Low pass filters and differential tympanal tuning in a paleotropical bushcricket with an unusually low frequency call

Rajaraman, Kaveri; Mhatre, Natasha; Jain, Manjari; Postles, Mathew; Balakrishnan, Rohini; Robert, Daniel

doi:10.1242/jeb.078352

Cited by 13 publications

(12 citation statements)

References 60 publications

(97 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…But even for male calls there may be opposing pressures for providing good cues for directionality (typically higher frequencies) and for being optimally transmitted through the biotope (typically lower frequencies; Schul and Patterson 2003). Recently, a very unusual case has been described for a pseudophylline bushcricket (Rajamaran et al 2013): one of the two tympana (all bushcrickets have two tympana in each foreleg) is tuned to the lowfrequency call of the male, the other tympanum is tuned to higher frequencies, which might be contained in sounds of predators. The same is true for the directional response of the two tympana.…”

Section: Balancing and Opposing Selective Forces On Existing Ears Andmentioning

confidence: 99%

Selective forces on origin, adaptation and reduction of tympanal ears in insects

Strauß

Stumpner

2014

J Comp Physiol A

View full text Add to dashboard Cite

Insect ears evolved many times independently. As a consequence, a striking diversity exists in the location, construction and behavioural implementation of ears. In this review, we first summarise what is known about the evolutionary origin of ears and the presumed precursor organs in the various insect groups. Thereafter, we focus on selective forces for making and keeping an ear: we discuss detecting and localising predators and conspecifics, including establishing new "private" channels for intraspecific communication. More advanced aspects involve judging the distance of conspecifics, or assessing individual quality from songs which makes auditory processing a means for exerting sexual selection on mating partners. We try to identify negative selective forces, mainly in the context of energy expenditure for developing and keeping an ear, but also in conjunction with acoustic communication, which incorporates risks like eavesdropping by predators and parasitoids. We then discuss balancing pressures, which might oppose optimising an ear for a specific task (when it serves different functions, for example). Subsequently, we describe various scenarios that might have led to a reduction or complete loss of ears in evolution. Finally, we describe cases of sex differences in ears and potential reasons for their appearance.

show abstract

Section: Balancing and Opposing Selective Forces On Existing Ears Andmentioning

confidence: 99%

Selective forces on origin, adaptation and reduction of tympanal ears in insects

Strauß

Stumpner

2014

J Comp Physiol A

View full text Add to dashboard Cite

show abstract

“…However, for the subfamily Pseudophyllinae (a large group with some 1000 species described) the acoustic spiracle is reduced (a character used as diagnostic for this subfamily) and the bulla is replaced by a small chamber [18][19][20]. In other species, the AT forms a large U-shaped bend at the bulla site [6]. Although poorly understood, in Pseudophyllinae, the AT is unlikely to be the main acoustic input, and some authors suggest that the tympanal slits might play an important role as waveguides [18,20].…”

Section: Introductionmentioning

confidence: 99%

Auditory mechanics in a bush-cricket: direct evidence of dual sound inputs in the pressure difference receiver

Jonsson

Montealegre‐Z²,

Soulsbury³

et al. 2016

J. R. Soc. Interface.

Self Cite

View full text Add to dashboard Cite

The ear of the bush-cricket, Copiphora gorgonensis, consists of a system of paired eardrums (tympana) on each foreleg. In these insects, the ear is backed by an air-filled tube, the acoustic trachea (AT), which transfers sound from the prothoracic acoustic spiracle to the internal side of the eardrums. Both surfaces of the eardrums of this auditory system are exposed to sound, making it a directionally sensitive pressure difference receiver. A key feature of the AT is its capacity to reduce the velocity of sound propagation and alter the acoustic driving forces at the tympanum. The mechanism responsible for reduction in sound velocity in the AT remains elusive, yet it is deemed to depend on adiabatic or isothermal conditions. To investigate the biophysics of such multiple input ears, we used micro-scanning laser Doppler vibrometry and micro-computed X-ray tomography. We measured the velocity of sound propagation in the AT, the transmission gains across auditory frequencies and the time-resolved mechanical dynamics of the tympanal membranes in C. gorgonensis Tracheal sound transmission generates a gain of approximately 15 dB SPL, and a propagation velocity of ca 255 m s, an approximately 25% reduction from free field propagation. Modelling tracheal acoustic behaviour that accounts for thermal and viscous effects, we conclude that reduction in sound velocity within the AT can be explained, among others, by heat exchange between the sound wave and the tracheal walls.

show abstract

“…and the species with the highest known sensillum number (Ancylecha fenestrata) has a cover at the anterior tympanum. Specific evolu-Biomechanical analysis in Onomarchus uninotatus (Pseudophyllinae) showed fascinating adaptations for the two tympanal membranes with differential tympanal tuning (acoustic partitioning) of the anterior tympanum as a low-pass filter and the posterior tympanum as a high-pass filter (Rajaraman et al 2013). The structure and mechanics of the CA and associated elements would be interesting for their organization in this case.…”

Section: Diversity Of Tettigoniid Auditory Organs and Evolutionary Camentioning

confidence: 99%

What determines the number of auditory sensilla in the tympanal hearing organs of Tettigoniidae? Perspectives from comparative neuroanatomy and evolutionary forces

Strauß¹

2019

JOR

View full text Add to dashboard Cite

Insects have evolved complex receptor organs for the major sensory modalities. For the sense of hearing, the tympanal organ of Tettigoniidae (bush crickets or katydids) shows remarkable convergence to vertebrate hearing by impedance conversion and tonotopic frequency analysis. The main auditory receptors are scolopidial sensilla in the crista acustica. Morphological studies established that the numbers of auditory sensilla are species-specific. However, the factors determining the specific number of auditory sensilla are not well understood. This review provides an overview of the functional organization of the auditory organ in Tettigoniidae, including the diversification of the crista acustica sensilla, a list of species with the numbers of auditory sensilla, and a discussion of evolutionary forces affecting the number of sensilla in the crista acustica and their sensitivity. While all species of Tettigoniidae studied so far have a crista acustica, the number of sensilla varies on average from 15–116. While the relative differences or divergence in sensillum numbers may be explained by adaptive or regressive changes, it is more difficult to explain a specific number of sensilla in the crista acustica of a specific species (like for the model species Ancistrura nigrovittata, Copiphora gorgonensis, Gampsocleis gratiosa, Mecopoda elongata, Requena verticalis, or Tettigonia viridissima): sexual and natural selection as well as allometric relationships have been identified as key factors influencing the number of sensilla. Sexual selection affects the number of auditory sensilla in the crista acustica by the communication system and call patterns. Further, positive allometric relationships indicate positive selection for certain traits. Loss of selection leads to evolutionary regression of the auditory system and reduced number of auditory sensilla. This diversity in the auditory sensilla can be best addressed by comparative studies reconstructing adaptive or regressive changes in the crista acustica.

show abstract

Low pass filters and differential tympanal tuning in a paleotropical bushcricket with an unusually low frequency call

Cited by 13 publications

References 60 publications

Selective forces on origin, adaptation and reduction of tympanal ears in insects

Selective forces on origin, adaptation and reduction of tympanal ears in insects

Auditory mechanics in a bush-cricket: direct evidence of dual sound inputs in the pressure difference receiver

What determines the number of auditory sensilla in the tympanal hearing organs of Tettigoniidae? Perspectives from comparative neuroanatomy and evolutionary forces

Contact Info

Product

Resources

About