Involvement of the TRAP-1 homologue, Dd-TRAP1, in spore differentiation during Dictyostelium development

Tumor necrosis factor receptor-associated protein 1 (TRAP1) is a member of the molecular chaperone HSP90 (90-kDa heat shock protein) family. We have previously demonstrated that Dictyostelium discoideum TRAP1 (Dd-TRAP1) synthesized at the vegetative growth phase is retained during the whole course of D. discoideum development, and that at the multicellular slug stage, it is located in prespore-specific vacuoles (PSVs) of prespore cells as well as in the cell membrane and mitochondria. Thereupon, we examined the function of Dd-TRAP1 in prepore and spore differentiation, using Dd-TRAP1-knockdown cells (TRAP1-RNAi cells) produced by the RNA interference method. As was expected, Dd-TRAP1 contained in the PSV was found to be exocytosed during sporulation to constitute the outer-most layer of the spore cell wall. In the TRAP1-RNAi cells, PSV formation and therefore prespore differentiation were significantly impaired, particularly under a heat stress condition. Although the TRAP1-RNAi cells formed apparently normal-shaped spores with a cellulosic wall, the spores were less resistant to heat and detergent treatments, as compared with those of parental MB35 cells derived from Ax-2 cells. These findings strongly suggest that Dd-TRAP1 may be closely involved in late development including spore differentiation, as well as in early development as realized by its induction of prestarvation response.     

CHANGES OF THE PRESPORE SPECIFIC STRUCTURE DURING DEDIFFERENTIATION AND CELL TYPE CONVERSION OF A SLIME MOLD CELL

In the slug of the cellular slime mold, Dictyostelium discoideum , are differentiated the anterior prestalk cells and the posterior prespore cells, whose differentiation is characterized by formation of the prespore specific vacuole (PSV). The ultrastructural changes of the PSV were investigated during dedifferentiation of a prespore cell disaggregated from a slug and also during conversion of the cell type, caused by fragmentation of a slug, between the prespore and the prestalk cells.
During the dedifferentiation, the PSV first lost its lining membrane which subsequently congregated, together with the inner filamentous material, to form some electron dense granules. Finally, the vacuole membrane was punctured, and the granules were released into cytoplasm. During conversion of the prespore to the prestalk cell, the PSV was degraded through the same process as in dedifferentiation, but the degradation proceeded much more synchronously in a converting cell. When a prestalk fragment was isolated from a slug, formation of the PSV was detected in no cell until 2 hr of incubation. After a lag, the PSV was formed in a converting cell through the process which is not a simple reversal of its degrading process.     

Dual Effects of cAMP on the Stability of Prespore Vesicles and 8-bromo cAMP-enhanced Maturation of Spore and Stalk Cells of Dictyostelium discoideum

It is well known that interconversion between prestalk and prespore cells occurs in 3-dimensional (3–D) isolates of Dictyostelium. The present work was undertaken to examine whether or not the interconversion occurs even in monolayer sheets. The results suggested that in monolayer sheets of either prespore or prestalk cells, the interconversion does not occur. Furthermore, effects of cAMP were examined in relation to the formation or loss of prespore vesicles (PSVs). In monolayer sheets, prespore cells retain their PSVs in the presence of cAMP, though they lose them in its absence. In 3–D masses, however, cAMP induces the conversion into stalk cells, stimulating PSV loss. In the case of prestalk cells, cAMP induces the maturation of prestalk cells to stalk cells in 3–D masses, but it does not induce stalk differentiation in monolayer sheets.
8-Bromo cAMP stimulates the maturation of prespore and prestalk cells into spore and stalk cells, respectively. However, the vegetative and the aggregative cells remain amoeboid even in its presence. These observations suggest that 8-bromo cAMP stimulates the maturation rather than inducing prespore and prestalk differentiation.     

