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Swarm Intelligence

Erschienen in:

05.11.2020

Assessing the robustness of decentralized gathering: a multi-agent approach on micro-biological systems

verfasst von: Daniele Proverbio, Luca Gallo, Barbara Passalacqua, Marco Destefanis, Marco Maggiora, Jacopo Pellegrino

Erschienen in: Swarm Intelligence | Ausgabe 4/2020

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Abstract

Adopting a multi-agent systems paradigm, we developed, tested and exploited a computational testbed that simulates gathering features of the social amoeba Dictyostelium discoideum. It features a tailored design and implementation to manage discrete simulations with autonomous agents on a microscopic scale, thus focusing on their social behavior and mutual interactions. Hence, we could assess the behavioral conditions under which decentralized gathering could occur. We investigated the dependence of the model dynamics on the main physical variables, namely density and number of amoebas, gaining indications that the process strongly depends on both. This result integrates previous researches, where density is identified as the sole relevant variable. We determined a high-density and high-numerosity region where assuming a scale-free behavior is safe. We also estimated the systematic uncertainties arising from a number of amoebas off the scale-free region, when coping with limited computational resources. Finally, we probed the robustness of the simulated gathering process against both extrinsic and intrinsic noise sources.

Vorheriger Artikel Self-adaptive potential-based stopping criteria for Particle Swarm Optimization with forced moves

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Alcantara, F., & Monk, M. (1974). Signal propagation during aggregation in the slime mould Dictyostelium discoideum. Microbiology, 85(2), 321–334.

Baker, R., Gaffney, E., & Maini, P. (2008). PDEs for self-organization in cellular and developmental biology. Nonlinearity, 21(11), 251–290.MathSciNetMATH

Bhalla, U. S., & Iyengar, R. (1999). Emergent properties of networks of biological signaling pathways. Science, 283(5400), 381–387.

Bonabeau, E., Dorigo, M., & Theraulaz, G. (1999). Swarm intelligence: From natural to artificial systems. Oxford: Oxford University Press.MATH

Bonner, J. (1970). Induction of stalk cell differentiation by cyclic AMP in the cellular slime mold Dictyostelium discoideum. Proceedings of the National Academy of Sciences, 65(1), 110–113.

Bonner, J. T. (1998). A way of following individual cells in the migrating slugs of Dictyostelium discoideum. Proceedings of the National Academy of Sciences, 95(16), 9355–9359.

Bonner, J., & Savage, L. (1947). Evidence for the formation of cell aggregates by chemotaxis in the development of the slime mold Dictyostelium discoideum. Journal of Experimental Zoology Part A: Ecological Genetics and Physiology, 106(1), 1–26.

Borshchev, A., & Filippov, A. (2004). From system dynamics and discrete event to practical agent based modeling: Reasons, techniques, tools. In Proceedings of the 22nd international conference of the system dynamics society, pp. 959–966.

Bruno in Columbus. (2018). Dictyostelium aggregation. Retrieved from https://bit.ly/2SlZqy2.

Camazine, S., Deneubourg, J.-L., Franks, N., Sneyd, J., Bonabeau, E., & Theraula, G. (2003). Self-organization in biological systems. Princeton: Princeton University Press.MATH

Cantrell, R., & Cosner, C. (2004). Spatial ecology via reaction–diffusion equations. New York: Wiley.MATH

Coates, J., & Harwood, A. (2001). Cell–cell adhesion and signal transduction during Dictyostelium development. Journal of Cell Science, 114(24), 4349–4358.

Dallon, J., Dalton, B., & Malani, C. (2011). Understanding streaming in Dictyostelium discoideum: Theory versus experiments. Bulletin of Mathematical Biology, 73(7), 1603–1626.MathSciNetMATH

Dallon, J., & Othmer, H. (1997). A discrete cell model with adaptive signalling for aggregation of Dictyostelium discoideum. Philosophical Transactions of the Royal Society B: Biological Sciences, 352(1351), 391–417.

Darmon, M., Brachet, P., & Da Silva, L. (1975). Chemotactic signals induce cell differentiation in Dictyostelium discoideum. Proceedings of the National Academy of Sciences, 72(8), 3163–3166.

Devreotes, P. (1989). Dictyostelium discoideum: A model system for cell–cell interactions in development. Science, 245(4922), 1054–1058.

Di Marzo Serugendo, G., Gleizes, M.-P., & Karageorgos, A. (2011). Self-organising software: From natural to artificial adaptation. Berlin: Springer.MATH

Di Criscio, S. (2011). A simple mechanism for complex social behavior. Retrieved from https://bit.ly/2oMYNBD.

Dorigo, M., Birattari, M., Blum, C., Clerc, M., Stützle, T., & Winfield, A. (2008). In Proceedings of ant colony optimization and swarm intelligence: 6th international conference, ANTS 2008, Brussels, Belgium, September 22–24, 2008, Vol. 5217, Springer.

