An analysis of discoidin I binding sites in Dictyostelium discoideum (NC4).

Vegetative wild-type (strain NC4) D. discoideum cells and cells at the 10h stage of development (aggregation) were harvested in the presence of 0.5 M-galactose to remove any endogenous discoidin I already bound to the cell surface, and fixed with glutaraldehyde. Affinity-purified 125I-labelled discoidin I bound to these fixed cells in a specific manner, greater than or equal to 95% of binding being inhibited by 0.5 M-galactose. Binding of 125I-labelled discoidin I was essentially complete in 90 min at 22 degrees C. Based on specific radioactivity measurements, vegetative (0h) D. discoideum (NC4) cells bind approx. 8.4 x 10(5) discoidin I tetramers/cell and aggregated (10h) cells bind 5.1 x 10(5) discoidin I tetramers/cell, each exhibiting apparent positive co-operativity of binding with highest limiting affinity constants (Ka) of approx. 1 x 10(7) and 2 x 10(7) M-1, respectively. Klebsiella aerogenes, the food source used for growth of D. discoideum NC4 amoebae, also binds 125I-labelled discoidin I and this is greater than 99% inhibited by 0.5 M-galactose. However, at the levels of bacterial contamination present, greater than 97% of 125I-labelled discoidin I binding to D. discoideum cell preparations was to the cells themselves. Confirmation of the number of discoidin I tetramers bound per D. discoideum cell was obtained by elution of bound 125I-labelled discoidin I followed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and then quantification by scanning of stained discoidin I bands.     

Founder Cell Differentiation and Acrasin Production in an Aggregateless Mutant of Polyspondylium violaceum

A specific class of aggregation-deficient mutants, aggA , of Polyshondylium violaceum are unable to aggregate unless supplied exogenously with a stimulating factor called D factor. The present study examines the effect of D factor on the induction of founder cells and on the production of the chemoattractant of aggregation, N-propionyl-γ-L-glutamyl-L-ornithine-δ-lactam ethyl ester (or glorin). Founder cells initiate aggregate formation and are morphologically distinct from the majority of the amoebae. Founder cell differentiation and oriented movement of attracted amoebae have been studied by time-lapse videotape analysis. In wild-type strains, on the average 90 min after the onset of starvation, a single, motile, irregularly shaped amoeba stops wandering and becomes round in shape. This founder cell has differentiated randomly from the pool of starved amoebae and within 2.5 min after the cessation of movement begins to attract and establish cellular contacts nighboring amoebae. The aggA mutants neither aggregate nor differentiate founder cells in the absence of D factor; whereas, aggregate formation and founder cell differentiation occur in the presence of physiological concentrations of purified, externally added D factor. However, in either the presence or absence of D factor, aggA amoebae produce and excrete glorin (measured using a bioassay) at levels comparable to their parental strain. These studies suggest that D factor is required for founder cell differentiation and organization of the aggregate, and that the ability to synthesize and excrete glorin is not sufficient to trigger aggregation.     

gdt1, a new signal transduction component for negative regulation of the growth-differentiation transition in Dictyostelium discoideum

Discoidin I expression was used as a marker to screen for mutants affected in the growth-differentiation transition (GDT) of Dictyostelium. By REMI mutagenesis we have isolated mutant 2-9, an overexpressor of discoidin I. It displays normal morphogenesis but shows premature entry into the developmental cycle. The disrupted gene was denominated gdt1. The mutant phenotype was reconstructed by disruptions in different parts of the gene, suggesting that all had a complete loss of function. gdt1 was expressed in growing cells; the levels of protein and mRNA appear to increase with cell density and rapidly decrease with the onset of development. gdt1 encodes a 175-kDa protein with four putative transmembrane domains. In the C terminus, the derived amino acid sequence displays some similarity to the catalytic domain of protein kinases. Mixing experiments demonstrate that the gdt1(-) phenotype is cell autonomous. Prestarvation factor is secreted at wild-type levels. The response to folate, a negative regulator of discoidin expression, was not impaired in gdt1 mutants. Cells that lack the G protein alpha2 display a loss of discoidin expression and do not aggregate. gdt1(-)/Galpha2(-) double mutants show no aggregation but strong discoidin expression. This suggests that gdt1 is a negative regulator of the GDT downstream of or in a parallel pathway to Galpha2.     

