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Main Authors: Tröger, Lucas, Goirand, Florian, Alim, Karen
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.12825
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author Tröger, Lucas
Goirand, Florian
Alim, Karen
author_facet Tröger, Lucas
Goirand, Florian
Alim, Karen
contents Many cells face search problems, such as finding food, mates or shelter, where their success depends on their search strategy. In contrast to other unicellular organisms, the slime mold Physarum polycephalum forms a giant network-shaped plasmodium while foraging for food. What is the advantage of the giant cell on the verge of multicellularity? We experimentally study and quantify the migration behavior of P. polycephalum plasmodia on the time scale of days in the absence and presence of food. We develop a model which successfully describes its migration in terms of ten data-derived parameters. Using the mechanistic insights provided by our data-driven model, we find that regardless of the absence or presence of food, P. polycephalum achieves superdiffusive migration by performing a self-avoiding run-and-tumble movement. In the presence of food, the run duration statistics change, only controlling the short-term migration dynamics. However, varying organism size, we find that the long-term superdiffusion arises from self-avoidance determined by cell size, highlighting the potential evolutionary advantage that this macroscopically large cell may have.
format Preprint
id arxiv_https___arxiv_org_abs_2409_12825
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Size-dependent self-avoidance enables superdiffusive migration in macroscopic unicellulars
Tröger, Lucas
Goirand, Florian
Alim, Karen
Biological Physics
Many cells face search problems, such as finding food, mates or shelter, where their success depends on their search strategy. In contrast to other unicellular organisms, the slime mold Physarum polycephalum forms a giant network-shaped plasmodium while foraging for food. What is the advantage of the giant cell on the verge of multicellularity? We experimentally study and quantify the migration behavior of P. polycephalum plasmodia on the time scale of days in the absence and presence of food. We develop a model which successfully describes its migration in terms of ten data-derived parameters. Using the mechanistic insights provided by our data-driven model, we find that regardless of the absence or presence of food, P. polycephalum achieves superdiffusive migration by performing a self-avoiding run-and-tumble movement. In the presence of food, the run duration statistics change, only controlling the short-term migration dynamics. However, varying organism size, we find that the long-term superdiffusion arises from self-avoidance determined by cell size, highlighting the potential evolutionary advantage that this macroscopically large cell may have.
title Size-dependent self-avoidance enables superdiffusive migration in macroscopic unicellulars
topic Biological Physics
url https://arxiv.org/abs/2409.12825