Correlative tomography of exceptionally preserved Jurassic ammonite implies hyponome-propelled swimming

Lesley  Cherns; Alan RT Spencer; Imran Rahman; Russell J. Garwood; Christopher Reedman; Genoveva Burca; Martin Turner; Neville Hollingworth; Jason Hilton

doi:10.1130/G49551.1

Correlative tomography of exceptionally preserved Jurassic ammonite implies hyponome-propelled swimming

Lesley Cherns, Alan RT Spencer, Imran Rahman, Russell J. Garwood, Christopher Reedman, Genoveva Burca, Martin Turner, Neville Hollingworth, Jason Hilton

Earth and Environmental Sciences

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Abstract

The extreme rarity of soft tissue preservation in ammonoids has meant there are open questions regarding fundamental aspects of their biology. We report an exceptionally preserved Middle Jurassic ammonite with unrivalled information on soft body organization interpreted through correlative neutron and X-ray tomography. 3D-imaging of muscles and organs of the body mass for the first time in this iconic fossil group provides key insights into functional morphology. We show that paired dorsal muscles withdrew the body into the shell, rather than acting with the funnel controlling propulsion as in Nautilus. This suggests a mobile, retractable body as a defence strategy and necessitates a distinct swimming mechanism of hyponome propulsion, a trait that we infer evolved early in the ammonoid–coleoid lineage.

Original language	English
Journal	Geology
Early online date	7 Dec 2021
DOIs	https://doi.org/10.1130/G49551.1
Publication status	E-pub ahead of print - 7 Dec 2021

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title = "Correlative tomography of exceptionally preserved Jurassic ammonite implies hyponome-propelled swimming",

abstract = "The extreme rarity of soft tissue preservation in ammonoids has meant there are open questions regarding fundamental aspects of their biology. We report an exceptionally preserved Middle Jurassic ammonite with unrivalled information on soft body organization interpreted through correlative neutron and X-ray tomography. 3D-imaging of muscles and organs of the body mass for the first time in this iconic fossil group provides key insights into functional morphology. We show that paired dorsal muscles withdrew the body into the shell, rather than acting with the funnel controlling propulsion as in Nautilus. This suggests a mobile, retractable body as a defence strategy and necessitates a distinct swimming mechanism of hyponome propulsion, a trait that we infer evolved early in the ammonoid–coleoid lineage.",

author = "Lesley Cherns and Spencer, {Alan RT} and Imran Rahman and Garwood, {Russell J.} and Christopher Reedman and Genoveva Burca and Martin Turner and Neville Hollingworth and Jason Hilton",

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doi = "10.1130/G49551.1",

language = "English",

journal = "Geology",

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T1 - Correlative tomography of exceptionally preserved Jurassic ammonite implies hyponome-propelled swimming

AU - Cherns, Lesley

AU - Spencer, Alan RT

AU - Rahman, Imran

AU - Garwood, Russell J.

AU - Reedman, Christopher

AU - Burca, Genoveva

AU - Turner, Martin

AU - Hollingworth, Neville

AU - Hilton, Jason

PY - 2021/12/7

Y1 - 2021/12/7

N2 - The extreme rarity of soft tissue preservation in ammonoids has meant there are open questions regarding fundamental aspects of their biology. We report an exceptionally preserved Middle Jurassic ammonite with unrivalled information on soft body organization interpreted through correlative neutron and X-ray tomography. 3D-imaging of muscles and organs of the body mass for the first time in this iconic fossil group provides key insights into functional morphology. We show that paired dorsal muscles withdrew the body into the shell, rather than acting with the funnel controlling propulsion as in Nautilus. This suggests a mobile, retractable body as a defence strategy and necessitates a distinct swimming mechanism of hyponome propulsion, a trait that we infer evolved early in the ammonoid–coleoid lineage.

AB - The extreme rarity of soft tissue preservation in ammonoids has meant there are open questions regarding fundamental aspects of their biology. We report an exceptionally preserved Middle Jurassic ammonite with unrivalled information on soft body organization interpreted through correlative neutron and X-ray tomography. 3D-imaging of muscles and organs of the body mass for the first time in this iconic fossil group provides key insights into functional morphology. We show that paired dorsal muscles withdrew the body into the shell, rather than acting with the funnel controlling propulsion as in Nautilus. This suggests a mobile, retractable body as a defence strategy and necessitates a distinct swimming mechanism of hyponome propulsion, a trait that we infer evolved early in the ammonoid–coleoid lineage.

U2 - 10.1130/G49551.1

DO - 10.1130/G49551.1

M3 - Article

SN - 0091-7613

JO - Geology

JF - Geology

ER -

Correlative tomography of exceptionally preserved Jurassic ammonite implies hyponome-propelled swimming

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