Abstract
Juvenile and adult reef fishes often undergo migration, ontogenic habitat shifts, and nocturnal foraging movements. The orientation cues used for these behaviours are largely unknown. In this study, the use of sound as an orientation cue guiding the nocturnal movements of adult and juvenile reef fishes at Lizard Island, Great Barrier Reef was examined. The first experiment compared the movements of fishes to small patch reefs where reef noise was broadcast, with those to silent reefs. No significant responses were found in the 79 adults that were collected, but the 166 juveniles collected showed an increased diversity each morning on the reefs with broadcast noise, and significantly greater numbers of juveniles from three taxa (Apogonidae, Gobiidae and Pinguipedidae) were collected from reefs with broadcast noise. The second experiment compared the movement of adult and juvenile fishes to reefs broadcasting high (>570 Hz), or low (<570 Hz) frequency reef noise, or to silent reefs. Of the 122 adults collected, the highest diversity was seen at the low frequency reefs; and adults from two families (Gobiidae and Blenniidae) preferred these reefs. A similar trend was observed in the 372 juveniles collected, with higher diversity at the reefs with low frequency noises. This preference was seen in the juvenile apogonids; however, juvenile gobiids were attracted to both high and low sound treatments equally, and juvenile stage Acanthuridae preferred the high frequency noises. This evidence that juvenile and adult reef fishes orientate with respect to the soundscape raises important issues for management, conservation and the protection of sound cues used in natural behaviour.
This is a preview of subscription content, log in via an institution to check access.
References
Au WWL, Banks K (1998) The acoustics of the snapping shrimp Synalpheus parneomeris in Kaneohe Bay. J Acoust Soc Am 103:41–47
Beck MW, Heck KL, Able KW, Childers DL, Eggleston DB, Gillanders BM, Halpern B, Hays CG, Hoshino K, Minello TJ, Orth RJ, Sheridan PF, Weinstein MR (2001) The identification, conservation, and management of estuarine and marine nurseries for fish and invertebrates. Bioscience 51:633–641
Booth DJ (1995) Juvenile groups in a coral reef damselfish: density-dependent effects on individual fitness and population demography. Ecology 76:91–106
Cato DH (1978) Marine biological choruses observed in tropical waters near Australia. J Acoust Soc Am 64:736–743
Cato DH (1980) Some unusual sounds of apparent biological origin responsible for sustained background noise in the Timor Sea. J Acoust Soc Am 68:1056–1060
Colin PL, Clavijo IE (1988) Spawning activity of fishes producing pelagic eggs on a shelf edge coral reef, southwestern Puerto Rico. Bull Mar Sci 43:249–279
Domeier ML, Colin PL (1997) Tropical reef fish spawning aggregations: defined and reviewed. Bull Mar Sci 60:698–726
Fay RR, Simmons AM (1998) The sense of hearing in fishes and amphibians. In: Fay RR, Popper AN (eds) Comparative hearing: fish and amphibians. Springer, New York, pp 269–318
Fish MP, Mowbray WH (1970) Sounds of the western north Atlantic. Johns Hopkins, Baltimore
Jasny M (1999) Sounding the depths: supertankers, sonar, and the rise of undersea noise. Natural Resources Defense Council, New York
Kenyon TN (1994) The significance of sound interception to males of the bicolor damselfish, Pomacentrus partitus, during courtship. Environ Biol Fish 40:391–405
Kingsford MJ, Leis JM, Shanks A, Lindeman KC, Morgan SG, Pineda J (2002) Sensory environments, larval abilities and local self-recruitment. Bull Mar Sci 70:309–340
Kolm N, Hoffman EA, Olsson J, Berglund A, Jones AG (2005) Group stability and homing behavior but no kin group structures in a coral reef fish. Behav Ecol 16:521–527
Leis JM, Sweatman HPA, Reader SE (1996) What the pelagic stages of coral reef fishes are doing out in blue water: daytime field observations of larval behavioural capabilities. Mar Freshw Res 47:401–411
Leis JM, Carson-Ewart BM, Hay AC, Cato DH (2003) Coral-reef sounds enable nocturnal navigation by some reef-fish larvae in some places and at some times. J Fish Biol 63:724–737
Leis JM, Lockett MM (2005) Localization of reef sounds by settlement-stage larvae of coral-reef fishes (Pomacentridae). Bull Mar Sci 76:715–724
Mann DA, Lobel PS (1997) Propagation of damselfish (Pomacentridae) courtship sounds. J Acoust Soc Am 101:3783–3791
Mann DA, Lobel PS (1998) Acoustic behavior of the damselfish Dascyllus albisella: behavioral and geographic variation. Environ Biol Fish 51:421–428
Marnane MJ (2000) Site fidelity and homing behaviour in coral reef cardinalfishes. J Fish Biol 57:1590–1600
Mazeroll AI, Montgomery WL (1998) Daily migrations of a coral reef fish in the Red Sea (Gulf of Aqaba, Israel): initiation and orientation. Copeia 4:893–905