A mitochondrion as the structural basis of the formation of a cell-type-specific organelle inDictyostelium development

Summary The mitochondrion has been mainly given attention as a self-reproductive and respiratory organelle. We report here that the mitochondrion may participate in the formation of a cell-type-specific organelle, coupling with the Golgi complex. During the development ofDictyostelium discoideum, the two types of cells, i.e., the anterior prestalk cells and the posterior prespore cells form a polarized cell mass. Prespore differentiation is characterized by the presence of unique vacuoles named PSVs (prespore-specific vacuoles) in the cytoplasm. Thus the PSV is the most essential organelle to understand the structural basis of cell differention in this organism. In differentiating prespore cells, the mitochondrion exerts a remarkable transformation to form a sort of vacuole (M-vacuole). Using a PSV specific antibody, it was immunocytochemically shown that a PSV antigen (C-10) is localized in the M-vacuole as well as in the lining membrane of PSV. Interestingly, the C-10 antigen was also noticed in the Golgi cisternae that had fused with M-vacuole. Based on these findings, we propose here a promising model which suggests how both mitochondria and Golgi cisternae may be coordinately involved in the PSV formation. This model will provide a new aspect of mitochondrial functions in cell differentiation.     

Unique behavior of a dictyostelium homologue of TRAP-1, coupling with differentiation of D. discoideum cells

Dd-TRAP1 is a Dictyostelium homologue of TRAP-1, a human protein that binds to the type 1 tumor necrosis factor (TNF) receptor. TRAP-1 has a putative mitochondrial localization sequence and shows significant homology to members of the HSP90 family. Although TRAP-1 is mainly localized to mitochondria in several mammalian cells, in certain tissues it is also localized at specific extramitochondrial sites. In Dictyostelium cells, Dd-TRAP1 is predominantly located in the cell membrane/cortex during growth and just after starvation. Double staining of vegetatively growing cells with the anti-Dd-TRAP1 antibody and TRITC-phalloidin has demonstrated colocalization of Dd-TRAP1 and F-actin at the leading edge of cortical protrusions such as pseudopodes. Coupled with differentiation, however, Dd-TRAP1 located at the cortical region is translocated to mitochondria in spite of the absence of the mitochondrial localization sequence at its N-terminus. The translocation of this protein raises interesting and fundamental questions regarding possible mechanisms by which Dd-TRAP1 is involved in cellular differentiation.     

Glycoantigen expression is regulated both temporally and spatially during development in the cellular slime molds Dictyostelium discoideum and D. mucoroides

Six monoclonal antibodies were isolated which react with common antigens shared by multiple glycoconjugate species in the cellular slime mold Dictyostelium discoideum. Based on competition of antibody binding by glycopeptides and simple sugars, and inhibition of antibody binding by antigen pretreatment with Na periodate, it is argued that at least five of the six antibodies recognize epitopes which contain carbohydrate. These epitopes are consequently referred to as glycoantigens (GAs).Three of the GAs are expressed during growth and throughout the developmental cycle, but are eventually enriched in prestalk and stalk cells. The remaining three are expressed only during and/or after aggregation and are exclusively expressed or highly enriched in prespore cells and spores. These conclusions are derived from Western blot immunoanalysis of purified cell types, immunofluorescence, and EM immunocytochemistry.The two GAs found only in prespore cells appear to be exclusively enclosed within prespore vesicles. The third GA of this type, which is only enriched in prespore cells compared to prestalk cells, is also found in other vesicle types as well as on the cell surface.Two of the GAs enriched in prestalk cells are initially found in all cells of the slug. They are undetectable in spores and prominent in stalk cells. The third GA, though found in the interiors of both prestalk and prespore cells, is enriched on the cell surface of prestalk cells.The chief characteristics of expression of four of these GAs are conserved in the related species D. mucoroides. This species is characterized by continuous trans differentiation of prespore cells into prestalk cells. This shows that the prespore cells maintain specific mechanisms for turning over their cell type specific GAs and that prestalk cells express a specific mechanism for inducing at least one of their cell-type specific GAs.These observations identify specific carbohydrate structures (as GAs) whose synthesis, subsequent localization and turnover are developmentally regulated. The exclusive association of two GAs with prespore vesicles identifies these GAs as markers for this organelle and raises questions regarding the functional significance of this association. The restricted cell surface localization of the other four GAs, together with data from cell adhesion studies, suggest the possibility of a potential role for these GAs in intercellular recognition leading to cell sorting.This paper is dedicated to the memory of the late Daniel McMahon.     

