Novel vocal repertoire and paired swimbladders of the three-spined toadfish, Batrachomoeus trispinosus: insights into the diversity of the Batrachoididae

doi:10.1242/jeb.028506

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First published online April 17, 2009
Journal of Experimental Biology 212, 1377-1391 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.028506

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Novel vocal repertoire and paired swimbladders of the three-spined toadfish, Batrachomoeus trispinosus: insights into the diversity of the Batrachoididae

Aaron N. Rice^* and Andrew H. Bass

Department of Neurobiology and Behavior, Cornell University, Ithaca, NY 14853, USA

^* Author for correspondence (e-mail: arice{at}cornell.edu)

Accepted 23 February 2009

Summary

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Toadfishes (Teleostei: Batrachoididae) are one of the best-studiedgroups for understanding vocal communication in fishes. However,sounds have only been recorded from a low proportion of taxawithin the family. Here, we used quantitative bioacoustic, morphologicaland phylogenetic methods to characterize vocal behavior andmechanisms in the three-spined toadfish, Batrachomoeus trispinosus.B. trispinosus produced two types of sound: long-duration `hoots'and short-duration `grunts' that were multiharmonic, amplitudeand frequency modulated, with a dominant frequency below 1 kHz.Grunts and hoots formed four major classes of calls. Hoots were typicallyproduced in succession as trains, while grunts occurred either singlyor as grunt trains. Aside from hoot trains, grunts and grunttrains, a fourth class of calls consisted of single grunts withacoustic beats, apparently not previously reported for individualsfrom any teleost taxon. Beats typically had a predominant frequencyaround 2 kHz with a beat frequency around 300 Hz. Vocalizationsalso exhibited diel and lunar periodicities. Spectrographiccross-correlation and principal coordinates analysis of hoots fromfive other toadfish species revealed that B. trispinosus hoots weredistinct. Unlike any other reported fish, B. trispinosus hada bilaterally divided swimbladder, forming two separate swimbladders. Phylogeneticanalysis suggested B. trispinosus was a relatively basal batrachoidid,and the swimbladder and acoustic beats were independently derived.The swimbladder in B. trispinosus demonstrates that toadfisheshave undergone a diversification of peripheral sonic mechanisms, whichmay be responsible for the concomitant innovations in vocal communication,namely the individual production of acoustic beats as reported insome tetrapods.

Key words: acoustic communication, courtship, functional morphology, ontogeny, phylogeny, sound production, swimbladder, vocalization

INTRODUCTION

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Of the many species of fishes that are known to acousticallycommunicate, perhaps the group most intensively studied andbest understood is the Batrachoididae, which are generally referredto as toadfishes, but also include several genera referred tomore specifically as toadfish and midshipman (see Nelson, 2006). Toadfishesare best known for their distinctive multiharmonic, male advertisementvocalizations used in courtship to attract females to male nest sites(reviewed by Bass and McKibben, 2003). Within the family, thereis considerable variation in the temporal properties of courtshipvocalizations. For example, the `boatwhistle' of the toadfishOpsanus beta typically includes an initial broad-band, brief( $~$ 50 ms) `grunt' that continues as a longer duration ( $~$ 200–300ms) multiharmonic `hoot' (Tavolga, 1958; Tavolga, 1960). Incontrast, the multiharmonic `hum' of the plainfin midshipman(Porichthys notatus) is only hoot like with little to no amplitudemodulation and can last from minutes to upwards of 1 h (Brantleyand Bass, 1994; Hubbs, 1920; Ibara et al., 1983).

The batrachoidid vocal repertoire also includes sounds thatfunction in aggression. Aggressive vocalizations are usuallyemitted during nest defense and are distinct from courtshipcalls in two specific temporal properties: duration and callrate. In agonistic interactions, both male and female toadfishesproduce `grunts': short duration, typically non-harmonic calls.In some cases, grunts can be rapidly repeated to form a `grunttrain' that may last for several seconds (e.g. see Amorim etal., 2008; Brantley and Bass, 1994; Gray and Winn, 1961). Unlikecourtship sounds, agonistic grunts are not seasonally dependent.Midshipman also produce an amplitude- and frequency-modulatedcall known as a `growl' that has grunt and hoot-like portionslike the boatwhistle of some toadfishes (see above), can lastfor several seconds, and probably functions in agonistic contexts (Basset al., 1999).

The role of the swimbladder in toadfish sound production hasbeen investigated for over a century (Tower, 1908), and it remainsthe best-studied system for peripheral sonic mechanisms in fishes(for a review, see Ladich and Fine, 2006). Vocalizations areproduced by the rapid contraction of paired striated muscles attachedto the walls of the swimbladder (Fine et al., 2001; Fine etal., 2002), with ultrastructural traits divergent from trunkskeletal muscles (e.g. Bass and Marchaterre, 1989; Fawcett andRevel, 1961), that are adapted to contraction frequencies whichare among the fastest of vertebrate skeletal muscles (Rome, 2006;Rome et al., 1996; Skoglund, 1961).

While broad comparisons have been made across species betweenthe different toadfish sounds and divergent neural and peripheralvocal mechanisms (Amorim et al., 2008; Bass and Marchaterre,1989; Bass and Baker, 1991; Bass and McKibben, 2003; dos Santoset al., 2000; Mann et al., 2002; Tavolga, 1958; Tavolga, 1965),no robust quantitative methods have been used to rigorouslyinvestigate the species-level diversity of vocalizations inthe family, as have been used in studying acoustics in othervertebrate taxa (e.g. Buck and Tyack, 1993; Clark et al., 1987; Mitaniand Marler, 1989; Nowicki and Nelson, 1990; Rendell and Whitehead,2003; Young et al., 1999). Additionally, the majority of thiswork has focused only on three species within the Batrachoididae(O. beta, O. tau and P. notatus) (Amorim, 2006; Bass and McKibben,2003), despite the moderate diversity of the family, which contains25 genera and 78 species (Greenfield et al., 2008) (see alsoNelson, 2006).

Little is known about the natural history, internal anatomy,or behavior of most toadfishes. An example of one such speciesis the three-spined toadfish, Batrachomoeus trispinosus. Outsideof some taxonomic and systematic work (e.g. Hutchins, 1976; Miyaet al., 2005), little is known about the behavioral biologyof this taxon. Batrachomoeus trispinosus is a tropical euryhalinespecies, ranging from 0 to 36 m in depth in fresh and saltwaterhabitats throughout the tropical western Pacific (Greenfield,1999). Based on specimens collected in trawls, individuals appearto occur in low densities within estuarine environments (Hajisamae etal., 2006; Tonks et al., 2008). Despite this lack of knowledgeof B. trispinosus in the wild, they have become popular in theaquarium trade, appearing under a variety of (often misleading)names such as frogfish, lionfish or Halophryne trispinosus (Norman, 1976).Though disturbance/agonistic sounds have been anecdotally reportedfrom a congeneric species, B. dubius (Graham, 1992; Grant, 1987),no quantitative or in-depth analyses have been conducted forsounds of the genus.

This investigation of B. trispinosus has two main goals. Thefirst is to characterize the vocal repertoire and quantitativelycompare it with that of other toadfishes. The second goal isto describe the unique morphology of the sonic swimbladder andits functional implications. By generating a molecular phylogenyof the toadfishes, we demonstrate that B. trispinosus has evolvedboth a novel vocal signal (acoustic beat) and a novel swimbladder(bilaterally divided). The diversity in vocal behaviors and supportingbiomechanical mechanisms in this family broadens our understanding ofthe evolution of acoustic communication in toadfishes, and amongclosely related groups of fishes in general (Malavasi et al.,2008).

MATERIALS AND METHODS

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Batrachomoeus trispinosus (Günther) were acquired throughthe aquarium trade and maintained in freshwater aquaria (150and 380 l) at 26°C. The room was maintained on a 13 h:11h light:dark cycle along with incandescent moonlight timer replicatingthe lunar cycle (Solar 1000 dimmer, Blueline Aquatics, Ambler,PA, USA). The overhead lights in the aquarium room were offfrom 20:00 h to 07:00 h. Fish were fed live minnows and small goldfishweekly. All procedures were approved by the Institutional AnimalCare and Use Committee at Cornell University.

Recordings were made in aquaria using a hydrophone (AquarianAQ-6, Aquarian Audio Products, Anacortes, WA, USA, frequencyresponse 20 Hz to 100 kHz; or 171/1/5 hydrophone, High Tech,Gulfport, MS, USA, sensitivity –168.2 dB re: 1 V µPa^–1,frequency response 2 Hz to 30 kHz) suspended 20–30 cmabove fish nests. Sounds were recorded either through the Audacity1.2.5 software package (http://audacity.sourceforge.net/) ona MacBook Pro or on an Olympus LS-10 digital recorder (OlympusImaging America, Center Valley, PA, USA), at a sampling rateof 44.1 kHz as 16-bit WAV files. The hydrophone passively recordedin aquaria for 12–15 h periods to detect mainly undisturbedconspecific sounds; as reported, a few sounds were recordedfrom individual fish while they were chased by an observer. Soundswere then analyzed using Raven 1.3 (Bioacoustics Research Program, CornellLaboratory of Ornithology, Cornell University, Ithaca, NY, USA).

