Influence of Plasticity and Learning on Evolution under Directional Selection

Paenke, Ingo; Sendhoff, Bernhard; Kawecki, Tadeusz J.

doi:10.1086/518952

Cited by 119 publications

(159 citation statements)

References 30 publications

Supporting

Mentioning

157

Contrasting

Order By: Relevance

“…However, learning can be costly, such as when it results in the copying of maladaptive behavior that leads to the rejection of conspecific or acceptance of heterospecific mates, or misidentification of competitors [82,94]. Fourth, learning influences the strength and direction of selection by shaping phenotypic variation and its relationship to genetic variation [81]. For example, learned recognition can permit selection causing character displacement of recognition traits [82].…”

Section: Box 4 Learningmentioning

confidence: 99%

“…Current theory also fails to fully address the consequences of asymmetries in behavioral interference [79,80], while empirical research suggests that asymmetries are common and closely linked to the ecological and evolutionary consequences of the interactions [25,27,42,45,47]. Learned mate and competitor recognition also pose interesting and largely unexplored challenges (Box 4; see Outstanding Questions) [81,82]. Further integration of theoretical and empirical research is needed.…”

Section: Concluding Remarks and Future Directionsmentioning

confidence: 99%

See 1 more Smart Citation

Causes and Consequences of Behavioral Interference between Species

Grether

Peiman

Tobias

et al. 2017

Trends in Ecology & Evolution

131

156

View full text Add to dashboard Cite

Behavioral interference between species, such as territorial aggression, courtship, and mating, is widespread in animals. While aggressive and reproductive forms of interspecific interference have generally been studied separately, their many parallels and connections warrant a unified conceptual approach. Substantial evidence exists that aggressive and reproductive interference have pervasive effects on species coexistence, range limits, and evolutionary processes, including divergent and convergent forms of character displacement. Alien species invasions and climate change-induced range shifts result in novel interspecific interactions, heightening the importance of predicting the consequences of species interactions, and behavioral interference is a fundamental but neglected part of the equation. Here, we outline priorities for further theoretical and empirical research on the ecological and evolutionary consequences of behavioral interference. Interspecific Aggression and Reproductive InterferenceFew subjects in animal behavior have attracted more attention than aggression and sex, yet research tends to stop at species boundaries even when the behaviors themselves do not. Aggressive and sexual interactions between species are surprisingly common and share many parallels in their causes and ecological and evolutionary effects [1][2][3][4][5][6]. Both types of behavioral interference (Box 1) have been hypothesized to: (i) arise as a byproduct of intraspecific interactions (Box 2); (ii) cause local extinction as well as temporal and spatial habitat partitioning; (iii) prevent species from coexisting that otherwise would be expected to coexist; (iv) enable coexistence between species that otherwise would not be expected to coexist; (v) promote or prevent species range shifts and the spread of invasive species; (vi) cause sympatric species to diverge or converge through character displacement processes; (vii) cause populations within a species to diverge from each other due to character displacement in areas of sympatry; and (viii) contribute to reproductive isolation and speciation ( Figure 1).Despite their connections, aggressive interference and reproductive interference (see Glossary) have largely been studied by different researchers in relation to different theoretical frameworks [2,4,7] and in different study systems [3], even though many closely related species interfere with each other in both ways (see Table S1 in [8]). We do not believe that these two categories of interspecific interactions should be synonymized, because this would obscure important differences between them. Instead, we propose that their similarities and interrelationships merit a common conceptual framework, which we introduce here ( Figure 1). TrendsAggressive and reproductive forms of behavioral interference between species are widespread in animals and share many parallels in their underlying causes and their ecological and evolutionary effects.Behavioral interference can determine whether species coexist and, thus, affects speci...

show abstract

Section: Box 4 Learningmentioning

confidence: 99%

Section: Concluding Remarks and Future Directionsmentioning

confidence: 99%

Causes and Consequences of Behavioral Interference between Species

Grether

Peiman

Tobias

et al. 2017

Trends in Ecology & Evolution

131

156

View full text Add to dashboard Cite

show abstract

“…Andersson 1995;Dopazo et al 2001). Recent models (Borenstein et al 2006;Paenke et al 2007) represent an attempt at unifying these predictions and do so by defining the theoretical conditions under which one or the other effect of learning prevails. In particular, Paenke et al (2007) argue that the curvature of the fitness landscape predicts when adaptive learning accelerates or decelerates evolution because it determines whether learning confers a larger fitness increase to those phenotypes (as well as underlying genotypes) that are relatively closer to the fitness peak (see also Egas et al (2004) for a similar argument).…”