Mutants of Dictyostelium discoideum blocked in expression of all members of the developmentally regulated discoidin multigene family

Mutant strains of D. discoideum are described that can complete morphogenesis and cytodifferentiation but which express vastly reduced levels of the galactose-binding lectins discoidin I and II (less than 1% and 1%-2% respectively) compared to the wild-type control. Mutant cells proceeding through development lack lectin activity, lectin protein, and specific lectin mRNA. In contrast, the genes encoding these proteins are present in their wild-type configurations in the genome. Since these proteins are encoded by four to five discrete genes, the mutations in these strains are most likely in genes involved in the regulation of the expression of members of this multigene family. The results also indicate that the discoidin lectins may not be required for fruiting body construction in this organism. Finally, coupled with the recent ability to transform D. discoideum, these mutants open the way to identification and isolation of regulatory genes and their products.     

Interaction of gdt1 and protein kinase A (PKA) in the growth-differentiation-transition in Dictyostelium

The gdt1 gene is a negative regulator of the growth-differentiation-transition (GDT) in Dictyostelium. gdt1- cells express the GDT marker discoidin earlier and at higher levels and prematurely enter the differentiation pathway. Protein kinase A is a positive regulator of the GDT and is required for multicellular development. Disruption of the PKA catalytic subunit or overexpression of a constitutively active mutant of the regulatory subunit results in cells which do not form multicellular aggregates and which show strongly reduced levels of discoidin. We have created PKA-/gdt1- double mutants and show that these display high levels of discoidin expression but no aggregation, suggesting that gdt1 may be a downstream target of PKA in a branched signaling cascade initiating differentiation. Data obtained with the PKA inhibitor H89 support these result: in wild type cells H89 inhibits discoidin expression while in gdt1- mutants there is no obvious effect. However, since PKA-/gdt1- cells display less discoidin expression than the single gdt1 mutant, we propose that PKA and gdt1 are in two parallel interacting pathways. To get insight into the mechanism how PKA may block gdt1, we have tested two putative PKA phosphorylation sites in the protein and found that one of them is efficiently phosphorylated by PKA in vitro. A model for the interplay between PKA and gdt1 during the growth-differentiation-transition is discussed.     

A cysteine-rich extracellular protein containing a PA14 domain mediates quorum sensing in Dictyostelium discoideum

Much remains to be understood about quorum-sensing factors that allow cells to sense their local density. Dictyostelium discoideum is a simple eukaryote that grows as single-celled amoebae and switches to multicellular development when food becomes limited. As the growing cells reach a high density, they begin expressing discoidin genes. The cells secrete an unknown factor, and at high cell densities the concomitant high levels of the factor induce discoidin expression. We report here the enrichment of discoidin-inducing complex (DIC), an ~400-kDa protein complex that induces discoidin expression during growth and development. Two proteins in the DIC preparation, DicA1 and DicB, were identified by sequencing proteolytic digests. DicA1 and DicB were expressed in Escherichia coli and tested for their ability to induce discoidin during growth and development. Recombinant DicB was unable to induce discoidin expression, while recombinant DicA1 was able to induce discoidin expression. This suggests that DicA1 is an active component of DIC and indicates that posttranslational modification is dispensable for activity. DicA1 mRNA is expressed in vegetative and developing cells. The mature secreted form of DicA1 has a molecular mass of 80 kDa and has a 24-amino-acid cysteine-rich repeat that is similar to repeats in Dictyostelium proteins, such as the extracellular matrix protein ecmB/PstA, the prespore cell-inducing factor PSI, and the cyclic AMP phosphodiesterase inhibitor PDI. Together, the data suggest that DicA1 is a component of a secreted quorum-sensing signal regulating discoidin gene expression during Dictyostelium growth and development.     

