*Result*: Associative conditioning in gene regulatory network models increases integrative causal emergence.
Title:
Associative conditioning in gene regulatory network models increases integrative causal emergence.
Authors:
Pigozzi F; Allen Discovery Center at Tufts University, Medford, MA, USA., Goldstein A; Department of Physiology, Anatomy and Genetics, University of Oxford, Oxford, UK., Levin M; Allen Discovery Center at Tufts University, Medford, MA, USA. michael.levin@allencenter.tufts.edu.; Wyss Institute for Biologically Inspired Engineering, Harvard University, Boston, MA, USA. michael.levin@allencenter.tufts.edu.
Source:
Communications biology [Commun Biol] 2025 Jul 09; Vol. 8 (1), pp. 1027. Date of Electronic Publication: 2025 Jul 09.
Publication Type:
Journal Article
Language:
English
Journal Info:
Publisher: Nature Publishing Group UK Country of Publication: England NLM ID: 101719179 Publication Model: Electronic Cited Medium: Internet ISSN: 2399-3642 (Electronic) Linking ISSN: 23993642 NLM ISO Abbreviation: Commun Biol Subsets: MEDLINE
Imprint Name(s):
Original Publication: London, United Kingdom : Nature Publishing Group UK, [2018]-
MeSH Terms:
Comments:
Erratum in: Commun Biol. 2026 Feb 23;9(1):298. doi: 10.1038/s42003-026-09668-x.. (PMID: 41731027)
References:
Juarrero, A. Top-down causation and autonomy in complex systems. In Downward Causation and the Neurobiology of Free Will (eds Murphy N., Ellis G. F. R., O’Connor T.) (Springer, 2009).
Ellis, G. F. R. Top-down causation and the human brain. In Downward Causation and the Neurobiology of Free Will (eds Murphy N., Ellis G. F. R., O’Connor T.) 63–81 (Springer, 2009).
Auletta, G., Ellis, G. F. & Jaeger, L. Top-down causation by information control: from a philosophical problem to a scientific research programme. J. R. Soc. Interface 5, 1159–1172 (2008). (PMID: 18319208322699310.1098/rsif.2008.0018)
Walker S., Cisneros L., Davies P. C. W. Evolutionary transitions and top-down causation. In Proc. ALIFE 2012: The Thirteenth International Conference on the Synthesis and Simulation of Living Systems (ASME, 2012).
Pezzulo, G. & Levin, M. Top-down models in biology: explanation and control of complex living systems above the molecular level. J. R. Soc. Interface 13, 20160555 (2016).
Lagasse, E. & Levin, M. Future medicine: from molecular pathways to the collective intelligence of the body. Trends Mol. Med. 29, 687–710 (2023). (PMID: 374813821052723710.1016/j.molmed.2023.06.007)
McMillen, P. & Levin, M. Collective intelligence: a unifying concept for integrating biology across scales and substrates. Commun. Biol. 7, 378 (2024). (PMID: 385488211097887510.1038/s42003-024-06037-4)
Couzin, I. Collective minds. Nature 445, 715 (2007). (PMID: 1730177510.1038/445715a)
Deisboeck, T. S. & Couzin, I. D. Collective behavior in cancer cell populations. Bioessays 31, 190–197 (2009). (PMID: 1920499110.1002/bies.200800084)
Werfel J. Collective construction with robot swarms. In: Morphogenetic Engineering (eds Doursat R., Sayama H., Michel O.) (Springer, 2012).
Abdel-Rahman, A., Cameron, C., Jenett, B., Smith, M. & Gershenfeld, N. Self-replicating hierarchical modular robotic swarms. Commun. Eng. 1, 35 (2022). (PMID: 1095588810.1038/s44172-022-00034-3)
Slavkov, I. et al. Morphogenesis in robot swarms. Sci. Robot. 3, eaau9178 (2018).
Strassmann, J. E. & Queller, D. C. The social organism: congresses, parties, and committees. Evolution 64, 605–616 (2010). (PMID: 2010021310.1111/j.1558-5646.2009.00929.x)
Levin, M. The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition. Front. Psychol. 10, 2688 (2019). (PMID: 31920779692365410.3389/fpsyg.2019.02688)
Levin, M. Technological approach to mind everywhere: an experimentally-grounded framework for understanding diverse bodies and minds. Front. Syst. Neurosci. 16, 768201 (2022). (PMID: 35401131898830310.3389/fnsys.2022.768201)
Fields, C. & Levin, M. Competency in navigating arbitrary spaces as an invariant for analyzing cognition in diverse embodiments. Entropy 24, 819 (2022).
Baluška, F. & Levin, M. On having no head: cognition throughout biological systems. Front. Psychol. 7, 902 (2016). (PMID: 27445884491456310.3389/fpsyg.2016.00902)
Lyon, P. The cognitive cell: bacterial behavior reconsidered. Front. Microbiol. 6, 264 (2015). (PMID: 25926819439646010.3389/fmicb.2015.00264)
Eckert, L. et al. Biochemically plausible models of habituation for single-cell learning. Curr. Biol. 34, 5646–5658 e5643 (2024). (PMID: 3956649710.1016/j.cub.2024.10.041)
Marshall, W., Kim, H., Walker, S. I., Tononi, G. & Albantakis, L. How causal analysis can reveal autonomy in models of biological systems. Philos. Trans. A 375, 20160358 (2017).
Juel, B. E., Comolatti, R., Tononi, G. & Albantakis, L. When is an action caused from within? Quantifying the causal chain leading to actions in simulated agents. ALIFE 2019: The 2019 Conference on Artificial Life (2019).
Mayner, W. G. P. et al. PyPhi: a toolbox for integrated information theory. PLoS Comput. Biol. 14, e1006343 (2018). (PMID: 30048445608080010.1371/journal.pcbi.1006343)
Marshall, W., Albantakis, L. & Tononi, G. Black-boxing and cause-effect power. PLoS Comput. Biol. 14, e1006114 (2018). (PMID: 29684020593381510.1371/journal.pcbi.1006114)
Dewan, E. M. Consciousness as an emergent causal agent in the context of control system theory. (eds Globus G., Maxwell G., Savodnik I.) (Plenum Press, 1976).
Davidson, E. H. et al. A genomic regulatory network for development. Science 295, 1669–1678 (2002). (PMID: 1187283110.1126/science.1069883)
Singh, A. J., Ramsey, S. A., Filtz, T. M. & Kioussi, C. Differential gene regulatory networks in development and disease. Cell Mol. Life Sci. 75, 1013–1025 (2018). (PMID: 2901886810.1007/s00018-017-2679-6)
Gyurkó, D. M. et al. Adaptation and learning of molecular networks as a description of cancer development at the systems-level: potential use in anti-cancer therapies. Semin. Cancer Biol. 23, 262–269 (2013). (PMID: 2379646310.1016/j.semcancer.2013.06.005)
Csermely, P., Korcsmáros, T., Kiss, H. J., London, G. & Nussinov, R. Structure and dynamics of molecular networks: a novel paradigm of drug discovery: a comprehensive review. Pharm. Ther. 138, 333–408 (2013). (PMID: 10.1016/j.pharmthera.2013.01.016)
Ten Tusscher, K. H. & Hogeweg, P. Evolution of networks for body plan patterning; interplay of modularity, robustness and evolvability. PLoS Comput. Biol. 7, e1002208 (2011). (PMID: 21998573318850910.1371/journal.pcbi.1002208)
Peter, I. S. & Davidson, E. H. Evolution of gene regulatory networks controlling body plan development. Cell 144, 970–985 (2011). (PMID: 21414487307600910.1016/j.cell.2011.02.017)
Uller, T., Moczek, A. P., Watson, R. A., Brakefield, P. M. & Laland, K. N. Developmental bias and evolution: a regulatory network perspective. Genetics 209, 949–966 (2018). (PMID: 30049818606324510.1534/genetics.118.300995)
Velazquez, J. J., Su, E., Cahan, P. & Ebrahimkhani, M. R. Programming morphogenesis through systems and synthetic biology. Trends Biotechnol. 36, 415–429 (2018). (PMID: 2922949210.1016/j.tibtech.2017.11.003)
Brophy, J. A. & Voigt, C. A. Principles of genetic circuit design. Nat. Methods 11, 508–520 (2014). (PMID: 24781324423027410.1038/nmeth.2926)
Saltepe, B., Bozkurt, E. U., Güngen, M. A., Çiçek, A. E. & Şeker, U. O. S. Genetic circuits combined with machine learning provides fast responding living sensors. Biosens. Bioelectron. 178, 113028 (2021). (PMID: 3350853810.1016/j.bios.2021.113028)
Krzysztoń, R., Wan, Y., Petreczky, J. & Balázsi, G. Gene-circuit therapy on the horizon: synthetic biology tools for engineered therapeutics. Acta Biochim. Pol. 68, 377–383 (2021). (PMID: 344602098590856)
Peng, W., Song, R. & Acar, M. Noise reduction facilitated by dosage compensation in gene networks. Nat. Commun. 7, 12959 (2016). (PMID: 27694830506396310.1038/ncomms12959)
Peng, W., Liu, P., Xue, Y. & Acar, M. Evolution of gene network activity by tuning the strength of negative-feedback regulation. Nat. Commun. 6, 6226 (2015). (PMID: 2567037110.1038/ncomms7226)
Guye, P., Li, Y., Wroblewska, L., Duportet, X. & Weiss, R. Rapid, modular and reliable construction of complex mammalian gene circuits. Nucleic Acids Res. 41, e156 (2013). (PMID: 23847100376356110.1093/nar/gkt605)
Slusarczyk, A. L., Lin, A. & Weiss, R. Foundations for the design and implementation of synthetic genetic circuits. Nat. Rev. Genet. 13, 406–420 (2012). (PMID: 2259631810.1038/nrg3227)
Beal, J., Lu, T. & Weiss, R. Automatic compilation from high-level biologically-oriented programming language to genetic regulatory networks. PLoS ONE 6, e22490 (2011). (PMID: 21850228315125210.1371/journal.pone.0022490)
Kim, H. & Sayama, H. How criticality of gene regulatory networks affects the resulting morphogenesis under genetic perturbations. Artif. Life 24, 85–105 (2018). (PMID: 2966434410.1162/artl_a_00262)
Solé, R. V., Fernández, P. & Kauffman, S. A. Adaptive walks in a gene network model of morphogenesis: insights into the Cambrian explosion. Int. J. Dev. Biol. 47, 685–693 (2003). (PMID: 1475634410.1387/ijdb.14756344)
Villani M., D’Addese G., Kauffman S. A., Serra R. Attractor-specific and common expression values in random boolean network models (with a preliminary look at single-cell data). Entropy 24, 311(2022).
