Litcius/Paper detail

Cellular memory in eukaryotic chemotaxis depends on the background chemoattractant concentration

Richa Karmakar, Man-Ho Tang, Haicen Yue, Daniel Lombardo, Aravind Karanam, Brian A. Camley, Alex Groisman, Wouter‐Jan Rappel

2021Physical review. E27 citationsDOI

Abstract

Cells of the social amoeba Dictyostelium discoideum migrate to a source of periodic traveling waves of chemoattractant as part of a self-organized aggregation process. An important part of this process is cellular memory, which enables cells to respond to the front of the wave and ignore the downward gradient in the back of the wave. During this aggregation, the background concentration of the chemoattractant gradually rises. In our microfluidic experiments, we exogenously applied periodic waves of chemoattractant with various background levels. We find that increasing background does not make detection of the wave more difficult, as would be naively expected. Instead, we see that the chemotactic efficiency significantly increases for intermediate values of the background concentration but decreases to almost zero for large values in a switch-like manner. These results are consistent with a computational model that contains a bistable memory module, along with a nonadaptive component. Within this model, an intermediate background level helps preserve directed migration by keeping the memory activated, but when the background level is higher, the directional stimulus from the wave is no longer sufficient to activate the bistable memory, suppressing directed migration. These results suggest that raising levels of chemoattractant background may facilitate the self-organized aggregation in Dictyostelium colonies.

Topics & Concepts

ChemotaxisDictyostelium discoideumBistabilityDictyosteliumTraveling waveBackhaul (telecommunications)Stimulus (psychology)BiologyPhysicsBiological systemNeuroscienceComputer scienceMathematicsGeneticsTelecommunicationsPsychologyMathematical analysisGeneReceptorOptoelectronicsWirelessPsychotherapistCellular Mechanics and Interactions3D Printing in Biomedical ResearchMicrofluidic and Bio-sensing Technologies