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.     

The timing of phenotypic suppression of an aggregation defect by an aggregation-stimulating factor from Polyspboadylium violaceum

Abstract. A class of aggregation deficient mutants of Polysphondylium violaceum ( aggA ) had previously been shown to aggregate in the presence of an excreted, dialyzable product (D factor) prepared from wild type amoebae. We have characterized further the development of the aggA mutants in liquid culture. In the absence of an external source of D factor, aggA mutants never become aggregation competent. D factor must be added to the mutants in order for them to be able to aggregate when removed from liquid culture and plated on a surface. The ability of D factor to stimulate the development of aggregation competence can be illustrated with both the aggA mutant and wild type amoebae. D factor is only required by the aggA mutants at a late stage in development of aggregation competence and does not have to be present continuously during incubation. Wild type amoebae provided with additional D factor become aggregation competent earlier than amoebae incubated without additional D factor. These data suggest that the amoebae develop most of the biochemical functions necessary in order to aggregate and that D factor is necessary to trigger aggregation. One of these biochemical functions, development of aggregation-specific adhesion sites, has been shown to occur in the aggA mutant in the absence of D factor.     

Purification, characterization, and partial structure of D factor from Polysphondylium violaceum

The A component of D factor (DfA) was overproduced during development of wild type Polyspondylium violaceum strain China after starvation in liquid medium. Crude DfA excreted by strain China was partially purified by ultrafiltration using Amicon YM10 and YM2 filters with DfA extracted from the filtrate by absorption onto a preparative grade C-18 resin. The concentrated material was further purified on a C-18 analytical column using both acetonitrile:water and methanol:water gradients. This highly purified fraction was a single component with a final specific activity of greater than 10(6) units per mg dry weight. Purified DfA is red having a broad visible absorbance at 500 nm and a ultraviolet (uv) absorbance at 290-300 nm. The red chromophore is sensitive to pH and to oxidation-reduction. 1H and 13C nmr studies with purified DfA indicate that it is a C11 compound with both polar and non-polar regions. The non-polar region has been identified as a hexanone and is the same as the side chain of DIF from Dictyostelium discoideum. Purified DfA has been used in studies with the D factor non-producing mutant, tsg-119 cyc-1 aggA586 (A586), to show that neither production of glorin nor chemotactic sensitivity to glorin are affected by D factor. However, founder cells develop in A586 mutant populations only after addition of D factor. These data suggest that DfA may be necessary for induction of aggregate formation by aggregation-competent amoebae.     

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.     

Developmental regulation of production of an aggregation-stimulating factor from the cellular slime mold Polysphondylium violaceum

An excreted, dialyzable component(s) produced during development of wild-type Polysphondylium violaceum has been previously shown to stimulate aggregation of aggregateless mutants in the complementation group aggA. Production of this aggregation-stimulating factor, called D factor, is greater during development in liquid culture than during development on a surface. after partial purification of crude D factor using high performance liquid chromatography, multiple species are found that retain the ability to stimulate aggregation of the aggA mutants. The three major components (DfA, DfB, and DfC) show decreasing polarity based on purification using reverse-phase chromatography. The proportion of each component secreted varies, depending on the developmental conditions (surface versus liquid) and the time after starvation when the factors are isolated. Preliminary physical and chemical characterization of the three D factor components suggests that they are related.     

Analysis of developmentally defective chemical signaling mutants of Polysphondylium violaceum.

Six aggregation-defective mutants of Polysphondylium violaceum dependent on external addition of the pheromone D factor for aggregation were isolated after nitrosoguanidine mutagenesis. With a screening technique based on synergistic development, D-factor-dependent mutants can be separated from other kinds of aggregateless mutants. Genetic complementation analyses of the newly isolated mutants showed them to be mutant at the aggA locus. Individual mutants exhibited different sensitivities to D factor(s), responding maximally over a 300-fold range of concentrations.     

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.     

