Mutational Analysis of the Role of Rap1 in Regulating Cytoskeletal Function inDictyostelium

It was shown previously that increased expression of theras-relatedrap1gene inDictyostelium discoideumaltered cell morphology (Rebsteinet al., Dev. Genet.,1993, 14, 347–355). Vegetative Rap1 transformants were more flattened and spread than parental Ax2 cells and had increased F-actin near the cell periphery. In addition, starving Rap1 cells were inhibited in the rapid cell contraction that occurs upon refeeding with nutrient media. In this communication, we show that expression of Rap also markedly reduces the contraction response that occurs upon addition of azide to vegetative cells. The changes in cell morphology, the refeeding contraction response, and the azide contraction response have been used to analyze mutants of Rap1 generated by site-directed mutagenesis. The substitution G12V, predicted to increase the proportion of protein binding GTP, did not alter the effect of Rap on cell morphology or on its ability to inhibit the contraction response to azide, but modestly enhanced the ability of Rap1 to inhibit cell rounding in response to nutrient media. The substitution S17N, predicted to restrict the protein to the GDP-bound state, did not produce the flattened cell morphology and abolished the inhibitory effects of Rap in the two cell contraction assays. These results are consistent with a requirement of GTP binding for the Rap-induced effects. Transformants carrying the Rap-S17N protein had a more polar morphology than the parental Ax2 cells, suggesting the possibility that Rap-S17N interferes with the ability of endogenous Rap to regulate the cytoskeleton. Substitutions at amino acid 38, within the presumptive effector domain, reduced but did not abolish the effects of Rap1 on cell contraction, while the substitution T61Q had no effect on Rap1 activity. Taken together, the results suggest that Rap may have multiple regulatory effects on cytoskeletal function.     

Identification of the regulatory subunit of a cAMP-dependent protein kinase in Dictyostelium discoideum

The occurrence of a cytosolic cAMP-binding protein of an approximate molecular weight of 41,000 daltons was monitored in vegetative and developing amoebae of $\text{Dictyostelium}\text{discoideum}$ by the use of the photoaffinity probe (³²P) 8N₃-cAMP. There was a large apparent increase in the amount of this binding protein during development; its molecular weight remained constant, if appropriate methods were employed for the disruption of the amoebae. Comigration during electrophoresis on two-dimensional gels identifies this cAMP-binding protein, photoaffinity-labeled in crude extracts, as the regulatory subunit of the cAMP-dependent protein kinase of $\text{D.}\text{discoideum}$.     

The activation of cell aggregation by phosphorylation in Dictyostelium discoideum

Single amoebae of D. discoideum are phosphorylated in the presence of external ATP. Phosphorylation is catalyzed by a cAMP independent cell membrane bound protein kinase. As a result of phosphorylation cell aggregation is induced and the chemotactic sensitivity of the amoebae to a cAMP gradient decreased. Cell membrane phosphorylation may be involved in triggering cell aggregation in vivo. The fact that the number of free phosphorylable sites per cell decreases at the onset of aggregation gives support to this hypothesis. The existence of a plasma membrane bound phosphoprotein phosphatase suggests a possible regulator role for this enzyme on the phosphorylation of the amoebae. Finally, ATP inhibits intercellular contact sites outside the aggregation center. Despite this inhibiting effect on cell adhesiveness, amoebal movement toward an aggregation center maintains its normal periodicity.     

Expression of the Bacillus licheniformis PWD-1 keratinase gene in B. subtilis

The kerA gene which encodes the enzyme keratinase was isolated from the feather-degrading bacterium Bacillus licheniformis PWD-1. The entire gene, including pre-, pro- and mature protein regions, was cloned with P_ker, its own promoter, P43, the vegetative growth promoter, or the combination of P43-P_ker into plasmid pUB18. Transformation of the protease-deficient strain B. subtilis DB104 with these plasmids generated transformant strains FDB-3, FDB-108 and FDB-29 respectively. All transformants expressed active keratinase in both feather and LB media, in contrast to PWD-1, in which kerA was repressed when grown in LB medium. With P43-P_ker upstream of kerA, FDB-29 displayed the highest activity in feather medium. Production of keratinase in PWD-1 and transformants was further characterized when glucose or casamino acids were supplemented into the feather medium. These studies help understand the regulation of kerA expression and, in the long run, can help strain development and medium conditioning for the production of this industrially important keratinase. Received 31 December 1996/ Accepted in revised form 23 June 1997     

Characterization of a GDP-sensitive phosphorylation in plasma membranes of D. discoideum

In a previous study, we reported the GDP-dependent phosphorylation of a 36 kD membrane protein, p36, inD. discoideum membranes prepared from starved (aggregation competent) cells (Anschutzet al., 1989). Here we show that p36 can be phosphorylated when membranes are supplied either ATP or GTP as the phosphate donor, but that a greater level of p36 phosphorylation is achieved with GTP. The rate of phosphorylation of p36, using either nucleotide triphosphate, is enhanced by GDP. This reflects a decrease in the apparentK _m of the enzyme for the particular nucleotide triphosphate. p36 can also be phosphorylated in membranes prepared from vegetative cells. However, the ability of GDP to stimulate p36 phosphorylation is not observed in vegetative cell membranes. Competition experiments indicate that there are also developmental differences in the nucleotide triphosphate site(s) available to phosphorylate p36.     

