Neuroethology of the Katydid T-cell. I. Tuning and Responses to Pure Tones
Overview
Affiliations
The tuning and pure-tone physiology of the T-cell prothoracic auditory interneuron were investigated in the nocturnal katydid Neoconocephalus ensiger. The T-cell is extremely sensitive and broadly tuned, particularly to high-frequency ultrasound (>20 kHz). Adult thresholds were lowest and showed their least variability for frequencies ranging from 25 to 80 kHz. The average best threshold of the T-cell in N. ensiger ranged from 28 to 38 dB SPL and the best frequency from 20 to 27 kHz. In females, the T-cell is slightly more sensitive to the range of frequencies encompassing the spectrum of male song. Tuning of the T-cell in non-volant nymphs was comparable with that of adults, and this precocious ultrasound sensitivity supports the view that it has a role in the detection of terrestrial sources of predaceous ultrasound. In adults, T-cell tuning is narrower than that of the whole auditory (tympanic) organ, but only at audio frequencies. Superthreshold physiological experiments revealed that T-cell responses were ultrasound-biased, with intensity/response functions steeper and spike latencies shorter at 20, 30 and 40 kHz than at 5, 10 and 15 kHz. The same was also true for T-cell stimulation at 90 degrees compared with stimulation at 0 degrees within a frequency, which supports early T-cell research showing that excitation of the contralateral ear inhibits ipsilateral T-cell responses. In a temporal summation experiment, the integration time of the T-cell at 40 kHz (integration time constant tau =6.1 ms) was less than half that measured at 15 kHz ( tau =15.0 ms). Moreover, T-cell spiking in response to short-duration pure-tone trains mimicking calling conspecifics (15 kHz) and bat echolocation hunting sequences (40 kHz) revealed that temporal pattern-copying was superior for ultrasonic stimulation. Apparently, T-cell responses are reduced or inhibited by stimulation with audio frequencies, which leads to the prediction that the T-cell will encode conspecific song less well than bat-like frequency-modulated sweeps during acoustic playback. The fact that the T-cell is one of the most sensitive ultrasound neurons in tympanate insects is most consistent with it serving an alarm, warning or escape function in both volant and non-volant katydids (nymphs and adults).
Symes L, Martinson S, Kernan C, Ter Hofstede H Proc Biol Sci. 2020; 287(1933):20201212.
PMID: 32842929 PMC: 7482258. DOI: 10.1098/rspb.2020.1212.
Temporal processing properties of auditory DUM neurons in a bush-cricket.
Stumpner A, Lefebvre P, Seifert M, Ostrowski T J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2019; 205(5):717-733.
PMID: 31327050 DOI: 10.1007/s00359-019-01359-9.
Frederick K, Schul J PLoS Curr. 2016; 8.
PMID: 27110432 PMC: 4824388. DOI: 10.1371/currents.tol.0c5d76728d73ef9c3dbe8065f70ea4cb.
Dynamic dendritic compartmentalization underlies stimulus-specific adaptation in an insect neuron.
Presern J, Triblehorn J, Schul J J Neurophysiol. 2015; 113(10):3787-97.
PMID: 25878158 PMC: 4473517. DOI: 10.1152/jn.00945.2014.
Temporal integration at consecutive processing stages in the auditory pathway of the grasshopper.
Wirtssohn S, Ronacher B J Neurophysiol. 2015; 113(7):2280-8.
PMID: 25609104 PMC: 4416565. DOI: 10.1152/jn.00390.2014.