Guanidine hydrochloride-induced shedding of a Dictyostelium discoideum plasma membrane fraction enriched in the cyclic adenosine 3',5'-monophosphate receptor

The cell surface cyclic AMP receptor of Dictyostelium discoideum is under study in a number of laboratories with respect to both its role in development of the organism and the physiology of excitation-response coupling. We report here that when starved amoebae are exposed to the chaotrope guanidine hydrochloride at 1.8 M, they shed a particulate cyclic AMP binding activity into the medium. This activity is due to membrane vesicles which originate from the cell surface. The vesicles are enriched up to 150-fold in cyclic AMP binding activity and up to 14-fold in phospholipid content when compared to the starting amoebae. The cyclic AMP binding activity of the membrane vesicles is identical to that of the cell surface receptor with respect to the following properties; (i) it is lacking in preparations from unstarved, vegetative amoebae; (ii) it is not inhibited by cyclic GMP and is stimulated by calcium ions; (iii) it has very rapid rates of association and dissociation of bound cyclic AMP; (iv) it has two classes of binding sites with dissociation constants similar to those of the surface receptors of whole amoebae. The binding activity of the isolated membranes is stable for several days at 4 degrees C and the lower affinity binding sites are stable up to several months when stored at -80 degrees C. Due to enrichment and stability of the receptor in this preparation, it should be highly suitable for many types of studies. The usefulness is enhanced by the fact that the preparation does not contain detectable cyclic AMP phosphodiesterase activity.     

The influence of light and different ATP concentrations on cell aggregation in cyclic AMP sensitive and insensitive species of the cellular slime molds

The influence of light and different concentrations of ATP on cell aggregation in cyclic AMP sensitive (Dictyostelium mucoroides, D. purpureum) and cyclic AMP insensitive species (Polysphondylium violaceum, P. pallidum, D. lacteum) of the cellular slime molds was observed in small and in large amoebal populations.Both light and ATP (optimal concentration:10^-5M) accelerated cell aggregation and increased the number of aggregating centers in large populations. For cyclic AMP sensitive species the effect of ATP in large populations was more pronounced than for the species that do not react to cyclic AMP.A possible explanation for the similar effect of light and ATP has been discussed.     

Cytokinin oxidase activity in the cellular slime mold, Dictyostelium discoideum

The cytokinin N6-(delta 2-isopentenyl)adenine (i6Ade) is produced during the development of the cellular slime mold, Dictyostelium discoideum, and functions in this organism as the immediate precursor of the spore germination inhibitor, discadenine. The metabolism of i6Ade in axenic cultures of D. discoideum Ax-3 amoebae has been investigated in the present study. An enzyme activity that specifically catalyzes the degradation of i6Ade has been detected in Ax-3 amoebae. This enzyme is similar to the cytokinin oxidases present in higher plant systems and cleaves the N6-side chain of i6Ade to form adenine. Discadenine synthase activity was also detected in axenically cultured Ax-3 amoebae. The cytokinin oxidase activity detected in Dictyostelium decreased during aggregation and development of Ax-3 amoebae and in starving Ax-3 amoebae maintained under either fast-shake (230 rpm) or slow-shake (70 rpm) conditions. In the latter case, the fall in enzyme activity was accelerated by treatment with cyclic AMP. In contrast to these results, discadenine synthase activity in Ax-3 amoebae rose sharply during the culmination phase of development, exhibited little change in starving Ax-3 amoebae maintained under fast-shake conditions, and fell under slow-shake conditions unless the amoebae were treated with cyclic AMP. Possible functions of the Dictyostelium cytokinin oxidase and the significance of the i6Ade metabolism observed in vegetative Dictyostelium amoebae are discussed.     

Cell Differentiation in Dictyostelium discoideum

We have shown previously that amoebae of D. discoideum strain V12 M2 starved at low density in the presence of cyclic AMP fail to form either stalk cells or prespore cells; a low molecular weight factor released by cells at high density promotes stalk formation under these conditions but formation of prespore cells requires 'cell contact'. Here we summarise evidence that:
1. Elevated intracellular cyclic AMP levels are required for all developmental gene expression beyond the preaggregative phase, and ammonia antagonises this expression in some way. However, the action of ammonia is not pathway specific.
2.'Cell contact' is a specific requirement for entry into the prespore pathway of gene expression since isolated cells provided with cyclic AMP synthesise much reduced amounts of the presporespecific enzyme uridine diphosphate (UDP) galactose polysaccharide transferase but normal amounts of the pathway-indifferent enzyme glycogen phosphorylase.
3. The 'cell contact' mechanism is uniquely sensitive to low concentrations of pronase. This protease selectively inhibits transferase synthesis and blocks in vitro spore differentiation (in a spore-forming mutant). It does not prevent chemotactic aggregation, stream formation, or stalk cell formation in the presence of cyclic AMP.     