The physical parameters of the aquaria were taken into accountwhen positioning the hydrophones and analyzing the fish sounds,as fish sound recordings in captivity are known to be affectedby the dimensions of aquaria (Akamatsu et al., 2002; Okumuraet al., 2002; Parvulescu, 1967). The speed of sound in tankswas calculated to be 1547 cm s^–1 following the equationof Medwin (Medwin, 1975). This calculated sound velocity wasthen used to determine the minimum resonant frequency (150 ltank: 2761 Hz, 380 l tank: 2482 Hz) and attenuation distance(20–30 cm) of the sounds in aquaria (Akamatsu et al.,2002; Okumura et al., 2002). Attenuation distance is the lengthover which the sound pressure decreases by 20 dB (Akamatsu etal., 2002; Okumura et al., 2002). Because of the small aquariumsize, the amplitude of upper frequency components of the soundsnear the resonant frequency of the tank may be distorted (Akamatsuet al., 2002). Additionally, the size constraints of the aquariumcaused all sounds to be recorded in the near field and, combinedwith the fact that the distance between the vocalizing fishand the hydrophone could not be exactly quantified, the absolutesound pressure level was not measured.

Sound analysis
Seven variables were measured for the two basic types of sound,hoots and grunts: total sound duration, interval between successivesounds, fundamental frequency (the lowest frequency componentin a harmonic sound), dominant frequency (the highest amplitudefrequency component in either a broad-band or harmonic sound),relative amplitude, number of pulses and inter-pulse interval foreach sound (see Bradbury and Vehrencamp, 1998; Fine et al., 1977;Winn, 1964). The temporal properties of sounds were determinedfrom oscillograms, while the frequency properties were determinedfrom both spectrograms and power spectra (Hann filter, 3 dBfilter bandwidth 9 Hz, FFT 3524 samples, 50% overlap). Onlysounds that had a clear structure and minimal background noisewere included in quantitative analyses. Sounds were classifiedas a particular call type based on their relative duration,pattern of amplitude modulation and frequency content.

Quantitative comparisons of toadfish sounds
Spectrographic cross-correlation (Clark et al., 1987; Nowickiand Nelson, 1990) combined with principal coordinates analysis (SPCC–PCo)(Cortopassi and Bradbury, 2000) was used to quantitatively comparethe multiharmonic, boatwhistle-like calls of different speciesof toadfish. While the boatwhistles of some toadfish includean initial grunt-like segment (Remage-Healey and Bass, 2005; Tavolga,1958; Thorson and Fine, 2002a), only the otherwise subsequentmultiharmonic hoot portion of the call was analyzed here asthe putative boatwhistles of Batrachomoeus, like those of someother batrachoidids (e.g. midshipman), lack an initial grunt. Fifty-ninerepresentative hoots from B. trispinosus were quantitativelycompared with hoot-like sounds from five other toadfish species:Halobatrachus didactylus (N=9), O. beta (N=29), O. phobetron(N=5), O. tau (N=30) and P. notatus (N=18). Additionally, because thegrowl of P. notatus acoustically resembles the Opsanus boatwhistlein having both broad-band and multiharmonic portions (Bass etal., 1999), examples of these growls (N=18) were also includedin the analysis. Halobatrachus didactylus sounds were recordedby M. C. P. Amorim (July 2001 and 2002, Tagus Estuary, Portugal),O. beta sounds were recorded by L. Remage-Healey (June 2002at the Florida State University Coastal and Marine Laboratory,St Teresa, FL, USA), O. tau sounds were recorded by J. R. McKibben(July 1994, Point Pleasant, NJ, USA), and P. notatus soundswere recorded by M. A. Marchaterre (July 1998, Bodega MarineLaboratory, Bodega Bay, CA, USA). Opsanus phobetron sounds wereobtained from the Macaulay Library of Animal Sounds at the Cornell Laboratoryof Ornithology (ML catalog number 112910, recorded by M. P.Fish and W. H. Mowbray, Bimini, Bahamas). All sounds were down-sampledto 22.05 kHz. Because the P. notatus hum is substantially longerin duration than any of the other vocalizations in the analysis,10 long-duration hums (greater than 20 min) were sub-sampledto create 10 s hums to avoid biasing the correlation due tothe extreme disparity in sound duration.

Sounds were cross-correlated in Raven 1.3 using the batch correlator function.Sounds were normalized and bandpass filtered between 0 and 5000Hz to reduce the effects of any incidental background noise (Cortopassiand Bradbury, 2000). Both spectrograms (Hann Window, 3 dB bandwidth49.6 Hz, FFT 1280 samples) and waveforms were cross-correlated.A total of 166 sounds were included in the SPCC analysis resultingin 27,556 sound comparisons. The resulting output is a similaritymatrix, consisting of the similarity score between all possiblepair-wise comparisons of sounds. This matrix was converted toa distance matrix (distance=1–similarity) and analyzedwith a PCo analysis using the PCoord script in the R Package (Casgrainand Legendre, 2004) following the method used by Cortopassiand Bradbury (Cortopassi and Bradbury, 2000).

The relative temporal position of the maximum amplitude of each batrachoididsound was calculated as a function of its occurrence withinthe sound (time of maximum amplitude/duration=relative temporalposition of maximum amplitude), and differences among specieswere analyzed with an ANOVA.

Morphological measurements
Specimens preserved in 70% ethanol (N=28) were dissected to examinethe swimbladder morphology. Standard length, body mass and sexwere recorded. Two specimens were cleared and stained [followingthe protocol of Song and Parenti (Song and Parenti, 1995)] andthe swimbladder was left in place to allow its morphology tobe visualized in relation to the rest of the body. The length andwidth of swimbladders were measured in situ with calipers and photographedunder a dissecting microscope. Sexual dimorphism of the swimbladdercharacteristics was tested with an ANCOVA using JMP 5.0.1.2(SAS Institute, Cary, NC, USA) with standard length as the covariate.

Swimbladders were dissected out from the peritoneal cavity (N=11) andthe muscles attached to the walls were dissected free, blottedtwice with filter paper, and then weighed. Differences in massbetween the left and right swimbladder muscles were tested withStudent's paired t-test using the residuals of the swimbladdermuscle mass from a regression against swimbladder length (toaccount for differences in swimbladder size). Differences inmuscle mass between the sexes were tested using an ANOVA onthe muscle residuals.

To visualize the light microscopic structure of the swimbladderand muscles, swimbladders were sectioned at 70 µm on asledge microtome (Microm HM440E, Neuss, Germany). Sections weremounted on glass slides, stained with Methylene Blue, dehydratedand coverslipped, and then photographed under a microscope atx4 and x10 magnification.

Molecular systematics
To understand the evolutionary relationships of the includedtoadfish taxa, a molecular phylogeny was constructed based onfour genes from available toadfish taxa with sequences previouslydeposited in GenBank: 16S, 28S, cytochrome oxidase subunit I(COI) and cytochrome b (CytB). A list of accession numbers ofthe sequences used in the phylogenetic analysis is given insupplementary material Table S1. Gadus morhua was used as anoutgroup (see Nelson, 2006). As secondary structural informationis critical for the determination of ribosomal DNA homologyin multiple sequence alignment (Kjer, 1995), 16S and 28S geneswere aligned using the alignment program Expresso (Armougomet al., 2006), which uses structural information to calculatealignments. COI and CytB sequences were aligned using the programMCoffee (Moretti et al., 2007), which outputs a consensus alignmentusing eight different alignment algorithms. The most appropriatenucleotide substitution model, TrN+G (rmat=1.0000 2.4742 1.00001.0000 4.5176, pinvar=0), was selected using the hierarchical likelihoodtest in ModelTest 3.7 (Posada and Crandall, 1998). Using thealigned sequences and the nucleotide substitution model, a maximumlikelihood analysis was conducted in PAUP^* 4.10b (Swofford, 1998)using a heuristic search with 10 random sequence additions [followingWestneat and Alfaro (Westneat and Alfaro, 2005)]. To determinestatistical support of each node, a bootstrap analysis was performedusing tree bisection–reconnection branch swapping [followingWestneat and Alfaro (Westneat and Alfaro, 2005)].

RESULTS

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Over a period of 6 months in captivity (January to June 2008),a total of 1094 sounds produced by B. trispinosus were recorded.The sounds were initially classified mainly on the basis ofthe similarity of two temporal characters, duration and repetitionrate, that apply to other toadfish sounds (see Introduction):short duration grunts and longer duration hoots produced eitheralone or in succession as grunt trains. Together with additional analysesof spectral (e.g. either broad-band or multiharmonic) and temporal (e.g.sound pulse number and inter-pulse intervals) characters, fourmajor classes of calls were identified: hoot trains, singlebroad-band grunts, multiharmonic grunt trains, and single broad-bandgrunts with acoustic beats. Of the total calls recorded (N=198calls, comprising 1094 individual sounds), 34.8% were hoot trains(N=69 trains, composed of 592 individual hoots), 48.0% weresingle grunts (N=95), 7.1% were grunt trains (N=14 trains, composedof 392 grunts within the train) and 10.1% were grunts with acousticbeats (N=20). There were only three occurrences of single hootsand hence these were not considered a separate class of calls.

Hoot trains
The hoots of B. trispinosus were the longest duration sounds, typicallyheard in succession (Fig. 1A). Individual hoot duration rangedfrom 0.285 to 6.077 s (1.15±0.04 s mean±s.e.m.,N=295 hoots analyzed). The mean fundamental frequency of hootswas 151.35±0.39 Hz, while the mean dominant frequency(either the second or third harmonics) was 426.40±10.10Hz. Hoots typically had around 10 pronounced harmonics, withthe strongest power contained in the fundamental and the firstthree to four harmonics (Fig. 1B,C). Though not as strong asin frequencies below 1000 Hz, energy in the hoot extended intothe 2000 Hz range (Fig. 1B,C). The fine temporal structure ofthe hoot shows a highly regular pattern, with the largest peaksin the wave corresponding to the fundamental frequency ( $~$ 150Hz), and the smaller peaks corresponding to upper harmonics(Fig. 1D). Many hoots exhibited frequency modulation that waspresent at all harmonics, but most prevalent through the tenthharmonics – a shift of around 10 Hz in lower harmonics,and as much as 20–40 Hz in upper harmonics (Fig. 1B).Hoots also exhibited amplitude modulation, typically showinga gradual increase in overall amplitude throughout the sound(Fig. 1A; also see single hoot on an expanded time scale asan inset in Fig. 1C).

