Evolution of bower building in Lake Malawi cichlid fish: phylogeny, morphology, and behavior

York, Ryan A.; Patil, Chinar; Hulsey, C. Darrin; Anoruo, Onyemaechi; Streelman, J. Todd; Fernald, Russell D.

doi:10.3389/fevo.2015.00018

Cited by 33 publications

(47 citation statements)

References 68 publications

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“…In York et al (2015) we provide evidence that amongst the cichlid fish of Lake Malawi, Africa adaptions arising from stages (i) (macrohabitat) and (ii) (trophic style) have influenced the evolution of a courtship signal: the construction of sand mating nests or "bowers." Males of more than 100 species within the sand-dwelling lineage of Malawi cichlids seasonally build bowers in large aggregations ("leks") solely in order to attract and mate with females, a purpose almost identical to that of the eponymous bowerbirds of Oceania (Diamond, 1986;McKaye et al, 2001;Magalhaes et al, 2013).…”

Section: Key Concept 4 | Adaptive Radiations (Ars)mentioning

confidence: 99%

“…first major feature of the landscape is that there are several of instances or repeated evolution with more than 10 conversions including the evolution of bower building in cichlid fish (likely >10 conversions; York et al, 2015) and eusociality across inverterbrates and vertebrate taxa (17 conversions; Duffy et al, 2000). A density distribution of repeated behavioral evolution instances across evolutionary time ( Figure 1B) shows a skew toward more recent evolutionary events with the majority of <100 MYA (39/49; 79.59%).…”

Section: Key Concept 3 | Phenotypic Transitionsmentioning

confidence: 99%

“…Males of more than 100 species within the sand-dwelling lineage of Malawi cichlids seasonally build bowers in large aggregations ("leks") solely in order to attract and mate with females, a purpose almost identical to that of the eponymous bowerbirds of Oceania (Diamond, 1986;McKaye et al, 2001;Magalhaes et al, 2013). Bowers are extended phenotypes that can exist in two basis form: "pits"-depressions dug out of the sand substrate-and "castles"-aggregations of sand collected from around the bower area and deposited to create a mound (Figure 2A; Dawkins, 1992;York et al, 2015). Phylogenetic analysis shows that pit and castle type bowers are evolutionarily labile.…”

Section: Key Concept 4 | Adaptive Radiations (Ars)mentioning

confidence: 99%

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The Repeated Evolution of Behavior

York

Fernald

2017

Front. Ecol. Evol.

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A major tool in the evolutionary biologist's kit is to study the repeated emergence of certain biological traits. Employment of this tool has allowed substantial recent advances to be made in understanding the adaptive molecular basis of certain key biological traits. However, behavior, one life's most pervasive, and complex traits, is not one. Here we review the concepts of repeated evolution and how they apply to behavior. We assess the distribution and evolutionary dynamics of known cases of repeated behavioral evolution and examine their prospects for success in identifying the genetic and mechanistic bases of behavior. We propose that studying adaptive radiations, such as that seen amongst the cichlids of Lake Malawi, will likely yield results quickly due to the tractability of genetic and comparative analyses. Finally we suggest some possible scenarios that might be observed in the pursuit of the adaptive molecular basis of behavior and advocate for research on a diverse number of case studies of behavioral evolution, allowing for a knowledge base from which general principles of behavioral evolution might be gleaned.

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Section: Key Concept 4 | Adaptive Radiations (Ars)mentioning

confidence: 99%

Section: Key Concept 3 | Phenotypic Transitionsmentioning

confidence: 99%

Section: Key Concept 4 | Adaptive Radiations (Ars)mentioning

confidence: 99%

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The Repeated Evolution of Behavior

York

Fernald

2017

Front. Ecol. Evol.

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“…2B) (Branson et al, 2009;Jhuang et al, 2010) and the transition probabilities between behaviors (also called 'kinematic diagrams' or 'ethograms'; Fig. 2C) (Adamo and Hoy, 1995;Dankert et al, 2009;Seeds et al, 2014;York et al, 2015). Both time budgets and transition probabilities can be compared across species (Petru et al, 2009), strains (de Chaumont et al, 2012Kabra et al, 2013) or experimental conditions (Branson et al, 2009;Saka et al, 2004).…”

Section: Summarizing Behavioral Labelsmentioning

confidence: 99%

Machine vision methods for analyzing social interactions

Robie

Seagraves

Egnor

et al. 2017

Journal of Experimental Biology

123

101

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Recent developments in machine vision methods for automatic, quantitative analysis of social behavior have immensely improved both the scale and level of resolution with which we can dissect interactions between members of the same species. In this paper, we review these methods, with a particular focus on how biologists can apply them to their own work. We discuss several components of machine vision-based analyses: methods to record high-quality video for automated analyses, video-based tracking algorithms for estimating the positions of interacting animals, and machine learning methods for recognizing patterns of interactions. These methods are extremely general in their applicability, and we review a subset of successful applications of them to biological questions in several model systems with very different types of social behaviors.

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“…In particular, we believe that researchers should strategically focus their efforts to study the microevolution of behavior in closely related species or different populations of the same species. There are a number of evolutionary systems where a strong foundation has already been laid, including territoriality and flocking in songbirds (71), schooling behavior in threespine stickleback fish (79), courtship and parental behaviors in African cichlid fish (80,81), aggression and schooling in blind cavefish (82,83), mating system and mating tactics in voles (84,85), and parental behavior in Peromyscus mice (86). These systems provide insight into not only the specifics of how social behavior evolves but also, the extent to which we should expect conservation of network function across much more distantly related species.…”

Section: Resultsmentioning

confidence: 99%

Applying gene regulatory network logic to the evolution of social behavior

Baran

McGrath

Streelman

2017

Proc. Natl. Acad. Sci. U.S.A.

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Animal behavior is ultimately the product of gene regulatory networks (GRNs) for brain development and neural networks for brain function. The GRN approach has advanced the fields of genomics and development, and we identify organizational similarities between networks of genes that build the brain and networks of neurons that encode brain function. In this perspective, we engage the analogy between developmental networks and neural networks, exploring the advantages of using GRN logic to study behavior. Applying the GRN approach to the brain and behavior provides a quantitative and manipulative framework for discovery. We illustrate features of this framework using the example of social behavior and the neural circuitry of aggression.gene regulatory networks | social behavior network | neural networks | evolution | development

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Evolution of bower building in Lake Malawi cichlid fish: phylogeny, morphology, and behavior

Cited by 33 publications

References 68 publications

The Repeated Evolution of Behavior

The Repeated Evolution of Behavior

Machine vision methods for analyzing social interactions

Applying gene regulatory network logic to the evolution of social behavior

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