Dynamics of the Dictyostelium discoideum mitochondrial proteome during vegetative growth,starvation and early stages of development

In this study, a quantitative comparative proteomics approach has been used to analyze the Dictyostelium discoideum mitochondrial proteome variations during vegetative growth, starvation and the early stages of development. Application of 2‐D DIGE technology allowed the detection of around 2000 protein spots on each 2‐D gel with 180 proteins exhibiting significant changes in their expression level. In total, 96 proteins (51 unique and 45 redundant) were unambiguously identified. We show that the D. discoideum mitochondrial proteome adaptations mainly affect energy metabolism enzymes (the Krebs cycle, anaplerotic pathways, the oxidative phosphorylation system and energy dissipation), proteins involved in developmental and signaling processes as well as in protein biosynthesis and fate. The most striking observations were the opposite regulation of expression of citrate synthase and aconitase and the very large variation in the expression of the alternative oxidase that highlighted the importance of citrate and alternative oxidase in the physiology of the development of D. discoideum. Mitochondrial energy states measured in vivo with MitoTracker Orange CM^?Ros showed an increase in mitochondrial membrane polarization during D. discoideum starvation and starvation‐induced development.     

Cell surface changes during the differentiation of Dictyostelium discoideum : Interaction of cells with Concanavalin A

The parameters affecting the agglutination of cells of Dictyostelium discoideum by Concanavalin A (ConA) have been investigated. Under the incubation conditions employed, incubation time does not markedly affect agglutination, but there are distinct optima for cell density and gyration speed. Agglutination does not occur at low temperatures, but the transition temperature between the unagglutinated and fully agglutinated states is markedly influenced by ConA concentration. The rate of aggregation of strain NC-4 is considerably reduced by ConA. In contrast, the differentiation of strain Ax-2 in the presence of ConA is either unaffected or only slightly inhibited, depending on the incubation conditions. Succinylated-ConA binds to the same sites as the unmodified lectin, but has no effect on the differentiation of strain NC-4, suggesting that ConA binding sites are not directly involved in cell-cell contacts vital to the differentiation of D. discoideum. There is a gradual decrease in the susceptibility of cells of D. discoideum to agglutination by ConA as the cells pass from exponential growth phase to stationary growth phase in axenic medium and from vegetative amoebae to aggregates on a solid substratum. These results provide quantitative evidence for a gradual change in carbohydrate containing binding sites during differentiation.     

ADP phosphorylation and glutamate oxidation in mitochondria isolated from Dictyostelium discoideum amoebae

Mitochondria have been isolated from $\text{D.}\text{discoideum}$ amoebae in which respiration is coupled to ADP phosphorylation. P:O ratios and respiratory control ratios have been obtained for a number of metabolites. In rat liver mitochondria, glutamate is oxidized almost exclusively by a respiration-dependent cyclic transamination pathway, in which glutamate is converted to aspartate. When $\text{D.}\text{discoideum}$ amoebae are incubated with glutamate alone, aspartate does not accumulate appreciably. Furthermore, when the mitochondria are incubated with glutamate plus malonate at a concentration sufficient to inhibit respiration, their utilization of glutamate is depressed only slightly. Thus, it appears that glutamate oxidation within the mitochondria of $\text{D.}\text{discoideum}$ amoebae does not, for the most part, proceed by the cyclic transamination pathway.     

Changes in cellular adhesiveness during the development of the slime mold Dictyostelium discoideum

A method was devised to measure the adhesiveness to the substratum of the amoebae of the cellular slime mold, Dictyostelium discoideum, and measurements were conducted with the cells at various stages of development. The adhesiveness of the vegetative amoebae was low, and remained unchanged as long as they fed on bacteria. During the transition from the vegetative stage to the interphase (due to the cessation of feeding), the adhesiveness increased rapidly, and afterwards continued to rise, as development proceeded. The adhesiveness of the interphase amoebae was greatly decreased by the treatment with proteolytic enzymes, lipase, and acid phosphatase. These indicate that accumulation of some substance(s) such as lipoprotein on the cell surface is responsible for the increase in adhesiveness during the interphase. EDTA and periodic acid had no noticeable effect on the adhesiveness of the interphase amoebae. EDTA, however, decreased the adhesiveness in co-operation with trypsin or lipase. The cells disaggregated from the anterior part of the migrating slug showed higher adhesiveness than those from the posterior part. The adhesiveness of either cells was higher than that of the interphase amoebae.     

