Relationships of song structure to phylogenetic history, habitat, and morphology in the vireos, greenlets, and allies (Passeriformes: Vireonidae)

Mejías, Miguel A.; Roncal, Julissa; Imfeld, Tyler S.; Boisen, Sander; Wilson, David R.

doi:10.1111/evo.14099

Cited by 15 publications

(31 citation statements)

References 147 publications

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“…The craniomandibular complex of birds, especially the beak, constitutes an all‐in‐one tool used for multiple tasks, including preening (Bush & Clayton, 2018), vocal modulation (Mejías et al, 2020), nest building (Hansell, 2000), thermoregulation (Tattersall et al, 2009), displaying behaviors (Murphy et al, 2009), intra‐ or interspecific fighting (Rico‐Guevara et al, 2019), and, most obviously, foraging and feeding (Beecher, 1951; Demmel Ferreira et al, 2019; Tokita et al, 2017). As such, ecomorphological variation and evolution of the skull and lower jaw are expected to be multifactorial in nature, being the outcome of several adaptive trade‐offs, as well as phylogenetic and/or developmental constraints (Bright et al, 2019; Navalón et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Why the long beak? Phylogeny, convergence, feeding ecology, and evolutionary allometry shaped the skull of the Giant Cowbird Molothrus oryzivorus (Icteridae)

Gómez

Lois‐Milevicich

2021

Journal of Morphology

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Cowbirds are a successful group of obligate brood parasites in the Neotropical passerine family Icteridae that offer an interesting model to explore the factors behind the evolution of the bird craniomandibular complex. The Giant Cowbird, Molothrus oryzivorus, stands out from its congeners, among other features, in diet (feeds mostly on fruit, nectar, and arthropods, instead on seeds), its larger body size, and longer, more robust beak with a much broader bony casque than in other cowbirds. In turn, Giant Cowbirds show a remarkable resemblance in these features to the distantly related caciques and oropendolas (some are its breeding hosts). However, the causes behind the latter resemblance and the distinctiveness among cowbirds have not yet been elucidated. We aim to explore the factors involved in the diverging morphology of the Giant Cowbird from its congeners and the convergence with caciques and oropendolas, surveying their skull and lower jaw under an explicit evolutionary framework. Using geometric morphometrics and comparative methods, we assessed the signal of phylogeny, convergence, feeding ecology, and size in skull shape. Our results indicated that evolution of the craniomandibular complex of icterids in general, and of the beak morphology in the Giant Cowbird in particular, are shaped by multiple factors, with phylogeny being largely overridden by changes in size (evolutionary allometry), primarily, and feeding ecology, secondarily. However, the evolution of a broad bony casque in the Giant Cowbird, otherwise a hallmark of caciques and oropendolas, does not appear to have primarily been ruled by evolutionary allometry. Instead, taking into account the unique extreme convergence between Giant Cowbirds and some of its caciques hosts, it might be consequence of selective regimes associated with parasite–host interactions acting on top of other evolutionary processes. This suggests chick mimicry as a reasonable explanation for this peculiar morphology that would require further investigation.

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Section: Introductionmentioning

confidence: 99%

Why the long beak? Phylogeny, convergence, feeding ecology, and evolutionary allometry shaped the skull of the Giant Cowbird Molothrus oryzivorus (Icteridae)

Gómez

Lois‐Milevicich

2021

Journal of Morphology

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“…Reduction of morphological divergence and similar plumage patterns have been recognized among most species (Hamilton, 1962), postulating that ecological differences could have been a mode of speciation in Vireo (Hamilton, 1959;1962;Barlow 1980). Additionally, a recent study found phylogenetic history strongly shapes song structure and morphology among vireos (Mejías et al, 2020). Several cryptic species have been rectified from species complexes within Vireo, including Hutton's vireo, Vireo huttoni (Cassin, 1851) (Cicero & Johnson, 1992), blue-headed vireo, Vireo solitarius (Wilson, 1810) (Johnson, 1995;Cicero & Johnson, 1998), and red-eyed vireo, Vireo olivaceus (Linnaeus, 1766) (Slager et al, 2014;Battey & Klicka, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The genus Vireo (Vieillot, 1808) (Order: Passeriformes; Family: Vireonidae) contains 34 species and is found throughout the New World (Gill & Donsker, 2019). Thirteen species breed in North America, occupying a mosaic of habitats including temperate and boreal forests, shrublands, and woodland edges (Gill & Donsker, 2019; Mejías et al ., 2020). Reduction of morphological divergence and similar plumage patterns have been recognized among most species (Hamilton, 1962), postulating that ecological differences could have been a mode of speciation in Vireo (Hamilton, 1959; 1962; Barlow 1980).…”

