Riverine Barriers as Obstacles to Dispersal in Amazonian Birds

Naka, Luciano N.; Costa, Bruna M. da Silva; Lima, Gisiane Rodrigues; Claramunt, Santiago

doi:10.3389/fevo.2022.846975

Cited by 12 publications

(13 citation statements)

References 72 publications

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“…This metric is typically based either on morphology, such as wing shape (Claramunt, 2021; Kipp, 1959), or on ecological traits thought to predispose species to dispersive lifestyles, such as foraging ecology and diet (Burney & Brumfield, 2009; Miller et al, 2021). Recently, researchers have also conducted dispersal challenge experiments to measure an individual's relative flying ability (Moore et al, 2008; Naka et al, 2022). Naka et al (2022) found no correlation in these experiments between flight distance and riverine island specialization, suggesting that wing shape, rather than ecological preference, better explains the capacity of birds to cross an open gap of water.…”

Section: Discussionmentioning

confidence: 99%

“…The Amazon Basin has high avian species richness (Jenkins et al, 2013; Wallace, 1878), long‐term evolutionary persistence (Bicudo et al, 2019; Harvey et al, 2017b), a wide diversity of habitat types (Tuomisto et al, 1995; Tuomisto et al, 2019), and species with a diversity of habitat preferences and specializations (e.g., Álvarez Alonso et al, 2013; Kratter, 1997; Rosenberg, 1990; Terborgh, 1985). Additionally, experimental dispersal challenges over water are now available for some Neotropical birds (Moore et al, 2008; Naka et al, 2022). Claramunt et al (2022) found that wing morphology was a significant predictor of overwater flight ability and Weeks et al (2022) found a significant association between flight ability and natal dispersal distance in a phylogenetically diverse set of 114 bird species, supporting wing measurements from research specimens as a proxy for dispersal.…”

Section: Introductionmentioning

confidence: 99%

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Amazonian birds in more dynamic habitats have less population genetic structure and higher gene flow

et al. 2023

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Understanding the factors that govern variation in genetic structure across species is key to the study of speciation and population genetics. Genetic structure has been linked to several aspects of life history, such as foraging strategy, habitat association, migration distance, and dispersal ability, all of which might influence dispersal and gene flow. Comparative studies of population genetic data from species with differing life histories provide opportunities to tease apart the role of dispersal in shaping gene flow and population genetic structure. Here, we examine population genetic data from sets of bird species specialized on a series of Amazonian habitat types hypothesized to filter for species with dramatically different dispersal abilities: stable upland forest, dynamic floodplain forest, and highly dynamic riverine islands. Using genome-wide markers, we show that habitat type has a significant effect on population genetic structure, with species in upland forest, floodplain forest, and riverine islands exhibiting progressively lower levels of structure. Although morphological traits used as proxies for individual-level dispersal ability did not explain this pattern, population genetic measures of gene flow are elevated in species from more dynamic riverine habitats. Our results suggest that the habitat in which a species occurs drives the degree of population genetic structuring via its impact on long-term fluctuations in levels of gene flow, with species in highly dynamic habitats having particularly elevated gene flow. These differences in genetic variation across taxa specialized in distinct habitats may lead to disparate responses to environmental change or habitatspecific diversification dynamics over evolutionary time scales.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Amazonian birds in more dynamic habitats have less population genetic structure and higher gene flow

et al. 2023

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“…Data on dispersal capacity, however, indicate that C. bicolor is a better disperser than both M. propinqua and S. napensis (Naka et al, 2022). In dispersal challenge experiments conducted on the Rio Branco, C. bicolorcolour managed to safely cross river gaps in all trials (10:0), whereas S. napensis failed in 25% and M. propinqua in more than 50% of the trials.…”

Section: Discussionmentioning

confidence: 99%

Late Pleistocene landscape changes and habitat specialization as promoters of population genomic divergence in Amazonian floodplain birds

et al. 2022

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Although vicariant processes are expected to leave similar genomic signatures among codistributed taxa, ecological traits such as habitat and stratum can influence genetic divergence within species. Here, we combined landscape history and habitat specialization to understand the historical and ecological factors responsible for current levels of genetic divergence in three species of birds specialized in seasonally flooded habitats in muddy rivers and which are widespread in the Amazon basin but have isolated populations in the Rio Branco. Populations of the white‐bellied spinetail (Mazaria propinqua), lesser wagtail‐tyrant (Stigmatura napensis) and bicolored conebill (Conirostrum bicolor) are currently isolated in the Rio Branco by the black‐waters of the lower Rio Negro, offering a unique opportunity to test the effect of river colour as a barrier to gene flow. We used ultraconserved elements (UCEs) to test alternative hypotheses of population history in a comparative phylogeographical approach by modelling genetic structure, demographic history and testing for shared divergence time among codistributed taxa. Our analyses revealed that (i) all three populations from the Rio Branco floodplains are genetically distinct from other populations along the Amazon River floodplains; (ii) these divergences are the result of at least two distinct events, consistent with species habitat specialization; and (iii) the most likely model of population evolution includes lower population connectivity during the Late Pleistocene transition (~250,000 years ago), with gene flow being completely disrupted after the Last Glacial Maximum (~21,000 years ago). Our findings highlight how landscape evolution modulates population connectivity in habitat specialist species and how organisms can have different responses to the same historical processes of environmental change, depending on their habitat affinity.

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“…In these habitats, species need larger foraging areas and thus enhanced mobility in order to obtain sufficient resources. Finally, even in productive tropical forests, ground‐foraging species may show higher levels of mobility than species that forage on understory vegetation (Claramunt et al, 2022 ; Naka et al, 2022 ). These factors may complicate the relationship between foraging behavior and dispersal distances.…”

Section: Discussionmentioning

confidence: 99%

“…Because of its role in determining the efficiency of movements through space, flight efficiency can also influence other aspects of birds' biology. For example, flight efficiency has a strong influence on the species' ability to cross habitat gaps and move across fragmented landscapes (Claramunt et al, 2012(Claramunt et al, , 2022Hartfelder et al, 2020;Ibarra-Macias et al, 2011;Naka et al, 2022). Flight efficiency may also be linked to foraging behavior and, by extension, to diet and habitat (Norberg, 1990;Rayner, 1988;Sherry, 2016).…”

Section: Discussionmentioning

confidence: 99%

Determinants of natal dispersal distances in North American birds

Chu

Claramunt

2023

Ecology and Evolution

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Natal dispersal—the movement from birth site to first breeding site—determines demographic and population genetic dynamics and has important consequences for ecological and evolutionary processes. Recent work suggested that one of the main factors determining natal dispersal distances is the cost of locomotion. We evaluated this hypothesis using band recovery data to estimate natal dispersal distances for 50 North American bird species. We then analyzed the relationships between dispersal distances and a suite of morphological and ecological predictors, including proxies for the cost of locomotion (flight efficiency), using phylogenetic regression models. We found that flight efficiency, population size, and habitat influence natal dispersal distances. We discuss how the effects of population size and habitat can also be related to mobility and locomotion. Our findings are consistent with a predominant effect of adaptations for mobility on dispersal distances.

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Riverine Barriers as Obstacles to Dispersal in Amazonian Birds

Cited by 12 publications

References 72 publications

Amazonian birds in more dynamic habitats have less population genetic structure and higher gene flow

Amazonian birds in more dynamic habitats have less population genetic structure and higher gene flow

Late Pleistocene landscape changes and habitat specialization as promoters of population genomic divergence in Amazonian floodplain birds

Determinants of natal dispersal distances in North American birds

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