Beggs, J. M. The criticality hypothesis: how local cortical networks might optimize information processing. Philos. Trans. A366, 329–343 (2008).
Graudenzi, A. et al. Dynamical properties of a boolean model of gene regulatory network with memory. J. Comput. Biol. 18, 1291–1303 (2011). (PMID: 2121434210.1089/cmb.2010.0069)
Graudenzi, A., Serra, R., Villani, M., Colacci, A. & Kauffman, S. A. Robustness analysis of a Boolean model of gene regulatory network with memory. J. Comput. Biol. 18, 559–577 (2011). (PMID: 2141793910.1089/cmb.2010.0224)
Serra, R., Villani, M., Barbieri, A., Kauffman, S. A. & Colacci, A. On the dynamics of random boolean networks subject to noise: attractors, ergodic sets and cell types. J. Theor. Biol. 265, 185–193 (2010). (PMID: 2039921710.1016/j.jtbi.2010.04.012)
Damiani, C., Kauffman, S. A., Serra, R., Villani, M. & Colacci, A. Information transfer among coupled random boolean networks. Lect. Notes Comput. Sci. 6350, 1 (2010). (PMID: 10.1007/978-3-642-15979-4_1)
Csermely, P. et al. Learning of signaling networks: molecular mechanisms. Trends Biochem. Sci. 45, 284–294 (2020). (PMID: 3200889710.1016/j.tibs.2019.12.005)
Perez-Lopez, A. R. et al. Targets of drugs are generally, and targets of drugs having side effects are specifically good spreaders of human interactome perturbations. Sci. Rep. 5, 10182 (2015). (PMID: 25960144442669210.1038/srep10182)
Kovács, I. A., Mizsei, R. & Csermely, P. A unified data representation theory for network visualization, ordering and coarse-graining. Sci. Rep. 5, 13786 (2015). (PMID: 26348923464256910.1038/srep13786)
Gyurkó, M. D., Steták, A., Sőti, C. & Csermely, P. Multitarget network strategies to influence memory and forgetting: the Ras/MAPK pathway as a novel option. Mini Rev. Med. Chem. 15, 696–704 (2015). (PMID: 2569407210.2174/1389557515666150219144336)
Csermely, P. et al. Cancer stem cells display extremely large evolvability: alternating plastic and rigid networks as a potential Mechanism: network models, novel therapeutic target strategies, and the contributions of hypoxia, inflammation and cellular senescence. Semin. Cancer Biol. 30, 42–51 (2015). (PMID: 2441210510.1016/j.semcancer.2013.12.004)
Schreier, H. I., Soen, Y. & Brenner, N. Exploratory adaptation in large random networks. Nat. Commun. 8, 14826 (2017). (PMID: 28429717541394710.1038/ncomms14826)
Soen, Y., Knafo, M. & Elgart, M. A principle of organization which facilitates broad Lamarckian-like adaptations by improvisation. Biol. Direct. 10, 68 (2015). (PMID: 26631109466862410.1186/s13062-015-0097-y)
Hoel, E. & Levin, M. Emergence of informative higher scales in biological systems: a computational toolkit for optimal prediction and control. Commun. Integr. Biol. 13, 108–118 (2020). (PMID: 33014263751845810.1080/19420889.2020.1802914)
Tononi, G., Boly, M., Massimini, M. & Koch, C. Integrated information theory: from consciousness to its physical substrate. Nat. Rev. Neurosci. 17, 450–461 (2016). (PMID: 2722507110.1038/nrn.2016.44)
Balduzzi, D. & Tononi, G. Qualia: the geometry of integrated information. PLoS Comput. Biol. 5, e1000462 (2009). (PMID: 19680424271340510.1371/journal.pcbi.1000462)
Hoel, E. P., Albantakis, L., Marshall, W. & Tononi, G. Can the macro beat the micro? Integrated information across spatiotemporal scales. Neurosci. Conscious 2016, niw012 (2016). (PMID: 30788150636796810.1093/nc/niw012)
Rajpal, H. et al. Quantifying Hierarchical Selection. Preprint at https://arxiv.org/abs/2310.20386 (2023).
Cang, Z. & Nie, Q. Inferring spatial and signaling relationships between cells from single cell transcriptomic data. Nat. Commun. 11, 2084 (2020). (PMID: 32350282719065910.1038/s41467-020-15968-5)
Varley, T. F., Pope, M., Faskowitz, J. & Sporns, O. Multivariate information theory uncovers synergistic subsystems of the human cerebral cortex. Commun. Biol. 6, 451 (2023). (PMID: 370952821012599910.1038/s42003-023-04843-w)
Oizumi, M., Albantakis, L. & Tononi, G. From the phenomenology to the mechanisms of consciousness: Integrated Information Theory 3.0. PLoS Comput. Biol. 10, e1003588 (2014). (PMID: 24811198401440210.1371/journal.pcbi.1003588)
Mediano, P. A. M., Rosas, F. E., Carhart-Harris, R. L., Seth, A. K. & Barrett, A. B. Beyond integrated information: a taxonomy of information dynamics phenomena. Preprint at https://arxiv.org/abs/1909.02297 (2019).
Mediano, P. A. M. et al. Greater than the parts: a review of the information decomposition approach to causal emergence. Philos. Trans. A380, 20210246 (2022).
Rosas, F. E. et al. Reconciling emergences: an information-theoretic approach to identify causal emergence in multivariate data. PLoS Comput. Biol. 16, e1008289 (2020). (PMID: 33347467783322110.1371/journal.pcbi.1008289)
Luppi, A. I. et al. A synergistic core for human brain evolution and cognition. Nat. Neurosci. 25, 771–782 (2022). (PMID: 35618951761477110.1038/s41593-022-01070-0)
Luppi, A. I. et al. A synergistic workspace for human consciousness revealed by Integrated Information Decomposition. Elife 12, RP88173 (2024). (PMID: 390229241125769410.7554/eLife.88173.4)
Luppi, A. I. et al. Reduced emergent character of neural dynamics in patients with a disrupted connectome. Neuroimage 269, 119926 (2023). (PMID: 36740030998966610.1016/j.neuroimage.2023.119926)
Malik-Sheriff, R. S. et al. BioModels-15 years of sharing computational models in life science. Nucleic Acids Res. 48, D407–D415 (2020). (PMID: 317011507145643)
Reinitz, J. & Sharp, D. H. Mechanism of eve stripe formation. Mech. Dev. 49, 133–158 (1995). (PMID: 774878510.1016/0925-4773(94)00310-J)
LeCun, Y., Bengio, Y. & Hinton, G. Deep learning. Nature 521, 436–444 (2015). (PMID: 2601744210.1038/nature14539)
Hartigan, J. A. & Wong, M. A. Algorithm AS 136: a K-means clustering algorithm. Appl. Stat. 28, 100–108 (1979). (PMID: 10.2307/2346830)
van der Maaten, L. & Hinton, G. Visualizing data using t-SNE. J. Mach. Learn. Res. 9, 2579–2605 (2008).