Drasdo, D., Hoehme, S., & Block, M. (2007). On the role of physics in the growth and pattern formation of multi-cellular systems: What can we learn from individual-cell based models? Journal of Statistical Physics, 128(1–2), 287.MathSciNetMATH

Duan, W., Ding, H., Zhu, W., Srinivasan, K., Otterson, G., & Villalona-Calero, M. (2002). cAMP binding protein assay for widespread use in cell signaling studies. Biotechniques, 33(1), 66–72.

Durston, A. (2013). Dislocation is a developmental mechanism in Dictyostelium and vertebrates. Proceedings of the National Academy of Sciences, 110(49), 19826–19831.

Elliott, C., Stinner, B., & Venkataraman, C. (2012). Modelling cell motility and chemotaxis with evolving surface finite elements. Journal of The Royal Society Interface, rsif20120276.

Fates, N. (2008). Gathering agents on a lattice by coupling reaction–diffusion and chemotaxis. inria-00132266v4.

Fey, P., Kowal, A., Gaudet, P., Pilcher, K., & Chisholm, R. (2007). Protocols for growth and development of Dictyostelium discoideum. Nature Protocols, 2(6), 1307.

Futrelle, R., Traut, J., & McKee, W. (1982). Cell behavior in Dictyostelium discoideum: Preaggregation response to localized cyclic AMP pulses. The Journal of Cell Biology, 92(3), 807–821.

Galle, J., Hoffmann, M., & Aust, G. (2009). From single cells to tissue architecture—A bottom-up approach to modelling the spatio-temporal organisation of complex multi-cellular systems. Journal of Mathematical Biology, 58(1–2), 261.MathSciNetMATH

Gierer, A., & Meinhardt, H. (1972). A theory of biological pattern formation. Kybernetik, 12(1), 30–39.MATH

Grignard, A., Taillandier, P., Gaudou, B., D.A., V., Huynh, N., & Drogoul, A. (2013). GAMA 1.6: Advancing the art of complex agent-based modeling and simulation. In International conference on principles and practice of multi-agent systems, Springer, pp. 117–131.

Gross, J., Peacey, M., & Trevan, D. (1976). Signal emission and signal propagation during early aggregation in Dictyostelium discoideum. Journal of Cell Science, 22(3), 645–656.

Grüne Yanoff, T., & Weirich, P. (2010). The philosophy and epistemology of simulation: A review. Simulation & Gaming, 41(1), 20–50.

Hart, E., Timmis, J., Mitchell, P., Nakano, T., & Dabri, F. (2012). Bio-inspired models of network, information, and computing systems: 6th international ICST conference, BIONETICS 2011, York, UK, December 5–6, 2011, Revised Selected Papers, Springer.

Iglesias, P., & Ingalls, B. (2010). Control theory and systems biology. Boston: MIT Press.MATH

Jowhar, D., & Janetopoulos, C. (2013). The Chemotactic Compass. In Dictyostelids, Springer, pp. 71–87.

Kennedy, R., Ropella, G., & Hunt, C. (2016). A cell-centered, agent-based framework that enables flexible environment granularities. Theoretical Biology and Medical Modelling, 13(1), 4.

Kessin, R. (2001). Dictyostelium: Evolution, cell biology, and the development of multicellularity. Cambridge: Cambridge University Press.

Kessin, R. (2003). Cell motility: Making streams. Nature, 422(6931), 481.

Khan, S., Makkena, R., McGeary, F., Decker, K., Gillis, W., & Schmidt, C. (2003). A multi-agent system for the quantitative simulation of biological networks. In Proceedings of the second international joint conference on Autonomous agents and multiagent systems, ACM, pp. 385–392.

Kim, J., & Bates, D. (2010). Robustness of oscillations in biological systems. In P. Iglesias (Eds.), Control theory and systems biology, Chapter 11, MIT Press, Boston, pp. 225–243.

Kim, J., Heslop-Harrison, P., Postlethwaite, I., & Bates, D. (2007). Stochastic noise and synchronisation during Dictyostelium aggregation make cAMP oscillations robust. PLoS Computational Biology, 3(11), e218.MathSciNet

Kitano, H. (2004). Biological robustness. Nature Reviews Genetics, 5(11), 826.

Kitano, H. (2007). Towards a theory of biological robustness. Molecular Systems Biology, 3(1), 137.

MacKay, S. (1978). Computer simulation of aggregation in Dictyostelium discoideum. Journal of Cell Science, 33(1), 1–16.

McCann, C. P., Kriebel, P. W., Parent, C. A., & Losert, W. (2010). Cell speed, persistence and information transmission during signal relay and collective migration. Journal of Cell Science, 123(10), 1724–1731.

Morris, H., Taylor, G. W., Masento, M. S., Jermyn, K. A., & Kay, R. R. (1987). Chemical structure of the morphogen differentiation inducing factor from Dictyostelium discoideum. Nature, 328(6133), 811.

Nagano, S. (1998). Diffusion-assisted aggregation and synchronization in Dictyostelium discoideum. Physical Review Letters, 80(21), 4826.

Nagano, S. (2000). Modeling the model organism Dictyostelium discoideum. Development, Growth & Differentiation, 42(6), 541–550.

Nanjundiah, V. (1988). Periodic stimuli are more successful than randomly spaced ones for inducing development in Dictyostelium discoideum. Bioscience Reports, 8(6), 571–577.