cAMP production by adenylyl cyclase G induces prespore differentiation in Dictyostelium slugs

Encystation and sporulation are crucial developmental transitions for solitary and social amoebae, respectively. Whereas little is known of encystation, sporulation requires both extra- and intracellular cAMP. After aggregation of social amoebae, extracellular cAMP binding to surface receptors and intracellular cAMP binding to cAMP-dependent protein kinase (PKA) act together to induce prespore differentiation. Later, a second episode of PKA activation triggers spore maturation. Adenylyl cyclase B (ACB) produces cAMP for maturation, but the cAMP source for prespore induction is unknown. We show that adenylyl cyclase G (ACG) protein is upregulated in prespore tissue after aggregation. acg null mutants show reduced prespore differentiation, which becomes very severe when ACB is also deleted. ACB is normally expressed in prestalk cells, but is upregulated in the prespore region of acg null structures. These data show that ACG induces prespore differentiation in wild-type cells, with ACB capable of partially taking over this function in its absence.     

The amoebal cell of Physarum polycephalum: colony formation and growth.

Two stages of colony growth were observed during microscopic studies of Physarum polycephalum amoebae. During the first stage, “spreading growth,” the colony is composed of dispersed single cells. During the second stage, “aggregate growth,” most of the active cells in a colony are aggregated in a ring at the colony boundary. Measurements of cell movement as a function of bacterial concentration indicate that, during both spreading and aggregate growth, cell movements are not affected by changes in bacterial concentration but that the transition from spreading to aggregate growth occurs earlier on plates with lower bacterial concentrations. These results indicate that autonomous characteristics of the amoebae are more important for the determination of colony form than local variations in the concentrations of nutrients.The genetic determination of colony form is demonstrated by the existence of mutants that display specific alterations in colony morphology. Because the aggregate rings of these mutants move at an increased rate, mutant clones appear as variant sectors of wild-type colonies. The increased rate of mutant ring movement suggests that this selection method may be a useful technique for isolating mutant myxamoebae with defects in movement and behavior.     

Phenotypic suppression of morphogenetic mutants of Dictyostelium discoideum.

The effects of cAMP pulses on the capacity of 15 aggregateless mutants to differentiate and construct fruiting bodies are compared to those obtained when mutant cells are starved with wild-type amoebae. Mutant strains are classified into three main groups depending upon the degree to which their phenotypic defects can be corrected. These data extend studies published earlier [Darmon, M., Brachet, P., and Pereira da Silva, L. (1975). Chemotactic signals induce cell differentiation in Dictyostelium discoideum. Proc. Nat. Acad. Sci. USA72, 3163–3166; Pereira da Silva, L., Darmon, M., Brachet, P., Klein, C., and Barrand, P. (1975). Induction of cell differentiation by the chemotactic signal in Dictyostelium discoideum. In “Proceedings of the Tenth FEBS Meeting,” pp. 269–276]. (1) Only one mutant was unresponsive both to cAMP pulses and to the presence of wild-type amoebae and did not display any of the properties of differentiated cells. (2) Following treatment with cAMP pulses, 11 mutants developed certain properties of aggregation-competent amoebae. They increased their levels of cellular phosphodiesterase, showed an enhanced chemotactic sensitivity to cAMP, and established specific cell contacts. None of these amoebae could differentiate further. They did co-aggregate to some extent with wild-type cells, but failed to differentiate into spores. Rather, mutant cells were excluded from the pseudoplasmodium during the process of morphogenesis of the fruiting body. (3) In contrast, the aggregateless phenotype of three mutants was fully corrected by both cAMP pulses and the presence of wild-type cells. These findings are discussed on the basis of a relationship between the chemotactic signal and cell differentiation.     

