Cell communication by periodic cyclic-AMP pulses.

At the surface of aggregating cells of the slime mould, Dictyostelium discoideum, two different sites interacting with extracellular cAMP are detectable: binding sites and cycl-nucleotide phosphodiesterase. Both sites are developmentally regulated. An adequate stimulus for the chemoreceptor system in D. discoideum is the change of cAMP concentration in time, rather than concentration per se: long-term binding of cAMP causes only short-term response. The system is, consequently, adapted to the recognition of pulses rather than to steady-state concentrations of cAMP. The ce,lls are, nevertheless, able to sense stationary spatial gradients and to respond to them by chemotactic orientation. The possibility is discussed that they do so by transforming spatial concentration changes into temporal ones, using extending pseudopods as sensors. The cAMP recognition system is part of a molecular network involved in the generation of spatio-temporal patterns of cellular activities. This system controls the periodic formation of chemotactic signals and their propagation from cell to cell. The phosphodiesterase limits the duration of the cAMP pulses and thus sharply separates the periods of signalling; the binding sites at the cell surface are supposed to be the chemoreceptors. The control of cellular activities via cAMP receptors can be studied with biochemical techniques with cell suspensions in which spatial inhomogeneities are suppressed by intense stirring, whereas the temporal aspect of the spatiotemporal pattern is preserved. Under these conditions it can be shown that the extracellular cAMP concentration changes periodically, and that the phase of the cellular oscillator can be shifted by external pulses of cAMP. It can also be shown that small cAMP pulses induce a high output of cAMP, which demonstrates signal amplification, a function necessary for a cellular relay system.     

Cyclic AMP-induced reversible decrease in cAMP-binding to cell surface receptors of Dictyostelium discoideum

Abstract Adaptation may be the result of a change in affinity and/or number of cAMP-binding sites at the cell surface. To test this possibility we used agip 53, a mutant that does not synthesize cAMP in response to cAMP stimulation. cAMP induced a fast decrease in cAMP-binding to aggregation-competent cells, which reached a maximum at 10–20 s and was reversible with a t _0.5 of about 70 s. The decrease in cAMP-binding involved 46000 sites per cell and was mainly due to a reduction in the apparent affinity for cAMP-binding and to a smaller extent to slowly dissociating cAMP. Our results suggest that under these conditions only a fraction of the cAMP-binding sites at the cell surface are involved in transmembrane signalling, which is indeed observed for many of the physiological responses in Dictyostelium discoideum .     

Developmental control of cAMP-induced Ca2+-influx by cGMP: influx is delayed and reduced in a cGMP-phosphodiesterase D deficient mutant of Dictyostelium discoideum

It was previously shown that cGMP enhances cAMP-induced Ca2+-influx in Dictyostelium discoideum. This finding is based on experiments done with strains defective in cGMP-hydrolysis, the streamer F cells. In this work, we show that these chemically mutagenized cells display different properties in their cAMP-induced light-scattering response and cAMP-induced Ca2+-influx compared with a cGMP-phosphodiesterase knock-out strain, pdeD KO, generated by homologous recombination. PdeD KO cells possess a reduced Ca2+-influx that is developmentally regulated. This finding contradicts the result of streamer F cells, where cAMP-induced Ca2+-influx is prolonged and elevated. Both mutants, however, showed a three to four-fold delayed response to cAMP at 3-4h of starvation. Thus, the consequence of an elevated cGMP concentration is a delay and an inhibition of Ca2+-influx and not an enhancement. Results obtained with streamer F cells should therefore be interpreted with caution because the mutation(s) responsible for the divergent phenotype to pdeD KO cells has not been identified. We show by the use of membrane-permeant cGMP-analogues in wild type (wt) cells, permeabilized cells and measurements on isolated vesicles that the cause for the reduced Ca2+-influx seems to be due to developmentally regulated Ca2+-channel inhibition by cGMP.