Invariance in ecological pattern

Frank, Steven A.; Bascompte, Jordi

doi:10.12688/f1000research.21586.1

Cited by 6 publications

(4 citation statements)

References 48 publications

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“… 47 Some of this dynamic is captured by the emphasis of the extended evolutionary synthesis approach [ 190 , 191 , 192 , 193 , 194 ]. This is especially consistent with the concepts of constructive neutral evolution and the paradox of robustness developed by Susan Lindquist and Steve Frank [ 195 , 196 , 197 , 198 , 199 , 200 , 201 , 202 , 203 , 204 , 205 , 206 , 207 , 208 ]. In the evolutionary context, robust traits enable degeneracy and drift to accumulate underneath, providing a ratchet which stabilizes the trait (since it is now required to tame the noise underneath).…”

Section: Notessupporting

confidence: 85%

“…Behavioral intelligence in 3D space evolved from morphogenetic problem-solving competencies in anatomical space [97,124]. Those competencies in turn were required by the inevitability of evolutionary and physiological damage (mutations and injury), and the ratchet mechanisms of constructive neutral evolution and the paradox of robustness [203][204][205][206][207][208]. The capacity for creative robustness is implemented by the polycomputing property-the ability to see the same physical process as computing and providing different functions depending on perspective 62 .…”

Section: Discussionmentioning

confidence: 99%

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Self-Improvising Memory: A Perspective on Memories as Agential, Dynamically Reinterpreting Cognitive Glue

Levin

2024

Entropy

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Many studies on memory emphasize the material substrate and mechanisms by which data can be stored and reliably read out. Here, I focus on complementary aspects: the need for agents to dynamically reinterpret and modify memories to suit their ever-changing selves and environment. Using examples from developmental biology, evolution, and synthetic bioengineering, in addition to neuroscience, I propose that a perspective on memory as preserving salience, not fidelity, is applicable to many phenomena on scales from cells to societies. Continuous commitment to creative, adaptive confabulation, from the molecular to the behavioral levels, is the answer to the persistence paradox as it applies to individuals and whole lineages. I also speculate that a substrate-independent, processual view of life and mind suggests that memories, as patterns in the excitable medium of cognitive systems, could be seen as active agents in the sense-making process. I explore a view of life as a diverse set of embodied perspectives—nested agents who interpret each other’s and their own past messages and actions as best as they can (polycomputation). This synthesis suggests unifying symmetries across scales and disciplines, which is of relevance to research programs in Diverse Intelligence and the engineering of novel embodied minds.

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Section: Notessupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Self-Improvising Memory: A Perspective on Memories as Agential, Dynamically Reinterpreting Cognitive Glue

Levin

2024

Entropy

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“…All these processes can be modeled as multiplicative phenomena that change the size of a gene by a stochastic factor. The distribution arising from such a multiplicative process is precisely the lognormal distribution 17,18 , the very same one we have reported for gene and protein length distributions.…”

supporting

confidence: 82%

The emergence of eukaryotes as an evolutionary algorithmic phase transition

Bascompte

Muro

Ballesteros

et al. 2023

Preprint

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The origin of eukaryotes represents one of the most significant events in evolution, since it allowed the posterior emergence of multicellular organisms1,2. Evolutionary biologists have tried to unveil the mechanism leading to eukaryotes, most likely the symbiosis between two previously unrelated organisms3. Yet, it remains unclear how the genetic architecture of life was transformed to allow this increase in complexity. Here, we try to fill this gap by studying the size distributions of genes and their corresponding proteins in 6,519 species across the tree of life. We find a scale-invariant relationship between gene mean length and variance, with clades appearing in evolutionary order. Our analysis unveils a common multiplicative process of gene growth along evolution, but reveals a phase transition corresponding with the emergence of the eukaryotic cell. Proteins and genes grow in parallel in prokaryotes. However, the number of constraints in order to have a protein with the right three-dimensional structure increases very fast with its length. This increasing computational difficulty eventually gave way to a new phase as happens in the phase transitions of certain search algorithms4-6. This new regulatory phase is characterized by the incorporation of gene non-coding sequences7-9, in agreement with the introns-late model8. Our approach allows us to predict not only the macroscopic details underlying the emergence of eukaryotes (e.g., the rate and shape of this evolutionary innovation), but the timing of this event.

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“…Therefore, we have to ask here: Are not forest resistance and resilience to disturbances the result of ecological invariance? Because the essence of ecological patterns and processes is invariance [6]. Ecological invariants are known as "scaling" and "power laws" that describe power relationships across species or across ecological systems [7].…”

Section: Introductionmentioning

confidence: 99%

Forest Climax Phenomenon: An Invariance of Scale

Petrokas

2020

Forests

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We can think of forests as multiscale multispecies networks, constantly evolving toward a climax or potential natural community—the successional process-pattern of natural regeneration that exhibits sensitivity to initial conditions. This is why I look into forest succession in light of the Red Queen hypothesis and focus on the key aspects of ecological self-organisation: dynamical criticality, evolvability and intransitivity. The idea of the review is that forest climax should be associated with habitat dynamics driven by a large continuum of ecologically equivalent time scales, so that the same ecological conclusions could be drawn statistically from any scale. A synthesis of the literature is undertaken in order to (1) present the framework for assessing habitat dynamics and (2) present the types of successional trajectories based on tree regeneration mode in forest gaps. In general, there are four types of successional trajectories within the process-pattern of forest regeneration that exhibits sensitivity to initial conditions: advance reproduction specialists, advance reproduction generalists, early reproduction generalists and early reproduction specialists. A successional trajectory is an expression of a fractal connectivity among certain patterns of natural regeneration in the multiscale multispecies networks of landscape habitats. Theoretically, the organically derived measures of pattern diversity, integrity and complexity, determined by the rates of recruitment, growth and mortality of forest tree species, are the means to test the efficacy of specific interventions to avert the disturbance-related decline in forest regeneration. That is of relevance to the emerging field of biocomplexity research.

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Invariance in ecological pattern

Cited by 6 publications

References 48 publications

Self-Improvising Memory: A Perspective on Memories as Agential, Dynamically Reinterpreting Cognitive Glue

Self-Improvising Memory: A Perspective on Memories as Agential, Dynamically Reinterpreting Cognitive Glue

The emergence of eukaryotes as an evolutionary algorithmic phase transition

Forest Climax Phenomenon: An Invariance of Scale

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