Clawson, W. P. & Levin, M. Endless forms most beautiful 2.0: teleonomy and the bioengineering of chimaeric and synthetic organisms. Biol. J. Linn. Soc. 139, 457–486 (2023). (PMID: 10.1093/biolinnean/blac073)
Rosenblueth, A., Wiener, N. & Bigelow, J. Behavior, purpose, and teleology. Philos. Sci. 10, 18–24 (1943). (PMID: 10.1086/286788)
Latora, V., Nicosia, V. & Russo, G. Complex Methods: Principles, Methods and Applications (Cambridge University Press, 2017).
Brin M., Stuck G. Introduction to Dynamical Systems (Cambridge University Press, 2002).
de Jong, H. Modeling and simulation of genetic regulatory systems: a literature review. J. Comput. Biol. 9, 67–103 (2002). (PMID: 1191179610.1089/10665270252833208)
Kim, D. et al. Gene regulatory network reconstruction: harnessing the power of single-cell multi-omic data. NPJ Syst. Biol. Appl. 9, 51 (2023). (PMID: 378576321058707810.1038/s41540-023-00312-6)
Schlitt, T. & Brazma, A. Current approaches to gene regulatory network modelling. BMC Bioinform. 8, S9 (2007). (PMID: 10.1186/1471-2105-8-S6-S9)
Ho, C. & Morsut, L. Novel synthetic biology approaches for developmental systems. Stem Cell Rep. 16, 1051–1064 (2021). (PMID: 10.1016/j.stemcr.2021.04.007)
Liu, Y. Y., Slotine, J. J. & Barabási, A. L. Controllability of complex networks. Nature 473, 167–173 (2011). (PMID: 2156255710.1038/nature10011)
Zañudo, J. G. T., Yang, G. & Albert, R. Structure-based control of complex networks with nonlinear dynamics. Proc. Natl. Acad. Sci. USA 114, 7234–7239 (2017). (PMID: 28655847551470210.1073/pnas.1617387114)
Gates, A. J. & Rocha, L. M. Control of complex networks requires both structure and dynamics. Sci. Rep. 6, 24456 (2016). (PMID: 27087469483450910.1038/srep24456)
Biswas, S., Manicka, S., Hoel, E. & Levin, M. Gene regulatory networks exhibit several kinds of memory: quantification of memory in biological and random transcriptional networks. iScience 24, 102131 (2021). (PMID: 33748699797012410.1016/j.isci.2021.102131)
Biswas, S., Clawson, W. & Levin, M. Learning in transcriptional network models: computational discovery of pathway-level memory and effective interventions. Int. J. Mol. Sci. 24, 285 (2022).
Mathews, J., Chang, A. J., Devlin, L. & Levin, M. Cellular signaling pathways as plastic, proto-cognitive systems: Implications for biomedicine. Patterns4, 100737 (2023). (PMID: 372232671020130610.1016/j.patter.2023.100737)
Baluška, F., Miller, W. B. & Reber, A. S. Cellular and evolutionary perspectives on organismal cognition: from unicellular to multicellular organisms. Biol. J. Linn. Soc. 139, 503–513 (2023). (PMID: 10.1093/biolinnean/blac005)
Reber, A. S. & Baluška, F. Cognition in some surprising places. Biochem. Biophys. Res. Commun. 564, 150–157 (2021). (PMID: 3295023110.1016/j.bbrc.2020.08.115)
Lyon, P. Of what is “minimal cognition” the half-baked version? Adapt. Behav. 28, 407–424 (2019). (PMID: 10.1177/1059712319871360)
Lyon, P. The biogenic approach to cognition. Cogn. Process 7, 11–29 (2006). (PMID: 1662846310.1007/s10339-005-0016-8)
Abramson, C. I. & Levin, M. Behaviorist approaches to investigating memory and learning: a primer for synthetic biology and bioengineering. Commun. Integr. Biol. 14, 230–247 (2021). (PMID: 34925687867700610.1080/19420889.2021.2005863)
Volkov, A. G., Nyasani, E. K., Blockmon, A. L. & Volkova, M. I. Memristors: memory elements in potato tubers. Plant Signal Behav. 10, e1071750 (2015). (PMID: 26237427488390410.1080/15592324.2015.1071750)
Kauffman S. A. The Origins of Order:Self Organization and Selection in Evolution (Oxford University Press, 1993).
Varley, T. F. & Bongard, J. Evolving higher-order synergies reveals a trade-off between stability and information-integration capacity in complex systems. Chaos 34, 063127 (2024). (PMID: 3886509210.1063/5.0200425)
Gallimore, A. R. Restructuring consciousness -the psychedelic state in light of integrated information theory. Front. Hum. Neurosci. 9, 346 (2015). (PMID: 26124719446417610.3389/fnhum.2015.00346)
Bayne, T. & Carter, O. Dimensions of consciousness and the psychedelic state. Neurosci. Conscious. 2018, niy008 (2018). (PMID: 30254752614615710.1093/nc/niy008)
Evolution and Diversification of Land Plants (Springer 1997).
Gullan, P. J. & Cranston, P. S. The Insects: an Outline of Entomology 5th edn (Wiley Blackwell, 2014).
Eryomin, A. L. Biophysics of evolution of intellectual systems. Biophysics67, 320–326 (2022). (PMID: 35789557924402610.1134/S0006350922020051)
Vallverdú, J. et al. Slime mould: the fundamental mechanisms of biological cognition. Biosystems 165, 57–70 (2018). (PMID: 2932606810.1016/j.biosystems.2017.12.011)
Pearson, G. et al. Mitogen-activated protein (MAP) kinase pathways: regulation and physiological functions. Endocr. Rev. 22, 153–183 (2001). (PMID: 11294822)
Veres, T. et al. Cellular forgetting, desensitisation, stress and ageing in signalling networks. When do cells refuse to learn more?. Cell Mol. Life Sci. 81, 97 (2024). (PMID: 383727501087675710.1007/s00018-024-05112-7)
Shreesha, L. & Levin, M. Stress sharing as cognitive glue for collective intelligences: a computational model of stress as a coordinator for morphogenesis. Biochem. Biophys. Res. Commun. 731, 150396 (2024). (PMID: 390189741135609310.1016/j.bbrc.2024.150396)
Jiang, L., Chen, Y., Luo, L. & Peck, S. C. Central roles and regulatory mechanisms of dual-specificity MAPK phosphatases in developmental and stress signaling. Front. Plant Sci. 9, 1697 (2018). (PMID: 30515185625598710.3389/fpls.2018.01697)
Barbuti, R., Gori, R., Milazzo, P. & Nasti, L. A survey of gene regulatory networks modelling methods: from differential equations, to Boolean and qualitative bioinspired models. J. Membr. Comput. 2, 207–226 (2020). (PMID: 10.1007/s41965-020-00046-y)
Etcheverry, M., Moulin-Frier, C., Oudeyer, P.-Y. & Levin, M. AI-driven automated discovery tools reveal diverse behavioral competencies of biological networks. Elife 13, RP92683 (2024).
Pietak, A. & Levin, M. Bioelectric gene and reaction networks: computational modelling of genetic, biochemical and bioelectrical dynamics in pattern regulation. J. R. Soc. Interface 14, 20170425 (2017).
Pietak, A. & Levin, M. Exploring instructive physiological signaling with the bioelectric tissue simulation engine. Front. Bioeng. Biotechnol. 4, 55 (2016). (PMID: 27458581493371810.3389/fbioe.2016.00055)
Riol, A., Cervera, J., Levin, M. & Mafé, S. Cell systems bioelectricity: how different intercellular gap junctions could regionalize a multicellular aggregate. Cancers 13, 5300 (2021).