The role of regulation of cell speed in the behavior of Physarum polycephalum amoebae

Studies on the behavior of wild-type and mutant Physarum polycephalum amoebae have revealed that regulation of cell speed results in different patterns of cell dispersion in different environments and have shown that P. polycephalum can be used for genetic studies of the mechanisms responsible for this element of cell behavior. Colonies generated by clonal populations of amoebae growing on E. coli display alternate colony morphologies depending on the pH of the culture medium and the presence of live E. coli as a nutrient. In the larger ‘spreading colonies’ cells at the outside of a colony are dispersed over a wide band of bacteria while in the smaller ‘aggregate ring colonies’ most cells moving on bacteria are aggregated in a regularly shaped ring on a narrow band of bacteria at the border of the bacterial lawn created when amoebae completely consume the bacteria available in the colony center. Measurements of cell growth, the rate of colony expansion, and the rate of single cell movement show that cells in contact with bacteria move more slowly in aggregate ring than in spreading colonies. Moreover, since in aggregate ring colonies the rate of movement of cells in contact with bacteria is also reduced relative to that of cells moving on adjacent regions of the agar surface, inhibition of cell speed appears to be at least partially responsible for generating the aggregate ring morphology. Characterization of the behavior of a single locus mutant which generates spreading colonies under conditions where aggregate ring colonies are normally formed has provided additional evidence that a specific mechanism is involved in controlling the distribution of amoebae through regulation of cell speed. Furthermore, the studies of this mutant have shown that aberrant colony morphology can be used as an easily recognized phenotype for identifying and studying mutants with defects which affect the regulation of cell speed.     

Interaction of gdt1 and protein kinase A (PKA) in the growth-differentiation-transition in Dictyostelium

Abstract The gdt1 gene is a negative regulator of the growth-differentiation-transition (GDT) in Dictyostelium . gdt1 ⁻ cells express the GDT marker discoidin earlier and at higher levels and prematurely enter the differentiation pathway. Protein kinase A is a positive regulator of the GDT and is required for multicellular development. Disruption of the PKA catalytic subunit or overexpression of a constitutively active mutant of the regulatory subunit results in cells which do not form multicellular aggregates and which show strongly reduced levels of discoidin. We have created PKA ⁻/gdt1⁻ double mutants and show that these display high levels of discoidin expression but no aggregation, suggesting that gdt1 may be a downstream target of PKA in a branched signalling cascade initiating differentiation. Data obtained with the PKA inhibitor H89 support these result: in wild type cells H89 inhibits discoidin expression while in gdt1 ⁻ mutants there is no obvious effect. However, since PKA⁻/gdt1⁻ cells display less discoidin expression than the single gdt1 mutant, we propose that PKA and gdt1 are in two parallel interacting pathways.
To get insight into the mechanism how PKA may block gdt1, we have tested two putative PKA phosphorylation sites in the protein and found that one of them is efficiently phosphorylated by PKA in vitro. A model for the interplay between PKA and gdt1 during the growth-differentiation-transition is discussed.     

Chemotactic response of wild-type and aggregation-defective mutants of Polysphondylium violaceum

Abstract. The aggregation-specific chemoattractant for Polysphondylium violaceum is N-propionyl-γ-L-glutamyl-L-ornithine-δ-lactam ethyl ester, or glorin. Wild-type amoebae allowed to develop in liquid culture acquire increased ability to respond to glorin shortly after starvation, i.e., just prior to the time they become aggregation competent. Similarly, as development proceeds, the amoebae show decreased sensitivity to folic acid, but they show almost no response to cyclic AMP at any time during their development in liquid culture. The optimum concentrations for the chemotactic response are 10^-8 M for glorin and 10^-5–10^-6 M for folic acid. A class of aggregation-defective mutants, aggA , will not aggregate in the absence of an excreted pheromone, D factor. During development in liquid culture in the presence or absence of D factor, these aggA mutants show a chemotactic response similar to that of wild-type amoebae to folic acid and glorin. However, D factor does enhance the chemotactic response of aggA mutants to glorin. In the absence of D factor, mutant amoebae will form fruiting bodies if exposed to a chemotactic gradient of either folic acid or glorin. Under these conditions, the mutant amoebae circumvent the requirement for D factor in order to develop.     

