Ectoparasite borings, mesoparasite borings, and scavenging traces in early Miocene turtle and tortoise shell: Moghra Formation, Wadi Moghra, Egypt

Zonneveld, John‐Paul; Gawad, Mohamed Abdel; Miller, Ellen R.

doi:10.1017/jpa.2021.92

Cited by 22 publications

(22 citation statements)

References 101 publications

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“…The morphology and size of the bore marks on RAM 27109 are consistent with Karethraichnus lakkos Zonneveld, Bartels, Gunnell and McHugh, 2016, a common ectoparasitic ichnotaxon on turtles and tortoises from Cretaceous and Tertiary deposits in North America and Africa (Zonneveld et al 2016(Zonneveld et al , 2021Adrian et al 2021). Congeneric ichnospecies are also known from a Campanian dermochelyid (marine) turtle in Japan and from Late Pleistocene armadillos in Brazil (Sato and Jenkins 2020;Moura et al 2021).…”

Section: Resultsmentioning

confidence: 54%

“…Congeneric ichnospecies are also known from a Campanian dermochelyid (marine) turtle in Japan and from Late Pleistocene armadillos in Brazil (Sato and Jenkins 2020;Moura et al 2021). Tracemakers usually associated with K. lakkos include leeches and ixodid arthropods (ticks), which are known to feed on blood sinuses within shell bone, especially at sulci between epidermal scales (Siddall and Gaffney 2004;Zonneveld et al 2016Zonneveld et al , 2021. Bore marks of K. lakkos are only emplaced in locations accessible on living turtles-external surfaces of the carapace and plastron, especially at marginal or lip areas (Zonneveld et al 2016).…”

Section: Resultsmentioning

confidence: 99%

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Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Adrian¹

2022

foss-rec

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New material of the derived baenid turtle Boremys pulchra from the Hell Creek Formation of Montana extends the stratigraphic range of the taxon through at minimum the latest Maastrichtian. Previously, the species was constrained to the Campanian of Montana and Alberta, so this extension constitutes at least 5 million years. Due to fossil reworking at the Bug Creek Anthills assemblage, where Maastrichtian and Paleocene deposits are mixed, a definitive extension for B. pulchra cannot currently include Paleocene strata. However, the presence of B. pulchra in latest Cretaceous strata, previous identification of Paleocene Boremys sp. and the general success of baenid taxa across the K–Pg boundary, make it quite plausible that B. pulchra survived the extinction event and that previously described Maastrichtian and Paleocene Boremys sp. material probably represents a new taxon. A stratigraphic extension beyond the Campanian indicates that B. pulchra survived the paleoenvironmental conditions of the latest Cretaceous, where adaptation to locally heterogeneous aquatic habitats and paleotemperature fluctuations may have facilitated latest Cretaceous and K–Pg survivorship. Additionally, ectoparasitic bore marks on the Boremys pulchra specimen described here can be attributed to the ichnotaxon Karethraichnus lakkos.

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Section: Resultsmentioning

confidence: 54%

Section: Resultsmentioning

confidence: 99%

Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Adrian¹

2022

foss-rec

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“…Seigel 1983), and turtle barnacles are sometimes referred to as parasites (e.g. Zonneveld et al 2022). As a matter of fact, there is some indication that some sea turtles may actively remove their epibiota by scrapping the shell against bottom rocks (Frick and McFall 2007).…”

Section: Introductionmentioning

confidence: 99%

“…This has started to change during the last few years, especially in the light of new research approaches that promote the integration between trace and body fossil analyses to identify and qualify ancient symbiotic associations, often based on the detection of skeletal intergrowths and bioclaustration structures (e.g. Yuan et al 2005;Tapanila 2008;Tapanila and Ekdale 2007;Stanley and Schootbrugge 2009;De Baets et al 2015;Wilson 2015, 2016;Vinn et al , 2018Vinn et al , 2019Vinn et al , 2021Vinn 2016Vinn , 2017aRobin et al 2016, Robin 2021Zonneveld et al 2022). Only a few studies, however, have explored the deep past of sea turtle epibiosis based on palaeontological lines of evidence (e.g.…”