Cervera, J., Levin, M. & Mafé, S. Bioelectrical coupling of single-cell states in multicellular systems. J. Phys. Chem. Lett. 11, 3234–3241 (2020). (PMID: 3224375410.1021/acs.jpclett.0c00641)
Cervera, J., Pai, V. P., Levin, M. & Mafé, S. From non-excitable single-cell to multicellular bioelectrical states supported by ion channels and gap junction proteins: Electrical potentials as distributed controllers. Prog. Biophys. Mol. Biol. 149, 39–53 (2019). (PMID: 3125570210.1016/j.pbiomolbio.2019.06.004)
Cervera, J., Manzanares, J. A., Mafé, S. & Levin, M. Synchronization of bioelectric oscillations in networks of nonexcitable cells: from single-cell to multicellular states. J. Phys. Chem. B 123, 3924–3934 (2019). (PMID: 3100357410.1021/acs.jpcb.9b01717)
Vanslambrouck, M. et al. Image-based force inference by biomechanical simulation. PLoS Comput. Biol. 20, e1012629 (2024). (PMID: 396217781163731310.1371/journal.pcbi.1012629)
Delile, J., Herrmann, M., Peyriéras, N. & Doursat, R. A cell-based computational model of early embryogenesis coupling mechanical behaviour and gene regulation. Nat. Commun. 8, 13929 (2017). (PMID: 28112150526401210.1038/ncomms13929)
Beloussov, L. V. & Grabovsky, V. I. A Geometro-mechanical model for pulsatile morphogenesis. Comput. Methods Biomech. Biomed. Eng. 6, 53–63 (2003). (PMID: 10.1080/1025584021000047641)
Bugaj, L. J., O’Donoghue, G. P. & Lim, W. A. Interrogating cellular perception and decision making with optogenetic tools. J. Cell Biol. 216, 25–28 (2017). (PMID: 2800333010.1083/jcb.201612094)
Friston, K. J. A free energy principle for biological systems. Entropy14, 2100–2121 (2012). (PMID: 10.3390/e14112100)
Safron, A. An integrated world modeling theory (IWMT) of consciousness: combining integrated information and global neuronal workspace theories with the free energy principle and active inference framework; toward solving the hard problem and characterizing agentic causation. Front. Artif. Intell. 3, 30 (2020). (PMID: 33733149786134010.3389/frai.2020.00030)
Lundbak Olesen, C., Waade, P. T., Albantakis, L. & Mathys, C. Phi fluctuates with surprisal: an empirical pre-study for the synthesis of the free energy principle and integrated information theory. PLoS Comput. Biol. 19, e1011346 (2023). (PMID: 378623641061980910.1371/journal.pcbi.1011346)
van Duijn, M. Phylogenetic origins of biological cognition: convergent patterns in the early evolution of learning. Interface Focus 7, 20160158 (2017). (PMID: 28479986541389710.1098/rsfs.2016.0158)
Watson, R. A. & Szathmáry, E. How can evolution learn? Trends Ecol. Evol. 31, 147–157 (2016). (PMID: 2670568410.1016/j.tree.2015.11.009)
Watson, R. A. et al. Evolutionary connectionism: algorithmic principles underlying the evolution of biological organisation in evo-devo, evo-eco and evolutionary transitions. Evol. Biol. 43, 553–581 (2016). (PMID: 2793285210.1007/s11692-015-9358-z)
Sznajder, B., Sabelis, M. W. & Egas, M. How adaptive learning affects evolution: reviewing theory on the Baldwin effect. Evol. Biol. 39, 301–310 (2012). (PMID: 2292385210.1007/s11692-011-9155-2)
Shreesha L., Levin M. Cellular competency during development alters evolutionary dynamics in an artificial embryogeny model. Entropy 25, 131 (2023).
Pio-Lopez, L., Bischof, J., LaPalme, J. V. & Levin, M. The scaling of goals from cellular to anatomical homeostasis: an evolutionary simulation, experiment and analysis. Interface Focus 13, 20220072 (2023). (PMID: 370652701010273410.1098/rsfs.2022.0072)
Jablonka, E. & Ginsburg, S. Learning and the evolution of conscious agents. Biosemiotics 15, 401–437 (2022). (PMID: 10.1007/s12304-022-09501-y)
Hinton, G. E. & Nowlan, J. How learning can guide evolution. Complex Syst. 1, 495–502 (1987).
Bayne, T. On the axiomatic foundations of the integrated information theory of consciousness. Neurosci. Conscious. 2018, niy007 (2018). (PMID: 30042860603081310.1093/nc/niy007)
Tononi, G. Integrated information theory of consciousness: an updated account. Arch. Ital. Biol. 150, 56–90 (2012). (PMID: 23165867)
Tononi, G. Consciousness as integrated information: a provisional manifesto. Biol. Bull. 215, 216–242 (2008). (PMID: 1909814410.2307/25470707)
Baluška, F., Reber, A. S. & Miller, W. B. Jr Cellular sentience as the primary source of biological order and evolution. Biosystems 218, 104694 (2022). (PMID: 3559519410.1016/j.biosystems.2022.104694)
Tan, T. H. et al. Odd dynamics of living chiral crystals. Nature 607, 287–293 (2022). (PMID: 3583159510.1038/s41586-022-04889-6)
Zampetaki A. V., Liebchen B., Ivlev A. V., Löwen H. Collective self-optimization of communicating active particles. Proc. Natl. Acad. Sci. USA 118, e2111142118 (2021).
Ozkan-Aydin, Y., Goldman, D. I. & Bhamla, M. S. Collective dynamics in entangled worm and robot blobs. Proc. Natl. Acad. Sci. USA 118, e2010542118 (2021).
Stern, M., Pinson, M. B. & Murugan, A. Continual learning of multiple memories in mechanical networks. Phys. Rev. X 10, 031044 (2020).
McGivern, P. Active materials: minimal models of cognition?. Adapt. Behav. 28, 441–451 (2019). (PMID: 10.1177/1059712319891742)
Bernheim-Groswasser, A., Gov, N. S., Safran, S. A. & Tzlil, S. Living matter: mesoscopic active materials. Adv. Mater. 30, e1707028 (2018). (PMID: 3025646310.1002/adma.201707028)
Kaspar, C., Ravoo, B. J., van der Wiel, W. G., Wegner, S. V. & Pernice, W. H. P. The rise of intelligent matter. Nature 594, 345–355 (2021). (PMID: 3413551810.1038/s41586-021-03453-y)
Adamatzky, A., Chiolerio, A. & Szaciłowski, K. Liquid metal droplet solves maze. Soft Matter 16, 1455–1462 (2020). (PMID: 3197699810.1039/C9SM01806A)
Safonov, A. A. Computing via natural erosion of sandstone. Int. J. Parallel, Emerg. Distrib. Syst. 33, 742–751 (2018). (PMID: 10.1080/17445760.2018.1455836)
Mayne, R., Whiting, J. & Adamatzky, A. Toxicity and applications of internalised magnetite nanoparticles within live paramecium caudatum cells. Bionanoscience 8, 90–94 (2018). (PMID: 2960015810.1007/s12668-017-0425-z)
Adamatzky, A. Towards fungal computer. Interface Focus 8, 20180029 (2018). (PMID: 30443330622780510.1098/rsfs.2018.0029)
Čejková, J., Banno, T., Hanczyc, M. M. & Štěpánek, F. Droplets as liquid robots. Artif. Life 23, 528–549 (2017). (PMID: 2898511310.1162/ARTL_a_00243)
Katz, E. Biocomputing—tools, aims, perspectives. Curr. Opin. Biotechnol. 34, 202–208 (2015). (PMID: 2576567210.1016/j.copbio.2015.02.011)
Etcheverry, M., Levin, M., Moulin-Frier, C. & Oudeyer P.-Y. SBMLtoODEjax: efficient simulation and optimization of biological network models in JAX. NeurIPS 2023 AI for Science Workshop (2023).
Blackiston, D. et al. Revealing non-trivial information structures in aneural biological tissues via functional connectivity. PLOS Comput. Biol. 21, e1012149 (2024).
Liu, T. T., Nalci, A. & Falahpour, M. The global signal in fMRI: nuisance or information? Neuroimage 150, 213–229 (2017). (PMID: 28213118540622910.1016/j.neuroimage.2017.02.036)
Afyouni, S., Smith, S. M. & Nichols, T. E. Effective degrees of freedom of the Pearson’s correlation coefficient under autocorrelation. Neuroimage 199, 609–625 (2019). (PMID: 31158478669355810.1016/j.neuroimage.2019.05.011)
Daube, C., Gross, J. & Ince, R. A. A. A whitening approach for transfer entropy permits the application to narrow-band signals. Preprint at https://arxiv.org/abs/2201.02461 (2022).
McMillen P., Walker S. I. & Levin M. Information theory as an experimental tool for integrating disparate biophysical signaling modules. Int. J. Mol. Sci. 23, 9580 (2022).
Williams, P. L. & Beer, R. D. Nonnegative decomposition of multivariate information. Preprint at https://arxiv.org/abs/1004.2515 (2010).
Tononi, G. An information integration theory of consciousness. BMC Neurosci. 5, 42 (2004). (PMID: 1552212154347010.1186/1471-2202-5-42)
Rosas, F. E., Mediano, P. A. M., Gastpar, M. & Jensen, H. J. Quantifying high-order interdependencies via multivariate extensions of the mutual information. Phys. Rev. E 100, 032305 (2019). (PMID: 3164003810.1103/PhysRevE.100.032305)
Barrett, A. B. Exploration of synergistic and redundant information sharing in static and dynamical Gaussian systems. Phys. Rev. E91, 052802 (2015). (PMID: 10.1103/PhysRevE.91.052802)
Friston, K. J. Functional and effective connectivity: a review. Brain Connect 1, 13–36 (2011). (PMID: 2243295210.1089/brain.2011.0008)
Jansma, A., Mediano, P. A. M. & Rosas, F. E. The Fast Möbius Transform: an algebraic approach to information decomposition. Preprint at https://arxiv.org/abs/2410.06224 (2024).
