Agent-based modelling and time series inference of filamentous yeast colonies
Agent-based modelling and time series inference of filamentous yeast colonies
The baker’s yeast Saccharomyces cerevisiae can form invasive filamentous colonies with non-uniform spatiotemporal patterns. We aimed to better understand how individual cellular actions give rise to colony-scale patterns. We used an off-lattice agent-based model to simulate colony growth, and used a neural likelihood estimator (NLE) to infer parameters for experimental photographs. Li et al. [1] used approximate Bayesian computation (ABC) to infer parameters using coarse summary statistics obtained from a single time point averaged across experimental replicates. The NLE overcomes the computational expense of ABC, allowing us to infer the parameters of individual colonies from a full time series of experimental photographs. To demonstrate the capabilities of our model and inference technique, we tested extensively on synthetic data and then predicted yeast growth under three different experimental conditions. As before, the proportion of total colony growth above which pseudohyphal growth is permitted was a key parameter that contributed to colony morphology. Since our NLE-based approach incorporates time series data, it yielded better parameter estimates and more accurate predictions compared to our ABC-based method. This updated approach improved understanding of how the probability that a stated cell produces a pseudohyphal cell influences colony morphology. In this way, the model also has the potential to generate hypotheses, which can be tested through biological experiments to increase the understanding of the basis for different growth patterns in yeast.
Li, Kai
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Tam, Alexander K.Y.
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Gardner, Jennifer M.
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Sundstrom, Joanna F.
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Jiranek, Vladimir
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Green, J. Edward F.
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Binder, Benjamin J.
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Black, Andrew J.
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17 September 2025
Li, Kai
f6a9f82f-dcfa-4c2f-b9fc-486a58755c19
Tam, Alexander K.Y.
ec2f1e67-95c8-4777-9e76-a499f084abb5
Gardner, Jennifer M.
0d95188b-206d-4817-8437-e163351f6e7f
Sundstrom, Joanna F.
7fce4ea1-7811-43ac-a96c-8e396a01c37a
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7
Green, J. Edward F.
79f22dac-8b72-45d9-8e6a-1b9c93ea8afd
Binder, Benjamin J.
4b861311-8ad2-417c-903a-1d35e541d14b
Black, Andrew J.
f141d87a-ca48-41d4-bd9f-d9bd21e5a2c1
[Unknown type: UNSPECIFIED]
Abstract
The baker’s yeast Saccharomyces cerevisiae can form invasive filamentous colonies with non-uniform spatiotemporal patterns. We aimed to better understand how individual cellular actions give rise to colony-scale patterns. We used an off-lattice agent-based model to simulate colony growth, and used a neural likelihood estimator (NLE) to infer parameters for experimental photographs. Li et al. [1] used approximate Bayesian computation (ABC) to infer parameters using coarse summary statistics obtained from a single time point averaged across experimental replicates. The NLE overcomes the computational expense of ABC, allowing us to infer the parameters of individual colonies from a full time series of experimental photographs. To demonstrate the capabilities of our model and inference technique, we tested extensively on synthetic data and then predicted yeast growth under three different experimental conditions. As before, the proportion of total colony growth above which pseudohyphal growth is permitted was a key parameter that contributed to colony morphology. Since our NLE-based approach incorporates time series data, it yielded better parameter estimates and more accurate predictions compared to our ABC-based method. This updated approach improved understanding of how the probability that a stated cell produces a pseudohyphal cell influences colony morphology. In this way, the model also has the potential to generate hypotheses, which can be tested through biological experiments to increase the understanding of the basis for different growth patterns in yeast.
Text
2025.09.15.676253v1.full
- Author's Original
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Published date: 17 September 2025
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Local EPrints ID: 509864
URI: http://eprints.soton.ac.uk/id/eprint/509864
PURE UUID: e2b54153-9e8c-41a8-a495-49ee9d0005b6
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Date deposited: 09 Mar 2026 17:42
Last modified: 10 Mar 2026 03:08
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Contributors
Author:
Kai Li
Author:
Alexander K.Y. Tam
Author:
Jennifer M. Gardner
Author:
Joanna F. Sundstrom
Author:
Vladimir Jiranek
Author:
J. Edward F. Green
Author:
Benjamin J. Binder
Author:
Andrew J. Black
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