O’day, D., & Keszei, A. (2012). Signalling and sex in the social amoebozoans. Biological Reviews, 87(2), 313–329.

Oss, C., Panfilov, A., Hogeweg, P., Siegert, F., & Weijer, C. (1996). Spatial pattern formation during aggregation of the slime mould Dictyostelium discoideum. Journal of Theoretical Biology, 181, 203–213.

Othmer, H., & Schaap, P. (1998). Oscillatory cAMP signaling in the development of Dictyostelium discoideum. Comments on Theoretical Biology, 5, 175–282.

Palsson, E., & Othmer, H. (2000). A model for individual and collective cell movement in Dictyostelium discoideum. Proceedings of the National Academy of Sciences, 97(19), 10448–10453.

Parhizkar, M., & Di Marzo Serugendo, G. (2018). Agent-based models for first-and second-order emergent collective behaviours of social amoeba Dictyostelium discoideum aggregation and migration phases. Artificial Life and Robotics, 1–10.

Pineda, M., Weijer, C. J., & Eftimie, R. (2015). Modelling cell movement, cell differentiation, cell sorting and proportion regulation in Dictyostelium discoideum aggregations. Journal of Theoretical Biology, 370, 135–150.MathSciNetMATH

Purcell, E. (1977). Life at low Reynolds number. American Journal of Physics, 45(1), 3–11.

Robertson, A., Drage, D., & Cohen, M. (1972). Control of aggregation in Dictyostelium discoideum by an external periodic pulse of cyclic adenosine monophosphate. Science, 175(4019), 333–335.

Romeralo, M., Baldauf, S., & Escalante, R. (2013). Dictyostelids: Evolution, genomics and cell biology. Berlin: Springer.

Saetzler, K., Sonnenschein, C., & Soto, A. (2011). Systems biology beyond networks: generating order from disorder through self-organization. In Seminars in cancer biology, Vol. 21, Elsevier, pp. 165–174.

Savill, N., & Hogeweg, P. (1997). Modelling morphogenesis: From single cells to crawling slugs. Journal of Theoretical Biology, 184(3), 229–235.

Singhal, A., Eunice, E., & James, D. A. (2006). An effective communication framework for inter-agent communication in a complex adaptive system simulation with application to biology. PhD thesis, Virginia Polytechnic Institute and State University.

Stelling, J., Sauer, U., Szallasi, Z., Doyle, F, I. I. I., & Doyle, J. (2004). Robustness of cellular functions. Cell, 118(6), 675–685.

Strmecki, L., Greene, D., & Pears, C. (2005). Developmental decisions in Dictyostelium discoideum. Developmental Biology, 284(1), 25–36.

Sugihara, K., & Suzuki, I. (1990). Distributed motion coordination of multiple mobile robots. In Proceedings of intelligent control, 5th IEEE international symposium, IEEE, pp. 138–143.

Van Haastert, P., & Postma, M. (2007). Biased random walk by stochastic fluctuations of chemoattractant-receptor interactions at the lower limit of detection. Biophysical Journal, 93(5), 1787–1796.

Van Haastert, P., Van der Meer, R., & Konijn, T. M. (1981). Evidence that the rate of association of adenosine 3’, 5’-monophosphate to its chemotactic receptor induces phosphodiesterase activity in Dictyostelium discoideum. Journal of Bacteriology, 147(1), 170–175.

Vidal-Henriquez, E., & Gholami, A. (2019). Spontaneous center formation in Dictyostelium discoideum. Scientific Reports, 9(1), 1–11.

Vlassopoulos, N., & Fates, N. (2011). Clustering behavior of a bio-inspired decentralized aggregation scheme. In European conference on artificial life-ECAL 2011, MIT Press, pp. 836–837.

Wang, H., Wang, K., & Sircar, T. (2010). A direct O (N log2 N) finite difference method for fractional diffusion equations. Journal of Computational Physics, 229(21), 8095–8104.MathSciNetMATH

Willard, S., & Devreotes, P. (2006). Signaling pathways mediating chemotaxis in the social amoeba, Dictyostelium discoideum. European Journal of Cell Biology, 85(9–10), 897–904.

Williams, J. (2010). Dictyostelium finds new roles to model. Genetics, 185(3), 717–726.

Wooldridge, M. (2002). An introduction to multiagent systems. New York: Wiley.

Zeghida, D., Meslati, D., & Bounour, N. (2018). Bio-IR-M: A multi-paradigm modelling for bio-inspired multi-agent systems. Informatica, 42(3), 51–466.

Titel: Assessing the robustness of decentralized gathering: a multi-agent approach on micro-biological systems
verfasst von: Daniele Proverbio
Luca Gallo
Barbara Passalacqua
Marco Destefanis
Marco Maggiora
Jacopo Pellegrino
Publikationsdatum: 05.11.2020
Verlag: Springer US
Erschienen in: Swarm Intelligence / Ausgabe 4/2020
Print ISSN: 1935-3812
Elektronische ISSN: 1935-3820
DOI: https://doi.org/10.1007/s11721-020-00186-y

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