Kitazono, J., Kanai, R. & Oizumi, M. Efficient algorithms for searching the minimum information partition in integrated information theory. Entropy 20, 173 (2018).
Ellis, G. F. R. Top-down causation and the human brain. In Downward Causation and the Neurobiology of Free Will (eds Murphy N., Ellis G. F. R., O’Connor T.) 63–81 (Springer, 2009).
Auletta, G., Ellis, G. F. & Jaeger, L. Top-down causation by information control: from a philosophical problem to a scientific research programme. J. R. Soc. Interface 5, 1159–1172 (2008). (PMID: 18319208322699310.1098/rsif.2008.0018)
Walker S., Cisneros L., Davies P. C. W. Evolutionary transitions and top-down causation. In Proc. ALIFE 2012: The Thirteenth International Conference on the Synthesis and Simulation of Living Systems (ASME, 2012).
Pezzulo, G. & Levin, M. Top-down models in biology: explanation and control of complex living systems above the molecular level. J. R. Soc. Interface 13, 20160555 (2016).
Lagasse, E. & Levin, M. Future medicine: from molecular pathways to the collective intelligence of the body. Trends Mol. Med. 29, 687–710 (2023). (PMID: 374813821052723710.1016/j.molmed.2023.06.007)
McMillen, P. & Levin, M. Collective intelligence: a unifying concept for integrating biology across scales and substrates. Commun. Biol. 7, 378 (2024). (PMID: 385488211097887510.1038/s42003-024-06037-4)
Couzin, I. Collective minds. Nature 445, 715 (2007). (PMID: 1730177510.1038/445715a)
Deisboeck, T. S. & Couzin, I. D. Collective behavior in cancer cell populations. Bioessays 31, 190–197 (2009). (PMID: 1920499110.1002/bies.200800084)
Werfel J. Collective construction with robot swarms. In: Morphogenetic Engineering (eds Doursat R., Sayama H., Michel O.) (Springer, 2012).
Abdel-Rahman, A., Cameron, C., Jenett, B., Smith, M. & Gershenfeld, N. Self-replicating hierarchical modular robotic swarms. Commun. Eng. 1, 35 (2022). (PMID: 1095588810.1038/s44172-022-00034-3)
Slavkov, I. et al. Morphogenesis in robot swarms. Sci. Robot. 3, eaau9178 (2018).
Strassmann, J. E. & Queller, D. C. The social organism: congresses, parties, and committees. Evolution 64, 605–616 (2010). (PMID: 2010021310.1111/j.1558-5646.2009.00929.x)
Levin, M. The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition. Front. Psychol. 10, 2688 (2019). (PMID: 31920779692365410.3389/fpsyg.2019.02688)
Levin, M. Technological approach to mind everywhere: an experimentally-grounded framework for understanding diverse bodies and minds. Front. Syst. Neurosci. 16, 768201 (2022). (PMID: 35401131898830310.3389/fnsys.2022.768201)
Fields, C. & Levin, M. Competency in navigating arbitrary spaces as an invariant for analyzing cognition in diverse embodiments. Entropy 24, 819 (2022).
Baluška, F. & Levin, M. On having no head: cognition throughout biological systems. Front. Psychol. 7, 902 (2016). (PMID: 27445884491456310.3389/fpsyg.2016.00902)
Lyon, P. The cognitive cell: bacterial behavior reconsidered. Front. Microbiol. 6, 264 (2015). (PMID: 25926819439646010.3389/fmicb.2015.00264)
Eckert, L. et al. Biochemically plausible models of habituation for single-cell learning. Curr. Biol. 34, 5646–5658 e5643 (2024). (PMID: 3956649710.1016/j.cub.2024.10.041)
Marshall, W., Kim, H., Walker, S. I., Tononi, G. & Albantakis, L. How causal analysis can reveal autonomy in models of biological systems. Philos. Trans. A 375, 20160358 (2017).
Juel, B. E., Comolatti, R., Tononi, G. & Albantakis, L. When is an action caused from within? Quantifying the causal chain leading to actions in simulated agents. ALIFE 2019: The 2019 Conference on Artificial Life (2019).
Mayner, W. G. P. et al. PyPhi: a toolbox for integrated information theory. PLoS Comput. Biol. 14, e1006343 (2018). (PMID: 30048445608080010.1371/journal.pcbi.1006343)
Marshall, W., Albantakis, L. & Tononi, G. Black-boxing and cause-effect power. PLoS Comput. Biol. 14, e1006114 (2018). (PMID: 29684020593381510.1371/journal.pcbi.1006114)
Dewan, E. M. Consciousness as an emergent causal agent in the context of control system theory. (eds Globus G., Maxwell G., Savodnik I.) (Plenum Press, 1976).
Davidson, E. H. et al. A genomic regulatory network for development. Science 295, 1669–1678 (2002). (PMID: 1187283110.1126/science.1069883)
Singh, A. J., Ramsey, S. A., Filtz, T. M. & Kioussi, C. Differential gene regulatory networks in development and disease. Cell Mol. Life Sci. 75, 1013–1025 (2018). (PMID: 2901886810.1007/s00018-017-2679-6)
Gyurkó, D. M. et al. Adaptation and learning of molecular networks as a description of cancer development at the systems-level: potential use in anti-cancer therapies. Semin. Cancer Biol. 23, 262–269 (2013). (PMID: 2379646310.1016/j.semcancer.2013.06.005)
Csermely, P., Korcsmáros, T., Kiss, H. J., London, G. & Nussinov, R. Structure and dynamics of molecular networks: a novel paradigm of drug discovery: a comprehensive review. Pharm. Ther. 138, 333–408 (2013). (PMID: 10.1016/j.pharmthera.2013.01.016)
Ten Tusscher, K. H. & Hogeweg, P. Evolution of networks for body plan patterning; interplay of modularity, robustness and evolvability. PLoS Comput. Biol. 7, e1002208 (2011). (PMID: 21998573318850910.1371/journal.pcbi.1002208)
Peter, I. S. & Davidson, E. H. Evolution of gene regulatory networks controlling body plan development. Cell 144, 970–985 (2011). (PMID: 21414487307600910.1016/j.cell.2011.02.017)
Uller, T., Moczek, A. P., Watson, R. A., Brakefield, P. M. & Laland, K. N. Developmental bias and evolution: a regulatory network perspective. Genetics 209, 949–966 (2018). (PMID: 30049818606324510.1534/genetics.118.300995)
Velazquez, J. J., Su, E., Cahan, P. & Ebrahimkhani, M. R. Programming morphogenesis through systems and synthetic biology. Trends Biotechnol. 36, 415–429 (2018). (PMID: 2922949210.1016/j.tibtech.2017.11.003)
Brophy, J. A. & Voigt, C. A. Principles of genetic circuit design. Nat. Methods 11, 508–520 (2014). (PMID: 24781324423027410.1038/nmeth.2926)
Saltepe, B., Bozkurt, E. U., Güngen, M. A., Çiçek, A. E. & Şeker, U. O. S. Genetic circuits combined with machine learning provides fast responding living sensors. Biosens. Bioelectron. 178, 113028 (2021). (PMID: 3350853810.1016/j.bios.2021.113028)
Krzysztoń, R., Wan, Y., Petreczky, J. & Balázsi, G. Gene-circuit therapy on the horizon: synthetic biology tools for engineered therapeutics. Acta Biochim. Pol. 68, 377–383 (2021). (PMID: 344602098590856)
Peng, W., Song, R. & Acar, M. Noise reduction facilitated by dosage compensation in gene networks. Nat. Commun. 7, 12959 (2016). (PMID: 27694830506396310.1038/ncomms12959)
Peng, W., Liu, P., Xue, Y. & Acar, M. Evolution of gene network activity by tuning the strength of negative-feedback regulation. Nat. Commun. 6, 6226 (2015). (PMID: 2567037110.1038/ncomms7226)
Guye, P., Li, Y., Wroblewska, L., Duportet, X. & Weiss, R. Rapid, modular and reliable construction of complex mammalian gene circuits. Nucleic Acids Res. 41, e156 (2013). (PMID: 23847100376356110.1093/nar/gkt605)
Slusarczyk, A. L., Lin, A. & Weiss, R. Foundations for the design and implementation of synthetic genetic circuits. Nat. Rev. Genet. 13, 406–420 (2012). (PMID: 2259631810.1038/nrg3227)
Beal, J., Lu, T. & Weiss, R. Automatic compilation from high-level biologically-oriented programming language to genetic regulatory networks. PLoS ONE 6, e22490 (2011). (PMID: 21850228315125210.1371/journal.pone.0022490)
Kim, H. & Sayama, H. How criticality of gene regulatory networks affects the resulting morphogenesis under genetic perturbations. Artif. Life 24, 85–105 (2018). (PMID: 2966434410.1162/artl_a_00262)
Solé, R. V., Fernández, P. & Kauffman, S. A. Adaptive walks in a gene network model of morphogenesis: insights into the Cambrian explosion. Int. J. Dev. Biol. 47, 685–693 (2003). (PMID: 1475634410.1387/ijdb.14756344)
Villani M., D’Addese G., Kauffman S. A., Serra R. Attractor-specific and common expression values in random boolean network models (with a preliminary look at single-cell data). Entropy 24, 311(2022).