Pinocytic stimulation in Dictyostelium discoideum by γ-benzene hexachloride

Pinocytic activity is greatly stimulated in γ-BHC (gamma isomer of benzene hexachloride) treated, vegetative cells of Dictyostelium discoideum as measured by ¹⁴C sucrose or FITC-dextran uptake. Transmission electron microscopic studies also reveal the presence of a greater number of pinosomal vesicles in the pesticide-treated Dictyostelium amoebae. The enhanced pinocytic activity has been discussed in relation to lipophilic interactions of γ-BHC with the hydrophobic cell surface and the observed changes in the cytoskeletal proteins of the treated cells. © 1994 Wiley-Liss, Inc.     

Identification of the Dictyostelium discoideum homolog of the N-ethylmaleimide-sensitive fusion protein

The N-ethylmaleimide-sensitive fusion protein (NSF) is required for vesicular membrane fusion in multiple cellular functions. We have cloned a cDNA encoding the Dictyostelium discoideum homolog of the NSF protein. This cDNA hybridizes with a single fragment in Southern blots suggesting that NSF is encoded by a single gene in the amoeba. It is expressed constitutively during vegetative growth and throughout the differentiation cycle. The encoded gene product comprises 738 aa with a predicted molecular mass of 82 kDa. It shows the characteristic three-domain structure of NSF proteins. A more divergent amino-terminal part is followed by two highly conserved ATP-binding domains featuring Walker A and B signature sequences. The D. discoideum protein presents an overall aa sequence identity of 44% when compared to known NSF homologs. The monoclonal antibody 2E5 directed against Cricetellus griseus NSF recognizes a protein with a molecular weight of approx. 80 000 in a D. discoideum crude extract and the recombinant D. discoideum His₆-NSF expressed in Escherichia coli.     

The regulation of glycoprotein synthesis by cAMP in Dictyostelium

Dictyostelium discoideum (Dd) 1-H vegetative amoebae exposed to cAMP differentiate into mature stalk cells within 48 h [6]. It was of interest to monitor the patterns of glycoprotein synthesis in the amoebae during the first 5 h of exposure to cAMP and phosphate buffer (PB) controls. Following the exposure period the amoebae were labeled with -[6-³H]fucose. It was determined by both silver grain counts of autoradiographs and scintillation spectroscopy that within minutes cAMP effects an inhibition of [³H]fucose incorporation. However, by 5 h of exposure both experimentals and controls lose a major amount of their labeling capacity based upon the initial PB control value. Vegetative amoebae exposed to cAMP mimics the sparse labeling found in prestalk cells. Prestalk cells synthesize cellulose as a result of cAMP-induced gluconeogenesis and consequently glycoprotein synthesis is reduced. Cellular interactions promoted by cAMP appears to initiate prestalk cell differentiation during the pre-aggregation phase of development. This event is accompanied by a loss in the ability of the aggregating cells to synthesize glycoprotein.     

Cross‐species functional complementation of cellulose synthase during the development of cellular slime molds

Cellulose is a major and important component of the extracellular matrix during the development of Dictyostelium discoideum. Upon starvation, solitary amoebae of D. discoideum gather and form fruiting bodies in which cells differentiate into stalk cells and spores. The stalk tubes and walls of spores and stalk cells are made of cellulose. In the genus Acytostelium, however, all cells are destined to become spores and the stalks comprise only a cellulose tube, suggesting species‐specific regulation of cellulose synthesis. In this study, we cloned a putative cellulose synthase gene (cesA) of Acytostelium subglobosum and performed comparative analyses with the D. discoideum cellulose synthase gene (dcsA). Although the deduced amino acid sequences were highly conserved between cesA and dcsA, the numbers of transmembrane spans preceding the catalytic domain were dissimilar; 2 and 3, respectively. Since ectopic expression of cesA in dcsA^?null cells failed to restore the developmental defects of the mutant, we constructed a series of chimerical genes for complementation analyses and found that the catalytic domain of cesA was functional in D. discoideum cells if the preceding transmembrane region was swapped with dcsA. The non‐functional products that contained the cesA‐derived transmembrane region were localized to lysosomes. These results indicate that the transmembrane region of cellulose synthase is essential for proper accumulation of cellulose during the development of D. discoideum and that its differential localization in A. subglobosum may be related to the characteristic morphogenesis in this species.     