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Fig. 1. Representative hoot train of Batrachomoeus trispinosus. (A) Waveform (amplitude is in dimensionless arbitrary units) and (B) spectrogram (Hz) of 13 boatwhistle calls in a train of 36 s in duration. Box indicates the position of the individual call represented in C. (C) Power spectrum of an individual, representative hoot on an expanded time base, shown in the inset (scale bar represents 250 ms). (D) Close-up of boatwhistle waveform, showing fine-scale call structure. Sounds were recorded at 44.1 kHz.

As mentioned above, hoots mainly occurred as trains. The meannumber of hoots in a train was 8±1, and the mean intervalbetween hoots in the train was 1.95±0.08 s (N=32 trains).Over the course of trains, hoots in immediate succession withina sequence significantly decreased in duration (one-way ANOVA:d.f.=292; F=39.8339, P<0.0001; Fig. 2A). However, there wasno relationship between the duration of the inter-hoot intervalas a function of the temporal position in the train.

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Fig. 2. Temporal patterns in different B. trispinosus vocalizations. (A) Duration of individual boatwhistle hoots within a train versus the order in which they occur within the train. (B) Duration of individual grunts within a grunt train versus the order in which they occur within the train. The duration of calls decreases with increasing order within the train (i.e. later calls are shorter), while there is no correlation with interval duration within the train.

Single grunts and grunt trains
Batrachomoeus trispinosus also produced short duration grunts, whichwere typically performed singly (N=65), but also occurred as groupsof two (N=10), three (N=4), four (N=2) or five (N=1). We referto the latter collectively as single grunts because they hadan irregular periodicity when occurring in groups of two to five,unlike grunt trains (see below). Singly produced grunts wereoften coincident with gravel-like movement sounds suggestiveof a rapid body movement and an agonistic role as observed inother toadfishes (e.g. Brantley and Bass, 1994; Gray and Winn,1961). On average, single grunts were much shorter in durationthan single hoots within a train, with a mean of 0.276±0.035s (range: 0.029–0.775 s, N=37 grunts analyzed; Fig. 3A).Like the grunts of other toadfishes (e.g. Amorim et al., 2008; Basset al., 1999; Thorson and Fine, 2002a), almost all B. trispinosussingle grunts were broad-band (Fig. 3B,C), in this case with amean dominant frequency of 968±172 Hz.

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Fig. 3. (A) Waveform, (B) spectrogram and (C) power spectrum of a representative individual grunt of B. trispinosus. Sounds were recorded at 44.1 kHz.

Fish also produced grunt trains (Fig. 4), with a mean numberof 28±3 grunts in the train (range 8–48, N=330grunts analyzed from 12 grunt trains). The mean fundamentalfrequency of grunts within the train was 182±1 Hz, witha dominant frequency of 1002±53 Hz. The mean intervalbetween grunts was 0.353±0.014 s. Different from singlegrunts, grunts within trains had a clear and well-defined harmonicstructure (Fig. 4B,D), though the harmonics were broader thanthose in hoots (Fig. 1B,C). The fine temporal structure didnot appear to change during the course of a train (Fig. 4E).

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Fig. 4. (A) Waveform and (B) spectrogram of a representative grunt train (composed of 45 individual grunts) of B. trispinosus. Boxes in A represent individual grunts within the train in C and E. (C) The waveform and (D) corresponding power spectrum of an individual grunt at the beginning of the grunt train. (E) Waveform of an individual grunt in the middle of the grunt train. Sounds were recorded at 44.1 kHz.

The first grunt in a train was significantly longer in durationthan subsequent ones (0.529±0.084 versus 0.135±0.004s, d.f.=329, F=261.0041, P<0.0001; Fig. 2B). Grunts in immediate successionsignificantly decreased in duration over the course of a train (R²=0.18,d.f.=329, F=69.5554, P<0.0001; Fig. 2B), with no relationshipbetween the duration of the inter-grunt interval and the temporalposition in the train.

The fundamental frequency was significantly different betweenthe component sounds within hoot and grunt trains (one-way ANOVA:d.f.=520, F=1230.50, P<0.0001), with the fundamental frequencyof hoots about 30Hz lower than that of grunts (see above). Thedominant frequency of hoots was also significantly lower thanthat of grunts either alone or in trains (one-way ANOVA: d.f.=571,F=63.06, P<0.0001, Tukey's HSD post-hoc test: q=2.35, ${alpha}$ =0.05, P<0.05),but grunts and grunt trains were not different from each other(Tukey's HSD post-hoc test: q=2.35, ${alpha}$ =0.05, P>0.05).

Acoustic beats
A small proportion of vocalizations exhibited acoustic beats (Fig. 5),to our knowledge previously undescribed in individual fishes.Although beats are known for the plainfin midshipman fish, theyare formed by the temporal overlap in the advertisement humsof neighboring males (see Bass et al., 1999). The most commonbeat sounds for B. trispinosus were classified as single grunts(N=20) because of their overall duration (mean 0.147±0.026s, range: 0.024–0.371 s) and lack of repetition as trains(Fig. 5A,E). Grunts with beats had a dominant frequency greaterthan 2000 Hz (2298±262Hz) and a distinct beat frequency(303±75Hz; Fig. 5C,G). However, some of these gruntshad a clearer harmonic structure than others (compare Fig. 5B,Cwith 5 F,G). Grunts with beats were recorded from fish in thedifferent sized aquaria (see Materials and methods). The shortduration of these calls, along with their stable temporal (Fig. 5D,H)and harmonic structure (e.g. Fig. 5B–G), support the conclusionthat they were produced by a single individual [see Thorsonand Fine (Thorson and Fine, 2002a) for stability of call structurefor individual toadfish]. Moreover, individual fish producedgrunts with beats when physically chased around the aquarium witha small net by an observer (N=4 grunts from two individuals,not shown). These grunts had a longer duration (0.39±0.04s, range: 0.31–0.482 s) and much lower dominant and beatfrequencies (176±1 and 21±2 Hz, respectively)than the conspecifically elicited ones.

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Fig. 5. Examples of two representative grunts exhibiting acoustic beats from B. trispinosus. (A) Waveform, (B) spectrogram, (C) power spectrum, (D) and waveform with expanded time base of a individual grunt. Box in A indicates enlarged section in D. Arrows in C represent peaks at 194, 2196, 2326 and 2498 Hz. (D) Waveform, (E) spectrogram, (F) power spectrum and (G) waveform with expanded time base of a second grunt, showing beat structure and clear harmonics. Box in E indicates enlarged section in H. Arrows in G represent peaks at 194, 2196, 2348 and 2520 Hz. For spectrograms (B,F) and power spectra (D,H), FFT size=1028 samples.

Diel and lunar periodicity of calls
Vocalizations exhibited both a diel and lunar periodicity (Fig. 6).The number of hoot and grunt trains were both highest between21:00 h and 05:00 h (Fig. 6A). The number of hoot trains declinedin occurrence during the early morning hours until 09:00 h. Singlegrunts were produced at higher levels during more hours of theday, and were the most common call type throughout the day,with an elevated number of calls between 19:00 and 07:00 h (Fig. 6A).Grunt trains were the most infrequently produced call type, producedonly between 21:00 h and 05:00 h (Fig. 6A). The occurrence of allthree call types increased leading up to the full moon (Fig. 6B).Both single grunts and hoots showed an increase in number followingthe three-quarter waxing gibbous moon (Fig. 6B). The numberof hoot trains dramatically increased during the full moon,and then proceeded to drop to lower levels afterwards, whilethe number of single grunts increased during the waning phaseof the lunar cycle, becoming the predominant call type duringthis period (Fig. 6B).

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Fig. 6. (A) Diel patterns of calling frequency of different call types in B. trispinosus. Horizontal bar beneath x-axis labels indicates light cycle: open bar represents the period of ambient lights on, filled bar represents the period of ambient lights off (with only moonlight on). (B) Number of different call types over the lunar cycle in B. trispinosus.

Comparison of toadfish sounds
The hoot portion of the calls of all species considered exhibiteddifferent patterns of amplitude modulation. The time point atwhich the maximum amplitude occurred within the harmonic, hootportion of all calls was significantly different among the batrachoididspecies sampled (Fig. 7A; one-way ANOVA: d.f.=165, F=149.82,P<0.0001). An a posteriori Tukey's HSD test (q=2.99, ${alpha}$ =0.05)revealed three significantly different groups: B. trispinosusand H. didactylus had the latest position of maximum amplitudein their calls, Opsanus spp. boatwhistles and P. notatus growlshad the earliest time of maximum amplitude, and P. notatus humshad a maximum amplitude intermediate between those of the twoother groups (Fig. 7B).

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Fig. 7. (A) Representative waveforms of different toadfish vocalizations. Horizontal scale bars represent 250 ms; amplitude of the different calls is not to scale. (B) Relative temporal position of the occurrence of the maximum amplitude in toadfish harmonic calls, for B. trispinosus (BT), Halobatrachus didactylus (HD), Opsanus beta (OB), O. phobetron (OP), O. tau (OT), and the growl and hum of Porichthys notatus (PN).

