Morphological determinants of signal carrier frequency in katydids (Orthoptera): a comparative analysis using biophysical evidence of wing vibration

Montealegre‐Z, Fernando; Ogden, Jessica; Jonsson, Thorin; Soulsbury, Carl D.

doi:10.1111/jeb.13179

Cited by 24 publications

(34 citation statements)

References 47 publications

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“…This has been observed in the Aerotegmina katydids (e.g., Heller and Hemp 2018). Carrier frequency is mainly dictated by the resonator anatomy (mirror and harp but see; Montealegre-Z and Postles 2010; Montealegre-Z 2012; Montealegre-Z et al 2017).…”

Section: Songs Of Asiophlugismentioning

confidence: 78%

“…The songs of Phlugidini are similar in that they are entirely ultrasonic, supporting the fact that Meconematinae species usually employ ultrasonic calls (Helfert and Sänger 1998;Montealegre-Z et al 2006Montealegre-Z et al , 2017Chamorro-Rengifo et al 2014;Chamorro-Rengifo and Braun 2016;Sarria-S et al 2017). A. rete (A. thai junior synonym) sings at frequencies between 30 and 50 kHz (Helfert and Sänger 1998) and neotropical species such as Phlugis ocraceovittata Piza, 1960 also sings at frequencies between 40 and 60 kHz (Chamorro-Rengifo and Braun 2016).…”

Section: Songs Of Asiophlugismentioning

confidence: 86%

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Ultrasonic songs and stridulum anatomy of Asiophlugis crystal predatory katydids (Tettigonioidea: Meconematinae: Phlugidini)

et al. 2019

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The behavioural ecology of ultrasonic-singing katydids is not well understood, and the general bioacoustics, barely known for a few Neotropical Meconematinae, tends to be overlooked for species from Southeast Asia. These include Asiatic species of Phlugidini, commonly known as crystal predatory katydids. One of its genera, Asiophlugis consists of 16 species for which acoustic signals and stridulum anatomy are broadly unknown. These characters can be used to understand species boundaries. Here, we sampled Asiophlugis from five sites in Malay Peninsula and Borneo Island, recorded the acoustic signals of five species plus one subspecies using ultrasound sensitive equipment, and examined their stridulum anatomy. The calling songs of the taxa involved were documented for the first time. We found that the stridulum anatomy (e.g., tooth distributions, tooth length and tooth density) is distinct between species but less so between subspecies. In contrary, songs of different taxa are different based on acoustic parameters (e.g., pulse duration, peak frequency) and descriptive patterns, even between the subspecies. We also did not observe that song signals are more different in sympatry than in allopatry. Whether this can be generalised requires further sampling, highlighting the need for more research on the ultrasonic acoustic communication in Asiatic katydids. ARTICLE HISTORY

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Section: Songs Of Asiophlugismentioning

confidence: 78%

Section: Songs Of Asiophlugismentioning

confidence: 86%

Ultrasonic songs and stridulum anatomy of Asiophlugis crystal predatory katydids (Tettigonioidea: Meconematinae: Phlugidini)

et al. 2019

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“…4 provides examples. Our main analysis focused on the harp area of the wing as it is a key determinant of the carrier frequency of male song in ensiferan insects (22). Table 2 reports the peak resonance of the harp (or vestigial harp) for each measured individual.…”

Section: Resultsmentioning

confidence: 99%

“…Research examining acoustic signal function and diversity in ensiferan singing insects (crickets and katydids) has mostly focused on the behavioral components of song (i.e., the pattern of sound pulses produced during wing movement) (19,20). However, a major source of variation in acoustic signals is their carrier frequency, which is increasingly recognized as an important signal feature distinguishing closely related species (21,22). Frequency is primarily determined by the morphology of soundresonating structures (23,24), and can be varied by mechanically shifting between different resonant modes in some species (25)(26)(27).…”

Section: Significancementioning

confidence: 99%

Testing the role of trait reversal in evolutionary diversification using song loss in wild crickets

Bailey

Pascoal

Montealegre‐Z

2019

Proc. Natl. Acad. Sci. U.S.A.

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The mechanisms underlying rapid macroevolution are controversial. One largely untested hypothesis that could inform this debate is that evolutionary reversals might release variation in vestigial traits, which then facilitates subsequent diversification. We evaluated this idea by testing key predictions about vestigial traits arising from sexual trait reversal in wild field crickets. In Hawaiian Teleogryllus oceanicus, the recent genetic loss of sound-producing and -amplifying structures on male wings eliminates their acoustic signals. Silence protects these “flatwing” males from an acoustically orienting parasitoid and appears to have evolved independently more than once. Here, we report that flatwing males show enhanced variation in vestigial resonator morphology under varied genetic backgrounds. Using laser Doppler vibrometry, we found that these vestigial sound-producing wing features resonate at highly variable acoustic frequencies well outside the normal range for this species. These results satisfy two important criteria for a mechanism driving rapid evolutionary diversification: Sexual signal loss was accompanied by a release of vestigial morphological variants, and these could facilitate the rapid evolution of novel signal values. Widespread secondary trait losses have been inferred from fossil and phylogenetic evidence across numerous taxa, and our results suggest that such reversals could play a role in shaping historical patterns of diversification.

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“…The mirror is an important structure for sound radiation and is considered as typical for bushcrickets (e.g. Montealegre-Z et al 2017). However, its systematic distribution and size have never been studied in detail.…”

Section: Discussionmentioning

confidence: 99%

Paraplangia sinespeculo, a new genus and species of bush-cricket, with notes on its biology and a key to the genera of Phaneropterinae (Orthoptera: Tettigonioidea) from Madagascar

Heller

Hemp

Massa

et al. 2018

JOR

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Madagascar is a well-known hotspot of biodiversity. However, many Orthoptera, and especially the Tettigonioidea, belong to little-studied groups. Here we describe a new genus and species of bush-cricket reared from field-collected eggs.Paraplangiasinespeculogen. nov., sp. nov. belongs to Phaneropterinae and shares diagnostic characteristics with members of the tribe Amblycoryphini and its African subtribe Plangiina stat. nov.Paraplangia, which has a chromosome number of 31 X0, differs from other African members of the tribe and subtribe such asEurycoryphaandPlangia, which both have 29 X0. In addition to morphology, we describe the male calling song, female acoustic response, and mating behavior. As calling song, the male produces two series of short syllables. At the end of the second series the female responds with signals of similar duration and spectral composition as the male sounds (peak about 8-9 kHz). To make future identification easier, a key to all genera of Phaneropterinae found in Madagascar is presented.

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Morphological determinants of signal carrier frequency in katydids (Orthoptera): a comparative analysis using biophysical evidence of wing vibration

Cited by 24 publications

References 47 publications

Ultrasonic songs and stridulum anatomy of Asiophlugis crystal predatory katydids (Tettigonioidea: Meconematinae: Phlugidini)

Ultrasonic songs and stridulum anatomy of Asiophlugis crystal predatory katydids (Tettigonioidea: Meconematinae: Phlugidini)

Testing the role of trait reversal in evolutionary diversification using song loss in wild crickets

Paraplangia sinespeculo, a new genus and species of bush-cricket, with notes on its biology and a key to the genera of Phaneropterinae (Orthoptera: Tettigonioidea) from Madagascar

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