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1. Five hundred million years to mobility: directed locomotion and its ecological function in a turtle barnacle

Author

Jens T. Høeg, Benny K. K. Chan, Yue Him Wong, Sing-Pei Yu, John D. Zardus, Jr-Chi Lin, Nathan J. Robinson, Niklas Dreyer, and I-Jiung Cheng

Subjects

Chelonibia testudinaria, BALANIDAE, ADHESION, Biology, General Biochemistry, Genetics and Molecular Biology, Optimal foraging theory, law.invention, MOVEMENT, Barnacle, law, Animals, Turtle (robot), sea turtle, Research Articles, General Environmental Science, Invertebrate, REATTACHMENT, adhesive locomotion, Functional ecology, Ecology, General Immunology and Microbiology, Reproduction, Thoracica, General Medicine, biology.organism_classification, EVOLUTION, CHELONIBIA-TESTUDINARIA, behaviour, Turtles, Sea turtle, CEMENT PROTEINS, movement ecology, optimal foraging, General Agricultural and Biological Sciences, Locomotion

Abstract

Movement is a fundamental characteristic of life, yet some invertebrate taxa, such as barnacles, permanently affix to a substratum as adults. Adult barnacles became ‘sessile’ over 500 Ma; however, we confirm that the epizoic sea turtle barnacle, Chelonibia testudinaria , has evolved the capacity for self-directed locomotion as adults. We also assess how these movements are affected by water currents and the distance between conspecifics. Finally, we microscopically examine the barnacle cement. Chelonibia testudinaria moved distances up to 78.6 mm yr −1 on loggerhead and green sea turtle hosts. Movements on live hosts and on acrylic panels occasionally involved abrupt course alterations of up to 90°. Our findings showed that barnacles tended to move directly against water flow and independent of nearby conspecifics. This suggests that these movements are not passively driven by external forces and instead are behaviourally directed. In addition, it indicates that these movements function primarily to facilitate feeding, not reproduction. While the mechanism enabling movement remained elusive, we observed that trails of cement bore signs of multi-layered, episodic secretion. We speculate that proximal causes of movement involve one or a combination of rapid shell growth, cement secretion coordinated with basal membrane lifting, and directed contraction of basal perimeter muscles.

Published

2021