mutant cells, while dipalmitoyl phosphatidylethanolamine did not. These results suggest that MFE1 protects the cells from the increase of the harmful xenobiotic fatty acids incorporated from their diets and optimizes cellular lipid composition for proper development. Hence, we propose that this enzyme plays an irreplaceable role in the survival strategy of Dictyostelium cells to form spores for their efficient dispersal in nature.     

A 130-kDa Plasma Membrane Glycoprotein Involved inDictyosteliumPhagocytosis

Phagocytosis involves interactions between cell-surface receptors and the actin-based cytoskeleton. Plasma membrane glycoproteins cosedimenting with detergent-insoluble cytoskeletons were postulated to be phagocytosis receptor candidates of the unicellular slime moldDictyostelium discoideum.A 130-kDa glycoprotein (gp130) was associated with cytoskeletons of bacterially but not axenically grown cells, suggesting a cytoskeletal interaction that depended on nutrient conditions. Labeling of gp130 with a membrane-impermeant biotinylating reagent showed it was surface-exposed and provided a tag that was used to monitor gp130. Biotin-labeled gp130 was an integral protein and found to be a single species by two-dimensional gel electrophoresis. An antibody was raised against a synthetic octapeptide corresponding to internal amino acid sequence of biotin-labeled gp130 enriched through avidin affinity chromatography. The affinity-purified antibody was monospecific, reacting with both axenic and bacterial forms of gp130 on immunoblots. There was less gp130 in plasma membranes of bacterially grown cells than in plasma membranes of axenically grown cells, which was consistent with the idea that as a receptor, gp130 would be internalized during phagocytosis and fewer molecules would be on the cell surface of actively feeding cells. This suggestion was supported by the observation that there was a reduced amount of surface (biotin)-labeled gp130 on bacterially grown cells relative to axenically grown cells. gp130 also was implicated in phagocytosis through immunoblotting analyses that revealed smaller versions of gp130 in plasma membranes of phagocytosis mutant HV29 (Vogelet al. J. Cell Biol.86: 456, 1980). Taken together, these biochemical and immunological data support the idea that gp130 plays a role in the phagocytosis process.     

Chemoresponsiveness to cAMP and Folic Acid during Growth, Development, and Dedifferentiation in Dictyostelium discoideum

Chemoresponsiveness to cAMP and to folic acid are monitored in growing, developing, and dedifferentiating amebae of the cellular slime mold Dictyostelium discoideum . Two semiquantitative assays are employed, one measuring the directed movement of cells up a gradient of chemoattractant ('chemotaxis' assay) and the other measuring the outward spreading of cells in response to a chemical stimulant distributed equally throughout the substratum ('spreading' assay). Vegetative amebae possess relatively insignificant levels of chemotactic responsiveness to cAMP. Six h after the initiation of development, at approximately the same time as the onset of aggregation, cells rapidly acquire chemotactic responsiveness to cAMP. During 'erasure', a dedifferentiation induced by resuspending aggregating cells in fresh nutrient medium, chemotactic responsiveness to cAMP is lost just after the erasure event. By the same chemotactic assay, it is demonstrated that vegetative amebae possess a significant level of chemotactic responsiveness to folic acid. Two h after the initiation of development, cells completely lose chemotactic responsiveness to folic acid. During erasure, cells reacquire chemotactic responsiveness to folic acid at approximately the same time that they lose responsiveness to cAMP.
Dramatically different results are obtained by the spreading assay. When cells lose chemotactic responsiveness to folic acid early in development and when erasing cells lose chemotactic responsiveness to cAMP, they retain the spreading response to the two stimulants, respectively. The different results obtained for chemoreception employing the two assays are discussed in terms of molecular mechanisms, and a testable hypothesis is proposed for the possible roles of chemoresponsiveness and erasure in late morphogenesis.     

Identification of a second member of the ponticulin gene family and its differential expression pattern

We have identified a homologue (ponB) of the ponticulin gene (ponA), an F-actin binding protein, in the expressed sequence tag library generated to mRNA isolated from fusion-competent cells of Dictyostelium discoideum. PonB is predicted to have many of the same characteristics as ponticulin. Both proteins are predicted to possess a cleaved signal peptide, a glycosyl anchor, an amphipathic beta-strand structure and six conserved cysteines. Because of the sequence similarity and predicted conserved structures, this gene constitutes the second member of a ponticulin gene family. Unlike ponticulin, ponB is not expressed in axenically grown cells or during the asexual reproductive phase of D. discoideum. PonB is expressed by cells grown on bacterial lawns and by cells induced to be fusion-competent, i.e., gametes. The expression of ponB correlates with the appearance of a new F-actin binding activity in cell lysates of bacterially grown ponA(-) cells. By immunofluorescence microscopy, ponB appears to be localized to vesicles and to the plasma membrane of bacterially grown cells. Because ponticulin is the major high-affinity link between the plasma membrane and the cytoskeleton, the ponticulin gene family is likely to be part of the redundant system of proteins involved in connecting the cytoskeleton to the plasma membrane.     