Involvement of the glucose-regulated protein 94 (Dd-GRP94) in starvation response of Dictyostelium discoideum cells

Upon deprivation of nutrients, Dictyostelium discoideum Ax-2 cells arrest proliferation and initiate a metamorphosed developmental program including induction of altered gene expressions which are necessary for differentiation. In Ax-2 cells, we found out a member of Hsp90 family usually contained in the endoplasmic reticulum (ER), Dd-GRP94 (Dictyostelium discoideum glucose-regulated protein 94). In general, GRP94 are induced either by glucose-depletion or by depletion of Ca(2+) in intracellular Ca(2+) stores. Unexpectedly, however, the expression of Dd-grp94 was greatly reduced within 60 min of starvation. Dd-grp94-overexpressing cells (GRP94(OE) cells) collected without forming distinct aggregation streams, and never formed normal fruiting bodies. Also, prespore differentiation as well as maturation into spores and stalk cells were particularly impaired in the GRP94(OE) cells. Thus Dd-GRP94 seems to be crucial in late differentiation as well as in starvation response.     

The Dictyostelium discoideum EB4 gene product and a truncated mutant form of the protein are localized in prespore vesicles but absent from mature spores

Using polyclonal antibodies directed against two different parts of the predicted Dictyostelium prespore protein EB4-PSV, we have investigated the regulation and localization of its 58-kDa gene product in wild-type cells and a 31-kDa truncated form in the gene disruption transformant A3. In both strains, the protein is synthesized during aggregation and is found in the membrane fraction of prespore vesicles (PSV). In contrast to other PSV proteins, the EB4 gene product is not found in mature spores.     

Differential Cell Cohesiveness Expressed by Prespore and Prestalk Cells of Dictyostelium discoideum

Pseudoplasmodia of Dictyostelium discoideum at the culmination stage were separated into two cell populations by sedimentation in a discontinuous renografin gradient. The two lighter fractions (I and II) had enzymatic activities characteristic of the anterior prestalk cells, while the heaviest fraction (III) showed enzyme activities characteristic of the posterior prespore cells. Cell-cell adhesion among prespore cells is much more resistant to EDTA dissociation than 10-h cells and prestalk cells. Fab fragments prepared from antibodies directed against a specific cell surface glycoprotein gp150 were more effective in dissociating prespore cells than prestalk cells. In addition, prespore cells contained an approximately 2-fold higher concentration of the endogenous carbohydrate binding protein discoidin-I than prestalk cells. These differences may account for the differential cohesiveness of these two cell populations and provide a basis for cell recognition and cell sorting at the slug stage.     

Production and turnover of cAMP signals by prestalk and prespore cells in Dictyostelium discoideum cell aggregates

Dictyostelium discoideum prestalk cells and prespore cells from migrating slugs and culminating cell aggregates were isolated by Percoll density centrifugation. Several activities relevant to the generation, detection, and turnover of extracellular cyclic AMP (cAMP) signals were determined. It was found that: the two cell types have the same basal adenylate cyclase activity; prespore cells and prestalk cells are able to relay the extracellular cAMP signal equally well; intact prestalk cells show a threefold higher cAMP phosphodiesterase activity on the cell surface than prespore cells, whereas their cytosolic activity is the same; intact prestalk cells bind three to four times more cAMP than prespore cells; no large differences in cAMP metabolism and detection were observed between cells derived from migrating slugs and culminating aggregates. The results are discussed in relation to the possible morphogenetic role of extracellular cAMP in Dictyostelium cell aggregates. On the basis of the properties of the isolated cells we assume that a gradient of extracellular cAMP exists in Dictyostelium aggregates. This gradient appears to be involved in the formation and stabilization of the prestalk-prespore cell pattern.     