Accumulation of cyclic guanosine 3':5'-monophosphate in the culture medium of growing cells of Escherichia coli.

In an exponentially growing culture of E. coli, the concentration of cyclic guanosine 3′:5′-monophosphate (cyclic GMP) was found to increase in parallel with the bacterial growth. As the cells approach the stationary phase of growth, the increment of cyclic GMP also ceases progressively to reach to a plateau. When cells are separated from the medium by centrifugation, almost all of the cyclic GMP is recovered in the culture supernatant. The amount of cyclic GMP accumulated is proportional to the number of cells present in the culture. These results suggest that a constant number of cyclic GMP molecules is synthesized each generation of E. coli, and is excreted from the cells to accumulate into the medium.     

Effects of Cyclic AMP on Components of the Cell Cycle Machinery Regulating DNA Synthesis in Cultured Astrocytes

Cyclic AMP is a second messenger for various hormones that inhibits cell multiplication and DNA synthesis in cultured astrocytes. We examined the effects of increasing intracellular cyclic AMP on the catalytic (cdks) and regulatory (cyclins and ckis) components of cyclin-dependent protein kinases, which regulate progression of the cell cycle before completion of DNA synthesis, in primary cultured astrocytes and in an astrocytic cell line C.LT.T.1.1. The amount of cdk4 changed little during the cell cycle and was not affected by cyclic AMP. There was little cdk1 and cdk2 in quiescent cells, and their expression increased during the G1-S phases. Cyclic AMP strongly inhibited cdk1 and cdk2 expression. Transforming growth factor beta also inhibited cdk1 expression in primary astrocytes. Cyclic AMP did not affect the two ckis p27KIP1 and p21CIP1. There was little cyclin D1 in quiescent cells, but it increased during the G1 phase and was reduced by cyclic AMP. Cyclin E increased during the G1-S phases and was not affected by cyclic AMP in primary astrocytes. The amount of cyclin A was low in quiescent cells and increased during the G1-S phases. Expression of its mRNA and protein was inhibited by cyclic AMP. The protein kinase activities associated with complexes of cyclins and cdks were increased by growth factors and prevented by cyclic AMP. We conclude that cyclic AMP inhibits progression of the cell cycle in astrocytes at least by preventing the expression of the regulatory subunits, cyclins D1 and A, and catalytic subunits, cdk1 and cdk2, of cyclin-regulated protein kinases. Key Words: Cyclin-dependent protein kinases-Glial cells-Cyclic AMP.     

Siderophore accumulation and phytopathogenicity in Microbotryum violaceum

We investigated the role of the siderophore rhodotorulic acid (RA) accumulation in the host-pathogen interaction of Microbotryum violaceum and Silene latifolia. While the wild-type M. violaceum accumulated RA in the culture medium in response to iron stress, the monogenic mutant 45 of M. violaceum did not accumulate detectable amounts of RA under limiting iron supply. Genetic analysis showed the mutant 45 locus to be 3.8 cM from the centromere, endorsing the pericentric gene clustering of M. violaceum. Crosses of mutant and wild-type strains demonstrated that the lack of siderophore accumulation in mutant 45 did not preclude pathogenesis, hence fungal reproduction.     

On a mathematical model describing the aggregation of amoebae

In this paper an extension of a mathematical model of Keller and Segel (1970) describing the aggregation of amoebae is presented. In their paper (Keller and Segel, 1970) they showed that the onset of the aggregation could be viewed as a spatial instability. Their instability condition involved diffusion constants of the cyclic AMP and of the amoebae as well as a constant describing the chemotactic behavior of the amoebae. In our case we consider a temporal instability that depends only on the kinetics of cyclic AMP production, degradation and transport through the cell wall. Our model then explains the oscillatory behavior of the cyclic AMP in well-stirred suspensions of amoebae. In addition we discuss existence and non-existence of nonuniform steady states of the nonlinear parabolic system involved.     

