Taming fitness: Organism‐environment interdependencies preclude long‐term fitness forecasting

Doulcier

Rose

et al. 2021

Preprint

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Evolutionary transitions in individuality (ETIs) involve the formation of Darwinian collectives from Darwinian particles. The transition from cells to multicellular life is a prime example. During an ETI, collectives become units of selection in their own right. However, the underlying processes are poorly understood. One observation used to identify the completion of an ETI is an increase in collective-level performance accompanied by a decrease in particle-level performance, for example, measured by growth rate. This seemingly counterintuitive dynamic has been referred to as "fitness decoupling" and has been used to interpret both models and experimental data. Using a mathematical approach we show this concept to be problematic in that the fitness of particles and collectives can never decouple: calculations of particle and collective fitness performed over appropriate and equivalent time intervals are necessarily the same. By way of solution, we draw attention to the value of mechanistic approaches that emphasise traits as opposed to fitness and tradeoffs among traits. This trait-based approach is sufficient to capture dynamics that underpin evolutionary transitions. In addition, drawing upon both experimental and theoretical studies, we show that while early stages of transitions might often involve tradeoffs among particle traits, later--and critical--stages are likely to involve rupture of such tradeoffs. Tradeoff-breaking thus stands as a useful marker for ETIs.

Section: Resultsmentioning

confidence: 99%

Section: Comparing Fitnessesmentioning

confidence: 99%

Tradeoff breaking as model of evolutionary transitions in individuality and the limits of the fitness decoupling metaphor

Doulcier

Rose

et al. 2021

Preprint

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“…The main reason is that it seems to imply that fitness is a material quantity that can be transferred from one entity to another, comparable to a liquid that can be poured from one container to another. While, at first glance, this analogy may seem a helpful image to get an intuitive idea of the problem, it contradicts our modern understanding of fitness as a predictor of evolutionary success (Bourrat, 2015a, 2015b; Doulcier et al, 2021). First, it implies that some cells with nil fitness or close to it are not dead, contradicting the principle of natural selection.…”

Section: Introductionmentioning

confidence: 95%

“…Instead, it must be tied to its potential success (or success in the long run). Without this point acknowledged, fitness is condemned to be tautological, as philosophers and biologists alike have long recognized (Manser, 1965; Popper, 1974; Smart, 2014; reviewed in Doulcier et al, 2021). 2 This conundrum led to establishing several frameworks for the interpretation of fitness, one among which is the propensity interpretation of fitness (Beatty, 1984; Brandon, 1978; Pence & Ramsey, 2013).…”

Section: Introductionmentioning

confidence: 99%

Life history tradeoffs, division of labor and evolutionary transitions in individuality

Doulcier

Hammerschmidt²,

2020

Preprint

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Reproductive division of labor has been proposed to play a key role for evolutionary transitions in individuality (ETIs). This chapter provides a guide to a theoretical model that addresses the role of a tradeoff between life-history traits in selecting for a reproductive division of labor during the transition from unicellular to multicellular organisms. In particular, it focuses on the five keys assumptions of the model, namely (1) fitness is viability times fecundity; (2) collective traits are linear functions of their cellular counterparts; (3) there is a tradeoff between cell viability and fecundity; (4) cell contribution to the collective is optimal; and (5) there is an initial reproductive cost in large collectives. Thereafter the chapter contrasts two interpretations of the model in the context of ETIs. Originally, the model was interpreted as showing that during the transition to multicellularity the fitness of the lower-level (the cells) is 'transferred' to the higher level (the collective). Despite its apparent intuitiveness, fitness transfer may obscure actual mechanisms in metaphorical language. Thus, an alternative and more conservative interpretation of the model that focuses on cell traits and the evolutionary constraints that links them is advocated. In addition, it allows for pursuing subsequent questions, such as the evolution of development.

“…Suppose a two-level setting in which particles are nested in collectives. Suppose, further, that collective-level and particle-level reproduction occurs 58 Another way to make the same point is that several authors have argued that, to be associated with natural selection, fitness must be a "static" property (see Ramsey 2006;Abrams 2009;Pence and Ramsey 2013;Bourrat 2015a;Bourrat 2017;Doulcier et al 2021). If fitness is variable, as in Okasha's example, it can no longer refer to natural selection.…”

Section: Fitness Decoupling : : : and Recouplingmentioning

confidence: 99%

Facts, Conventions, and the Levels of Selection

2021

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Debates concerning the units and levels of selection have persisted for over fifty years. One major question in this literature is whether units and levels of selection are genuine, in the sense that they are objective features of the world, or merely reflect the interests and goals of an observer. Scientists and philosophers have proposed a range of answers to this question. This Element introduces this literature and proposes a novel contribution. It defends a realist stance and offers a way of delineating genuine levels of selection by invoking the notion of a functional unit.