Involvements of a novel protein, DIA2, in cAMP signaling and spore differentiation during Dictyostelium development

Abstract The novel gene dia2 (differentiation-associated gene 2) was originally isolated as a gene expressed specifically in response to initial differentiation of Dictyostelium discoideum Ax-2 cells. Using dia2^AS cells in which the dia2 expression was inactivated by the antisense RNA method, DIA2 protein was found to be required for cAMP signaling during cell aggregation. During late development, the DIA2 protein changed its location from the endoplasmic reticulum (ER) to prespore-specific vacuoles (PSVs) that are specifically present in prespore cells of the slug. In differentiating prestalk cells, however, DIA2 was found to be nearly lost from the cells. Importantly, exocytosis of PSVs from prespore cells and the subsequent spore differentiation were almost completely impaired in dia2^AS cells. In addition, spore induction by externally applied 8-bromo cAMP was significantly suppressed in dia2^AS cells. Taken together, these results strongly suggested that DIA2 might be closely involved in cAMP signaling and spore differentiation as well as in the initiation of differentiation during Dictyostelium development.     

Cell differentiation in Dictyostelium discoideum controls assembly of protein-linked glycans

The prestalk and prespore cells from the Dictyostelium discoideummulticellular slug stage of development differ in assembly ofglycoconjugates. Prespore cells are 2- to 3-fold more activethan prestalk cells in the assembly of N-linked glycans and20-fold more active in their fucosylation. Only prespore cellssynthesize an O-linked glycan consisting in part of Fuc -linkedto N-acetylglucosamine. Incorporation of fucose, glucosamine,mannose and galactose into large pronase-resistant glycoconjugateswas almost exclusively into prespore cells. Such glucosamine-labelledglycoconjugates resist fragmentation by ß-eliminationand include a glycoantigen dependent on the modB genetic locus.In contrast, large fucose-labelled glycoconjugates consistedof multiple, small, O-linked oligosaccharides on carrier peptides.The spore coat protein SP96 has several fucosylated O-linkedoligosaccharides, one of which correlates with a fucose epitopepreviously shown to localize in prespore vesicles and the outerlayer of the spore coat. Dictyostelium discoideum glycoconjugates glycoproteins prespore prestalk     

Control of cell type proportions by a secreted factor in Dictyostelium discoideum

It has been shown that, in Dictyostelium discoideum, conversion of prestalk cells to prespore cells in suspension cultures is inhibited by coexisting prespore cells. To examine whether the inhibition of conversion requires direct cell contact or is mediated by substances secreted by the cells, prestalk cells and prespore cells were incubated in shaken suspension, separated from each other by a dialysis membrane, and conversion of the prestalk cells to prespore cells scored after 24 h. Prestalk-to-prespore conversion was significantly inhibited if the density of the prespore cells was sufficiently high. In contrast, prestalk cells had little influence on prestalk-to-prespore conversion. Media conditioned by prespore cells, but not by prestalk cells, also inhibited the conversion of prestalk cells. Adenosine, propionate, diethylstilboestrol and differentiation inducing factor (DIF), all of which are known to influence the prestalk/prespore differentiation, were examined for their effects on prestalk-to-prespore conversion. Among these, all except adenosine significantly inhibited the conversion. Based on these results, possible mechanisms for maintenance of the constant cell-type ratio in D. discoideum slugs were discussed.     

Rapid patterning in 2-D cultures of Dictyostelium cells and its relationship to zonal differentiation

Rapid patterning has been observed in confined 2-D cultures of Dictyostelium discoideum Ax-2 cells as an outer dark zone and a inner light zone. The width of outer zone was usually approximately100 microm, irrespective of the size of cell masses under atmospheric conditions. The width of the outer zone, however, changed depending on external O2 concentrations and reached up to 250 microm at 100% O2. A clear regional difference in tetramethyl rhodamine methyl ester (TMRM) staining was noticed between the outer zone and the inner zone: the inner zone was more strongly stained with TMRM than the outer zone, which faced the air. Using inhibitors of oxidative phosphorylation (dinitrophenol (DNP) or NaN3) and a specific inhibitor of CN-resistant respiration (benzohydroxamic acid (BHAM)), it has been demonstrated that the outer zone is basically formed by the O2 threshold for oxidative phosphorylation, while the inner cells mainly perform cyanide-resistant respiration. When cells around the early mound stage (just before prestalk and prespore differentiation) were cultured as 2-D cell masses, ecmA-expressing cells (pstA cells), ecmB-expressing cells (pstB cells) and D19-expressing cells (prespore; psp cells), arose in a position-dependent manner in the outer zone. In the inner zone, cell motility seemed to be markedly impaired and neither prestalk nor prespore differentiation occurred. In addition, once-differentiated prespore cells were found to dedifferentiate rapidly in the inner zone. The reason for dedifferentiation as well as for failure of cells to differentiate in the inner zone is discussed with reference to O2 radicals.     