Studies on sex-organ development. The hormonal regulation of steroidogenesis and adenosine 3'':5''-cyclic monophosphate in embryonic-chick ovary.

1. We investigated the production of steroid hormones by the ovaries of the developing embryonic chick under conditions of organ culture. Radioimmunoassay techniques were used to measure the amount of steroid hormone released into the culture medium. Stimulation of the production of steroid hormones by choriogonadotropin from the urine of pregnant human was dose-dependent. Oestradio and testosterone production was optimal when 20 i.u. of gonadotropic hormone was present in the culture medium 2. During development, both left and right ovaries responded to gonadotropic hormone stimulation with a 2.5-3-fold increase in oestrogen production. However, the right ovary was twice as efficient in testosterone production as the left one. The presence of dibutyryl cyclic AMP in the culture medium of the embryonic ovaries mimicked the effect of the gonadotropic hormone. 3. The human choriogonadotropic hormone stimulated cyclic AMP production in the embryonic ovarian tissue. Thyrotropin, growth hormone and insulin had no stimulating effect. 3-Isobutyl-1-methylxanthine potentiated the gonadotropic hormone effect by increasing the concentration of cyclic AMP in the ovarian tissue. 4. The amount of cyclic AMP synthesized in the embryonic ovary was gradually increased (from 1.2 to 6.5 pmol/mg of tissue) when incubated with increasing doses of human choriogonadotropic hormone in vitro. The newly synthesized cyclic AMP reached the maximum concnentration after 30 min of incubation, then decreased at 2 h of incubation. A portion of the newly synthesized cyclic AMP was released into the culture medium. 5. At various developmental stages, both left and right embryonic-chick ovaries responded to stimulation by gonadotropic hormone with an increase in cyclic AMP production. The cyclic AMP concentration in the right ovary was 80% higher than that in the corresponding left ovary.     

In vitro stimulation of alkaline phosphatase activity in immature embryonic chick pelvic cartilage by adenosine

Cyclic AMP content in embryonic chick pelvic cartilage increases significantly as the embryo ages from 8 to 10 d. This in ovo elevation in cyclic AMP content precedes maximal cartilage alkaline phosphatase activity by some 24 h. We studied whether this temporal relationship may be causally related, using an in vitro organ culture. Incubation of pelvic cartilage from 9- and 10-d embryos in medium containing monobutyryl cyclic AMP (BtcAMP) resulted in significant increases in alkaline phosphatase activity (220 and 66 percent, respectively) as compared to that of cartilages incubated in medium alone. This stimulation was both concentration- and time-dependent with maximal response at 0.5 mM BtcAMP and 4-h incubation, respectively. Similar incubations of cartilage in medium containing 1-methyl-3-isobutyl xanthine (MIX), 0.25 mM, also resulted in increased alkaline phosphatase activity (114 percent). However, pelvic cartilage from 11-d embryos incubated in medium containing BtcAMP or MIX showed no increase in alkaline phosphatase activity. We postulated that developmental age was the factor responsible for this difference in response and that immature cartilage (that with little or no alkaline phosphatase activity) would respond to BtcAMP whereas mature cartilage (that with significant alkaline phosphatase activity) would not. This was tested by incubating end sections of 11-d cartilage, which have little alkaline phosphatase activity, and center sections, which have significantly alkaline phosphatase activity, with both BtcAMP and MIX. Alkaline phosphatase activity in end sections (immature cartilage) was stimulated by BtcAMP and MIX, whereas it was not stimulated in the center sections. Actinomycin D and cycloheximide inhibited BtcAMP and MIX stimulation of alkaline phosphatase activity. Thus, the in vitro data suggest that cyclic AMP is a mediator for the stimulation of alkaline phosphatase activity in embryonic cartilage.     

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.