McCauley RD, Cato DH (2000) Patterns of fish calling in a nearshore environment in the Great Barrier Reef. Philos Trans R Soc Lond B 355:1289–1293
McCauley RD, Fewtrell J, Popper AN (2003) High intensity anthropogenic sound damages fish ears. J Acoust Soc Am 113:638–642
Meekan MG, Milicich MJ, Doherty PJ (1993) Larval production drives temporal patterns of larval supply and recruitment of a coral reef damselfish. Mar Ecol Prog Ser 93:217–225
Milicich MJ, Meekan MG, Doherty PJ (1992) Larval supply: a good predictor of recruitment of 3 species of reef fish (Pomacentridae). Mar Ecol Prog Ser 86:153–166
Montgomery JC, Tolimieri N, Haine OS (2001) Active habitat selection by pre-settlement reef fishes. Fish Fish 2:261–277
Montgomery JC, Jeffs A, Simpson SD, Meekan MG, Tindle C (2006) Sound as an orientation clue for the pelagic larvae of reef fish and crustaceans. Adv Mar Biol 51:143–196
Myrberg AA (1997) Sound production by a coral reef fish (Pomacentrus partitus): evidence for a vocal, territorial “keep-out” signal. Bull Mar Sci 60:1017–1025
Myrberg AA, Mohler M, Catala JD (1986) Sound production by males of a coral reef fish (Pomacentrus partitus): its significance to females. Anim Behav 34:913–923
Myrberg AA, Ha SJ, Shamblott MJ (1993) The sounds of bicolor damselfish (Pomacentrus partitus): predictors of body size and a spectral basis for individual recognition and assessment. J Acoust Soc Am 94:3067–3070
Nagelkerken I, Dorenbosch M, Verberk W, de la Moriniere EC, van der Velde G (2000) Importance of shallow-water biotopes of a Caribbean bay for juvenile coral reef fishes: patterns in biotope association, community structure and spatial distribution. Mar Ecol Prog Ser 202:175–192
Pollard DA (1984) A review of ecological studies on seagrass fish communities, with particular reference to recent studies in Australia. Aquat Bot 18:3–42
Reese ES (1989) Orientation behavior of butterflyfishes (family Chaetodontidae) on coral reefs: spatial learning of route specific landmarks and cognitive maps. Environ Biol Fish 25:79–86
Richardson WJ, Greene CR, Malme CI, Thomson DH (1995) Marine mammals and noise. Academic, San Diego
Rogers PH, Cox M (1988) Underwater sound as a biological stimulus. In: Atema J, Fay RR, Popper AN, Travolga WN (eds) Sensory biology of aquatic animals. Springer, New York, pp 131–149
Shulman MJ, Ogden JC (1987) What controls tropical reef fish populations: recruitment or benthic mortality––an example in the Caribbean reef fish Haemulon flavolineatum. Mar Ecol Prog Ser 39:233–242
Simpson SD, Meekan MG, McCauley RD, Jeffs A (2004) Attraction of settlement-stage coral reef fishes to reef noise. Mar Ecol Prog Ser 276:263–268
Simpson SD, Meekan M, Montgomery J, McCauley R, Jeffs A (2005) Homeward sound. Science 308:221–221
Smith ME, Coffin AB, Miller DL, Popper AN (2006) Anatomical and functional recovery of the goldfish (Carassius auratus) ear following noise exposure. J Exp Biol 209:4193–4202
Stobutzki IC, Bellwood DR (1998) Nocturnal orientation to reefs by late pelagic stage coral reef fishes. Coral Reefs 17:103–110
Sweatman H (1988) Field evidence that settling coral reef fish larvae detect resident fishes using dissolved chemical cues. J Exp Mar Biol Ecol 124:163–174
Tolimieri N, Jeffs A, Montgomery JC (2000) Ambient sound as a cue for navigation by the pelagic larvae of reef fishes. Mar Ecol Prog Ser 207:219–224
Tolimieri N, Haine O, Jeffs A, McCauley R, Montgomery J (2004) Directional orientation of pomacentrid larvae to ambient reef sound. Coral Reefs 23:184–191
Versluis M, Schmitz B, von der Heydt A, Lohse D (2000) How snapping shrimp snap: through cavitating bubbles. Science 289:2114–2117
Warner RR (1988) Traditionality of mating site preferences in a coral reef fish. Nature 335:719–721
Zar JH (1999) Biostatistical analysis. Prentice-Hall, Upper Saddle River
Acknowledgments
We thank the staff at the Lizard Island Research Station, M. Wolter, C. Simpson, and N. Larsen for assistance in the field, C. Radford for analysis of sound treatments, and A. Heenan, C. Johansson, and four anonymous reviewers for valuable comments on the manuscript. This work was supported by a Natural Environment Research Council postdoctoral fellowship, the Fisheries Society of the British Isles and the British Ecological Society (to S.D.S.), the Marsden Fund (to A.J. and J.C.M), and the Australian Institute of Marine Science (to M.G.M.).
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by Biology Editor M. P. Lesser.
Rights and permissions
About this article
Cite this article
Simpson, S.D., Jeffs, A., Montgomery, J.C. et al. Nocturnal relocation of adult and juvenile coral reef fishes in response to reef noise. Coral Reefs 27, 97–104 (2008). https://doi.org/10.1007/s00338-007-0294-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00338-007-0294-y