Chemotaxis and binding of cyclic AMP in cellular slime molds.

To obtain more information about how cyclic AMP mediates cell aggregation as found in some species of the cellular slime molds, we determined the maximal binding activity of cyclic AMP in different species under various environmental conditions. The binding of cyclic AMP is limited to amoebae using this cyclic nucleotide as chemotactic agent. Maximal binding activity proved to coincide with a maximal chemotactic response and to be related to the length of the period between the vegetative and the aggregative phase. Of the species studied, Dictyostelium discoideum has the highest cellular density of cyclic AMP receptors and is the most sensitive to cyclic AMP as attractant. At 15 degrees C, aggregation begins later, chemotaxis takes effect over a greater distance, and the maximal binding activity is higher than 22 degrees C. The number of cyclic AMP receptors is independent of temperature. The delay in the onset of aggregation and the increased chemotactic response in darkness is not due to a change in the maximal binding activity. The binding of cyclic AMP and its inactivation is discussed in the light of cell aggregation.     

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.     

Reciprocal periodicity in cyclic AMP binding and phosphorylation of differentiating Dictyostelium discoideum cells.

The binding of [³H]cyclic AMP to cell surface receptors of differentiated D. discoideum cells at 25° is an oscillatory process with a periodicity of 2 min. This alternating change in the cells' binding capacity for cyclic AMP may be the basis for the refractory period to cyclic AMP stimulation, an essential feature of the chemotactic system. The incorporation of [³²P] by whole cells from [γ³²P]ATP is also oscillatory with a periodicity identical to that of [³H]cyclic AMP binding. However, the two processes are inversely related in time such that periods of maximal cyclic AMP binding correspond to periods of minimal cellular phosphorylation. These results suggest a receptor kinase/phosphatase mediated desensitization of the cyclic AMP receptor.     

The cyclic AMP receptor of Escherichia coli: Immunological studies in extracts of Escherichia coli and other organisms

An antiserum specific for the cyclic adenosine 3′,5′-monophosphate receptor from Escherichia coli has been employed to detect the presence of a similar protein in cellular extracts of a number of diverse organisms. In Ouchterlony double-diffusion experiments cellular extracts from Photobacterium fisheri, Aerobacter aerogenes, Proteus mirabilis, and Salmonella typhimurium all showed precipitin bands with E. coli cyclic AMP receptor-antiserum. The extract from Caulobacter crescentus exhibited slight cross-reactivity. Similar results were obtained with an immuno-precipitation assay used to quantitate the amount of cyclic AMP receptor-like protein present. Extracts from a variety of organisms were found to bind cyclic AMP when the usual (NH₄)₂SO₄ precipitation assay for cyclic AMP receptor was employed. Only the extract from Methanosarcina barkeri was inactive. Some extracts prepared from E. coli grown on Luria broth were observed to have no cyclic AMP binding activity. Antiserum was used to determine the presence of cyclic AMP receptor in these inactive extracts. These preparations usually regain binding activity on standing at 4°C for 2–3 days.     

On the mechanism of action of cholera toxin on isolated rat adrenocortical cells Comparison with the effects of adrenocorticotropin on steroidogenesis and cyclic AMP output

The effects of cholera toxin on isolated rat adrenocortical cells have been investigated. Both steroid and cyclic AMP output from adrenal cells were increased by the toxin in a dose dependent fashion. The concentration of toxin for half maximal stimulation for both of these responses was about 40 ng/ml. Maximal steroidogenesis and cyclic AMP output was obtained with similar concentrations of the toxin. A correlation was observed between the low amounts of cyclic AMP produced in response to all doses of cholera toxin and to physiologically significant concentrations of adrenocorticotropin (ACTH) (< 0.1 munit/ml; i.e. submaximal for steroidogenesis in this system). This was in direct contrast to the much higher levels of cyclic AMP generated by concentrations of ACTH greater than 1 munits/ml. Time course studies demonstrated a time-lag between toxin addition and steroid response of at least 40 min. Binding of cholera toxin to adrenal cells was rapid and was 90% complete within 15 min at both 37 and 0°C. These data indicate that most of the delay in response to cholera toxin is due to processes subsequent to the initial binding interaction. Following the initial delay the subsequent maximal rate of steroidogenesis brought about by cholera toxin was very similar to that obtained with a concentration of ACTH that was maximal for steroidogenesis. Significant increases in cyclic AMP levels were detected about 20 min before increased steroidogenesis was apparent. Possible explanations for this result are considered. The results presented indicate great potential use for cholera toxin in the study of adrenal steroidogenic control mechanisms, particularly at the level of receptor mechanisms and the role of cyclic AMP.     

