Negative chemotaxis, where eukaryotic cells migrate away from repellents, is important throughout biology, for example in nervous system patterning and resolution of inflammation. However, the mechanisms by which molecules repel migrating cells are unknown. Here, we use a combination of modelling and experiments with Dictyostelium cells to show that competition between different ligands that bind to the same receptor leads to effective chemorepulsion. 8-CPT-cAMP, widely described as a simple chemorepellent, is inactive on its own, and only repels cells if it interacts with the attractant cAMP. If cells degrade either competing ligand, the pattern of migration becomes more complex; cells may be repelled in one part of a gradient but attracted elsewhere, leading to populations moving in different directions in the same assay, or converging in an arbitrary place. More counterintuitively still, two chemicals can each attract cells on their own, but repel cells when combined together. We have thus identified a new mechanism that drives reverse chemotaxis, verified by mathematical models and experiments with real cells, and important anywhere several ligands compete for the same receptors.
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