Beggs, J. M. The criticality hypothesis: how local cortical networks might optimize information processing. Philos. Trans. A366, 329–343 (2008).
Graudenzi, A. et al. Dynamical properties of a boolean model of gene regulatory network with memory. J. Comput. Biol. 18, 1291–1303 (2011). (PMID: 2121434210.1089/cmb.2010.0069)
Graudenzi, A., Serra, R., Villani, M., Colacci, A. & Kauffman, S. A. Robustness analysis of a Boolean model of gene regulatory network with memory. J. Comput. Biol. 18, 559–577 (2011). (PMID: 2141793910.1089/cmb.2010.0224)
Serra, R., Villani, M., Barbieri, A., Kauffman, S. A. & Colacci, A. On the dynamics of random boolean networks subject to noise: attractors, ergodic sets and cell types. J. Theor. Biol. 265, 185–193 (2010). (PMID: 2039921710.1016/j.jtbi.2010.04.012)
Damiani, C., Kauffman, S. A., Serra, R., Villani, M. & Colacci, A. Information transfer among coupled random boolean networks. Lect. Notes Comput. Sci. 6350, 1 (2010). (PMID: 10.1007/978-3-642-15979-4_1)
Csermely, P. et al. Learning of signaling networks: molecular mechanisms. Trends Biochem. Sci. 45, 284–294 (2020). (PMID: 3200889710.1016/j.tibs.2019.12.005)
Perez-Lopez, A. R. et al. Targets of drugs are generally, and targets of drugs having side effects are specifically good spreaders of human interactome perturbations. Sci. Rep. 5, 10182 (2015). (PMID: 25960144442669210.1038/srep10182)
Kovács, I. A., Mizsei, R. & Csermely, P. A unified data representation theory for network visualization, ordering and coarse-graining. Sci. Rep. 5, 13786 (2015). (PMID: 26348923464256910.1038/srep13786)
Gyurkó, M. D., Steták, A., Sőti, C. & Csermely, P. Multitarget network strategies to influence memory and forgetting: the Ras/MAPK pathway as a novel option. Mini Rev. Med. Chem. 15, 696–704 (2015). (PMID: 2569407210.2174/1389557515666150219144336)
Csermely, P. et al. Cancer stem cells display extremely large evolvability: alternating plastic and rigid networks as a potential Mechanism: network models, novel therapeutic target strategies, and the contributions of hypoxia, inflammation and cellular senescence. Semin. Cancer Biol. 30, 42–51 (2015). (PMID: 2441210510.1016/j.semcancer.2013.12.004)
Schreier, H. I., Soen, Y. & Brenner, N. Exploratory adaptation in large random networks. Nat. Commun. 8, 14826 (2017). (PMID: 28429717541394710.1038/ncomms14826)
Soen, Y., Knafo, M. & Elgart, M. A principle of organization which facilitates broad Lamarckian-like adaptations by improvisation. Biol. Direct. 10, 68 (2015). (PMID: 26631109466862410.1186/s13062-015-0097-y)
Hoel, E. & Levin, M. Emergence of informative higher scales in biological systems: a computational toolkit for optimal prediction and control. Commun. Integr. Biol. 13, 108–118 (2020). (PMID: 33014263751845810.1080/19420889.2020.1802914)
Tononi, G., Boly, M., Massimini, M. & Koch, C. Integrated information theory: from consciousness to its physical substrate. Nat. Rev. Neurosci. 17, 450–461 (2016). (PMID: 2722507110.1038/nrn.2016.44)
Balduzzi, D. & Tononi, G. Qualia: the geometry of integrated information. PLoS Comput. Biol. 5, e1000462 (2009). (PMID: 19680424271340510.1371/journal.pcbi.1000462)
Hoel, E. P., Albantakis, L., Marshall, W. & Tononi, G. Can the macro beat the micro? Integrated information across spatiotemporal scales. Neurosci. Conscious 2016, niw012 (2016). (PMID: 30788150636796810.1093/nc/niw012)
Rajpal, H. et al. Quantifying Hierarchical Selection. Preprint at https://arxiv.org/abs/2310.20386 (2023).
Cang, Z. & Nie, Q. Inferring spatial and signaling relationships between cells from single cell transcriptomic data. Nat. Commun. 11, 2084 (2020). (PMID: 32350282719065910.1038/s41467-020-15968-5)
Varley, T. F., Pope, M., Faskowitz, J. & Sporns, O. Multivariate information theory uncovers synergistic subsystems of the human cerebral cortex. Commun. Biol. 6, 451 (2023). (PMID: 370952821012599910.1038/s42003-023-04843-w)
Oizumi, M., Albantakis, L. & Tononi, G. From the phenomenology to the mechanisms of consciousness: Integrated Information Theory 3.0. PLoS Comput. Biol. 10, e1003588 (2014). (PMID: 24811198401440210.1371/journal.pcbi.1003588)
Mediano, P. A. M., Rosas, F. E., Carhart-Harris, R. L., Seth, A. K. & Barrett, A. B. Beyond integrated information: a taxonomy of information dynamics phenomena. Preprint at https://arxiv.org/abs/1909.02297 (2019).
Mediano, P. A. M. et al. Greater than the parts: a review of the information decomposition approach to causal emergence. Philos. Trans. A380, 20210246 (2022).
Rosas, F. E. et al. Reconciling emergences: an information-theoretic approach to identify causal emergence in multivariate data. PLoS Comput. Biol. 16, e1008289 (2020). (PMID: 33347467783322110.1371/journal.pcbi.1008289)
Luppi, A. I. et al. A synergistic core for human brain evolution and cognition. Nat. Neurosci. 25, 771–782 (2022). (PMID: 35618951761477110.1038/s41593-022-01070-0)
Luppi, A. I. et al. A synergistic workspace for human consciousness revealed by Integrated Information Decomposition. Elife 12, RP88173 (2024). (PMID: 390229241125769410.7554/eLife.88173.4)
Luppi, A. I. et al. Reduced emergent character of neural dynamics in patients with a disrupted connectome. Neuroimage 269, 119926 (2023). (PMID: 36740030998966610.1016/j.neuroimage.2023.119926)
Malik-Sheriff, R. S. et al. BioModels-15 years of sharing computational models in life science. Nucleic Acids Res. 48, D407–D415 (2020). (PMID: 317011507145643)
Reinitz, J. & Sharp, D. H. Mechanism of eve stripe formation. Mech. Dev. 49, 133–158 (1995). (PMID: 774878510.1016/0925-4773(94)00310-J)
LeCun, Y., Bengio, Y. & Hinton, G. Deep learning. Nature 521, 436–444 (2015). (PMID: 2601744210.1038/nature14539)
Hartigan, J. A. & Wong, M. A. Algorithm AS 136: a K-means clustering algorithm. Appl. Stat. 28, 100–108 (1979). (PMID: 10.2307/2346830)
van der Maaten, L. & Hinton, G. Visualizing data using t-SNE. J. Mach. Learn. Res. 9, 2579–2605 (2008).
Clawson, W. P. & Levin, M. Endless forms most beautiful 2.0: teleonomy and the bioengineering of chimaeric and synthetic organisms. Biol. J. Linn. Soc. 139, 457–486 (2023). (PMID: 10.1093/biolinnean/blac073)
Rosenblueth, A., Wiener, N. & Bigelow, J. Behavior, purpose, and teleology. Philos. Sci. 10, 18–24 (1943). (PMID: 10.1086/286788)
Latora, V., Nicosia, V. & Russo, G. Complex Methods: Principles, Methods and Applications (Cambridge University Press, 2017).
