Tethered unitary recordings suggest a spike-timing electrosensory code in the electrosensory lobe of Gymnotus omarorum

Rodríguez-Cattaneo, A. - Pereira, A.C. - Aguilera, P.A. - Caputi, A.A.

Resumen:

Evaluation of neural activity during natural behaviours is essential for understanding how the brain works. Here we show that neuron-specific self-evoked firing patterns are modulated by an object’s presence, at the electrosensory lobe neurons of tethered-moving Gymnotus omarorum. This novel preparation shows that electrosensory signals in these pulse-type weakly electric fish are not only encoded in the number of spikes per electric organ discharge (EOD), as is the case in wave-type electric fish, but also in the spike timing pattern after each EOD, as found in pulse-type Mormyroidea. Present data suggest that pulsant electrogen esis and spike timing coding of electrosensory signals developed concomitantly in the same species, and evolved convergently in African and American electric fish


Detalles Bibliográficos
2020
Agencia Nacional de Investigación e Innovación
Chronic recordings
Neural code
Electroreception
Pulse emitting weackly electric fish
Electrosensory lobe
Ciencias Médicas y de la Salud
Medicina Básica
Neurociencias
Inglés
Instituto de Investigaciones Biológicas Clemente Estable
IIBCE en REDI
https://hdl.handle.net/20.500.12381/3529
Acceso abierto
Reconocimiento 4.0 Internacional. (CC BY)
Resumen:
Sumario:Evaluation of neural activity during natural behaviours is essential for understanding how the brain works. Here we show that neuron-specific self-evoked firing patterns are modulated by an object’s presence, at the electrosensory lobe neurons of tethered-moving Gymnotus omarorum. This novel preparation shows that electrosensory signals in these pulse-type weakly electric fish are not only encoded in the number of spikes per electric organ discharge (EOD), as is the case in wave-type electric fish, but also in the spike timing pattern after each EOD, as found in pulse-type Mormyroidea. Present data suggest that pulsant electrogen esis and spike timing coding of electrosensory signals developed concomitantly in the same species, and evolved convergently in African and American electric fish