Molecular Cloning and Characterization of the cDNA for Discoidin II of Dictyostelium discoideum

By using monoclonal antibodies directed against discoidin II,we have isolated cDNA clones from axenically grown Ax-2 cells.On cDNA clone (D2) condtained a 1.2-k.b insert encoding theentire discoidin II protein, which is conposed of 257 aminoacid residuces and has a calculated molecular mass of 28,574.The amino acid sequences, determined by Edman degradation ofsix tryptic peptides of discoidin II, were identical to thosededuced from the cDNA sequences. The protein bears no resemblanceto any proteins in the data banks, except that its sequenceis 49% identical with the amino acid sequence of discoidin I.Discoidin II shares with discoidin I both a carbohydratebindingsite and an Arg-Gly-Asp (RGD) sequence, which has been foundin fibronectin in mammalian cells. With the onset of aggregation(8 h of development), a 1.3-kb discoidin II mRNA begins to accumulate.A similar pattern of regulation occurs at the protein level. ¹Present address: MRC Laboratory for Molecular Cell Biology,University College London, Gower Street, London, WC1E 6BT UnitedKingdom     

Cysteine proteinase changes during microcyst formation and germination inPolysphondylium pallidum

Microcyst formation inPolysphondylium pallidum WS320 was accompanied by a decrease in intracellular cysteine proteinase activity measured with the peptide nitroanilides Z-Arg-Arg-Nan and Bz-Pro-Phe-Arg-Nan. Some activity was released into the buffer, and secretion of that towards Z-Arg-Arg-Nan continued until encystment occurred. Cells grown in association withEscherichia coli had an electrophoretic proteinase pattern different from cells grown axenically. Microcysts formed from the two cell populations also had distinct proteinase patterns; those from bacterially grown cells retained significant quantities of proteinase ppCP22, whereas those derived from axenic cells were devoid of detectable proteinases. No significant changes in cysteine proteinase activities were observed during microcyst germination, although some changes in activity occurred subsequent to emergence. The results indicate that there is not a close correlation between particular cysteine proteinases and specific stages of microcyst formation. Intracellular proteinase loss and concomitant secretion are, however, processes typical of cellular slime molds developing in response to starvation.     

Single-cell fluorescence resonance energy transfer analysis demonstrates that caspase activation during apoptosis is a rapid process. Role of caspase-3

Activation of effector caspases is considered to be the final step in many apoptosis pathways. We transfected HeLa cells with a recombinant caspase substrate composed of cyan and yellow fluorescent protein and a linker peptide containing the caspase cleavage sequence DEVD, and we examined the cleavage kinetics at the single-cell level by fluorescence resonance energy transfer (FRET) analysis. Caspase activation in response to tumor necrosis factor-alpha, staurosporine, or etoposide resulted in cleavage of the linker peptide and subsequent disruption of the FRET signal. The time to caspase activation varied among individual cells, depending on the type of treatment and concentration used. However, once initiated, disruption of the FRET signal was always rapid (相似文献   

Differences in the biotransformation of 2,4,6-trinitrotoluene (TNT) between wild and axenically grown isolates of Myriophyllum aquaticum

The aim of this study was to demonstrate the potential for aquatic plants and their associated microbes to bioremediate wetland sites contaminated with 2,4,6-trinitrotoluene (TNT). The transformation of TNT was studied using both wild and axenically grown isolates of Myriophyllum aquaticum (parrot feather). Differences in TNT transformation rates and nitroaromatic metabolites were observed between different plants. The wild isolates, containing a consortium of associated microorganisms, transformed TNT into 2-amino-4,6-dinitrotoluene (2-A-DNT) and 4-amino-2,6-dinitrotoluene (4-A-DNT) via 2- and 4-hydroxylamino-dinitrotoluene, which were detected as intermediates. The wild M. aquaticum also converted the metabolites, 2-A-DNT and 4-A-DNT, into low levels of 2,4-diaminotoluene (2,4-DAT). The axenically grown plants, containing no cultureable microorganisms, also transformed TNT into 2-A-DNT and 4-A-DNT, but at a much lower rate than that observed for the wild isolates. Unlike the wild plants, axenically grown M. aquaticum could not transform either 2-A-DNT or 4-A-DNT into 2,4-DAT over the incubation period. The differences in the performance between these plants could indicate that plant-associated microorganisms assisted in the overall transformation of TNT. For each plant, unidentifiable metabolites were observed and the soluble monoamino-derivatives present in the wild and axenic medium accounted for 14 and 7% of the initial TNT concentration, respectively. Thus, the majority of nitroaromatic derivatives remained associated with the plant tissues. Furthermore, only 7 and 3% of the initial TNT concentration were extracted as monoamino-derivatives from the tissues of the wild and axenically grown plants, respectively.