Spectrographic cross-correlation and PCo analysis of differentbatrachoidid hoots and the hoot-like portion of midshipman growls(included because of structural similarity to Opsanus boatwhistles)showed that the first three principal coordinates accountedfor 27.96% of the total variation (PCo1: 13.83%, PCo2: 7.47%,PCo3: 6.66%). Cross-correlation analysis of the waveform producedsimilar results to spectrographic cross-correlation. Vocalizations fromwithin species were clustered closely together in the PCo (Fig. 8).Batrachomoeus trispinosus formed a distinct cluster apart fromall the other species with a positive distribution along PCo1,and some dispersion along PCo2 (0.1 to –0.1). Opsanustau and O. phobetron formed clusters extending to the lowerleft of the plot (with negative PCo1 and PCo2 values). Thoughthere were fewer samples of O. phobetron, the variance along PCo1was approximately the same as that of O. tau. Opsanus beta hada similar distribution along PCo1 to the other Opsanus species,but had positive PCo2 values. Halobatrachus didactylus callsand P. notatus growls overlapped with the calls of O. beta andO. phobetron, while Porichthys hums were tightly clustered nearthe center of the plot. When maximum amplitude position wasregressed against PCo1, the result was a strong and highly significantrelationship between these variables (R²=0.60, d.f.=165, F=231.13, P<0.0001),suggesting that the position of maximum amplitude within thecall (Fig. 7) was influencing PCo1.

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Fig. 8. Results from a principal coordinates analysis (PCo2 versus PCo1) of spectrographic cross-correlation (SPCC–PCo) (Cortopassi and Bradbury, 2000

) of 166 vocalizations from six species of toadfishes. Sounds analyzed included harmonic hoots from the boatwhistle vocalizations of B. trispinosus (filled blue squares), H. didactylus (filled red circles), O. beta (open green circles), O. phobetron (open purple squares), O. tau (open blue triangles) and the hum of P. notatus (filled orange triangles). Due to their temporal similarity to toadfish boatwhistles, `growls' of P. notatus (filled yellow diamonds) were also analyzed.

Swimbladder morphology
The swimbladder of B. trispinosus, unlike that of any other toadfishstudied so far, was found to be laterally divided into two asymmetrical,physically separate swimbladders (Fig. 9). Within the peritoneal cavity,the swimbladder extended anteriorly to the pelvic girdle and posteriorlyto the caudal third of the cavity. The intrinsic swimbladder musclesspanned the entire lateral wall of each swimbladder and werewhitish in coloration in unfixed material. The vocal nerve insertedon the dorsomedial edge of each bladder muscle. Each swimbladderhad its own rete mirabele, located on the posterior dorsal endof bladder, rather than a single rete as in other batrachoidids[described by Greene (Greene, 1924)]. Each swimbladder alsohad its own latitudinal septum; a pore in the center of the septum[described by Fänge and Wittenberg, and by Tower (Fängeand Wittenberg, 1958; Tower, 1908)] was visible in four outof seven specimens examined.

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Fig. 9. (A) Ventral view of a cleared and stained B. trispinosus specimen (6.6 cm standard length) showing the bilateral swimbladder. The skin and viscera of the abdominal cavity were removed and the swimbladder was left in place. Specimen was cleared and stained for cartilage (with Alcian Blue) and bone (with Alizarin Red) following the protocol of Song and Parenti (Song and Parenti, 1995

). Scale bar represents 1 cm. The right pelvic and pectoral fins are labeled for reference orientation. (B) Ventral view of dissected swimbladders from a 9.9 cm standard length female, showing asymmetry between left and right bladders. Arrows indicate points of attachment, where the bladders are connected to each other by connective tissue. Scale bar represents 1 cm.

A single muscle was attached to the lateral wall of each swimbladder.When viewed in cross-section, the lateral wall was concave insmaller fish (7.1 cm standard length; Fig. 10A), becoming moreconvex in larger body size fish (15.1 cm standard length; Fig. 10B).Muscle fibers were arranged vertically, perpendicular to thelong axis of each bladder (Fig. 10A,B). The bladder muscle wasthicker in the smaller fish (standard length of 7.1 cm), whileit was larger in the dorsoventral axis in larger fish (standardlength of 15.1 cm; Fig. 10A,B). A thin membrane, appearing tobe part of the external swimbladder wall, covered the swimbladdermuscle (Fig. 10C).

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Fig. 10. Cross-section (70 µm thick sections) of swimbladder wall and intrinsic swimbladder muscle of B. trispinosus, stained with Methylene Blue from 7.1 cm standard length male (A) and 15.1 cm standard length male (B). The medial side of the swimbladder is to the left. Scale bar represents 1 mm for A and B. (C) High magnification view of junction of swimbladder wall and muscle from the area represented by the box in A. Medial side of the swimbladder is to the left. Scale bar represents 1 mm.

The left and right swimbladders were obviously asymmetricalin terms of length (Fig. 9), with the anterior poles of thetwo adjacent; however, one side was not consistently longer.Of the specimens measured (N=25), the left swimbladder was longerthan the right in 15 fish (nine males and six females), theright was longer in nine (seven males and two females), andonly one (a female) had equal-sized swimbladders. Differencesin the width of the left and right bladders did not necessarilycorrespond to differences in length. Of the 15 with the longerleft bladder, seven also had a wider left bladder; of the nine withthe longer right bladder, six also had a wider right bladder.

Swimbladder length and width increased with standard length (Fig. 11;see Table 1 for statistics) and were sexually dimorphic (Fig. 11;see Table 2 for results from statistical tests); however, whilemales had wider swimbladders, females had longer ones. The degreeof asymmetry of either length or width (i.e. the differencefor each measurement between the two bladders) showed no strongrelationship with body size (R²=0.04).

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Fig. 11. Ontogenetic changes in swimbladder morphology of B. trispinosus males and females. (A) Length of left swimbladder versus standard length; (B) length of right swimbladder versus standard length; (C) left swimbladder width versus standard length; (D) right swimbladder width versus standard length. Solid lines represent regression lines of males (black) and females (gray). For all parameters measured, males were significantly different from females (ANCOVA, P<0.0001); females had longer swimbladders and wider swimbladder muscles than males, while males had wider swimbladders than females.

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Table 1. Results of linear regressions from morphological measurements of the left and right Batrachomoeus trispinosus swimbladders

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Table 2. Tests for sexual dimorphism of swimbladder and muscle morphology of Batrachomoeus trispinosus

There was no consistent difference in the proportional musclemass (i.e. corrected for body mass) between the left and rightbladders (two-tailed paired t-test: d.f.=5, t=–0.00000025, P=0.99);there was also no significant sex difference in this parameterfor either the left or right bladder (Table 2). We attemptedto get accurate volumetric measurements for each swimbladder,but were unable to successfully separate the vocal muscle fromeach bladder and keep the entire bladder intact.

Evolutionary relationships of the toadfishes
The maximum likelihood analysis resulted in a topology witha negative log likelihood score of 17838.52 (Fig. 12). Likelihoodbootstrapping analysis showed high support (>75) in 9 of11 nodes. Halobatrachus was the most basal out of the toadfishesincluded in the analysis, followed by Batrachomoeus trispinosus+Allenbatrachusgrunniens. Opsanus spp. and Porichthys spp. were sister cladesand the most derived, and a monophyletic Thalassophryninae (Daector+Thalassophryne) (Collette,1966) was their sister group.

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Fig. 12. Phylogenetic relationships of toadfishes generated from a maximum likelihood analysis of genes from available sequences (16S; 28S; cytochrome oxidase subunit I, COI; cytochrome b, CytB) in GenBank. Branch lengths are drawn proportional to the amount of character change. Bootstrap values are shown next to nodes. The gadid, Gadus morhua, was used as an outgroup for the Batrachoididae. Boxes around species names indicate taxa used in the comparative sound analysis, and a representative waveform of the species' call and swimbladder is shown for each taxon analyzed.

	DISCUSSION

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

Like other toadfishes, B. trispinosus produces an array of differentvocalizations. However, in contrast to other studied membersof the family, B. trispinosus has evolved a novel swimbladdermorphology – laterally divided into two separate bladders– and is capable of producing sounds with beats: bothunique features among vocal fish. As discussed below, theseunique morphological and behavioral adaptations of B. trispinosusmay represent one of the most highly derived vocal systems infishes, convergent with tetrapod taxa in their ability to produce acousticbeats.

Swimbladder development and functional morphology
Despite the morphological diversity of actinopterygian swimbladders,the completely divided swimbladder of B. trispinosus is uniqueamong those species so far studied. Species of Opsanus and Porichthyshave a single, heart-shaped swimbladder (Bass and Baker, 1991; Fängeand Wittenberg, 1958; Tower, 1908). The swimbladder of Batrachomoeusmost closely resembles that of H. didactylus (dos Santos etal., 2000) and descriptions of that of Allenbatrachus grunniens(=Opsanus grunniens) (Rauther, 1945), in which the two halvesof the swimbladder are connected by a short hollow tube in theposterior third of the bladders, and perpendicular to theirlong axis. The available phylogenetic evidence suggests thatthe swimbladder of Batrachomoeus represents a divergent conditionfrom that of the semi-connected swimbladders of Halobatrachusand Allenbatrachus (Fig. 12).

