Abstract
Interactions between individuals are thought to shape evolution and speciation through natural selection, but little is known about how an individual (or player) strategically interacts with others to maximize its payoff. We develop a simple decision-theoretic model that generates four hypotheses about the choice of an optimal behavioral strategy by a player in response to the strategies of other players. The golden threshold hypothesis suggests that 62% is the critical threshold determining the transition of a larger player's strategy in reaction to its smaller dove-like partner. Below this critical point, the larger one exploits the smaller one, whereas above it, the larger one chooses to cooperate with the smaller one. The competition-to-cooperation shift hypothesis states that a larger player never cooperates with a smaller hawk-like player unless the former is reversely surpassed in size by the latter by 75%. The Fibonacci retracement mark hypothesis proposes that, faced with a larger dove-like player, a smaller player chooses to either cooperate or cheat, depending on whether its size relative to the larger player is less or more than 38%. The surrender-resistance hypothesis suggests that, in reaction to a larger hawk-like player, a smaller player can either gain some benefit from resistance or is sacrificed by choosing to surrender. We test these hypotheses by re-analyzing body mass data of full-sib fishes that were co-cultured in a common water pool. Pairwise analysis of these co-existing fishes broadly suggests the prediction of our hypotheses. Taken together, our model unveils detectable yet previously unknown quantitative mechanisms that mediate the strategic choice of animal behavior in populations or communities. Given the ubiquitous nature of biological interactions occurring at different levels of organizations and the paucity of quantitative approaches to understand them, results by our decision-theoretic model represent an initial step towards the deeper understanding of how biological entities interact with each other to drive their evolution.
Highlights
Organisms in communities from bacteria colonies to human societies should mutually interact in various ways to form complex behavioral relationships as they strive to acquire resources for survival and reproduction (Stachowicz 2001; Perc et al, 2013; Barraclough 2015; Jolles et al, 2020)
We found that a significant positive correlation exists between zmuðtÞ and MuðtÞ (P < 0.001) over cooperation and competition regions in all three experiments EP (Figure 2A) and SP (Figure 2B)
Correlation analysis of networks suggests that the pattern of social interactions does not depend on how much genetic similarity there is between the fish
Summary
Organisms in communities from bacteria colonies to human societies should mutually interact in various ways to form complex behavioral relationships as they strive to acquire resources for survival and reproduction (Stachowicz 2001; Perc et al, 2013; Barraclough 2015; Jolles et al, 2020) These interactions range from antagonistic to mutualistic, including exploitation and altruism. Phenotypic heterogeneity that mediates collective behaviors and group-level pattern and assortment is determined by many morphological, physiological (i.e., biomechanics, energetics, and neuroendocrinology), and cognitive traits Among all these traits that are strongly hierarchical, body size is considered as a key driving force of animal interaction strategies We develop a simple decision-theoretic model and apply it to a real-world problem, from which a rule of thumb is extracted to guide animal interactions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
