Sound production and pectoral spine locking in a Neotropical catfish (Iheringichthys labrosus, Pimelodidae)

Tellechea, Javier S.; Mello, Franco Teixeira de; González‐Bergonzoni, Ivan; Vidal, Nicolás

doi:10.1590/s1679-62252011005000041

Cited by 11 publications

(6 citation statements)

References 25 publications

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“…Click frequency spectra are similar to pectoral spine stridulation sounds of other catfish (Pfeiffer & Eisenberg, ; Fine et al ., ; Ladich, ; Kaatz et al ., ; Parmentier et al ., ; Tellechea et al ., ). Pectoral spines, however, are absent in Malapteruridae and no pectoral fin movements were observed during clicks.…”

Section: Discussionmentioning

confidence: 97%

“…The malapterurid electric organ is superficial to body musculature and is derived from obliquus inferioris hypaxial musculature (Howes, ). Surprisingly, the three call types observed did not bear similarity to ESA muscle‐driven sounds of other catfish (Tavolga, ; Kastberger, , ; Ladich, ; Tellechea et al ., ; Kaatz & Stewart, ; Boyle et al ., ). The mechanism for these sounds and role of the unusual swim bladder morphology is not understood.…”

Section: Discussionmentioning

confidence: 99%

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Agonistic sounds and swim bladder morphology in a malapterurid electric catfish

2015

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Several catfish families possess an elastic spring apparatus (ESA) morphology that is assumed to function as a swim bladder drumming sound production mechanism. Although they have an ESA, drumming sounds in the electric catfish (Malapteruridae) have not been described. We have recorded several different sound types in Malapterurus beninensis and we examined the morphology of the swim bladder, the ESA and the ultrastructure of the protractor muscle. The protractor muscle contains small rounded muscle fibers with abundant mitochondria, narrow myofibrils, elaborated sarcoplasmic reticula and sometimes sarcoplasmic cores. Contractions of the protractor muscle should pull the Müllerian ramus (MR) and attached swim bladder anteriorly. Further, the MR possesses an anterior fulcrum that abuts upon the vertebral complex. Several sound types were elicited during agonistic interactions in the laboratory. We observed ratchet, click train and mouth sounds. Mouth sounds are single event, low-frequency (mean dominant frequency 176 Hz) sounds that coincide with a bite-like motion. Ratchet and click sounds are high-frequency (mean dominant frequency 1568 and 3739 Hz, respectively) and occur in trains. Ratchet and click train sound characteristics are not indicative of a muscle-driven drumming sound predicted by ESA morphology. We propose several hypotheses for these sound production mechanisms. Click sounds, in particular, could result from gas movement through the neck between the anterior and posterior swim bladder chambers.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Agonistic sounds and swim bladder morphology in a malapterurid electric catfish

2015

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“…6-12 kHz). The potential sources of the predominant frequencies found within the seagrass-dominated site are unknown, because fish are known to generally produce sounds at frequencies lower than 1 kHz (Ghazali 2011;Parmentier et al 2011;Tellechea et al 2011). One of the most ubiquitous sound sources of biological sound within either habitat was snapping shrimp (Alpheus sp.…”

Section: Discussionmentioning

confidence: 99%

Eavesdropping on the Kaipara Harbour: characterising underwater soundscapes within a seagrass bed and a subtidal mudflat

Pine

Radford

Jeffs

2015

New Zealand Journal of Marine and Freshwater Research

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With considerable commercial interest in renewable energy production in estuarine environments, there is a critical need to better understand ambient sound from these habitats. This study investigated the ambient sound from two sites of differing habitats within the Kaipara Harbour, a site previously allocated for tidal turbine development. Analyses revealed highest sound levels occurring in autumn (120 ± 0.6 dB rms re 1 µPa) and summer (117 ± 0.6 dB rms re 1 µPa) within the seagrass-dominated and mudflat sites respectively. There was significant temporal variation over a 24 h period in measured sound levels both between and within the two estuarine sites, with higher sound levels generally occurring at dawn within either site. Spectral analysis revealed a rise in spectral power in the 2-4 kHz and 6-9 kHz bandwidths during dawn and dusk periods within the seagrass-dominated and mudflat sites respectively. With most acoustic energy residing in low frequencies, underwater turbine sound may mask estuarine soundscapes, thereby potentially disrupting important ecological processes.

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“…The pectoral spine is one of the several adaptations (Fine & Ladich, ) underlying the success of catfishes, a group with over 3000 species (Ferraris, ). The spine base has derived dorsal, anterior and ventral processes (Hubbs & Hibbard, ) that allow it to be bound, locked and rubbed to produce stridulatory sounds (Fine et al, , ; Heyd & Pfeiffer, ; Kaatz et al, ; Parmentier et al, ; Tellechea et al, ). Additionally, these sounds function in agonistic and courtship communication in some catfish clades (Pruzsinszky & Ladich, ; Hadjiaghai & Ladich, ).…”

Section: Introductionmentioning

confidence: 99%

Explosive development of pectoral muscle fibres in large juvenile blue catfish Ictalurus furcatus

Lahiri

Fine

2015

Journal of Fish Biology

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As part of an effort on scaling of pectoral spines and muscles, the basis for growth was examined in six pectoral muscles in juvenile blue catfish Ictalurus furcatus, the largest catfish in North America. Fibre number increases slowly in fish from 13.0 to 26.4 cm in total length, doubles by 27.0 cm and remains stable in larger individuals. Simultaneously, mean fibre diameter decreases by half, caused by the addition of new small fibres, before increasing non-linearly in larger fish. The orders of magnitude disparity between the size at hatching and the size of large adults may have selected for rapid muscle fibre addition at a threshold size.

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Sound production and pectoral spine locking in a Neotropical catfish (Iheringichthys labrosus, Pimelodidae)

Cited by 11 publications

References 25 publications

Agonistic sounds and swim bladder morphology in a malapterurid electric catfish

Agonistic sounds and swim bladder morphology in a malapterurid electric catfish

Eavesdropping on the Kaipara Harbour: characterising underwater soundscapes within a seagrass bed and a subtidal mudflat

Explosive development of pectoral muscle fibres in large juvenile blue catfish Ictalurus furcatus

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