Interestingly, the highly derived swimbladder of B. trispinosus appearsto be relatively basal for the batrachoidids. A combinationof more complete taxon sampling in creating a phylogeny of theBatrachoididae as well as determining the, as yet, unclear sistertaxon to the family (Greenfield et al., 2008; Miya et al., 2005; Pattersonand Rosen, 1989; Regan, 1912; Smith and Wheeler, 2006) will helpclarify patterns and processes in toadfish swimbladder evolution.The systematic relationships of toadfish inferred from our molecularphylogeny are largely congruent with the visual consensus treefrom a recent, more thorough morphological phylogenetic studyof the Batrachoididae (Greenfield et al., 2008). The largestdiscrepancy between our phylogeny and those from Greenfieldet al. (Greenfield et al., 2008) is that the clade of Batrachomoeus+Allenbatrachusis basal to Halobatrachus. However, even with the phylogenetictopology of Greenfield and colleagues (Greenfield et al., 2008),the swimbladder condition of B. trispinosus is uniquely derived(autapomorphic) within the family, given the retained closerelationship between B. trispinosus and A. grunniens (with anundivided swimbladder).

The Batrachomoeus swimbladder phenotype raises intriguing questionsabout mechanisms of its development: whether it originates asa single structure and laterally divides during ontogeny orinitially develops as two separate bladders. During the developmentof Opsanus and Porichthys, the swimbladder originates as a singleoutpocketing of the esophagus, remaining attached by a ductto the esophagus through a physostomous phase, after which theduct atrophies and the swimbladder becomes completely separateor physoclistous (Lindholm and Bass, 1993; Tracy, 1911). The swimbladdersof O. tau and P. notatus possess a longitudinal septum on theanterior portion of the bladder (Bass and Baker, 1991; Tracy,1911). It is possible that the extended growth of the septumultimately divides the swimbladder into two lateralized structures,different progressions of which give rise to either a partiallyor a completely separated swimbladder across species. The diversityof swimbladder morphologies in this family may be a fruitfularea for investigation of the evolution and consequences ofvariation in bilateral patterning during development, inclusiveof genetic control.

The collagenous membrane covering the swimbladder muscle (Fig. 10C)appears to be another unique feature of B. trispinosus comparedwith O. beta, O. tau and P. notatus. While the exact role ofthis membrane is unclear, it may serve to increase intramuscularpressure during vocal motor activity, which may in turn increasetensile forces along the swimbladder wall (sensu Wainwrightet al., 1978; Westneat et al., 1998), resulting in higher resonantfrequencies.

Sexually dimorphic bladders have been reported in H. didactylus,O. tau, O. beta and P. notatus (Brantley and Bass, 1994; Brantleyet al., 1993; Fine, 1975; Fine et al., 1990; Modesto and Canário, 2003;Walsh et al., 1987; Walsh et al., 1989). The sexual dimorphismin the swimbladders of B. trispinosus is complex; males hadwider swimbladders, while females had longer ones. The potentialfunctional significance of differences in either of these dimensionsremains unclear. More detailed biomechanical studies of each swimbladder(e.g. Fine et al., 2001) will be required to better understandthe role of dimorphisms in sound production.

Vocal repertoire
Vocalizations produced by B. trispinosus resemble the major acousticallyand behaviorally defined classes of vocalizations describedin other batrachoidids, namely agonistic grunts that are briefin duration, and comparatively longer duration, multiharmonicadvertisement boatwhistles and hums (e.g. Brantley and Bass, 1994;dos Santos et al., 2000; Gray and Winn, 1961; Ibara et al., 1983;Tavolga, 1958; Thorson and Fine, 2002b). Because of the similaritiesof the acoustical properties of B. trispinosus calls to thoseof other toadfishes, we suggest that the different classes ofcalls have a homologous social context: the long duration, multiharmonichoot serves as an advertisement or courtship call, while theshort duration grunts and grunt trains function in aggressionand territorial defense. A number of dissected females fromthe tanks were found to have ripe eggs in the ovaries (N=4),which is suggestive of courtship activity and reproductive behavior,as observed in other toadfishes (e.g. Brantley and Bass, 1994; Grayand Winn, 1961). The presence of reproductively mature femaleswithin the population further supports the hypothesis that thehoots serve a role in courtship behavior.

With the exception of P. notatus hums, B. trispinosus hootsare substantially longer than those in other toadfishes: individual B.trispinosus hoots last up to 6 s (compared with <1 s for Halobatrachus,Opsanus and Sanopus) (Amorim and Vasconcelos, 2008; Amorim etal., 2008; Mann et al., 2002); the hoot-like hums of P. notatuslast upwards of an hour (Bass et al., 1999; Brantley and Bass,1994; Ibara et al., 1983). The rich harmonic structure of B.trispinosus grunt trains also appears to be distinct from thatof most other toadfish (see above references). Like other toadfishes,B. trispinosus showed increased levels of calling at night (e.g.Brantley and Bass, 1994; Breder, 1968; Ibara et al., 1983; Thorsonand Fine, 2002b). However, it appears that other toadfish speciesdo not display the same degree of lunar synchrony in callingpatterns as B. trispinosus (Breder, 1968).

To our knowledge, the beats in the individual vocalizationsof B. trispinosus are the first to be reported in fishes [thoughgroups of chorusing P. notatus can collectively produce beats (McKibbenand Bass, 2001)]. This demonstrates that fishes have also independentlyevolved harmonically complex acoustical signals similar to thoseof other tetrapods, such as birds (Nowicki and Capranica, 1986) andfrogs (Suthers et al., 2006). We propose that the ability ofB. trispinosus to produce beats is dependent upon their bilaterallydivided swimbladder, reminiscent of the two halves of the aviansyrinx (Suthers, 1990; Suthers, 2001). Given the variabilityof the properties (i.e. dominant frequency, beat duration) of soundswith beats, it seems likely that the physiological generationof beats is under active control by the central vocal motorsystem (see Bass and McKibben, 2003). Alternatively, beats maybe generated passively due to the asymmetry of the swimbladder,similar to the asymmetric (type III) avian syrinx, as in oilbirds andpenguins (Aubin et al., 2000; Bradbury and Vehrencamp, 1998;Suthers and Hector, 1985). However, passive anatomical generationof beats seems unlikely, as the majority of B. trispinosus specimensexamined had some degree of asymmetry between the left and rightbladders, but the majority of sounds did not exhibit beats.

The spectral properties of the acoustic beats observed hereare reminiscent of the spectra for the two-voice/biphonationcalls in mockingbirds (Zollinger et al., 2008). In Batrachomoeuscalls, the difference in frequency between the two major highfrequency peaks, rather than between each of the three peaks, approximatesthe call's modulation rate; hence our interpretation of the signalsas beats rather than as amplitude-modulated signals. Interestingly, thereis also a significant amount of energy near 200 Hz, close tothe fundamental frequency of non-beat grunts. Whether thesenon-linear phenomena (see Fitch et al., 2002; Zollinger et al.,2008) arise from the activity of one or both swimbladders remainsto be investigated.

The high frequency dominant portion of grunts with beats (2000–2500 Hz)raises the question of whether B. trispinosus can, in fact, detectthis component of the signal. The available studies show thatthis dominant frequency is probably outside of the auditorysensitivity of other studied batrachoidids, namely H. didactylus,O. tau and P. notatus (e.g. Fay and Edds-Walton, 1997; Fishand Offutt, 1972; Sisneros et al., 2004; Vasconcelos and Ladich, 2008).However, increased hearing sensitivity to higher frequencies(>1000 Hz) has independently and repeatedly evolved in fishes (Braunand Grande, 2008). The detection of these sounds is often facilitatedby mechanical transduction mechanisms between the ear and anatomicalstructures with a different density from water; one of the mostcommon auditory specializations for sensitivity to higher soundfrequencies in fishes involves modifications of the swimbladder (e.g.Braun and Grande, 2008; Popper et al., 2003). From the dissectionsof B. trispinosus, the anterior end of the swimbladder is angleddorsally, pointing towards the neurocranium, and terminates1.25 mm behind the sacculus (measured in one specimen). Theswimbladder of B. trispinosus is much more rostral, elongateand closer to the ear than that of O. tau, in which the swimbladderhas been suggested to play no role in audition (Yan et al., 2000).Thus, given the unique morphology and position of the swimbladderin B. trispinosus for signal production, it may also be involvedin signal reception.

Underwater playback studies in midshipman investigated the discrimination oftwo-tone beats with modulation rates up to 10 Hz and showedthat both beat frequency and the depth of modulation contributeto acoustic recognition (McKibben and Bass, 1998; McKibben andBass, 2001). Comparable experiments with the distantly relatedgoldfish (Carassius auratus) show similar discrimination fortwo-tone beat stimuli, in this case with beat frequencies rangingup to 200 Hz (Fay, 1998), close to the modulation rate of theBatrachomoeus calls observed here. Single neuron recording studiesof the auditory system of batrachoidids also show the temporalencoding of two-tone beat stimuli. For midshipman, sensitivityto stimuli with 1–10 Hz beat frequencies overlaps thatof the naturally occurring beats generated by the concurrenthumming of neighboring males during the breeding season (Bodnarand Bass, 1997). The auditory system of the toadfish O. beta alsoencodes beats, but mainly for beat frequencies >10 Hz (Basset al., 2001). Future behavioral and sensory experiments willbe needed to investigate the recognition and behavioral significanceof acoustic beats.

The coral reef, nearshore and estuarine environments inhabitedby B. trispinosus (Greenfield, 1999) are complex acoustic environments (Bassand Clark, 2003). In shallow (10–100 m) and very shallow(<5 m) water systems (see Bass and Clark, 2003), lower frequencycomponents of an acoustic signal have a higher level of attenuation, whilethe higher frequency components propagate many times farther (Bassand Clark, 2003; Fine and Lenhardt, 1983; Mann and Lobel, 1997).Fine and Lenhardt demonstrated that the frequencies around thefundamental frequency of the boatwhistle of O. tau (around 200Hz) had an attenuation of –29.5 dB over 7 m, while upperharmonics around 800 Hz only had an attenuation of –13dB over the same distance (Fine and Lenhardt, 1983). Thus, forB. trispinosus, the high-frequency harmonic components of manyof the hoots, grunts and particularly the grunts with beatsmay be an adaptation to increase the propagation distance ofthe call in shallow water habitats. However, playback studies(sensu Fish, 1972; McKibben and Bass, 2001; Remage-Healey andBass, 2005) are needed to confirm any behavioral significanceof the higher frequency components of B. trispinosus calls,and whether increased propagation distance is biologically meaningful,advantageous or simply an artifact of swimbladder mechanicsduring sound production.