A temperature-sensitive adenylyl cyclase mutant of Dictyostelium

Dictyostelium development starts with the chemotactic aggregation of up to 10(6) amoebae in response to propagating cAMP waves. cAMP is produced by the aggregation stage adenylyl cyclase (ACA) and cells lacking ACA (aca null) cannot aggregate. Temperature-sensitive mutants of ACA were selected from a population of aca null cells transformed with a library of ACA genes, a major segment of which had been amplified by error-prone PCR. One mutant (tsaca2) that can complement the aggregation null phenotype of aca null cells at 22 degrees C but not at 28 degrees C was characterized in detail. The basal catalytic activity of the enzyme in this mutant was rapidly and reversibly inactivated at 28 degrees C. Using this mutant strain we show that cell movement in aggregates and mounds is organized by propagating waves of cAMP. Synergy experiments between wild-type and tsaca2 cells, shifted to the restrictive temperature at various stages of development, showed that ACA plays an important role in the control of cell sorting and tip formation.     

Role of spectrin in Amoeba proteus, as studied by microinjection of anti-spectrin monoclonal antibodies.

Spectrin is a major protein accounting for about 5% of whole-cell proteins in Amoeba proteus, and the precipitation of spectrin by intracellular injection of purified anti-spectrin monoclonal antibodies has a profound effect on cell morphology, motility, and movement-related cell activities in amoebae. Thus, amoebae injected with anti-spectrin antibodies show drastic changes in their shape and movement, suggesting that amoeba spectrin plays an important structural role, unlike nonerythroid spectrins in other cells. However, precipitation of spectrin does not affect the distribution of F-actin in amoebae.     

CbfA, the C-module DNA-binding factor, plays an essential role in the initiation of Dictyostelium discoideum development

We recently isolated from Dictyostelium discoideum cells a DNA-binding protein, CbfA, that interacts in vitro with a regulatory element in retrotransposon TRE5-A. We have generated a mutant strain that expresses CbfA at <5% of the wild-type level to characterize the consequences for D. discoideum cell physiology. We found that the multicellular development program leading to fruiting body formation is highly compromised in the mutant. The cells cannot aggregate and stay as a monolayer almost indefinitely. The cells respond properly to prestarvation conditions by expressing discoidin in a cell density-dependent manner. A genomewide microarray-assisted expression analysis combined with Northern blot analyses revealed a failure of CbfA-depleted cells to induce the gene encoding aggregation-specific adenylyl cyclase ACA and other genes required for cyclic AMP (cAMP) signal relay, which is necessary for aggregation and subsequent multicellular development. However, the cbfA mutant aggregated efficiently when mixed with as few as 5% wild-type cells. Moreover, pulsing cbfA mutant cells developing in suspension with nanomolar levels of cAMP resulted in induction of acaA and other early developmental genes. Although the response was less efficient and slower than in wild-type cells, it showed that cells depleted of CbfA are able to initiate development if given exogenous cAMP signals. Ectopic expression of the gene encoding the catalytic subunit of protein kinase A restored multicellular development of the mutant. We conclude that sensing of cell density and starvation are independent of CbfA, whereas CbfA is essential for the pattern of gene expression which establishes the genetic network leading to aggregation and multicellular development of D. discoideum.     

