TY - JOUR
T1 - Evolution of learning and levels of selection
T2 - A lesson from avian parent-offspring communication
AU - Lotem, Arnon
AU - Biran-Yoeli, Inbar
N1 - Funding Information: The authors wish to thank I. Erev for many fruitful discussions and suggestions, E. Borenstein, R. Dor, U. Grodzinski, M. Rodriguez-Girones, M. Kölliker and R. Ydenberg, for helpful comments at various stages of this project, and M.W. Feldman and another anonymous reviewer for improving the manuscript. This study was supported by the Israel Science Foundation Grants no. 353/03-17.2 and 1312/11 to A.L.
PY - 2014/2
Y1 - 2014/2
N2 - In recent years, it has become increasingly clear that the evolution of behavior may be better understood as the evolution of the learning mechanisms that produce it, and that such mechanisms should be modeled and tested explicitly. However, this approach, which has recently been applied to animal foraging and decision-making, has rarely been applied to the social and communicative behaviors that are likely to operate in complex social environments and be subject to multi-level selection. Here we use genetic, agent-based evolutionary simulations to explore how learning mechanisms may evolve to adjust the level of nestling begging (offspring signaling of need), and to examine the possible consequences of this process for parent-offspring conflict and communication. In doing so, we also provide the first step-by-step dynamic model of parent-offspring communication. The results confirm several previous theoretical predictions and demonstrate three novel phenomena. First, negatively frequency-dependent group-level selection can generate a stable polymorphism of learning strategies and parental responses. Second, while conventional reinforcement learning models fail to cope successfully with family dynamics at the nest, a newly developed learning model (incorporating behaviors that are consistent with recent experimental results on learning in nestling begging) produced effective learning, which evolved successfully. Third, while kin-selection affects the frequency of the different learning genes, its impact on begging slope and intensity was unexpectedly negligible, demonstrating that evolution is a complex process, and showing that the effect of kin-selection on behaviors that are shaped by learning may not be predicted by simple application of Hamilton's rule.
AB - In recent years, it has become increasingly clear that the evolution of behavior may be better understood as the evolution of the learning mechanisms that produce it, and that such mechanisms should be modeled and tested explicitly. However, this approach, which has recently been applied to animal foraging and decision-making, has rarely been applied to the social and communicative behaviors that are likely to operate in complex social environments and be subject to multi-level selection. Here we use genetic, agent-based evolutionary simulations to explore how learning mechanisms may evolve to adjust the level of nestling begging (offspring signaling of need), and to examine the possible consequences of this process for parent-offspring conflict and communication. In doing so, we also provide the first step-by-step dynamic model of parent-offspring communication. The results confirm several previous theoretical predictions and demonstrate three novel phenomena. First, negatively frequency-dependent group-level selection can generate a stable polymorphism of learning strategies and parental responses. Second, while conventional reinforcement learning models fail to cope successfully with family dynamics at the nest, a newly developed learning model (incorporating behaviors that are consistent with recent experimental results on learning in nestling begging) produced effective learning, which evolved successfully. Third, while kin-selection affects the frequency of the different learning genes, its impact on begging slope and intensity was unexpectedly negligible, demonstrating that evolution is a complex process, and showing that the effect of kin-selection on behaviors that are shaped by learning may not be predicted by simple application of Hamilton's rule.
KW - Game theory
KW - Honest signaling
KW - Kin-selection
KW - Learning rules
KW - Nestling begging
KW - Parent-offspring conflict
UR - http://www.scopus.com/inward/record.url?scp=84891157958&partnerID=8YFLogxK
U2 - https://doi.org/10.1016/j.tpb.2013.10.003
DO - https://doi.org/10.1016/j.tpb.2013.10.003
M3 - مقالة
SN - 0040-5809
VL - 91
SP - 58
EP - 74
JO - Theoretical Population Biology
JF - Theoretical Population Biology
ER -