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Comparative study on sound production in different Holocentridae species
Parmentier, E.; Vandewalle, P.; Brie, C.; Dinraths, L.; Lecchini, D. (2011). Comparative study on sound production in different Holocentridae species. Front. Zool. 8: 12. http://hdl.handle.net/10.1186/1742-9994-8-12
In: Frontiers in Zoology. BioMed Central: London. ISSN 1742-9994, more
Peer reviewed article  

Available in  Authors 

Keywords
    Beryciformes [WoRMS]; Holocentridae Bonaparte, 1833 [WoRMS]; Marine
Author keywords
    Holocentridae; swimbladder; acoustic; biogeography; sounds; sonic muscle; Beryciform

Authors  Top 
  • Parmentier, E., more
  • Vandewalle, P., more
  • Brie, C.
  • Dinraths, L., more
  • Lecchini, D.

Abstract

    Background

    Holocentrids (squirrelfish and soldierfish) are vocal reef fishes whose calls and sound-producing mechanisms have been studied in some species only. The present study aims to compare sound-producing mechanisms in different Holocentridae genera (Holocentrus, Myripristis, Neoniphon, Sargocentron) from separate regions and, in some cases, at different developmental stages. An accurate comparison was made by recording six species while being hand-held, by observing TEM) the sonic muscles and by dissections of the sound-producing mechanism.

    Results

    In all these species, calls presented harmonics, their dominant frequency was between 80 and 130 Hz and they were composed of trains of 4 to 11 pulses with gradual increasing periods towards the end of the call. In each case, the calls did not provide reliable information on fish size. The sounds were produced by homologous fast-contracting sonic muscles that insert on articulated ribs whose proximal heads are integrated into the swimbladder: each pulse is the result of the back and forth movements of the ribs. Small differences in the shape of the oscillograms of the different species could be related to the number of ribs that are involved in the sound-producing mechanism. These fish species are able to make sounds as soon as they settle on the reef, when they are 40 days old. Comparison between Neoniphon from Madagascar and from Rangiroa in French Polynesia showed a new, unexpected kind of dialect involving differences at the level of pulse distribution. Neoniphon calls were characterised by a single pulse that was isolated at the beginning of the remaining train in Madagascar whereas they did not show any isolated single pulses at the beginning of the call in Rangiroa.

    Conclusion

    This family cannot use the acoustic fundamental frequencies (or pulse periods) of grunts to infer the size of partners. Pulse duration and number of pulses are statistically related to fish size. However, these characteristics are poorly informative because the correlation slope values are weak. It remains other features (sound amplitude, resistance to muscle fatigue, calling frequency) could be used to assess the body size. Characteristics of the sound producing mechanisms are conservative. All species possess fast-contracting muscles and have the same kind of sound producing mechanism. They do show some change between clades but these differences are not important enough to deeply modify the waveforms of the calls. In this case, our description of the grunt could be considered as the signature for the holocentrid family and can be used in passive acoustic monitoring.


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