Diversity of toadfish vocalizations
The quantitative comparison of toadfish vocalizations offersan interesting insight into the diversity and perhaps the evolutionof toadfish acoustic communication. Taxonomically, the between-genusdiversity of toadfish sounds is primarily distributed alongPCo1, whereas within-genus diversity (Opsanus) is along PCo2.The PCo analysis also showed that the two most closely relatedspecies, O. phobetron and O. tau (Fig. 12) have the most similarsounds (Fig. 8). Unfortunately, while SPCC allows for the objectivediscrimination of sounds based on complex spectrographic andtemporal components, its principal shortcoming is that comparisonsbetween spectrograms result in a univariate similarity scoreand the PCo analysis is then conducted on the similarity matrix(Clark et al., 1987; Cortopassi and Bradbury, 2000). As such,it is impossible to determine which specific components of thesound (e.g. fundamental frequency, call duration, etc.) are specificallyinfluencing their distribution in the PCo analysis. However,the correlation between amplitude modulation pattern and PCo1suggests that amplitude envelope shape may be influencing thestatistical discrimination of the different sounds (Fig. 7B). Thehoots of O. beta and O. tau and the growls of P. notatus havedecreasing amplitude throughout the call; P. notatus hums, O.phobetron and H. didactylus have little amplitude modulationin their calls, whereas most B. trispinosus calls continuallyincrease in amplitude throughout the duration of the call (Fig. 7B). Interestingly,the hoots of the closely related B. trispinosus and H. didactylusshared the latest position of maximum amplitude in their callsamong the species studied. The behavioral importance of amplitude modulationis also shown by playback studies in midshipman fish (Bodnarand Bass, 2001; McKibben and Bass, 1998; McKibben and Bass,2001).

The diversity of intraspecific vocalizations in toadfishes parallelsthe diversification of acoustic signals in other fish families(e.g. Amorim et al., 2004; Gerald, 1971; Lobel, 2001; Malavasiet al., 2008; Rice and Lobel, 2003). While acoustic call diversityand evolution are frequently discussed in tetrapods (e.g. Priceand Lanyon, 2002; Ryan, 1986), similar evolutionary questionshave not been extensively tested in fishes (but see Malavasiet al., 2008). Due to the relative simplicity of many centraland peripheral vocal mechanisms (compared with tetrapods), fishtypically lack the ability to produce complex and dynamic, frequency-modulatedcalls (Bass, 1997; Bass and McKibben, 2003; Demski et al., 1973; Riceand Lobel, 2003). Consequently, it is often variation in eithertemporal patterning or frequency that is primarily responsiblefor vocal differences among fish populations and species (Kihslingerand Klimley, 2002; Malavasi et al., 2008; Mann and Lobel, 1998;Parmentier et al., 2005). Again, underwater playbacks in midshipmanfish show that individual fish can discriminate sounds basedon fine temporal structure, i.e. fundamental frequency (McKibbenand Bass, 1998; McKibben and Bass, 2001). The diversity of amplitude,frequency and beat-modulated vocalizations of Batrachomoeusmay present the most complex pattern of call structure so farshown for any toadfish species or, for that matter, any fish.How such variation shapes social communication at both behavioral andneural levels of organization remains to be explored.

Footnotes

Supplementary material available online at http://jeb.biologists.org/cgi/content/full/212/9/1377/DC1

We are grateful to Clara Amorim for providing Halobatrachusdidactylus sounds, Margaret Marchaterre for providing P. notatussounds, Luke Remage-Healey for providing O. beta sounds, JessicaMcKibben for providing O. tau sounds and Sunna Jo for helpingwith data collection and sound analysis. Lydia Smith providedhelpful advice with phylogenetic analyses. Additionally, wethank Adam Arterbery, Jack Bradbury, Boris Chagnaud, Bruce Land,Margaret Marchaterre, Janelle Morano, Kevin Rohmann and TineRubow for technical expertise, helpful suggestions and comments;and Bruce Collette, David Greenfield and Richard Winterbottomfor sharing results from their phylogenetic analyses and providingan early version of their publication. A.N.R. was supportedby NIMH training grant 5-T32-MH15793. Additional support wasprovided by NSF IOB-0516748 to A.H.B.

References

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Akamatsu, T., Okumura, T., Novarini, N. and Yan, H. Y. (2002). Empirical refinements applicable to the recording of fish sounds in small tanks. J. Acoust. Soc. Am. 112,3073 -3082.[CrossRef][Medline]

Amorim, M. C. P. (2006). Diversity of sound production in fish. In Communication in Fishes, vol.1 (ed. F. Ladich, S. P. Collin, P. Moller and B. G. Kapoor), pp. 71-105. Enfield, NH: Science Publishers.

Amorim, M. C. P. and Vasconcelos, R. O. (2008). Variability in the mating calls of the Lusitanian toadfish Halobatrachus didactylus: cues for potential individual recognition. J. Fish Biol. 73,1 -17.[CrossRef]

Amorim, M. C. P., Knight, M. E., Stratoudakis, Y. and Turner, G. F. (2004). Differences in sounds made by courting males of three closely related Lake Malawi cichlid species. J. Fish Biol. 65,1358 -1371.[CrossRef]

Amorim, M. C. P., Simões, J. M. and Fonseca, P. J. (2008). Acoustic communication in the Lusitanian toadfish, Halobatrachus didactylus: evidence for an unusual large vocal repertoire. J. Mar. Biol. Assoc. UK 88,1069 -1073.

Armougom, F., Moretti, S., Poirot, O., Audic, S., Dumas, P., Schaeli, B., Keduas, V. and Notredame, C. (2006). Expresso: automatic incorporation of structural information in multiple sequence alignments using 3D-Coffee. Nucleic Acids Res. 34,W604 -W608.[Abstract/Free Full Text]

Aubin, T., Jouventin, P. and Hildebrand, C. (2000). Penguins use the two-voice system to recognize each other. Proc. R. Soc. B 267,1081 -1087.[Abstract/Free Full Text]

Bass, A. H. (1997). Comparative neurobiology of vocal behaviour in teleost fishes. Mar. Freshw. Behav. Physiol. 29,47 -63.[CrossRef]

Bass, A. H. and Baker, R. (1991). Evolution of homologous vocal control traits. Brain Behav. Evol. 38,240 -254.[Medline]

Bass, A. and Clark, C. (2003). The physical acoustics of underwater sound communication. In Acoustic Communication (ed. A. M. Simmons, R. R. Fay and A. N. Popper), pp. 15-64. New York: Springer.

Bass, A. H. and Marchaterre, M. A. (1989). Sound-generating (sonic) motor system in a teleost fish (Porichthys notatus): sexual polymorphism in the ultrastructure of myofibrils. J. Comp. Neurol. 286,141 -153.[CrossRef][Medline]

Bass, A. H. and McKibben, J. R. (2003). Neural mechanisms and behaviors for acoustic communication in teleost fish. Prog. Neurobiol. 69,1 -26.[CrossRef][Medline]

Bass, A. H., Bodnar, D. and Marchaterre, M. A. (1999). Complementary explanations for existing phenotypes in an acoustic communication system. In The Design of Animal Communication (ed. M. D. Hauser and M. Konishi), pp.493 -514. Cambridge, MA: MIT Press.

Bass, A. H., Bodnar, D. A. and Marchaterre, M. A. (2001). Acoustic nuclei in the medulla and midbrain of the vocalizing gulf toadfish (Opsanus beta). Brain Behav. Evol. 57,63 -79.[CrossRef][Medline]

Bodnar, D. A. and Bass, A. H. (1997). Temporal coding of concurrent acoustic signals in auditory midbrain. J. Neurosci. 17,7553 -7564.[Abstract/Free Full Text]

Bodnar, D. A. and Bass, A. H. (2001). Coding of concurrent vocal signals by the auditory midbrain: effects of stimulus level and depth of modulation. J. Acoust. Soc. Am. 109,809 -825.[CrossRef][Medline]

Bradbury, J. W. and Vehrencamp, S. L. (1998). Principles of Animal Communication. Sunderland, MA: Sinauer Associates.

Brantley, R. K. and Bass, A. H. (1994). Alternative male spawning tactics and acoustic signals in the plainfin midshipman fish Porichthys notatus Girard (Teleostei, Batrachoididae). Ethology 96,213 -232.

Brantley, R. K., Tseng, J. and Bass, A. H. (1993). The ontogeny of intersexual and intrasexual vocal muscle dimorphisms in a sound-producing fish. Brain Behav. Evol. 42,336 -349.[Medline]

Braun, C. B. and Grande, T. (2008). Evolution of peripheral mechanisms for the enhancement of sound reception. In Fish Bioacoustics (ed. J. F. Webb, R. R. Fay and A. N. Popper), pp. 99-144. New York: Springer.

Breder, C. M., Jr (1968). Seasonal and diurnal occurrences of fish sounds in a small Florida Bay. Bull. Am. Mus. Nat. Hist. 138,325 -378.

