Body length estimation of Neogene macrophagous lamniform sharks (Carcharodon and Otodus) derived from associated fossil dentitions

Pérez, Víctor Juan Ventosa; Leder, Ronny M.; Badaut, Teddy

doi:10.26879/1140

Cited by 22 publications

(39 citation statements)

References 24 publications

(109 reference statements)

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“…This accords with our morphospace overlap of anacoracids and hexanchids (Fig P in S1 Text ) and is further compatible with some modern shark communities, in which the hexanchid, Notorynchus cepedianus , is known to invade apex predator niches once vacated by the lamnid, Carcharodon carcharias [ 93 ]. Unfortunately, shark body size is difficult to estimate accurately from fossil shark teeth [ 94 , 95 ], and the paleoecology of Cretaceous anacoracids and hexanchids is poorly understood. Irrespectively, the persistence of larger-bodied selachimorphs across the K/Pg boundary infers size-based niche continuity, a pattern consistent with static dental disparity (this study and [ 21 ]), and, thus, the likelihood that other drivers, including diet, habitat preference, and reproductive strategy [ 96 ], were influential in selecting for selachimorph extinction susceptibility.…”

Section: Discussionmentioning

confidence: 99%

Tooth morphology elucidates shark evolution across the end-Cretaceous mass extinction

et al. 2021

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Sharks (Selachimorpha) are iconic marine predators that have survived multiple mass extinctions over geologic time. Their prolific fossil record is represented mainly by isolated shed teeth, which provide the basis for reconstructing deep time diversity changes affecting different selachimorph clades. By contrast, corresponding shifts in shark ecology, as measured through morphological disparity, have received comparatively limited analytical attention. Here, we use a geometric morphometric approach to comprehensively examine tooth morphologies in multiple shark lineages traversing the catastrophic end-Cretaceous mass extinction—this event terminated the Mesozoic Era 66 million years ago. Our results show that selachimorphs maintained virtually static levels of dental disparity in most of their constituent clades across the Cretaceous–Paleogene interval. Nevertheless, selective extinctions did impact apex predator species characterized by triangular blade-like teeth. This is particularly evident among lamniforms, which included the dominant Cretaceous anacoracids. Conversely, other groups, such as carcharhiniforms and orectolobiforms, experienced disparity modifications, while heterodontiforms, hexanchiforms, squaliforms, squatiniforms, and †synechodontiforms were not overtly affected. Finally, while some lamniform lineages disappeared, others underwent postextinction disparity increases, especially odontaspidids, which are typified by narrow-cusped teeth adapted for feeding on fishes. Notably, this increase coincides with the early Paleogene radiation of teleosts as a possible prey source, and the geographic relocation of disparity sampling “hotspots,” perhaps indicating a regionally disjunct extinction recovery. Ultimately, our study reveals a complex morphological response to the end-Cretaceous mass extinction and highlights an event that influenced the evolution of modern sharks.

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Section: Discussionmentioning

confidence: 99%

Tooth morphology elucidates shark evolution across the end-Cretaceous mass extinction

et al. 2021

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“…In the absence of complete skeletons permitting measurement of body length, Carcharodon carcharias is a reasonable modern analog for reconstructing body length from otodontid tooth dimensions (Pimiento et al, 2010). Note, however, that a recent study suggests that these estimates might underestimate the maximum body length, and that posterior teeth overestimate body length versus anterior teeth (Perez et al, 2021). Because the goal of this study is to evaluate the relative size, and not evaluate different methods, we follow Pimiento et al (2010) and Shimada et al (2020) in using the equations from Shimada (2002).…”

