Depth patterns in microhabitat versatility and selectivity in coral reef damselfishes
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Increasing disturbances on coral reefs threaten fish species with close microhabitat associations in shallow waters, but deep reefs may provide refuge habitats. Assessing this potential requires a comprehensive understanding of how versatility in microhabitat use, preference, and selectivity interact with changes in habitat composition along depth gradients. We examined six damselfish species categorized by versatility of shallow-water microhabitat association (‘complex-coral-specialists’, ‘coral-associates’, and ‘generalists’), along a depth gradient from 10 to 30 m in Kimbe Bay, Papua New Guinea, and tested four important hypotheses. (1) We examined associations with hard-coral and complex-coral microhabitats. Hard-coral association declined with depth more among generalists than coral-associates but complex-coral microhabitat association declined for all species except one complex-coral-specialist. (2) We studied whether microhabitat selectivity declines with depth. Unexpectedly, selectivity increased with depth among both generalist and specialist species. (3) Within species, we tested for positive relationships between fish abundance and preferred microhabitat availability at each depth. However, relationships were stochastic across depths for all but one complex-coral-specialist. (4) Finally, we tested for positive relationships between the number of microhabitats selected by a species and the species’ abundance at each depth, finding that species’ abundances were not consistently related to microhabitat versatility. Our results suggest that several species currently utilize deep coral microhabitats (≤ 30 m), including specialists that strongly associate with vulnerable coral habitats in shallow water. Considerable microhabitat plasticity occurred along the gradient, even amidst stable preferences, and versatile species were not habitat limited, though restricted versatility may limit refuge potential for some species.
We thank Phillip Smith for field assistance and M. Bonin for theoretical and analytical advice, and J. Eurich and T. Rüger for helpful comments. M. Ikanga thanks her family for their support, patience and encouragement. Mahonia Na Dari—Guardians of the Sea and Walindi Plantation Resort provided valuable logistical support.
Compliance with ethical standards
This study was funded by a Grant to G. P. Jones from the Australian Research Council.
Conflict of interest
C. MacDonald declares that he has no conflict of interest. M. Ikanga declares that she has no conflict of interest. G. P. Jones declares that he has no conflict of interest.
All applicable international, national, and/or institutional guidelines for the care and use of animals were followed.
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
- Bongaerts P, Frade PR, Ogier JJ, Hay KB, Van Bleijswijk J, Englebert N, Vermeij MJ, Bak RP, Visser PM, Hoegh-Guldberg O (2013) Sharing the slope: depth partitioning of agariciid corals and associated Symbiodinium across shallow and mesophotic habitats (2–60 m) on a Caribbean reef. BMC Evol Biol 13:205CrossRefPubMedPubMedCentralGoogle Scholar
- Eckert GJ (1985) Settlement of coral reef fishes to different natural substrata and at different depths. In: Proc 5th int coral reef congr Tahiti vol 5, pp 385–390Google Scholar
- Hughes TP, Kerry JT, Álvarez-Noriega M, Álvarez-Romero JG, Anderson KD, Baird AH, Babcock RC, Beger M, Bellwood DR, Berkelmans R, Bridge TC, Butler IR, Byrne M, Cantin NE, Comeau S, Connolly SR, Cumming GS, Dalton SJ, Diaz-Pulido G, Eakin MC, Figueira WF, Gilmour JP, Harrison HB, Heron SF, Hoey AS, Hobbs JPA, Hoogenboom MO, Kennedy EV, Kuo C, Lough JM, Lowe RJ, Liu G, McCulloch MT, Malcolm HA, McWilliam MJ, Pandolfi JM, Pears RJ, Pratchett MS, Schoepf V, Simpson T, Skirving WJ, Sommer B, Torda G, Wachenfeld DR, Willis BL, Wilson SK (2017) Global warming and recurrent mass bleaching of corals. Nature 543:373–377CrossRefPubMedGoogle Scholar
- MacNally RC (1995) Ecological versatility and community ecology. In: Cambridge Studies in Ecology, Cambridge University Press. https://doi.org/10.1017/CBO9780511565427
- Manly B, McDonald L, Thomas D, McDonald T, Erickson W (2002) Resource selection by animals: statistical analysis and design for field studies. Kluwer, NordrechtGoogle Scholar
- Menza C, Kendall M, Hile S (2008) The deeper we go the less we know. Rev Biol Trop 56(Sup 1):11–24Google Scholar
- Pratchett MS, Munday P, Wilson SK, Graham NA, Cinner JE, Bellwood DR, Jones GP, Polunin NV, McClanahan TR (2008) Effects of climate-induced coral bleaching on coral-reef fishes - ecological and economic consequences. Oceanogr Mar Biol Annu Rev 46:251–296Google Scholar
- Randall JE, Allen GR, Steene RC (1997) Fishes of the Great Barrier Reef and Coral Sea. University of Hawaii Press, HonoluluGoogle Scholar
- Wilkinson E (2002) Status of coral reefs of the world. Australian Institute of Marine Science, TownsvilleGoogle Scholar