Defective discoidin domain structure,subunit assembly,and endoplasmic reticulum processing of retinoschisin are primary mechanisms responsible for X-linked retinoschisis

Retinoschisin is a 24-kDa discoidin domain-containing protein that is secreted from photoreceptor and bipolar cells as a large disulfide-linked multisubunit complex. It functions as a cell adhesion protein to maintain the cellular organization and synaptic structure of the retina. Over 125 different mutations in the RS1 gene are associated with X-linked juvenile retinoschisis, the most common form of early onset macular degeneration in males. To identify molecular determinants important for retinoschisin structure and function and elucidate molecular and cellular mechanisms responsible for X-linked juvenile retinoschisis, we have analyzed the expression, protein folding, disulfide-linked subunit assembly, intracellular localization, and secretion of wild-type retinoschisin, 15 Cys-to-Ser variants and 12 disease-linked mutants. Our studies, together with molecular modeling of the discoidin domain, identify Cys residues involved in intramolecular and intermolecular disulfide bonds essential for protein folding and subunit assembly. We show that misfolding of the discoidin domain, defective disulfide-linked subunit assembly, and inability of retinoschisin to insert into the endoplasmic reticulum membrane as part of the protein secretion process are three primary mechanisms responsible for the loss in the function of retinoschisin as a cell adhesion protein and the pathogenesis of X-linked juvenile retinoschisis.     

Differences in accumulation and phosphorylation of proteins in vegetatively growing and aggregation-competent cells of Dictyostelium discoideum.

A comparison of proteins from whole cell lysates of vegetative amoebae and aggregation-competent cells by high-resolution two-dimensional gel electrophoresis coupled with a sensitive silver staining method revealed distinct differences. In aggregation-competent cells, 16 proteins present in the vegetative amoebae disappeared, and 25 new proteins appeared. A few other proteins showed quantitative variation during the transition of vegetative amoebae to aggregation competence. Identification of phosphoproteins by in vivo labeling with [32P]orthophosphate showed that none of the developmentally regulated cellular proteins were modified. Phosphorylation was observed in four proteins. One protein was phosphorylated exclusively in aggregation-competent cells. The phosphorylation level of two other proteins was higher in aggregation-competent cells compared with vegetative amoebae. The data suggest that phosphorylation of cellular and certain ribosomal proteins may be regulated coordinately in Dictyostelium discoideum.     

Re-expression of ABP-120 rescues cytoskeletal, motility, and phagocytosis defects of ABP-120- Dictyostelium mutants.

The actin binding protein ABP-120 has been proposed to cross-link actin filaments in nascent pseudopods, in a step required for normal pseudopod extension in motile Dictyostelium amoebae. To test this hypothesis, cell lines that lack ABP-120 were created independently either by chemical mutagenesis or homologous recombination. Different phenotypes were reported in these two studies. The chemical mutant shows only a subtle defect in actin cross-linking, while the homologous recombinant mutants show profound defects in actin cross-linking, cytoskeletal structure, pseudopod number and size, cell motility and chemotaxis and, as shown here, phagocytosis. To resolve the controversy as to what the ABP-120- phenotype is, ABP-120 was re-expressed in an ABP-120- cell line created by homologous recombination. Two independently "rescued" cell lines that express wild-type levels of ABP-120 were analyzed. In both rescued cell lines, actin incorporation into the cytoskeleton, pseudopod formation, cell morphology, instantaneous velocity, phagocytosis, and chemotaxis were restored to wild-type levels. There is no alteration in the expression levels of several related actin binding proteins in either the original ABP-120- cell line or in the rescued cell lines, leading to the conclusion that neither the aberrant phenotype observed in ABP-120- cells nor the normal phenotype reasserted in rescued cells can be attributed to alterations in the levels of other abundant and related actin binding proteins. Re-expression of ABP-120 in ABP-120- cells reestablishes normal structural and behavioral parameters, demonstrating that the severity and properties of the structural and behavioral defects of ABP-120- cell lines produced by homologous recombination are the direct result of the absence of ABP-120.