Inherent High Correlation of Individual Motility Enhances Population Dispersal in a Heterotrophic, Planktonic Protist

Autor: Susanne Menden-Deuer
Jazyk: angličtina
Rok vydání: 2010
Předmět:
0106 biological sciences
Biophysics/Theory and Simulation
Ecology (disciplines)
Population
Marine and Aquatic Sciences
Biology
010603 evolutionary biology
01 natural sciences
Models
Biological
Cellular and Molecular Neuroscience
Cell Movement
Statistics
Genetics
Range (statistics)
Image Processing
Computer-Assisted
Ecology/Behavioral Ecology
education
Molecular Biology
lcsh:QH301-705.5
Ecology
Evolution
Behavior and Systematics
education.field_of_study
Analysis of Variance
Microscopy
Video
Ecology
Markov chain
010604 marine biology & hydrobiology
Autocorrelation
Computational Biology
Reproducibility of Results
Population ecology
Random walk
Plankton
Markov Chains
Computational Theory and Mathematics
lcsh:Biology (General)
Ecology/Theoretical Ecology
Modeling and Simulation
Dinoflagellida
Biological dispersal
Ecology/Environmental Microbiology
Research Article
Zdroj: PLoS Computational Biology
PLoS Computational Biology, Vol 6, Iss 10, p e1000942 (2010)
ISSN: 1553-7358
1553-734X
Popis: Quantitative linkages between individual organism movements and the resulting population distributions are fundamental to understanding a wide range of ecological processes, including rates of reproduction, consumption, and mortality, as well as the spread of diseases and invasions. Typically, quantitative data are collected on either movement behaviors or population distributions, rarely both. This study combines empirical observations and model simulations to gain a mechanistic understanding and predictive ability of the linkages between both individual movement behaviors and population distributions of a single-celled planktonic herbivore. In the laboratory, microscopic 3D movements and macroscopic population distributions were simultaneously quantified in a 1L tank, using automated video- and image-analysis routines. The vertical velocity component of cell movements was extracted from the empirical data and used to motivate a series of correlated random walk models that predicted population distributions. Validation of the model predictions with empirical data was essential to distinguish amongst a number of theoretically plausible model formulations. All model predictions captured the essence of the population redistribution (mean upward drift) but only models assuming long correlation times (minute), captured the variance in population distribution. Models assuming correlation times of 8 minutes predicted the least deviation from the empirical observations. Autocorrelation analysis of the empirical data failed to identify a de-correlation time in the up to 30-second-long swimming trajectories. These minute-scale estimates are considerably greater than previous estimates of second-scale correlation times. Considerable cell-to-cell variation and behavioral heterogeneity were critical to these results. Strongly correlated random walkers were predicted to have significantly greater dispersal distances and more rapid encounters with remote targets (e.g. resource patches, predators) than weakly correlated random walkers. The tendency to disperse rapidly in the absence of aggregative stimuli has important ramifications for the ecology and biogeography of planktonic organisms that perform this kind of random walk.
Author Summary Organism movement is fundamental to how organisms interact with each other and the environment. Such movements are also important on the population level and determine the spread of disease and invasion, reproduction, consumption, and mortality. Theoretical ecologists have sought to predict population dispersal rates, which are often hard to measure, from individual movement behaviors, which are often easier to measure. This problem has been non-trivial. This manuscript contributes seldom available, simultaneously measured movement behaviors and population distributions of a single celled planktonic organism. The empirical data are used to distinguish amongst a set of plausible theoretical modeling approaches to suggest that organism movements are highly correlated, meaning movement direction and speed is consistent over several minutes. Previous estimates suggested persistence only lasted several seconds. Minute-scale correlations result in much more rapid organism dispersal and greater dispersal distance, indicating that organisms encounter and impact a greater portion of their surrounding habitat than previously suspected.
Databáze: OpenAIRE
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