Brin M., Stuck G. Introduction to Dynamical Systems (Cambridge University Press, 2002).
de Jong, H. Modeling and simulation of genetic regulatory systems: a literature review. J. Comput. Biol. 9, 67–103 (2002). (PMID: 1191179610.1089/10665270252833208)
Kim, D. et al. Gene regulatory network reconstruction: harnessing the power of single-cell multi-omic data. NPJ Syst. Biol. Appl. 9, 51 (2023). (PMID: 378576321058707810.1038/s41540-023-00312-6)
Schlitt, T. & Brazma, A. Current approaches to gene regulatory network modelling. BMC Bioinform. 8, S9 (2007). (PMID: 10.1186/1471-2105-8-S6-S9)
Ho, C. & Morsut, L. Novel synthetic biology approaches for developmental systems. Stem Cell Rep. 16, 1051–1064 (2021). (PMID: 10.1016/j.stemcr.2021.04.007)
Liu, Y. Y., Slotine, J. J. & Barabási, A. L. Controllability of complex networks. Nature 473, 167–173 (2011). (PMID: 2156255710.1038/nature10011)
Zañudo, J. G. T., Yang, G. & Albert, R. Structure-based control of complex networks with nonlinear dynamics. Proc. Natl. Acad. Sci. USA 114, 7234–7239 (2017). (PMID: 28655847551470210.1073/pnas.1617387114)
Gates, A. J. & Rocha, L. M. Control of complex networks requires both structure and dynamics. Sci. Rep. 6, 24456 (2016). (PMID: 27087469483450910.1038/srep24456)
Biswas, S., Manicka, S., Hoel, E. & Levin, M. Gene regulatory networks exhibit several kinds of memory: quantification of memory in biological and random transcriptional networks. iScience 24, 102131 (2021). (PMID: 33748699797012410.1016/j.isci.2021.102131)
Biswas, S., Clawson, W. & Levin, M. Learning in transcriptional network models: computational discovery of pathway-level memory and effective interventions. Int. J. Mol. Sci. 24, 285 (2022).
Mathews, J., Chang, A. J., Devlin, L. & Levin, M. Cellular signaling pathways as plastic, proto-cognitive systems: Implications for biomedicine. Patterns4, 100737 (2023). (PMID: 372232671020130610.1016/j.patter.2023.100737)
Baluška, F., Miller, W. B. & Reber, A. S. Cellular and evolutionary perspectives on organismal cognition: from unicellular to multicellular organisms. Biol. J. Linn. Soc. 139, 503–513 (2023). (PMID: 10.1093/biolinnean/blac005)
Reber, A. S. & Baluška, F. Cognition in some surprising places. Biochem. Biophys. Res. Commun. 564, 150–157 (2021). (PMID: 3295023110.1016/j.bbrc.2020.08.115)
Lyon, P. Of what is “minimal cognition” the half-baked version? Adapt. Behav. 28, 407–424 (2019). (PMID: 10.1177/1059712319871360)
Lyon, P. The biogenic approach to cognition. Cogn. Process 7, 11–29 (2006). (PMID: 1662846310.1007/s10339-005-0016-8)
Abramson, C. I. & Levin, M. Behaviorist approaches to investigating memory and learning: a primer for synthetic biology and bioengineering. Commun. Integr. Biol. 14, 230–247 (2021). (PMID: 34925687867700610.1080/19420889.2021.2005863)
Volkov, A. G., Nyasani, E. K., Blockmon, A. L. & Volkova, M. I. Memristors: memory elements in potato tubers. Plant Signal Behav. 10, e1071750 (2015). (PMID: 26237427488390410.1080/15592324.2015.1071750)
Kauffman S. A. The Origins of Order:Self Organization and Selection in Evolution (Oxford University Press, 1993).
Varley, T. F. & Bongard, J. Evolving higher-order synergies reveals a trade-off between stability and information-integration capacity in complex systems. Chaos 34, 063127 (2024). (PMID: 3886509210.1063/5.0200425)
Gallimore, A. R. Restructuring consciousness -the psychedelic state in light of integrated information theory. Front. Hum. Neurosci. 9, 346 (2015). (PMID: 26124719446417610.3389/fnhum.2015.00346)
Bayne, T. & Carter, O. Dimensions of consciousness and the psychedelic state. Neurosci. Conscious. 2018, niy008 (2018). (PMID: 30254752614615710.1093/nc/niy008)
Evolution and Diversification of Land Plants (Springer 1997).
Gullan, P. J. & Cranston, P. S. The Insects: an Outline of Entomology 5th edn (Wiley Blackwell, 2014).
Eryomin, A. L. Biophysics of evolution of intellectual systems. Biophysics67, 320–326 (2022). (PMID: 35789557924402610.1134/S0006350922020051)
Vallverdú, J. et al. Slime mould: the fundamental mechanisms of biological cognition. Biosystems 165, 57–70 (2018). (PMID: 2932606810.1016/j.biosystems.2017.12.011)
Pearson, G. et al. Mitogen-activated protein (MAP) kinase pathways: regulation and physiological functions. Endocr. Rev. 22, 153–183 (2001). (PMID: 11294822)
Veres, T. et al. Cellular forgetting, desensitisation, stress and ageing in signalling networks. When do cells refuse to learn more?. Cell Mol. Life Sci. 81, 97 (2024). (PMID: 383727501087675710.1007/s00018-024-05112-7)
Shreesha, L. & Levin, M. Stress sharing as cognitive glue for collective intelligences: a computational model of stress as a coordinator for morphogenesis. Biochem. Biophys. Res. Commun. 731, 150396 (2024). (PMID: 390189741135609310.1016/j.bbrc.2024.150396)
Jiang, L., Chen, Y., Luo, L. & Peck, S. C. Central roles and regulatory mechanisms of dual-specificity MAPK phosphatases in developmental and stress signaling. Front. Plant Sci. 9, 1697 (2018). (PMID: 30515185625598710.3389/fpls.2018.01697)
Barbuti, R., Gori, R., Milazzo, P. & Nasti, L. A survey of gene regulatory networks modelling methods: from differential equations, to Boolean and qualitative bioinspired models. J. Membr. Comput. 2, 207–226 (2020). (PMID: 10.1007/s41965-020-00046-y)
Etcheverry, M., Moulin-Frier, C., Oudeyer, P.-Y. & Levin, M. AI-driven automated discovery tools reveal diverse behavioral competencies of biological networks. Elife 13, RP92683 (2024).
Pietak, A. & Levin, M. Bioelectric gene and reaction networks: computational modelling of genetic, biochemical and bioelectrical dynamics in pattern regulation. J. R. Soc. Interface 14, 20170425 (2017).
Pietak, A. & Levin, M. Exploring instructive physiological signaling with the bioelectric tissue simulation engine. Front. Bioeng. Biotechnol. 4, 55 (2016). (PMID: 27458581493371810.3389/fbioe.2016.00055)
Riol, A., Cervera, J., Levin, M. & Mafé, S. Cell systems bioelectricity: how different intercellular gap junctions could regionalize a multicellular aggregate. Cancers 13, 5300 (2021).
Cervera, J., Levin, M. & Mafé, S. Bioelectrical coupling of single-cell states in multicellular systems. J. Phys. Chem. Lett. 11, 3234–3241 (2020). (PMID: 3224375410.1021/acs.jpclett.0c00641)
Cervera, J., Pai, V. P., Levin, M. & Mafé, S. From non-excitable single-cell to multicellular bioelectrical states supported by ion channels and gap junction proteins: Electrical potentials as distributed controllers. Prog. Biophys. Mol. Biol. 149, 39–53 (2019). (PMID: 3125570210.1016/j.pbiomolbio.2019.06.004)
Cervera, J., Manzanares, J. A., Mafé, S. & Levin, M. Synchronization of bioelectric oscillations in networks of nonexcitable cells: from single-cell to multicellular states. J. Phys. Chem. B 123, 3924–3934 (2019). (PMID: 3100357410.1021/acs.jpcb.9b01717)
Vanslambrouck, M. et al. Image-based force inference by biomechanical simulation. PLoS Comput. Biol. 20, e1012629 (2024). (PMID: 396217781163731310.1371/journal.pcbi.1012629)
Delile, J., Herrmann, M., Peyriéras, N. & Doursat, R. A cell-based computational model of early embryogenesis coupling mechanical behaviour and gene regulation. Nat. Commun. 8, 13929 (2017). (PMID: 28112150526401210.1038/ncomms13929)
Beloussov, L. V. & Grabovsky, V. I. A Geometro-mechanical model for pulsatile morphogenesis. Comput. Methods Biomech. Biomed. Eng. 6, 53–63 (2003). (PMID: 10.1080/1025584021000047641)
Bugaj, L. J., O’Donoghue, G. P. & Lim, W. A. Interrogating cellular perception and decision making with optogenetic tools. J. Cell Biol. 216, 25–28 (2017). (PMID: 2800333010.1083/jcb.201612094)
Friston, K. J. A free energy principle for biological systems. Entropy14, 2100–2121 (2012). (PMID: 10.3390/e14112100)
Safron, A. An integrated world modeling theory (IWMT) of consciousness: combining integrated information and global neuronal workspace theories with the free energy principle and active inference framework; toward solving the hard problem and characterizing agentic causation. Front. Artif. Intell. 3, 30 (2020). (PMID: 33733149786134010.3389/frai.2020.00030)
Lundbak Olesen, C., Waade, P. T., Albantakis, L. & Mathys, C. Phi fluctuates with surprisal: an empirical pre-study for the synthesis of the free energy principle and integrated information theory. PLoS Comput. Biol. 19, e1011346 (2023). (PMID: 378623641061980910.1371/journal.pcbi.1011346)
van Duijn, M. Phylogenetic origins of biological cognition: convergent patterns in the early evolution of learning. Interface Focus 7, 20160158 (2017). (PMID: 28479986541389710.1098/rsfs.2016.0158)
Watson, R. A. & Szathmáry, E. How can evolution learn? Trends Ecol. Evol. 31, 147–157 (2016). (PMID: 2670568410.1016/j.tree.2015.11.009)
Watson, R. A. et al. Evolutionary connectionism: algorithmic principles underlying the evolution of biological organisation in evo-devo, evo-eco and evolutionary transitions. Evol. Biol. 43, 553–581 (2016). (PMID: 2793285210.1007/s11692-015-9358-z)
Sznajder, B., Sabelis, M. W. & Egas, M. How adaptive learning affects evolution: reviewing theory on the Baldwin effect. Evol. Biol. 39, 301–310 (2012). (PMID: 2292385210.1007/s11692-011-9155-2)
Shreesha L., Levin M. Cellular competency during development alters evolutionary dynamics in an artificial embryogeny model. Entropy 25, 131 (2023).