Analogs of cyclic AMP as chemoattractants and inhibitors of Dictyostelium chemotaxis.

Aggregative amoebae of Dictyostelium discoideum, D. mucoroides, D. purpureum, and D. rosarium react chemotactically to cyclic AMP (cAMP). We measured the chemotactic activity of 14 cAMP analogs and found that these four species have a similar sensitivity to chemical modifications of cAMP; this suggests that the cAMP receptor is identical in all of these species. Besides the induction of a chemotactic response, cAMP analogs also may delay or prevent cell aggregation. cAMP analogs like N1-O-cAMP, 2'-H-cAMP, and 5'NH-cAMP are chemotactically nearly as active as cAMP and induced no, or only a short, delay of cell aggregation. Other cAMP derivatives, such as 6-Cl-cPMP and 8-Br-cAMP, are chemotactically active only at high concentrations and delayed cell aggregation for several hours. Still other cAMP analogs, which do not induce a chemotactic reaction in D. mucoroides, D. purpureum, and D. rosarium, either prevented cell aggregation [cAMPS(S), cAMPS(R), and 3'-NH-cAMP[ or had no effect on cell aggregation [cAMPN(CH3)2(S) and cAMPN(CH3)2(R)]. cAMP analog 3'-NH-cAMP prevented cell aggregation by the inhibition of chemotaxis, whereas cell locomotion was not affected. Although we cannot provide a satisfactory explantation for these observations, our data suggest that occupation and activation of the cAMP receptors do not always induced a chemotactic response.     

Streamers: chemotactic mutants of Dictyostelium discoideum with altered cyclic GMP metabolism

Mutants of Dictyostelium discoideum that developed huge aggregation streams in expanding clones were investigated using optical and biochemical techniques. Representatives of the six complementation groups previously identified (stmA-stmF) were found to be similar to the parental wild-type strain XP55 in both the extent and timing of their ability to initiate and relay chemotactic signals and in the formation of cyclic AMP receptors and phosphodiesterases. The mutants differed from the wild-type in producing an abnormal chemotactic (movement) response visible using both dark-field optics with synchronously aggregating amoebae on solid substrata and light scattering techniques with oxygenated cell suspensions. Mutants of complementation group stmF showed chemotactic movement responses lasting up to 520 s, rather than 100 s as seen in the parental and other strains. Measurements of cyclic GMP formed intracellularly in response to chemotactic pulses of cyclic AMP in stmF mutants showed that abnormally high concentrations of this nucleotide were formed within 10 s and were not rapidly degraded. A causal correlation between defective cyclic GMP metabolism and the altered chemotactic response is suggested, and a model is proposed that accounts for the formation of huge aggregation streams in clones of these mutants.U     

Apparent Positive Cooperativity at a Surface cAMP Receptor in Dictyostelium

In the large species of the cellular slime mold Dictyostelium , cell aggregation is regulated by extracellular cAMP. During aggregation, cAMP is released in pulses from cells in the aggregation centers and these rhythmic signals are propagated through the population by a signal relay system. In addition to triggering the relay response, the pulsatile signals also regulate the chemotactic movement of the cells and early cell differentiation. These different cellular responses to exogenous cAMP are thought to be mediated via cAMP receptors, which appear on the cell surface shortly after starvation.
Using a sensitive assay, the equilibrium binding properties of these receptors were analyzed at low cAMP concentrations. As reported earlier, Scatchard plots of cAMP binding to preaggregative amoebae of D. discoideum strain NP187 in the concentration range 2–500 nM were curvilinear suggesting either receptor heterogeneity or negative cooperative interactions. However, at cAMP concentrations below approximately 1.5 nM, the affinity of the receptors was found to decline as a function of decreasing receptor occupancy. This apparent positive cooperativity was observed with binding sites on crude plasma membranes as well as on intact cells, and it occurred at both 0°C and 22°C. Moreover, apparent positive cooperativity was a property of the receptors on all strains of D. discoideum examined and on one strain of D. purpureum . Unlike preaggregative cells, receptors on postaggregative cells often lacked this property.
The lowest concentration of cAMP pulses that can appreciably stimulate membrane differentiation in strain NP187 was found to be 0.15–1.5 nM. Since similar concentrations of exogenous cAMP have been reported to trigger minimal chemotactic and relay responses in D. discoideum , the apparent positive cooperative behavior of the cAMP receptor might function to generate a steep cellular response threshold.     

Enhanced cell aggregation in Dictyostelium discoideum by ATP activation of Cyclic AMP receptors.