Buck, J. R. and Tyack, P. L. (1993). A quantitative measure of similarity for Tursiops truncatus signature whistles. J. Acoust. Soc. Am. 94,2497 -2506.[CrossRef][Medline]

Casgrain, P. and Legendre, P. (2004). The R Package for Multivariate and Spatial Analysis, v. 4.0 d6. Montreal: University of Montreal. http://www.bio.umontreal.ca/casgrain/en/.

Clark, C. W., Marler, P. and Beeman, K. (1987). Quantitative analysis of animal vocal phonology: an application to swamp sparrow song. Ethology 76,101 -115.

Collette, B. B. (1966). A review of the venomous toadfishes, subfamily Thalassophryninae. Copeia 1966,846 -864.[CrossRef]

Cortopassi, K. A. and Bradbury, J. W. (2000). The comparison of harmonically rich sounds using spectrographic cross-correlation and principal coordinates analysis. Bioacoustics 11,89 -127.

Demski, L. S., Gerald, J. W. and Popper, A. N. (1973). Central and peripheral mechanisms of teleost sound production. Am. Zool. 13,1141 -1167.

dos Santos, M. E., Modesto, T., Matos, R. J., Grober, M. S., Oliviera, R. F. and Canário, A. (2000). Sound production by the Lusitanian toadfish, Halobatrachus didactylus. Bioacoustics 10,309 -321.

Fänge, R. and Wittenberg, J. B. (1958). The swimbladder of the toadfish (Opsanus tau L.). Biol. Bull. 115,172 -179.[Abstract/Free Full Text]

Fawcett, D. W. and Revel, J. P. (1961). The sarcoplasmic reticulum of a fast-acting fish muscle. J. Biophys. Biochem. Cytol. 10,89 -109.[Medline]

Fay, R. R. (1998). Perception of two-tone complexes by the goldfish (Carassius auratus). Hear. Res. 120,17 -24.[CrossRef][Medline]

Fay, R. R. and Edds-Walton, P. L. (1997). Diversity in frequency response properties of saccular afferents of the toadfish, Opsanus tau. Hear. Res. 113,235 -246.[CrossRef][Medline]

Fine, M. L. (1975). Sexual dimorphism of the growth rate of the swimbladder of the toadfish Opsanus tau.Copeia 1975,483 -490.[CrossRef]

Fine, M. L. and Lenhardt, M. L. (1983). Shallow-water propagation of the toadfish mating call. Comp. Biochem. Physiol. A 76,225 -231.

Fine, M. L., Winn, H. E. and Olla, B. L. (1977). Communication in fishes. In How Animals Communicate (ed. T. A. Sebeok), pp.472 -518. Bloomington: Indiana University Press.

Fine, M. L., Burns, N. M. and Harris, T. M. (1990). Ontogeny and sexual dimorphism of sonic muscle in the oyster toadfish. Can. J. Zool. 68,1374 -1381.[CrossRef]

Fine, M. L., Malloy, K. L., King, C. B., Mitchell, S. L. and Cameron, T. M. (2001). Movement and sound generation by the toadfish swimbladder. J. Comp. Physiol. A 187,371 -379.[CrossRef][Medline]

Fine, M. L., Malloy, K. L., King, C. B., Mitchell, S. L. and Cameron, T. M. (2002). Sound generation by the toadfish swimbladder. Bioacoustics 12,221 -222.

Fish, J. F. (1972). The effect on sound playback on the toadfish. In Behavior of Marine Animals, Vol. 2: Vertebrates (ed. H. E. Winn and B. L. Olla), pp.386 -434. New York: Plenum Press.

Fish, J. F. and Offutt, G. C. (1972). Hearing thresholds from toadfish, Opsanus tau, measured in the laboratory and field. J. Acoust. Soc. Am. 51,1318 -1321.[CrossRef][Medline]

Fitch, W. T., Neubauer, J. and Herzel, H. (2002). Calls out of chaos: the adaptive significance of nonlinear phenomena in mammalian vocal production. Anim. Behav. 63,407 -418.[CrossRef]

Gerald, J. W. (1971). Sound production during courtship in six species of sunfish (Centrarchidae). Evolution 25,75 -87.[CrossRef]

Graham, R. (1992). Sounds fishy. Aust. Geogr. Mag. 14,76 -83.

Grant, E. M. (1987). Fishes of Australia. Scarborough, Queensland: E. M. Grant.

Gray, G. A. and Winn, H. E. (1961). Reproductive ecology and sound production of the toadfish, Opsanus tau.Ecology 42,274 -282.[CrossRef]

Greene, C. W. (1924). Physiological reactions and structure of the vocal apparatus of the California singing fish, Porichthys notatus. Am. J. Physiol. 70,496 -499.[Free Full Text]

Greenfield, D. W. (1999). Toadfishes. In FAO Species Identification Guide for Fisheries Purposes: The Living Marine Resources of the Western Central Atlantic, Vol 3. Batoid Fishes, Chimaeras and Bony Fishes, Part 1 (Elopidae to Linophrynidae) (ed. K. E. Carpenter and V. H. Niem), pp. 1999-2003. Rome, GA: Food and Agricultural Organization of the United Nations.

Greenfield, D. W., Winterbottom, R. and Collette, B. B. (2008). Review of the toadfish genera (Teleostei: Batrachoididae). Proc. Cal. Acad. Sci. 59,665 -710.

Hajisamae, S., Yeesin, P. and Chaimongkol, S. (2006). Habitat utilization by fishes in a shallow, semi-enclosed estuarine bay in southern Gulf of Thailand. Estuar. Coast. Shelf Sci. 68,647 -655.[CrossRef]

Hubbs, C. L. (1920). The bionomics of Porichthys notatus Girard. Am. Nat. 54,380 -384.[CrossRef]

Hutchins, J. B. (1976). A revision of the Australian frogfishes (Batrachoididae). Rec. West. Aust. Mus. 4,3 -43.

Ibara, R. M., Penny, L. T., Ebeling, A. W., van Dykhuizen, G. and Cailliet, G. (1983). The mating call of the plainfin midshipman fish, Porichthys notatus. In Predators and Prey in Fishes (ed. D. L. G. Noakes, D. G. Lindquist, G. S. Helfman and J. A. Ward), pp. 205-212. The Hague: Dr W. Junk Publishers.

Kihslinger, R. L. and Klimley, A. P. (2002). Species identity and the temporal characteristics of fish acoustic signals. J. Comp. Psychol. 116,210 -214.[CrossRef][Medline]

Kjer, K. M. (1995). Use of rRNA secondary structure in phylogenetic studies to identify homologous positions: an example of alignment and data presentation from the frogs. Mol. Phylogenet. Evol. 4,314 -330.[CrossRef][Medline]

Ladich, F. and Fine, M. L. (2006). Sound-generating mechanisms in fishes: a unique diversity in vertebrates. In Communication in Fishes, vol. 1 (ed. F. Ladich, S. P. Collin, P. Moller and B. G. Kapoor), pp.3 -43. Enfield, NH: Science Publishers.

Lindholm, M. M. and Bass, A. H. (1993). Early events in myofibrillogenesis and innervation of skeletal, sound-generating muscle in a teleost fish. J. Morphol. 216,225 -239.[CrossRef][Medline]

Lobel, P. S. (2001). Acoustic behavior of cichlid fishes. J. Aquaricult. Aquat. Sci. 9, 89-108.

Malavasi, S., Collatuzzo, S. and Torricelli, P. (2008). Interspecific variation of acoustic signals in Mediterranean gobies (Perciformes, Gobiidae): comparative analysis and evolutionary outlook. Biol. J. Linn. Soc. 93,763 -778.[CrossRef]

Mann, D. A. and Lobel, P. S. (1997). Propagation of damselfish (Pomacentridae) courtship sounds. J. Acoust. Soc. Am. 101,3783 -3791.[CrossRef]

Mann, D. A. and Lobel, P. S. (1998). Acoustic behavior of the damselfish Dascyllus albisella: behavioral and geographic variation. Environ. Biol. Fish. 51,421 -428.[CrossRef]

Mann, D. A., Ma, W. L. D. and Lobel, P. S. (2002). Sound production by the toadfish Sanopus astrifer. J. Acoust. Soc. Am. 112,2202 -2203.

McKibben, J. R. and Bass, A. H. (1998). Behavioral assessment of acoustic parameters relevant to signal recognition and preference in a vocal fish. J. Acoust. Soc. Am. 104,3520 -3533.[CrossRef][Medline]

McKibben, J. R. and Bass, A. H. (2001). Effects of temporal envelope modulation on acoustic signal recognition in a vocal fish, the plainfin midshipman. J. Acoust. Soc. Am. 109,2934 -2943.[CrossRef][Medline]

Medwin, H. (1975). Speed of sound in water: a simple equation for realistic parameters. J. Acoust. Soc. Am. 58,1318 -1319.[CrossRef]

Mitani, J. C. and Marler, P. (1989). A phonological analysis of male gibbon singing behavior. Behaviour 109,20 -45.[CrossRef]

Miya, M., Satoh, T. P. and Nishida, M. (2005). The phylogenetic position of toadfishes (order Batrachoidiformes) in the higher ray-finned fish as inferred from partitioned Bayesian analysis of 102 whole mitochondrial genome sequences. Biol. J. Linn. Soc. 85,289 -306.[CrossRef]

Modesto, T. and Canário, A. V. M. (2003). Hormonal control of swimbladder sonic muscle dimorphism in the Lusitanian toadfish Halobatrachus didactylus. J. Exp. Biol. 206,3467 -3477.[Abstract/Free Full Text]

Moretti, S., Armougom, F., Wallace, I. M., Higgins, D. G., Jongeneel, C. V. and Notredame, C. (2007). The M-Coffee web server: a meta-method for computing multiple sequence alignments by combining alternative alignment methods. Nucleic Acids Res. 35,W645 -W648.[Abstract/Free Full Text]

Nelson, J. S. (2006). Fishes of the World, 4th edn. Hoboken, NJ: John Wiley.

