Helical Lévy Walks: Adjusting Searching Statistics to Resource Availability in Microzooplankton

Helical Lévy Walks: Adjusting Searching Statistics to Resource Availability in Microzooplankton

The searching trajectories of different animals can be described with a broad class of flight length (Ij) distributions with P(Ij) = Ij -μ. Theoretical studies have shown that changes in these distributions (i.e., different μ values) are key to optimizing the long-term encounter statistics under cer...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 100; no. 22; pp. 12771 - 12775
Main Authors: Bartumeus, Frederic, Peters, Francesc, Pueyo, Salvador, Marrasé, Cèlia, Catalan, Jordi
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 28-10-2003
National Acad Sciences
Subjects:
Animals
Biological Sciences
Dinoflagellida - physiology
Flagella
Flight time
Marinas
Marine
Marine ecology
Models, Biological
Movement
Musical intervals
Oxyrrhis marina
Predation
Predators
Predatory Behavior
Random walk
Retraining
Rhodomonas
Searching behavior
Swimming
Trajectories
Zooplankton - physiology
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Summary:The searching trajectories of different animals can be described with a broad class of flight length (Ij) distributions with P(Ij) = Ij -μ. Theoretical studies have shown that changes in these distributions (i.e., different μ values) are key to optimizing the long-term encounter statistics under certain searcher-resource scenarios. In particular, they predict the advantage of Lévy searching (μ ≈ 2) over Brownian motion (μ ≥ 3) for low-prey-density scenarios. Here, we present experimental evidence of predicted optimal changes in the flight-time distribution of a predator's walk in response to gradual density changes of its moving prey. Flight times of the dinoflagellate Oxyrrhis marina switched from an exponential to an inverse square power-law distribution when the prey (Rhodomonas sp.) decreased in abundance. Concomitantly, amplitude and frequency of the short-term helical path increased. The specific biological mechanisms involved in these searching behavioral changes are discussed. We suggest that, in a three-dimensional environment, a stronger helical component combined with a Lévy walk searching strategy enhances predator's encounter rates. Our results support the idea of universality of the statistical laws in optimal searching processes despite variations in the biological details of the organisms.
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content type line 23
Edited by Simon A. Levin, Princeton University, Princeton, NJ, and approved August 22, 2003
Abbreviations: HFR, high-frequency regime; LFR, low-frequency regime.
This paper was submitted directly (Track II) to the PNAS office.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2137243100