Folic Acid as Second Chemotactic Substance in the Cellular Slime Moulds

IT has been known for some time that in certain species of cellular slime moulds acrasin, the substance which attracts the amoebae to central collection points during the aggregation phase, is cyclic AMP^1–4. We were also able to show that E. coli gave off another substance besides cyclic AMP (henceforth referred to as bacterial factor, or BF) which attracted the vegetative amoebae of Dictyostelium discoideum⁵. Here we demonstrate that this second attractant has the properties of folic acid or one of its derivatives. We also show that folic acid and related compounds not only attract the vegetative amoebae of D. discoideum (No. NC-4H) but also the amoebae of six other species (Dictyostelium rosarium No. CC-7; D. mucoroides No. 11; D. purpureum No. 2; D. minutum No. V-3; Polysphondylium violaceum No. 1; P. pallidum No. 2). For the latter three species cyclic AMP is not the aggregative attractant (ref. 6 and J. T. B., E. M. H., S. Noller, F. B. Oleson and A. B. Roberts, in preparation) which raises the interesting question of whether their acrasin might be related to the folates.     

The effect of tosyl lysine chloromethyl ketone on the activity of uridine diphosphoglucose pyrophosphorylase of the cellular slime mold Dictyostelium discoideum

We report here that the specific activity of UDPG pyrophosphorylase in extracts of $\text{D. discoideum}$ amoebae and preculmination-stage cells increases as a function of the length of their exposure to tosyl lysine chloromethyl ketone, an irreversible inhibitor of a number of serine and sulfhydryl proteases. This compound also stabilizes the activity of the enzyme in crude extracts of amoebae. These results can be interpreted, with some assumptions, as evidence in support of the hypothesis that the levels of the enzyme are maintained in $\text{D. discoideum}$ by a balance of synthesis and degradation.     

Characterization of a GDP-sensitive phosphorylation in plasma membranes ofD. discoideum

In a previous study, we reported the GDP-dependent phosphorylation of a 36 kD membrane protein, p36, inD. discoideum membranes prepared from starved (aggregation competent) cells (Anschutzet al., 1989). Here we show that p36 can be phosphorylated when membranes are supplied either ATP or GTP as the phosphate donor, but that a greater level of p36 phosphorylation is achieved with GTP. The rate of phosphorylation of p36, using either nucleotide triphosphate, is enhanced by GDP. This reflects a decrease in the apparentK _m of the enzyme for the particular nucleotide triphosphate. p36 can also be phosphorylated in membranes prepared from vegetative cells. However, the ability of GDP to stimulate p36 phosphorylation is not observed in vegetative cell membranes. Competition experiments indicate that there are also developmental differences in the nucleotide triphosphate site(s) available to phosphorylate p36.     

Evidence for a Second Chemotactic System in the Cellular Slime Mold, Dictyostelium discoideum

An unknown substance found in bacteria (Escherichia coli) is especially effective in attracting the vegetative amoebae of the cellular slime mold, Dictyostelium discoideum. However, the aggregating amoebae are not attracted to it at all. On the other hand, the vegetative amoebae show very little chemotactic response to cyclic adenosine monophosphate (cyclic AMP), whereas the aggregating amoebae are exceptionally responsive to it. It is suggested that the new factor may be used in food seeking, whereas cyclic AMP, the chemotactic substance responsible for aggregation, is the acrasin of this species. The important point is that the amoebae are differentially stage-specific in their responses to these two chemotactic agents.     

Phosphorylation of the contact site A glycoprotein (gp80) of Dictyostelium discoideum

Developmentally regulated cohesion of Dictyostelium discoideum can be blocked by the Fab fragment of antiserum prepared against a glycoprotein of about 80,000 daltons, gp80, purified from the membranes of developing amoebae. Immunoprecipitation of gp80 with this serum, from ³²P-labeled cell extracts of aggregating D. discoideum amoebae showed it to be a phosphoprotein. Serine phosphate was found in the molecule. All multiple isoelectric forms of gp80 were phosphorylated. Synthesis of the phosphorylated form of gp80 was found to be limited to the period of aggregation and coincided with the period of incorporation of [³⁵S]methionine into gp80. Phosphorylation could be rapidly inhibited by cycloheximide suggesting that phosphorylation occurs only on newly made gp80. No unphosphorylated gp80 could be detected in cell extracts.     

Polypeptide compositions of amoebae of the cellular slime mouldDictyostelium discoideum separated by partitioning during development

Amoebae of the cellular slime mouldDictyostelium discoideum at 8 h or l0 h development were separated into two populations by countercurrent distribution in a dextran-poly(ethylene glycol), two-phase system. Two-dimensional, polyacrylamide-gel electrophoresis was then used to separate the polypeptides from the populations of amoebae. The two populations of amoebae at 8 h development differed sn polypeptide composition as did the populations separated at 10 h development. This confirms that cell differentiation is initated inD. discoideum prior to g h development.