Norman, A. (1976). Halophryne trispinosus (Günther). Trop. Fish Hobby. 24, 83-84.

Nowicki, S. and Capranica, R. R. (1986). Bilateral syringeal interaction in vocal production of an oscine bird sound. Science 231,1297 -1299.[Abstract/Free Full Text]

Nowicki, S. and Nelson, D. A. (1990). Defining natural categories in acoustic signals: comparison of three methods applied to `chick-a-dee' call notes. Ethology 86, 89-101.

Okumura, T., Akamatsu, T. and Yan, H. Y. (2002). Analyses of small tank acoustics: empirical and theoretical approaches. Bioacoustics 12,330 -332.

Parmentier, E., Lagardere, J. P., Vandewalle, P. and Fine, M. L. (2005). Geographical variation in sound production in the anemonefish Amphiprion akallopisos. Proc. R. Soc. B 272,1697 -1703.[Abstract/Free Full Text]

Parvulescu, A. (1967). The acoustics of small tanks. In Marine Bio-Acoustics (ed. W. N. Tavolga), pp. 7-14. Oxford: Pergamon Press.

Patterson, C. and Rosen, D. E. (1989). The Paracanthopterygii revisited: order and disorder. Nat. Hist. Mus. Los Angeles Count. Sci. Ser. 32,5 -36.

Popper, A. N., Fay, R. R., Platt, C. and Sand, O. (2003). Sound detection mechanisms and capabilities of teleost fishes. In Sensory Processing in Aquatic Environments (ed. S. P. Collin and N. J. Marshall), pp. 3-38. New York: Springer-Verlag.

Posada, D. and Crandall, K. (1998). MODELTEST: testing the model of DNA substitution. Bioinformatics 14,817 -818.[Abstract/Free Full Text]

Price, J. J. and Lanyon, S. M. (2002). Reconstructing the evolution of complex bird song in the oropendolas. Evolution 56,1514 -1529.[CrossRef][Medline]

Rauther, M. (1945). Über die Schwimmblase und die zu ihr in Beziehung tretenden somatischen Muskeln bei den Triglidae und anderen Scleroparei. Zool. Jarhb. 69,159 -250.

Regan, C. T. (1912). The classification of the Teleostean fishes of the order Pediculati. Ann. Mag. Nat. Hist. 51,277 -289.

Remage-Healey, L. and Bass, A. H. (2005). Rapid elevations in both steroid hormones and vocal signaling during playback challenge: a field experiment in Gulf toadfish. Horm. Behav. 47,297 -305.[CrossRef][Medline]

Rendell, L. E. and Whitehead, H. (2003). Comparing repertoires of sperm whale codas: a multiple methods approach. Bioacoustics 14,61 -81.

Rice, A. N. and Lobel, P. S. (2003). The pharyngeal jaw apparatus of the Cichlidae and Pomacentridae (Teleostei: Labroidei): function in feeding and sound production. Rev. Fish Biol. Fish. 13,433 -444.[CrossRef]

Rome, L. C. (2006). Design and function of superfast muscles: new insights into the physiology of skeletal muscle. Annu. Rev. Physiol. 68,193 -221.[CrossRef][Medline]

Rome, L. C., Syme, D. A., Hollingworth, S., Lindstedt, S. L. and Baylor, S. M. (1996). The whistle and the rattle: the design of sound producing muscles. Proc. Natl. Acad. Sci. USA 93,8095 -8100.[Abstract/Free Full Text]

Ryan, M. J. (1986). Factors influencing the evolution of acoustic communication: biological constraints. Brain Behav. Evol. 28,70 -82.[CrossRef][Medline]

Sisneros, J. A., Forlano, P. M., Knapp, R. and Bass, A. H. (2004). Seasonal variation of steroid hormone levels in an intertidal-nesting fish, the vocal plainfin midshipman. Gen. Comp. Endocrinol. 136,101 -116.[CrossRef][Medline]

Skoglund, C. R. (1961). Functional analysis of swim-bladder muscles engaged in sound production of the toadfish. J. Biophys. Biochem. Cytol. 10,187 -200.

Smith, W. L. and Wheeler, W. C. (2006). Venom evolution widespread in fishes: a phylogenetic road map for the bioprospecting of piscine venoms. J. Hered. 97,206 -217.[Abstract/Free Full Text]

Song, J. and Parenti, L. R. (1995). Clearing and staining whole fish specimens for simultaneous demonstration of bone, cartilage, and nerves. Copeia 1995,114 -118.[CrossRef]

Suthers, R. A. (1990). Contributions to birdsong from the left and right sides of the intact syrinx. Nature 347,473 -477.[CrossRef]

Suthers, R. A. (2001). Peripheral vocal mechanisms in birds: are songbirds special? Neth. J. Zool. 51,217 -242.[CrossRef]

Suthers, R. A. and Hector, D. H. (1985). The physiology of vocalization by the echolocating oilbird, Steatornis caripensis. J. Comp. Physiol. A 156,243 -266.[CrossRef]

Suthers, R. A., Narins, P. M., Lin, W. Y., Schnitzler, H. U., Denzinger, A., Xu, C. H. and Feng, A. S. (2006). Voices of the dead: complex nonlinear vocal signals from the larynx of an ultrasonic frog. J. Exp. Biol. 209,4984 -4993.[Abstract/Free Full Text]

Swofford, D. L. (1998). PAUP^*: Phylogenetic Analysis Using Parsimony (^*and Other Methods). Version 4.10b. Sunderland, MA: Sinauer Associates.

Tavolga, W. N. (1958). Underwater sounds produced by two species of toadfish, Opsanus tau and Opsanus beta. Bull. Mar. Sci. Gulf Carib. 8, 278-284.

Tavolga, W. N. (1960). Sound production and underwater communication in fishes. In Animal Sounds and Communication (ed. W. E. Lanyon and W. N. Tavolga), pp.93 -136. Washington, DC: American Institute of Biological Sciences.

Tavolga, W. N. (1965). Review of marine bio-acoustics. NATRADEVCEN Report No. 1212-1,1 -100.

Thorson, R. F. and Fine, M. L. (2002a). Acoustic competition in the gulf toadfish Opsanus beta: acoustic tagging. J. Acoust. Soc. Am. 111,2302 -2307.[CrossRef][Medline]

Thorson, R. F. and Fine, M. L. (2002b). Crepuscular changes in emission rate and parameters of the boatwhistle advertisement call of the gulf toadfish, Opsanus beta. Environ. Biol. Fish. 63,321 -331.[CrossRef]

Tonks, M. L., Griffiths, S. P., Heales, D. S., Brewer, D. T. and Dell, Q. (2008). Species composition and temporal variation of prawn trawl bycatch in the Joseph Bonaparte Gulf, northwestern Australia. Fish. Res. 89,276 -293.[CrossRef]

Tower, R. W. (1908). The production of sound in the drumfishes, the sea-robin and the toadfish. Ann. NY Acad. Sci. 28,149 -180.

Tracy, H. C. (1911). The morphology of the swim-bladder in teleosts. Anat. Anz. 38, 600-606, 638-649.

Vasconcelos, R. O. and Ladich, F. (2008). Development of vocalization, auditory sensitivity and acoustic communication in the Lusitanian toadfish Halobatrachus didactylus. J. Exp. Biol. 211,502 -509.[Abstract/Free Full Text]

Wainwright, S. A., Vosburgh, F. and Hebrank, J. H. (1978). Shark skin: function in locomotion. Science 202,747 -749.[Abstract/Free Full Text]

Walsh, P. J., Bedolla, C. and Mommsen, T. P. (1987). Reexamination of metabolic potential in the toadfish sonic muscle. J. Exp. Zool. 241,133 -136.[CrossRef][Medline]

Walsh, P. J., Bedolla, C. and Mommsen, T. P. (1989). Scaling and sex-related differences in toadfish (Opsanus beta) sonic muscle enzymatic activities. Bull. Mar. Sci. 45,68 -75.

Westneat, M. W. and Alfaro, M. E. (2005). Phylogenetic relationships and evolutionary history of the reef fish family Labridae. Mol. Phylogenet. Evol. 36,370 -390.[CrossRef][Medline]

Westneat, M. W., Hale, M. E., McHenry, M. J. and Long, J. H. (1998). Mechanics of the fast-start: muscle function and the role of intramuscular pressure in the escape behavior of Amia calva and Polypterus palmas. J. Exp. Biol. 201,3041 -3055.[Abstract]

Winn, H. E. (1964). The biological significance of fish sounds. In Marine Bio-acoustics (ed. W. N. Tavolga), pp. 213-231. New York: Pergamon Press.

Yan, H. Y., Fine, M. L., Horn, N. S. and Colón, W. E. (2000). Variability in the role of the gasbladder in fish audition. J. Comp. Physiol. A 186,435 -445.[CrossRef][Medline]

Young, B. A., Nejman, N., Meltzer, K. and Marvin, J. (1999). The mechanics of sound production in the puff adder Bitis arietans (Serpentes: Viperidae) and the information content of the snake hiss. J. Exp. Biol. 202,2281 -2289.[Abstract]

Zollinger, S. A., Riede, T. and Suthers, R. A. (2008). Two-voice complexity from a single side of the syrinx in northern mockingbird Mimus polyglottos vocalizations. J. Exp. Biol. 211,1978 -1991.[Abstract/Free Full Text]

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