Cell aggregation in the cellular slime mold Dictyostelium discoideum is mediated by cyclic AMP. In the presence of ATP the onset of cell aggregation is enhanced and cyclic AMP receptors are activated. The number of phosphorylation sites is species dependent, and two main phosphorylated proteins with MW of, respectively, 20,000 and 15,000 are localized.     

Calcium,cyclic GMP and the control of myosin II during chemotactic signal transduction ofDictyostelium

Evidence is presented for Ca²⁺ and cyclic GMP being involved in signal transduction between the cell surface cyclic AMP receptors and cytoskeletal myosin II involved in chemotactic cell movement. Ca²⁺ is shown to be required for chemotactic aggregation of amoebae. The evidence for uptake and/or eflux of this ion being regulated by the nucleotide cyclic GMP is discussed. The connection between Ca²⁺, cyclic GMP and chemotactic cell movement has been explored using “streamer F” mutants. The primary defect in these mutants is in the structural gene for the cyclic GMP-specific phosphodiesterase which results in the mutants producing an abnormally prolonged peak of accumulation of cyclic GMP in response to stimulation with the chernoattractant cyclic AMP. While events associated with production and relay of cyclic AMP signals are normal, certain events associated with movement are (like the cyclic GMP response) abnormally prolonged in the mutants. These events include Ca²⁺ uptake, myosin II association with the cytoskeleton and inhibition of myosin heavy and light chain phosphorylation. These changes can be correlated with the amoebae becoming elongated and transiently decreasing their locomotive speed after chemotactic stimulation. Other mutants studied in which the accumulation of cyclic GMP in response to cyclic AMP stimulation was absent produced no myosin II responses. Models are described in which cyclic GMP (directly or indirectly via Ca²⁺) regulates accumulation of myosin II on the cytoskeleton by inhibiting phosphorylation of the myosin heavy and light chain kinases.     

ATP increases chemoattractant induced cyclic GMP accumulation in Dictyostelium discoideum

Changes in guanosine cyclic 3′,5′-monophosphate associated with adenosine cyclic 3′,5′-monophosphate and folic acid addition in the presence of ATP have been examined in Dictyostelium discoideum. Preincubation with 1 mM ATP had no effect on the basal cyclic GMP level but increased the cycli GMP accumulation in response to cylci AMP (5·10⁻⁸ M) or folic acid (5·10⁻⁶ M) 40–50%. ATP could not be replaced by ADP of 5′-adenylyliminodiphosphate. Because ATP has no effect on cyclic AMP receptor binding these results indicate that structural membrane alterations (e.g. membrane phosphorylation) may control the transduction of a chemotactic signal.     

Cyclic AMP-stimulating effect of vasoactive intestinal peptide in isolated epithelial cells of rat ventral prostate

Vasoactive intestinal peptide (VIP) has been shown to increase cyclic AMP content in isolated epithelial cells of rat ventral prostate. The stimulatory effect of VIP was dependent on time and temperature and was potentiated by a phosphodiesterase inhibitor. At 15°C, the response occurred in the 1·10⁻¹⁰−10⁻⁷ M range of VIP concentrations. Half-maximal stimulation of cellular cyclic AMP was obtained at 1.4 nM and maximal stimulation (3-fold basal level) at about 100 nM VIP. Chicken VIP and porcine secretin were agonists of porcine VIP but exhibited a 2-times higher and a 170-times lower potency, respectively. A high concentration (1·10⁻⁶ M) of glucagon, somatostatin, neurotensin, substance P, Met-enkephalin or Leu-enkephalin did not modify cAMP levels. The finding of a VIP-stimulated cAMP system in rat prostatic epithelial cells together with the previous characterization of high-affinity receptors for VIP in the same cell preparation, as well as the presence of VIP-containing neurones innervating the male genitourinary tract, strongly suggest that VIP may be involved in prostatic growth regulation and function.     

Transmethylation inhibitors decrease chemotactic sensitivity and delay cell aggregation in Dictyostelium discoideum

In Dictyostelium discoideum, extracellular cyclic AMP (cAMP) induces chemotaxis and cell aggregation. Suspensions of cAMP-sensitive cells respond to a cAMP pulse with a rapid, transient increase of protein carboxyl methylation. The transmethylation inhibitors cycloleucine, L-homocysteine thiolactone, and coformycin decrease chemotactic sensitivity and delay cell aggregation when administered in concentrations which do not influence cAMP binding to cell surface receptors or the activity of total phosphodiesterase. The ability of the drugs to inhibit chemotaxis could be correlated with their capacity to convert the initial transient positive response of carboxyl methylation to cAMP into a negative one. This suggests that both protein O-methyltransferase and protein methylesterase are activated after stimulation of aggregative cells with cAMP, the net effect being a transient, positive response of methylation. In the presence of a sufficiently large dose of inhibitor, methyltransferase is inhibited, whereas methylesterase activity is much less affected, so that a transient negative response of methylation to cAMP is observed. The slow, positive response of carboxyl methylation to cAMP which occurs ca. 2.5 to 5 min after stimulus administration is not affected by inhibitors of transmethylation. These results suggest that methylation reactions are involved in the chemotactic response of D. discoideum cells to cAMP.     