Section: Methodsmentioning

confidence: 99%

“…If the tooth position is incorrect, body length estimates might be overestimated. In order to exclude tooth posi-tion as a variable, each tooth was identified to approximate position based on comparison with the only known dentition of C. angustidens (OU 22261, Gottfried and Fordyce, 2001), but use A3 over I1 (intermediate) and include the posteriors as a continuation of the laterals after Shimada (2002) and Perez et al (2021). Anterior teeth are the largest, and generally have the longest (relative to root width) and most symmetrical crowns; lateral teeth are relatively smaller than anteriors and have proportionally shorter and more distally inclined crowns, and increasingly have proportionally smaller crowns in further distal tooth positions closer to the commissure (=posteriors of some authors, e.g., Gottfried and Fordyce, 2001).…”

Section: Methodsmentioning

confidence: 99%

“…3-4) and do not represent trees derived from cladistic analyses of morphological data. Though subsequent studies have followed this taxonomic decision (e.g., Boessenecker et al, 2019;Cooper et al, 2020;Herraiz et al, 2020;Perez et al, 2021), not all have (e.g., Godfrey et al, 2018;Kent, 2018;Perez et al, 2019). An exhaustive review of this subject is provided by Kent (2018: 80-85).…”

Section: Taxonomic Notementioning

confidence: 99%

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A megatoothed shark (Carcharocles angustidens) nursery in the Oligocene Charleston Embayment, South Carolina, USA

Miller

Gibson

Boessenecker

2021

Palaeontol Electron

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Many extant sharks are cosmopolitan as adults but inhabit nursery areas as youngsters -often shallow, dynamic ecosystems with abundant prey for neonates and juveniles. Megatoothed sharks (Otodontidae) were the largest sharks of all time, and nursery areas have been demonstrated for Carcharocles megalodon in the Miocene of Panama, Spain, Florida, and Maryland. An earlier study hypothesized a nursery area for Carcharocles angustidens in the upper Oligocene (23-25 Ma) Chandler Bridge Formation of Charleston, South Carolina. We tested this by reporting and analyzing two collections (n=127) dominated by small teeth of C. angustidens from the Chandler Bridge Formation and some teeth from the underlying lower Oligocene (29-26.57 Ma) Ashley Formation (n=9). Correcting for tooth position, published body length estimation equations yielded body length estimates of 1.5-6.5 m for most individuals. Size-based assignment to age classes (neonates, juveniles, adults) is modified from the larger C. megalodon and scaled based on the largest available specimens of C. angustidens, reported herein. These assemblages are dominated by small individuals (juveniles and neonates) and include few adults. The Oligocene Charleston embayment therefore represents the first documented paleo-nursery area for C. angustidens.

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“…48 Lamniforms, on the other hand, segregated into only a few distinctive dental morphologies that suffered synchronized disparity contractions during the mid-Miocene-early Pliocene (Figure 2A)-a time frame commenced by the global mid-Miocene climatic disruption. 49 These contractions are most evident among lamnids and otodontids (Figures S3B and S7), 8 which are lineages typified by apex predators, such as Otodus megalodon with an estimated maximum body length of 20 m. 50 Otodus megalodon possessed high-crowned triangular teeth that closely resemble those of Carcharodon carcharias and was probably likewise specialized for feeding on marine tetrapods (e.g., cetaceans and pinnipeds) as an adult. The decline of lamniform apex predators across the mid-Miocene-early Pliocene has been attributed to climate change and competition [51][52][53] but was possibly also influenced by niche specialization limiting their responsive capacity to environmental alterations.…”

Section: Articlementioning

confidence: 99%

Feeding ecology has shaped the evolution of modern sharks

et al. 2021

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Body length estimation of Neogene macrophagous lamniform sharks (Carcharodon and Otodus) derived from associated fossil dentitions

Cited by 22 publications

References 24 publications

Tooth morphology elucidates shark evolution across the end-Cretaceous mass extinction

Tooth morphology elucidates shark evolution across the end-Cretaceous mass extinction

A megatoothed shark (Carcharocles angustidens) nursery in the Oligocene Charleston Embayment, South Carolina, USA

Feeding ecology has shaped the evolution of modern sharks

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