Head adaptation for sound production and feeding strategy in dolphins (Odontoceti: Delphinida)

Frainer, Guilherme; Huggenberger, Stefan; Moreno, Ignacio B.; Plön, Stephanie; Galatius, Anders

doi:10.1111/joa.13364

Cited by 5 publications

(11 citation statements)

References 60 publications

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“…Using NBHF sounds might be advantageous for navigating the complex environment that surrounds them [39], and it also allows these taxa to avoid predation by large predators such as killer whales, which do not hear sounds at such high frequencies [4,39]. Nevertheless, they employ a variety of feeding strategies, from the specialized suction feeder Kogia to the raptorial feeder Pontoporia [4,39,40]. Morphologically, while they convergently evolved similar inner ear shapes in order to use this specialized type of echolocation [4], they do not consistently display similar skull traits.…”

Section: Discussionmentioning

confidence: 99%

“…They prevalently inhabit coastal and riverine environments, with the exception of Kogiidae [4]. Using NBHF sounds might be advantageous for navigating the complex environment that surrounds them [39], and it also allows these taxa to avoid predation by large predators such as killer whales, which do not hear sounds at such high frequencies [4,39]. Nevertheless, they employ a variety of feeding strategies, from the specialized suction feeder Kogia to the raptorial feeder Pontoporia [4,39,40].…”

Section: Discussionmentioning

confidence: 99%

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The ontogeny of asymmetry in echolocating whales

et al. 2022

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Extreme asymmetry of the skull is one of the most distinctive traits that characterizes toothed whales (Odontoceti, Cetacea). The origin and function of cranial asymmetry are connected to the evolution of echolocation, the ability to use high-frequency sounds to navigate the surrounding environment. Although this novel phenotype must arise through changes in cranial development, the ontogeny of cetacean asymmetry has never been investigated. Here we use three-dimensional geometric morphometrics to quantify the changes in degree of asymmetry and skull shape during prenatal and postnatal ontogeny for five genera spanning odontocete diversity (oceanic dolphins, porpoises and beluga). Asymmetry in early ontogeny starts low and tracks phylogenetic relatedness of taxa. Distantly related taxa that share aspects of their ecology overwrite these initial differences via heterochronic shifts, ultimately converging on comparable high levels of skull asymmetry. Porpoises maintain low levels of asymmetry into maturity and present a decelerated rate of growth, probably retained from the ancestral condition. Ancestral state reconstruction of allometric trajectories demonstrates that both paedomorphism and peramorphism contribute to cranial shape diversity across odontocetes. This study provides a striking example of how divergent developmental pathways can produce convergent ecological adaptations, even for some of the most unusual phenotypes exhibited among vertebrates.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

The ontogeny of asymmetry in echolocating whales

et al. 2022

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“…These species present distinct patterns of rostrum morphology, but they both depend on postnatal ontogeny for its maturation (Frainer et al. 2015, 2021). Humpback dolphins present a peculiar anteriorization (i.e.…”

Section: Discussionmentioning

confidence: 99%

“…2016; Frainer et al. 2021) and for prey capture (Werth 2006). Consequently, wounds and/or congenital anomalies of this structure could directly affect the feeding strategies and abilities of individuals.…”

Section: Introductionmentioning

confidence: 99%

Rostrum abnormalities in the endangered Indian Ocean humpback dolphin (Sousa plumbea) in South Africa

et al. 2022

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Morphological abnormalities in wild animals can be indicators of the underlying health of a population and may be determined through routine photographic surveys. Here, we assess unusual rostrum conditions in Indian Ocean humpback dolphins (Sousa plumbea) inhabiting South African coastal waters to understand the rate of prevalence of abnormal rostrums and formulate hypotheses on potential causes. Photographic data were collated from systematic boat surveys and opportunistic sightings, obtained between April 1998 and March 2021 in various regions along the South African coast. Overall, 31 unique individuals were found with abnormal rostrum conditions, varying from slight misalignments to severe wounds and/or aberrant morphologies. In most cases, injuries were likely caused by natural events during the animal's life history such as interactions with sharks and/or reef-associated hunting strategies. Mark-recapture data indicated that individuals had survived with these injuries for up to 10 years. This study reports the highest incidence of rostrum abnormalities in the species. As numbers reflect only those that have survived their injuries, they are considered a minimum estimate. A better understanding of the cause(s) of these injuries is important given the endangered status of this species.

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“…Head shape has also been proposed to be related to adaptation for efficient echolocation (eg. Frainer et al 2021). Changes to the orbit of the AS-Ta lineage might also be a result of living in a more turbid environment, again, the extreme being found in river dolphins, which have small eyes (Herald et al 1969).…”

Section: Morphological Differences (Within T Aduncus)mentioning

confidence: 99%

Evolutionary drivers of morphological differentiation among three bottlenose dolphin lineages,Tursiopsspp. (Delphinidae), in the northwest Indian Ocean utilizing linear and geometric morphometric techniques

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Waerebeek

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et al. 2021

Biological Journal of the Linnean Society

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Local adaptation and adaptive radiations are typically associated with phenotypic variation suited to alternative environments. In the marine environment, the nature of relevant ecological or environmental transitions is poorly understood, especially for highly mobile species. Here we compare three genetic lineages in the genus Tursiops (bottlenose dolphins), using linear measurements and geometric morphometric techniques, in the context of environmental variation in the northwest Indian Ocean. Cranial morphology was clearly differentiated comparing Tursiops truncatus and Tursiops aduncus, while a recently discovered genetic lineage, found in the Arabian Sea, was morphologically most similar to T. aduncus from the same region, but distinct for various measures, particularly metrics associated with the lateral dimension of the skull. The extent of divergence between T. truncatus and T. aduncus compared to differences between the T. aduncus lineages is consistent with the recent phylogeny for these species. Therefore, with the corroboration of genetic and morphological inference, we propose two conservation units of T. aduncus be recognized in the region at a sub-specific level so that their conservation can be managed effectively. We consider possible evolutionary mechanisms associated with regional habitat characteristics and the exploitation of distinct prey resources.

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Head adaptation for sound production and feeding strategy in dolphins (Odontoceti: Delphinida)

Cited by 5 publications

References 60 publications

The ontogeny of asymmetry in echolocating whales

The ontogeny of asymmetry in echolocating whales

Rostrum abnormalities in the endangered Indian Ocean humpback dolphin (Sousa plumbea) in South Africa

Evolutionary drivers of morphological differentiation among three bottlenose dolphin lineages,Tursiopsspp. (Delphinidae), in the northwest Indian Ocean utilizing linear and geometric morphometric techniques

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