Specific binding proteins for cyclic AMP and cyclic GMP in Dictyostelium discoideum.

In Dictyostelium discoideum both cyclic AMP and cyclic GMP are regulated by chemotactic stimuli. Binding proteins specific for cAMP and cGMP have been found in aggregation competent cells as well as in cells harvested during growth. The activity of binding proteins was, on the average, lower in the growth phase cells. cAMP binding proteins were separated into 3 fractions, whereas the cGMP binding activity appeared in 1 major peak both on DEAE-cellulose and Sephadex G-200. Protein kinase activity was present in most but not all cyclic necleotide binding fractions; evidence for a relationship is however missing.     

Cyclic AMP and calcium exchange in a cellular slime mold

Cyclic AMP is known to be an effective chemotactic agent for amebae of the cellular slime mold D. discoideum. A large amount of information from experiments on metazoa suggested that one cellular effect of cyclic AMP might be to alter the permeability of the cell membrane to Calcium or Sodium ions. On the basis of this information experiments were designed to test the effect of cyclic AMP on outflow of labeled Calcium or Sodium ions from amebae of D. discoideum. It was found that addition of cyclic AMP at 10^?4M resulted in a large increase of Ca⁴⁵ outflow from cells at the pre-aggregative or aggregative stage of development. No effect was found on Na²² outflow. It is suggested that this effect on Calcium permeability of the membrane is related to the chemotactic influence of ATP by some action on the contractile mechanism for ameboid movement. The phenomenon may be distinct from the enzyme inductive activity of cyclic AMP known for bacteria, and perhaps occurring in the cellular slime molds as well.     

Signal transduction and motility ofDictyostelium

This review is concerned with the roles of cyclic GMP and Ca²⁺ ions in signal transduction for chemotaxis ofDictyostelium. These molecules are involved in signalling between the cell surface cyclic AMP receptors and cytoskeletal myosin II involved in chemotactic cell movement. Evidence is presented for uptake and/or eflux of Ca²⁺ being regulated by cyclic GMP. The link between Ca²⁺, cyclic GMP and chemotactic cell movement has been explored using streamer F mutants whose primary defect is in the structural gene for the cyclic GMP-specific phosphodiesterase. This mutation causes the mutants to produce an abnormally prolonged peak of cyclic GMP accumulation in response to stimulation with the chemoattractant cyclic AMP. The production and relay of cyclic AMP signals is normal in these mutants, but certain events associated with movement are (like the cyclic GMP response) abnormally prolonged in the mutants. These events include Ca²⁺ uptake, myosin II association with the cytoskeleton and regulation of both myosin heavy and light chain phosphorylation. These changes can be correlated with changes in the shape of the amoebae after chemotactic stimulation. Other mutants in which the accumulation of cyclic GMP in response to cyclic AMP stimulation was absent produced no myosin II responses.A model is described in which cyclic GMP (directly or indirectly via Ca²⁺) regulates accumulation of myosin II on the cytoskeleton by regulating phosphorylation of the myosin heavy and light chain kinases.     

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.     

Effect of concanavalin A on cellular slime mold development: Premature appearance of membrane-bound cyclic AMP phosphodiesterase

Concanavalin A delays aggregation of slime mold amoebae, apparently by interfering with the cells' response to the chemotactic agent, cyclic AMP. Concanavalin A also induces the premature appearance in non-aggregating cells of a membrane-bound cyclic AMP phosphodiesterase normally found only at the time of aggregation. The appearance of this enzyme is not due to activation of an inactive form of the enzyme.     

Observations on the binding of adenosine 3′:5′-monophosphate to cell membrane fragments from ox cerebral cortex

Microsomal or synaptosome membrane fragments from ox brain bind cyclic AMP with a pH optimum of 7.0. Scatchard analysis shows the presence of at least two binding sites. Cyclic GMP and cyclic IMP only inhibit binding at concentrations 5000 times that of cyclic AMP and even higher concentration ratios of ATP and AMP have no effect. Membrane fragments saturated with cyclic [³H] AMP lost less than 7 % of bound nucleotide on incubation at 0°C for 45 min but lost 25 % in the same period in the presence of 10 μM non-radioactive cyclic AMP.