Section: Learning and Evolution á The Baldwin Effectmentioning

confidence: 99%

“…The common approach in theoretical studies of the Baldwin effect (including Paenke et al 2007) is to assume that the learning ability does not evolve. However, the emerging empirical evidence shows a genetic basis for learning ability such that it is possible to select for higher or lower levels of learning (McGuire and Hirsch 1977;Mery and Kawecki 2002;Dukas 2004).…”

Section: Learning and Evolution á The Baldwin Effectmentioning

confidence: 99%

The interplay between genetic and learned components of behavioral traits

Sznajder

Sabelis

Egas

2011

Journal of Plant Interactions

View full text Add to dashboard Cite

This article considers the evolution of behavioral traits that have both a genetic basis and can be modified. The modifications considered concern an adaptive (learnt) response to environmental influences. In theory, the evolution of such traits may lead to two extreme outcomes; one where the trait becomes genetically fixed (and phenotypically invariable) and the other where it is entirely shaped by environmental influences. Between these extremes lies a spectrum of traits containing a genetic component, but also, to differing degrees, a modifiable component. We review theory considering how learning may affect the genetic evolution of a behavioral trait (commonly referred to as the Baldwin effect). We claim behavioral interactions in tritrophic systems, such as the responses of natural enemies to herbivore-induced plant volatiles, provide an excellent model system to study the Baldwin effect and we illustrate this with recent findings on the searching behavior of the predatory mite Phytoseiulus persimilis.

show abstract

“…That is, how does phenotypic plasticity influence population establishment or persistence (for example, Chevin et al, 2010)? Once the population has established itself, how does plasticity influence rates and patterns of adaptation (reviewed in Paenke et al, 2007)? Finally, following local adaptation, does plasticity affect mate choice (for example, Price et al, 2003;Craig et al, 2005;Edelaar et al, 2008;Deere et al, 2012) thus promoting speciation (for example, Edelaar et al, 2008;Havens and Etges, 2013)?…”

Section: Introductionmentioning

confidence: 99%

Effects of dispersal plasticity on population divergence and speciation

Arendt

2015

Heredity

View full text Add to dashboard Cite

Phenotypic plasticity is thought to have a role in driving population establishment, local adaptation and speciation. However, dispersal plasticity has been underappreciated in this literature. Plasticity in the decision to disperse is taxonomically widespread and I provide examples for insects, molluscs, polychaetes, vertebrates and flowering plants. Theoretical work is limited but indicates an interaction between dispersal distance and plasticity in the decision to disperse. When dispersal is confined to adjacent patches, dispersal plasticity may enhance local adaptation over unconditional (non-plastic) dispersal. However, when dispersal distances are greater, plasticity in dispersal decisions strongly reduces the potential for local adaptation and population divergence. Upon dispersal, settlement may be random, biased but genetically determined, or biased but plastically determined. Theory shows that biased settlement of either type increases population divergence over random settlement. One model suggests that plasticity further enhances chances of speciation. However, there are many strategies for deciding on where to settle such as a best-of-N strategy, sequential sampling with a threshold for acceptance or matching with natal habitat. To date, these strategies do not seem to have been compared within a single model. Although we are just beginning to explore evolutionary effects of dispersal plasticity, it clearly has the potential to enhance as well as inhibit population divergence. Additional work should pay particular attention to dispersal distance and the strategy used to decide on where to settle.

show abstract

Influence of Plasticity and Learning on Evolution under Directional Selection

Cited by 119 publications

References 30 publications

Causes and Consequences of Behavioral Interference between Species

Causes and Consequences of Behavioral Interference between Species

The interplay between genetic and learned components of behavioral traits

Effects of dispersal plasticity on population divergence and speciation

Contact Info

Product

Resources

About