Pio-Lopez, L., Bischof, J., LaPalme, J. V. & Levin, M. The scaling of goals from cellular to anatomical homeostasis: an evolutionary simulation, experiment and analysis. Interface Focus 13, 20220072 (2023). (PMID: 370652701010273410.1098/rsfs.2022.0072)
Jablonka, E. & Ginsburg, S. Learning and the evolution of conscious agents. Biosemiotics 15, 401–437 (2022). (PMID: 10.1007/s12304-022-09501-y)
Hinton, G. E. & Nowlan, J. How learning can guide evolution. Complex Syst. 1, 495–502 (1987).
Bayne, T. On the axiomatic foundations of the integrated information theory of consciousness. Neurosci. Conscious. 2018, niy007 (2018). (PMID: 30042860603081310.1093/nc/niy007)
Tononi, G. Integrated information theory of consciousness: an updated account. Arch. Ital. Biol. 150, 56–90 (2012). (PMID: 23165867)
Tononi, G. Consciousness as integrated information: a provisional manifesto. Biol. Bull. 215, 216–242 (2008). (PMID: 1909814410.2307/25470707)
Baluška, F., Reber, A. S. & Miller, W. B. Jr Cellular sentience as the primary source of biological order and evolution. Biosystems 218, 104694 (2022). (PMID: 3559519410.1016/j.biosystems.2022.104694)
Tan, T. H. et al. Odd dynamics of living chiral crystals. Nature 607, 287–293 (2022). (PMID: 3583159510.1038/s41586-022-04889-6)
Zampetaki A. V., Liebchen B., Ivlev A. V., Löwen H. Collective self-optimization of communicating active particles. Proc. Natl. Acad. Sci. USA 118, e2111142118 (2021).
Ozkan-Aydin, Y., Goldman, D. I. & Bhamla, M. S. Collective dynamics in entangled worm and robot blobs. Proc. Natl. Acad. Sci. USA 118, e2010542118 (2021).
Stern, M., Pinson, M. B. & Murugan, A. Continual learning of multiple memories in mechanical networks. Phys. Rev. X 10, 031044 (2020).
McGivern, P. Active materials: minimal models of cognition?. Adapt. Behav. 28, 441–451 (2019). (PMID: 10.1177/1059712319891742)
Bernheim-Groswasser, A., Gov, N. S., Safran, S. A. & Tzlil, S. Living matter: mesoscopic active materials. Adv. Mater. 30, e1707028 (2018). (PMID: 3025646310.1002/adma.201707028)
Kaspar, C., Ravoo, B. J., van der Wiel, W. G., Wegner, S. V. & Pernice, W. H. P. The rise of intelligent matter. Nature 594, 345–355 (2021). (PMID: 3413551810.1038/s41586-021-03453-y)
Adamatzky, A., Chiolerio, A. & Szaciłowski, K. Liquid metal droplet solves maze. Soft Matter 16, 1455–1462 (2020). (PMID: 3197699810.1039/C9SM01806A)
Safonov, A. A. Computing via natural erosion of sandstone. Int. J. Parallel, Emerg. Distrib. Syst. 33, 742–751 (2018). (PMID: 10.1080/17445760.2018.1455836)
Mayne, R., Whiting, J. & Adamatzky, A. Toxicity and applications of internalised magnetite nanoparticles within live paramecium caudatum cells. Bionanoscience 8, 90–94 (2018). (PMID: 2960015810.1007/s12668-017-0425-z)
Adamatzky, A. Towards fungal computer. Interface Focus 8, 20180029 (2018). (PMID: 30443330622780510.1098/rsfs.2018.0029)
Čejková, J., Banno, T., Hanczyc, M. M. & Štěpánek, F. Droplets as liquid robots. Artif. Life 23, 528–549 (2017). (PMID: 2898511310.1162/ARTL_a_00243)
Katz, E. Biocomputing—tools, aims, perspectives. Curr. Opin. Biotechnol. 34, 202–208 (2015). (PMID: 2576567210.1016/j.copbio.2015.02.011)
Etcheverry, M., Levin, M., Moulin-Frier, C. & Oudeyer P.-Y. SBMLtoODEjax: efficient simulation and optimization of biological network models in JAX. NeurIPS 2023 AI for Science Workshop (2023).
Blackiston, D. et al. Revealing non-trivial information structures in aneural biological tissues via functional connectivity. PLOS Comput. Biol. 21, e1012149 (2024).
Liu, T. T., Nalci, A. & Falahpour, M. The global signal in fMRI: nuisance or information? Neuroimage 150, 213–229 (2017). (PMID: 28213118540622910.1016/j.neuroimage.2017.02.036)
Afyouni, S., Smith, S. M. & Nichols, T. E. Effective degrees of freedom of the Pearson’s correlation coefficient under autocorrelation. Neuroimage 199, 609–625 (2019). (PMID: 31158478669355810.1016/j.neuroimage.2019.05.011)
Daube, C., Gross, J. & Ince, R. A. A. A whitening approach for transfer entropy permits the application to narrow-band signals. Preprint at https://arxiv.org/abs/2201.02461 (2022).
McMillen P., Walker S. I. & Levin M. Information theory as an experimental tool for integrating disparate biophysical signaling modules. Int. J. Mol. Sci. 23, 9580 (2022).
Williams, P. L. & Beer, R. D. Nonnegative decomposition of multivariate information. Preprint at https://arxiv.org/abs/1004.2515 (2010).
Tononi, G. An information integration theory of consciousness. BMC Neurosci. 5, 42 (2004). (PMID: 1552212154347010.1186/1471-2202-5-42)
Rosas, F. E., Mediano, P. A. M., Gastpar, M. & Jensen, H. J. Quantifying high-order interdependencies via multivariate extensions of the mutual information. Phys. Rev. E 100, 032305 (2019). (PMID: 3164003810.1103/PhysRevE.100.032305)
Barrett, A. B. Exploration of synergistic and redundant information sharing in static and dynamical Gaussian systems. Phys. Rev. E91, 052802 (2015). (PMID: 10.1103/PhysRevE.91.052802)
Friston, K. J. Functional and effective connectivity: a review. Brain Connect 1, 13–36 (2011). (PMID: 2243295210.1089/brain.2011.0008)
Jansma, A., Mediano, P. A. M. & Rosas, F. E. The Fast Möbius Transform: an algebraic approach to information decomposition. Preprint at https://arxiv.org/abs/2410.06224 (2024).
Kitazono, J., Kanai, R. & Oizumi, M. Efficient algorithms for searching the minimum information partition in integrated information theory. Entropy 20, 173 (2018).
Entry Date(s):
Date Created: 20250709 Date Completed: 20250709 Latest Revision: 20260223
Update Code:
20260224
PubMed Central ID:
PMC12241368
DOI:
10.1038/s42003-025-08411-2
PMID:
40634498
Database:
MEDLINE
*Further Information*
*How does learning affect the integration of an agent's internal components into an emergent whole? We analyzed gene regulatory networks, which learn to associate distinct stimuli, using causal emergence, which captures the degree to which an integrated system is more than the sum of its parts. Analyzing 29 biological (experimentally derived) networks before, during, after training, we discovered that biological networks increase their causal emergence due to training. Clustering analysis uncovered five distinct ways in which networks' emergence responds to training, not mapping to traditional ways to characterize network structure and function but correlating to different biological categories. Our analysis reveals how learning can reify the existence of an agent emerging over its parts and suggests that this property is favored by evolution. Our data have implications for the scaling of diverse intelligence, and for a biomedical roadmap to exploit these remarkable features in networks with relevance for health and disease.
(© 2025. The Author(s).)*
*Competing interests: M.L. receives funding in the form of a sponsored research agreement to Tufts University from Astonishing Labs, a company that seeks to advance biomedicine via tools that exploit the basal cognition of molecular networks. All other authors declare no competing interests.*