The Computational Boundary of a “Self”: Developmental Bioelectricity Drives Multicellularity and Scale-Free Cognition

Levin, Michael

doi:10.3389/fpsyg.2019.02688

Cited by 161 publications

(235 citation statements)

References 293 publications

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“…If complexity is a measure of problem-solving capacity, then to some degree the opposites are true. An organism or system "complexifies" over time when it faces challenges, opportunities, or environments that it is ill equipped to handle [134][135][136]. With greater complexity come new options, additional flexibility, and expanded information processing.…”

Section: Organizing Principlesmentioning

confidence: 99%

Science-Driven Societal Transformation, Part I: Worldview

Boik

2020

Sustainability

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Humanity faces serious social and environmental problems, including climate change and biodiversity loss. Increasingly, scientists, global policy experts, and the general public conclude that incremental approaches to reduce risk are insufficient and transformative change is needed across all sectors of society. However, the meaning of transformation is still unsettled in the literature, as is the proper role of science in fostering it. This paper is the first in a three-part series that adds to the discussion by proposing a novel science-driven research-and-development program aimed at societal transformation. More than a proposal, it offers a perspective and conceptual framework from which societal transformation might be approached. As part of this, it advances a formal mechanics with which to model and understand self-organizing societies of individuals. While acknowledging the necessity of reform to existing societal systems (e.g., governance, economic, and financial systems), the focus of the series is on transformation understood as systems change or systems migration—the de novo development of and migration to new societal systems. The series provides definitions, aims, reasoning, worldview, and a theory of change, and discusses fitness metrics and design principles for new systems. This first paper proposes a worldview, built using ideas from evolutionary biology, complex systems science, cognitive sciences, and information theory, which is intended to serve as the foundation for the R&D program. Subsequent papers in the series build on the worldview to address fitness metrics, system design, and other topics.

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Section: Organizing Principlesmentioning

confidence: 99%

Science-Driven Societal Transformation, Part I: Worldview

Boik

2020

Sustainability

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“…Quantitative morphological analysis and an unbiased machine-learning approach revealed that this capability included significant distance in both time and space: small pieces of Physarum were able to detect the presence of objects at a distance of several centimeters, and decide which way to go hours before actually moving in that direction. This reveals a minimum bound on the spatio-temporal boundary of the basal cognition of this organism (Levin, 2019).…”

Section: Discussionmentioning

confidence: 79%

Mechanosensation Mediates Long-Range Spatial Decision-Making in an Aneural Organism

Murugan

Kaltman

Jin

et al. 2020

Preprint

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Running title:Mechanical force sensing underlies Physarum aneural cognition AbstractThe unicellular protist Physarum polycephalum is an important emerging model for understanding how aneural organisms process information toward adaptive behavior. Here, we reveal that Physarum can use mechanosensation to reliably make decisions about distant objects its environment, preferentially growing in the direction of heavier, substrate-deforming but chemically-inert masses. This long-range mass-sensing is abolished by gentle rhythmic mechanical disruption, changing substrate stiffness, or addition of a mechanosensitive transient receptor potential channel inhibitor. Computational modeling revealed that Physarum may perform this calculation by sensing the fraction of its growth perimeter that is distorted above a threshold straina fundamentally novel method of mechanosensation. Together, these data identify a surprising behavioral preference relying on biomechanical features and not nutritional content, and characterize a new example of an aneural organism that exploits physics to make decisions about growth and form. Highlights The aneural Physarum makes behavioral decisions by control of its morphology  It has a preference for larger masses, which it can detect at long range  This effect is mediated by mechanosensing, not requiring chemical attractants  Machine learning reveals that it surveys environment and makes decision in < 4 hours  A biophysical model reveals how its pulsations enable long-distance mapping of environmental features A defining feature of any living organism is its ability to select actions that maximize utility in diverse environments (Barandiaran and Moreno, 2006). Decision-making is a process that is well-characterized in behavioral studies of human and other vertebrate species possessing nervous systems. Increasingly, it is also recognized as a fundamental capability whose evolutionary roots extend to the most basal forms on the tree of life (Baluška and Levin, 2016;Lyon, 2006Lyon, , 2015. Even unicellular organisms, including bacteria, have been studied as computational systems that collect information from their environment and use it to guide subsequent behaviors (Balazsi et al.

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“…The "cells" in these models are Bayesian agents employing active inference (Friston, 2010;; they have both long-term (genetic) and short-term (cellular state) memories, inferential and communication capabilities, and the ability to modify their local microenvironment by moving in space relative to the other cells. They therefore exhibit a kind of "basal cognition" (Baluška and Levin, 2016;Levin, 2019) in the sense of systems that exhibit memories and make decisions about possible outcomes in a contextspecific manner. In these models, communication is cooperative: the cells do not withhold information, provide misinformation, manipulate each other's information processing, or send signals telling other cells to stop dividing or die.…”

Section: Building a Body Is Building An Environmentmentioning

confidence: 99%

Why isn’t sex optional? Stem-cell competition, loss of regenerative capacity, and cancer in metazoan evolution

Fields

Levin

2020

Communicative & Integrative Biology

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Animals that can reproduce vegetatively by fission or budding and also sexually via specialized gametes are found in all five primary animal lineages (Bilateria, Cnidaria, Ctenophora, Placozoa, Porifera). Many bilaterian lineages, including roundworms, insects, and most chordates, have lost the capability of vegetative reproduction and are obligately gametic. We suggest a developmental explanation for this evolutionary phenomenon: obligate gametic reproduction is the result of germline stem cells winning a winner-take-all competition with non-germline stem cells for control of reproduction and hence lineage survival. We develop this suggestion by extending Hamilton's rule, which factors the relatedness between parties into the cost/benefit analysis that underpins cooperative behaviors, to include similarity of cellular state. We show how coercive or deceptive cell-cell signaling can be used to make costly cooperative behaviors appear less costly to the cooperating party. We then show how competition between stem-cell lineages can render an ancestral combination of vegetative reproduction with facultative sex unstable, with one or the other process driven to extinction. The increased susceptibility to cancer observed in obligately-sexual lineages is, we suggest, a side-effect of deceptive signaling that is exacerbated by the loss of whole-body regenerative abilities. We suggest a variety of experimental approaches for testing our predictions.

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The Computational Boundary of a “Self”: Developmental Bioelectricity Drives Multicellularity and Scale-Free Cognition

Cited by 161 publications

References 293 publications

Science-Driven Societal Transformation, Part I: Worldview

Science-Driven Societal Transformation, Part I: Worldview

Mechanosensation Mediates Long-Range Spatial Decision-Making in an Aneural Organism

Why isn’t sex optional? Stem-cell competition, loss of regenerative capacity, and cancer in metazoan evolution

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