, Volume 189, Issue 1, pp 79–89 | Cite as

Multifunctional behaviour in a sandy shore crab enhances performance in extreme intertidal environments

  • Tin Yan Hui
  • Felix Landry Yuan
  • Timothy C. Bonebrake
  • Gray A. Williams
Behavioral ecology – original research


Soft sediment shores in the tropics are highly dynamic environments, where behavioural patterns of organisms are constrained by tidal conditions, and environmental temperatures during an organisms’ activity periods can exceed their thermal tolerance levels. In such extreme habitats, behavioural responses to environmental changes are key to survival, driving differential performance. We investigated sponging behaviour (water uptake from sediments) of the deposit-feeding crab, Scopimera intermedia, on tropical sandy shores to determine its thermoregulatory function. The thermal physiology of the crabs and their habitat conditions were quantified by measuring thermal performance curves and recording environmental temperatures during the crabs’ activity periods. Environmental temperatures were combined with experimental data to investigate the role of sponging on the thermal performances of the crabs by simulating field body temperatures. Sponging rate was strongly and positively correlated with feeding rate, as sponging replenishes water for flotation feeding. Sponging, however, also reduced body temperatures on average by 1.3 °C. Simulated populations of crabs which were unable to sponge had more variable body temperatures, which exceeded the critical thermal maximum of the crabs (~ 39 °C) nearly 2000 times more often than crabs able to sponge. Sponging is, therefore, a multifunctional behavioural trait important for both feeding and thermoregulation. The evolution of such multifunctional traits is likely to be a widespread, but overlooked phenomenon in intertidal species, as maintaining a functional body temperature is energetically costly in habitats where environmental conditions fluctuate strongly such as on tropical shores.


Behavioural thermoregulation Thermal performance Tropical shore Scopimera Evaporative cooling 



The authors would like to thank members of the Hard Rock Ecology Laboratory and Dr Stefano Cannicci at HKU for stimulating discussions; Prof. Jeffrey Levinton (Stony Brook University) and Prof. Matthew Evans (HKU) who gave constructive comments which helped improve this manuscript, and Dr. Pablo Munguia for suggesting modelling the trade-offs between environmental predictability and behavioural/physiological responses to stresses. Dr. Jenny Yuen Yung Lau (HKU) and Dr. Chun Chiu Pang (HKU) helped identify the Sporobolus specimens. This research was supported by HKU Postgraduate Scholarships to TYH and FLY.

Author contribution statement

This study was conceived by TYH, FLY, TCB and GAW. TYH conducted 100% of the surveys and experimental work, FLY contributed to the statistical analyses, while FLY, TCB and GAW contributed to writing the manuscript.

Compliance with ethical standards

Conflict of interest

There is no conflict of interest.

Supplementary material

442_2018_4299_MOESM1_ESM.docx (5.9 mb)
Supplementary material 1 (DOCX 6054 kb)


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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  • Tin Yan Hui
    • 1
  • Felix Landry Yuan
    • 2
  • Timothy C. Bonebrake
    • 2
  • Gray A. Williams
    • 1
  1. 1.The Swire Institute of Marine Science and School of Biological SciencesThe University of Hong KongHong KongPeople’s Republic of China
  2. 2.School of Biological SciencesThe University of Hong KongHong KongPeople’s Republic of China

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