Control of cell type proportioning in Dictyostelium discoideum by differentiation-inducing factor as determined by in situ hybridization

We have determined the proportions of the prespore and prestalk regions in Dictyostelium discoideum slugs by in situ hybridization with a large number of prespore- and prestalk-specific genes. Microarrays were used to discover genes expressed in a cell type-specific manner. Fifty-four prespore-specific genes were verified by in situ hybridization, including 18 that had been previously shown to be cell type specific. The 36 new genes more than doubles the number of available prespore markers. At the slug stage, the prespore genes hybridized to cells uniformly in the posterior 80% of wild-type slugs but hybridized to the posterior 90% of slugs lacking the secreted alkylphenone differentiation-inducing factor 1 (DIF-1). There was a compensatory twofold decrease in prestalk cells in DIF-less slugs. Removal of prespore cells resulted in cell type conversion in both wild-type and DIF-less anterior fragments. Thus, DIF-1 appears to act in concert with other processes to establish cell type proportions.     

Implications of Differential Chemotaxis and Cohesiveness for Cell Sorting in the Development of Dictyostelium discoideum

Cell sorting behavior was observed during the development of Dictyostelium discoideum Ax-2, between cells grown with [G(+) cells] and without [G(−) cells] glucose. Development of the G(−) cells was about 2-3 hr faster, as reflected by differences in chemotactic sensitivity of the cells and cell cohesiveness. Among various mixing combinations of G(−) and G(+) cells, the most clear sorting occured when vegetative G(+) cells were mixed with G(−) cells which had been allowed to develop for 3 hr, the G(−) cells being located in the anterior prestalk region of a migrating slug. In contrast, vegetative G(−) cells moved to the posterior prespore region of a slug when mixed with G(+) cells which had developed for 6 hr. These findings indicate a close relationship of the cellular developmental stage to the sorting behavior. Possible implications of the differential chemotactic ability and cohesiveness for the sorting mechanism are disscussed.     

Developmental regulation of a prestalk- and stalk-enriched protein in Dictyostelium discoideum

Abstract. Monoclonal antibodies reactive with proteins specifically present either in the prespore cells or the prestalk cells of Dictyostelium discoideum were obtained. Four of them recognized prespore-enriched proteins, as shown by both immunoblotting assays and immunofluorescent staining. The other monoclonal antibody ( mab150 ) produced more than 10 protein bands when reacted with both prespore and prestalk cell extracts in immunoblotting assays. However, a protein band with molecular weight 35 000 (st35) was specifically detected in prestalk cells as well as mature stalk cells. St35 was solubilized from the Triton X-100 insoluble fraction of mature stalks by sodium dodecyl sulfate (SDS). The purified sample gave a single spot on two-dimensional gel electrophoresis, with pI of 5.0. During development, st35 first appeared at the tipped aggregate stage and accumulated up to stalk-cell formation without modification. The protein was not lost even when slugs were disaggregated. The importance of the tipped aggregate stage for prestalk differentiation as well as prespore differentiation is discussed.     

Separation and properties of prestalk and prespore cells of Dictyostelium discoideum

We describe a method of separating prestalk and prespore cells of Dictyostelium discoideum slugs using a self-generating Percoll gradient. This method gives quantitative recovery of cells and good purity. Separated prestalk and prespore cells possess different levels of the enzymes UDP galactose :polysaccharide transferase, cAMP phosphodiesterase and glycogen phosphorylase. We have used this method, as well as mechanical dissection of slugs, to examine the fate of separated prestalk and prespore cells in Dictyostelium strains that are able to give rise to mature stalk and spore cells in cell monolayers. The results from such experiments provide direct evidence that prestalk and prespore cells from the migrating slug stage are programmed to differentiate into stalk and spore cells respectively.