Section: Introductionmentioning

confidence: 99%

Turtle barnacles have been turtle riders for more than 30 million years

Collareta

Rasser

Frey³

et al. 2022

PalZ

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In contrast to other kinds of biological interactions, symbiosis is a scarcely investigated aspect of the fossil record. This is largely due to taphonomic biases that often frustrate any attempt to make a strong case that two organisms shared an intimate association in life. Among extant marine vertebrates, the sea turtles (Cheloniidae and Dermochelyidae) bear a broad and diverse spectrum of epibiotic symbionts, including specialists such as the turtle barnacles (Chelonibiidae and Platyleapadidae). Here, we reappraise an early Oligocene (Rupelian) fossil cheloniid skeleton, featuring the remains of cirripedes on the exterior of its entoplastron, from the Rauenberg fossil-lagerstätte, southwestern Germany. The barnacle specimens are assigned to Protochelonibia melleni, an extinct protochelonibiine species and the geologically oldest known member of Chelonibiidae. In the light of taphonomic and palaeoenvironmental considerations, and given that the extant chelonibiids are mostly known as epizoic symbionts of sea turtles, we conclude that this unique fossil association resulted from the epizoic growth of the barnacles on the external surface of the plastron of the turtle during its lifetime. This remarkable fossil association provides evidence that chelonibiids, including the extinct protochelonibiines, have been chelonophilic epizoans for more than 30 Myr. A survey of the trace and body fossil records shows that platylepadids are also likely as old as the Rupelian as is their symbiotic association with cheloniid hosts. This early emergence of the modern-looking, turtle-dwelling barnacle lineages corresponds to a climate-driven phase of major radiation and taxonomic turnover among sea turtles at the Eocene–Oligocene transition.

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“…Many taphonomic processes may modify animal carcasses and bones between the time of death and the burial (e.g., [1][2][3]). Also, some parasites can modify bone tissue during the life of the animal [4,5]. The analysis of surface modifications on bone remains and the recognition of the different agents involved have exponentially grown during the last few decades.…”

Section: Introductionmentioning

confidence: 99%

Insect Marks on Bones from La Guillerma Archaeological Locality (Salado River Depression, Buenos Aires, Argentina)

2021

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The La Guillerma archaeological locality is located in the northeast sector of Buenos Aires province (Argentina). Two of its sites (LG1 and LG5), dated between ca. 1400- and 600-years BP, have a great amount of faunal remains including deer, rodents, fish and small birds that are subjected to taphonomic agents and processes (e.g., weathering, manganese, roots). Previous studies have shown osteophagic behaviour in different insects (e.g., Coleoptera, Blattodea). In this paper, we evaluate their incidence on La Guillerma faunal assemblage. We performed an analysis on marks that were identified in bone remains of various taxa and applied the criteria for identifying bone alteration by insects (i.e., by measuring each trace and comparing them with the types of insect marks described in the literature). Fifteen specimens (LG1 = 6 and LG5 = 9) exhibited different types of modifications (e.g., pits with striae in base, pits with emanating striae, striations) that are related to the action of insects. Although the proportion of affected bones is low in relation to the total sample, we highlight our study as the first detailed analysis of insect marks on archaeological bones from Argentina. We also emphasize the significance of addressing insect-produced modifications on Argentinean archaeological sites.

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Ectoparasite borings, mesoparasite borings, and scavenging traces in early Miocene turtle and tortoise shell: Moghra Formation, Wadi Moghra, Egypt

Cited by 22 publications

References 101 publications

Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Turtle barnacles have been turtle riders for more than 30 million years

Insect Marks on Bones from La Guillerma Archaeological Locality (Salado River Depression, Buenos Aires, Argentina)

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Ectoparasite borings, mesoparasite borings, and scavenging traces in early Miocene turtle and tortoise shell: Moghra Formation, Wadi Moghra, Egypt

Cited by 22 publications

References 101 publications

﻿Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

﻿Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Turtle barnacles have been turtle riders for more than 30 million years

Insect Marks on Bones from La Guillerma Archaeological Locality (Salado River Depression, Buenos Aires, Argentina)

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Product

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Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous

Stratigraphic range extension of the turtle Boremys pulchra (Testudinata, Baenidae) through at least the uppermost Cretaceous