Dictyostelium amebae alter motility differently in response to increasing versus decreasing temporal gradients of cAMP (original) (raw)
Related papers
Cell Motility and the Cytoskeleton, 1987
In an aggregation territory of Dictyostelium discoideum, outwardly moving, nondissipating waves of the chemoattractant cAMP sweep across each ameba. At the front of each wave, an ameba experiences an increasing temporal and a positive spatial gradient of CAMP. At the back of a wave, an ameba experiences a decreasing temporal and a negative spatial gradient of CAMP. Employing a perfusion chamber, we have mimicked the temporal dynamics of these waves in the absence of a spatial gradient and demonstrated that the frequency of lateral pseudopod formation and the frequency of turning are dramatically affected by the direction and dynamics of the temporal gradient. In addition, since an ameba will move in a directed fashion up a shallow, nonpulsatile gradient of CAMP, we also mimicked the increasing temporal gradient generated by an ameba moving up a shallow spatial gradient. The frequency of lateral pseudopod formation and the frequency of turning were depressed. Together, these results demonstrate that amebae can assess the direction of a temporal gradient of chemoattractant in the absence of a spatial gradient and alter both the frequency of pseudopod extension and turning, accordingly. Although these results do not rule out the involvement of a spatial mechanism in assessing a spatial gradient, they strongly suggest that the temporal dynamics of a cAMP wave or the temporal gradient generated by an ameba moving through a spatial gradient may play a major role in chemotaxis.
Unstable cAMP wave patterns during aggregation of Dictyostelium discoideum cells
Physics Letters, 2020
Flow-driven formation of unstable patterns of cyclic adenosine monophosphate (cAMP) is investigated in the Martiel-Goldbeter (MG) model. This is predicted via a complex Ginzburg-Landau equation, derived from the MG model, under the so-called modulational instability process. Regions of parameters where patterns exist are discussed analytically and verified numerically. Quasi-periodic waves, spiral seeds and chaotic patterns are found to control information driven in a colony of homogeneously distributed Dictyostelium discoideum cells under the change of the extracellular cAMP degradation rate (k e), the production rate of cAMP (σ) and the advection flow velocity (V f). Our results suggest that these quantities play a key role in the efficient regulation of communication within an amoebas colony, and the presence of the flow makes it possible to understand pattern formation process among D. discoideum cells under spontaneous fluid flow in their natural environment.
Local and spatially coordinated movements in Dictyostelium discoideum amoebae during chemotaxis
Cell, 1982
We have studied chemotaxis by individual Dictyostelium discoideum amoebae using strong, local gradients of the chemoattractant cyclic AMP. Gradients were provided by diffusion of cyclic AMP from a microneedle, which could be positioned at various points around the cell. Responses to changes in the gradient indicate how the cell is structurally organized for chemotactic movement. There is a polarity in the responsiveness of the surface to stimulation by cyclic AMP along the length of the amoeba. Furthermore, two aspects of chemotactic movement can be distinguished. The first response to cyclic AMP is a locally generated extension of a hyaline pseudopod from the region of the surface nearest the stimulus. The second response, the flow of cytoplasm in the direction of the stimulus, is coordinated and separate from the first response. The coordination appears to depend on the nucleus or on the microtubule-organizing center.
Journal of muscle research and …, 2002
In the natural aggregation process, Dictyostelium amoebae relay the cAMP signal outwardly through the cell population as symmetric, nondissipating waves. Each cell in turn responds in a specific manner to the different phases of the wave. In the front of each wave, each cell experiences an increasing temporal gradient and positive spatial gradient of cAMP; at the peak of each wave, each cell experiences a cAMP concentration inhibitory to locomotion; and in the back of each wave, each cell experiences a decreasing temporal and negative spatial gradient of cAMP. Protocols are described to analyze the basic motile behavior of mutant cells in the absence of a chemotactic signal, and to test the responsiveness of mutant cells to the individual temporal, spatial and concentration components of a natural wave. The results of such an analysis can then be used to develop realistic models of cell motility and chemotaxis. Examples are described in which this contextual framework has been applied to mutant cell lines. The results of these mutant studies result in a model in which independent parallel regulatory pathways emanating from different phases of the wave effect different phase-specific behaviors.
Folia Biologica, 2008
The cell fixatives formaldehyde and KMnO " at low concentrations reversibly inhibit the movement of D. discoideum amoebae without directly interfering with cell viability. This inhibition of cell movement is accompanied by the decreased attachment of cells to substratum. When the tenacity and attachment of immobilized cells are artificially increased by compressing cells between two glass surfaces, the amoebae begin to move even in the presence of the fixatives. Amoebae starved for 24 hours, subjected to fixatives and a mineral salt solution in which they remained motionless, maintained chemotactic responses to folic acid and only after a few hours of active locomotion became reactive to cAMP, in contrast to amoebae that reacted to cAMP after starvation in the absence of fixatives.
Cell motility and the cytoskeleton, 1987
Amebae of Dictyostelium discoideum normally chemotax to aggregation centers by assessing the direction of outwardly moving, nondissipating waves of the chemoattractant cAMP. However, D. discoideum amebae can also assess the direction of a relatively stable spatial gradient. We demonstrate that amebae migrating towards the "source" of a stable, spatial gradient move faster, extend fewer pseudopodia, and turn less frequently than amebae migrating away from the "source" in the same spatial gradient. In addition, amebae extend lateral pseudopods in a polarized fashion from the anterior half of the cell, and do so as frequently towards the source as away from the source. However, those formed towards the source more often produce a turn than those formed away from the source. These results suggest that there may be two decision-making systems, one localized in the pseudopods, and one along the entire cell body; they support the suggestion that Dictyostelium amebae may...
1999
The motile responses of Dictyostelium discoideum amoebae to a cyclic AMP (cAMP) concentration gradient were examined using a novel assay system. In this system, a cAMP concentration gradient was generated, while the overall cAMP concentration could be either increased or decreased in a chamber containing amoebae. The chemotactic responses of amoebae were examined immediately after they had been subjected to the cAMP concentration gradient. Amoebae moving in random directions in a reference solution ascended a cAMP concentration gradient after they had been exposed to the gradient irrespective of whether there was an increase or a decrease in the overall cAMP concentration. This strongly supports the idea that D. discoideum amoebae can sense a spatial cAMP gradient around them and that this causes their chemoaccumulation behavior. Ascending locomotion became less conspicuous when the amoebae were treated with a homogeneous cAMP solution for approximately 8 min before exposure to a cA...