Section: Introductionmentioning

confidence: 99%

Genetic, bioacoustic and morphological analyses reveal cryptic speciation in the warbling vireo complex (Vireo gilvus: Vireonidae: Passeriformes)

Carpenter

Graham

Spellman

et al. 2021

Preprint

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Cryptic species are closely related taxa that are difficult to separate morphologically, but are reproductively isolated. Here we examine the warbling vireo complex (Vireo gilvus), a widespread songbird speculated to be comprised of more than one cryptic species. We included three taxa within the complex: two of the western (Vireo gilvus swainsonii and Vireo gilvus brewsteri) subspecies and the single eastern (Vireo gilvus gilvus) subspecies. We used mtDNA and microsatellite loci to assess the congruence of genetic data to the current subspecies boundaries. We then incorporated bioacoustic, morphometric, and ecological niche modeling analyses to further examine differences. We found two genetic groups with mtDNA analysis. Microsatellite analyses revealed four genetic groups: an eastern group, a Black Hills group and two western groups that do not agree with current western subspecies boundaries based on phenotypic data. Our results suggest that eastern and western warbling vireos have been reproductively isolated for a long period of time and therefore, may be best treated as separate species; however, more research into areas of contact to examine the presence of hybridization is advised before making a taxonomic revision. Differences between the two western genetic groups appear less clear, requiring additional research.

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“…However, even in some of the best‐studied groups, such as birds, there is mixed evidence for the role of sensory drive in signal evolution (Boncoraglio and Saino 2007; Mejías et al. 2020; Mikula et al. 2021).…”

mentioning

confidence: 99%

“…Sensory drive shapes signal evolution and diversification in several animal groups, such as insects (Rutowski et al 2007), fishes (Endler 1980), birds (Morton 1975), and mammals (Ey et al 2009). However, even in some of the best-studied groups, such as birds, there is mixed evidence for the role of sensory drive in signal evolution (Boncoraglio and Saino 2007;Mejías et al 2020;Mikula et al 2021). This mixed evidence may result from trade-offs between different selective pressures and how they play out across species.…”

mentioning

confidence: 99%

Ecology and behavior predict an evolutionary trade‐off between song complexity and elaborate plumages in antwrens (Aves, Thamnophilidae)

et al. 2021

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The environment can impose constraints on signal transmission properties such that signals should evolve in predictable directions (Sensory Drive Hypothesis). However, behavioral and ecological factors can limit investment in more than one sensory modality leading to a trade‐off in use of different signals (Transfer Hypothesis). In birds, there is mixed evidence for both sensory drive and transfer hypothesis. Few studies have tested sensory drive while also evaluating the transfer hypothesis, limiting understanding of the relative roles of these processes in signal evolution. Here, we assessed both hypotheses using acoustic and visual signals in male and female antwrens (Thamnophilidae), a species‐rich group that inhabits diverse environments and exhibits behaviors, such as mixed‐species flocking, that could limit investment in different signal modalities. We uncovered significant effects of habitat (sensory drive) and mixed‐species flocking behavior on both sensory modalities, and we revealed evolutionary trade‐offs between song and plumage complexity, consistent with the transfer hypothesis. We also showed sex‐ and trait‐specific responses in visual signals that suggest both natural and social selection play an important role in the evolution of sexual dimorphism. Altogether, these results support the idea that environmental (sensory drive) and behavioral pressures (social selection) shape signal evolution in antwrens.

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Relationships of song structure to phylogenetic history, habitat, and morphology in the vireos, greenlets, and allies (Passeriformes: Vireonidae)

Cited by 15 publications

References 147 publications

Why the long beak? Phylogeny, convergence, feeding ecology, and evolutionary allometry shaped the skull of the Giant Cowbird Molothrus oryzivorus (Icteridae)

Why the long beak? Phylogeny, convergence, feeding ecology, and evolutionary allometry shaped the skull of the Giant Cowbird Molothrus oryzivorus (Icteridae)

Genetic, bioacoustic and morphological analyses reveal cryptic speciation in the warbling vireo complex (Vireo gilvus: Vireonidae: Passeriformes)

Ecology and behavior predict an evolutionary trade‐off between song complexity and elaborate plumages in antwrens (Aves, Thamnophilidae)

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