Osteohistology of <i>Greererpeton</i> provides insight into the life history of an early Carboniferous tetrapod

Whitney, Megan R.; Pierce, Stephanie E.

doi:10.1111/joa.13520

Cited by 3 publications

(7 citation statements)

References 103 publications

(153 reference statements)

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“…The pattern of growth described here for Whatcheeria strongly juxtaposes that recently described for a slightly younger Carboniferous stem tetrapod, Greererpeton 37 , whose elongated and gracile gross anatomy suggest a particularly aquatic, perhaps benthic lifestyle 63 (Fig. 5 ).…”

Section: Resultssupporting

confidence: 86%

“… Whatcheeria ( a – d ) is a large-bodied predator whose juvenile growth is characterized by fibrolamellar bone ( a ) that is eventually remodeled and completely replaced with parallel-fibered tissue ( b , c ) and subsequent slow deposition of lamellar bone ( c , d ). By contrast, Greererpeton 37 ( e – g ) is characterized by moderately paced bone deposition, even early in ontogeny ( e ), with a distinct lamellar band of bone deposited at the late juvenile stage ( e – g ). Sub-adult growth in Greererpeton is subsequently characterized by slowly deposited tissues ( f ) as well as endosteal deposition that results in a particularly thick adult cortex ( g ).…”

Section: Resultsmentioning

confidence: 99%

“…Finally, another possibility is that young juveniles occupied distinct habitats or nurseries 24 , 58 and therefore small individuals were not captured alongside the sub-adult and adult population. In any scenario, the absence of young juveniles is curious and important to note in the record of Whatcheeria and other early tetrapod ontogenetic series 37 .…”

Section: Resultsmentioning

confidence: 99%

“…5 ). An ontogenetic dataset showed that Greererpeton growth was characterized by a moderately paced rate of bone deposition, cortical thickening through development, and some evidence of growth marks 37 (Fig. 5e–g ).…”

Section: Resultsmentioning

confidence: 99%

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Fossil bone histology reveals ancient origins for rapid juvenile growth in tetrapods

et al. 2022

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Patterns of growth throughout the lifetime of an animal reflect critical life history traits such as reproductive timing, physiology, and ecological interactions. The ancestral growth pattern for tetrapods has traditionally been described as slow-to-moderately paced, akin to modern amphibians, with fast growth and high metabolic rates considered a specialized physiological trait of amniotes. Here, we present bone histology from an ontogenetic series of the Early Carboniferous stem tetrapod Whatcheeria deltae, and document evidence of fibrolamellar bone—primary bone tissue associated with fast growth. Our data indicate that Whatcheeria juveniles grew rapidly and reached skeletal maturity quickly, allowing them to occupy a large-bodied predator niche in their paleoenvironment. This life history strategy contrasts with those described for other stem tetrapods and indicates that a diversity of growth patterns existed at the origins of tetrapod diversification. Importantly, Whatcheeria marks an unexpectedly early occurrence of fibrolamellar bone in Tetrapoda, both temporally and phylogenetically. These findings reveal that elevated juvenile growth is not limited to amniotes, but has a deep history in the tetrapod clade and may have played a previously unrecognized role in the tetrapod invasion of land.

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Section: Resultssupporting

confidence: 86%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Fossil bone histology reveals ancient origins for rapid juvenile growth in tetrapods

et al. 2022

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“…(distal tarsals 1 and 2) ( 62 ), and two early tetrapods from the Carboniferous, Greererpeton burkemorani (dt 1) ( 64 ) and Proterogyrinus scheelei (distal carpals 1 and 2) ( 65 ). The phylogenetic positions of these two Carboniferous tetrapods are unstable; Greererpeton was recovered as closely related to either the basal crown or stem tetrapods, and Proterogyrinus is widely accepted as affiliated to Embolomeri, which, in turn, was argued as an order of crown or stem tetrapods or Reptiliomorpha [e.g., ( 66 , 67 )]. An even more primitive stem tetrapod, Whatcheeria deltae , was recently shown to have ossified distal tarsals 1, 4, and 5, with distal tarsal 4 being the largest in the digital arch ( 68 ).…”

Section: Discussionmentioning

confidence: 99%

Ossification patterns of the carpus and tarsus in salamanders and impacts of preaxial dominance on the fin-to-limb transition

et al. 2022

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Early limb skeletogenesis in salamanders is characterized by preaxial elements, digits I and II forming earlier than their postaxial counterparts (digits III to V), a phenomenon known as preaxial dominance, whereas in amniotes and anurans, these developmental sequences are reversed. This pattern characterizes the late skeletogenesis of digits and zeugopodium of anamniote tetrapods but remains unknown in carpals/tarsals. To correct this gap in knowledge, we investigate the ossification patterns of the carpals/tarsals in six salamander families/clades based on micro–computed tomography scans. We found that preaxial dominance is seen in the distal carpals/tarsals of several salamander clades and diverse early tetrapods, such as temnospondyls and amniotes. This distribution suggests that preaxial dominance is a primitive developmental pattern in tetrapods. Our results demonstrate that the distal carpals/tarsals are developmentally and evolutionarily independent in the autopodium, and preaxial dominance facilitates stabilization of the number of distal carpals/tarsals during fin-to-limb transition and digit reduction in early tetrapods.

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Applying 3D Models of Giant Salamanders to Explore Form–Function Relationships in Early Digit-Bearing Tetrapods

Kawano,

Martin,

Medina

et al. 2024

Integrative and Comparative Biology

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Extant salamanders are used as modern analogs of early digit-bearing tetrapods due to general similarities in morphology and ecology but the study species have been primarily terrestrial and relatively small when the earliest digit-bearing tetrapods were aquatic and an order of magnitude larger. Thus, we created a 3D computational model of underwater walking in extant Japanese giant salamanders (Andrias japonicus) using 3D photogrammetry and open-access graphics software (Blender) to broaden the range of testable hypotheses about the incipient stages of terrestrial locomotion. Our 3D model and software protocol represent the initial stages of an open-access pipeline that could serve as a “one-stop-shop” for studying locomotor function, from creating 3D models to analyzing the mechanics of locomotor gaits. While other pipelines generally require multiple software programs to accomplish the different steps in creating and analyzing computational models of locomotion, our protocol is built entirely within Blender and fully customizable with its Python scripting so users can devote more time to creating and analyzing models instead of navigating the learning curves of several software programs. The main value of our approach is that key kinematic variables (e.g., speed, stride length, elbow flexion) can be easily altered on the 3D model, allowing scientists to test hypotheses about locomotor function and conduct manipulative experiments (e.g., lengthening bones) that are difficult to perform in vivo. The accurate 3D meshes (and animations) generated through photogrammetry also provide exciting opportunities to expand the abundance and diversity of 3D digital animals available for researchers, educators, artists, conservation biologists, etc. to maximize societal impacts.

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Osteohistology of Greererpeton provides insight into the life history of an early Carboniferous tetrapod

Cited by 3 publications

References 103 publications

Fossil bone histology reveals ancient origins for rapid juvenile growth in tetrapods

Fossil bone histology reveals ancient origins for rapid juvenile growth in tetrapods

Ossification patterns of the carpus and tarsus in salamanders and impacts of preaxial dominance on the fin-to-limb transition

Applying 3D Models of Giant Salamanders to Explore Form–Function Relationships in Early Digit-Bearing Tetrapods

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