Enhanced sensory sampling precedes self-initiated locomotion in an electric fish

Jun, James J.; Longtin, André; Maler, Leonard

doi:10.1242/jeb.105502

Cited by 36 publications

(37 citation statements)

References 72 publications

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“…This suggests that, even in a “resting state,” there is ongoing neural activity in the brain of these fish that can modulate sensory processing. A similar conclusion was reached for motor activity and EOD discharge in related gymnotiform fish (Jun et al, 2014). …”

Section: Discussionsupporting

confidence: 80%

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Subsecond Sensory Modulation of Serotonin Levels in a Primary Sensory Area and Its Relation to Ongoing Communication Behavior in a Weakly Electric Fish

Fotowat

Harvey‐Girard

Cheer

et al. 2016

eNeuro

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Serotonergic neurons of the raphe nuclei of vertebrates project to most regions of the brain and are known to significantly affect sensory processing. The subsecond dynamics of sensory modulation of serotonin levels and its relation to behavior, however, remain unknown. We used fast-scan cyclic voltammetry to measure serotonin release in the electrosensory system of weakly electric fish, Apteronotus leptorhynchus. These fish use an electric organ to generate a quasi-sinusoidal electric field for communicating with conspecifics. In response to conspecific signals, they frequently produce signal modulations called chirps. We measured changes in serotonin concentration in the hindbrain electrosensory lobe (ELL) with a resolution of 0.1 s concurrently with chirping behavior evoked by mimics of conspecific electric signals. We show that serotonin release can occur phase locked to stimulus onset as well as spontaneously in the ELL region responsible for processing these signals. Intense auditory stimuli, on the other hand, do not modulate serotonin levels in this region, suggesting modality specificity. We found no significant correlation between serotonin release and chirp production on a trial-by-trial basis. However, on average, in the trials where the fish chirped, there was a reduction in serotonin release in response to stimuli mimicking similar-sized same-sex conspecifics. We hypothesize that the serotonergic system is part of an intricate sensory–motor loop: serotonin release in a sensory area is triggered by sensory input, giving rise to motor output, which can in turn affect serotonin release at the timescale of the ongoing sensory experience and in a context-dependent manner.

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Section: Discussionsupporting

confidence: 80%

“…6), even though gymnotiform fish are known to be very sensitive to sound (Harvey-Girard et al, 2010; Jun et al, 2014). It is therefore possible that distinct populations of DRN neurons innervate different sensory regions of the brain in a modality-specific manner.…”

Section: Discussionmentioning

confidence: 99%

Subsecond Sensory Modulation of Serotonin Levels in a Primary Sensory Area and Its Relation to Ongoing Communication Behavior in a Weakly Electric Fish

Fotowat

Harvey‐Girard

Cheer

et al. 2016

eNeuro

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“…The resulting changes in the transcutaneous electric field are transduced by cutaneous electroreceptors and encoded as train of spikes in primary electroreceptive afferents (Bullock et al, 1961;Fessard and Szabo, 1961;Lissmann, 1958;Szabo and Fessard, 1974;Wright, 1958). This information is further processed in the brain stem (Aumentado-Armstrong et al, 2015;Bell and Maler, 2005;Heiligenberg and Rose, 1985;Kawasaki, 2005) and telencephalon (Harvey Girard et al, 2010;Trinh et al, 2016), giving origin to reflex Post and von der Emde, 1999), stereotyped (Heiligenberg, 1991;Kawasaki, 2005;Moller, 1995) and learned behaviors (Jun et al, 2014;Schumacher et al, 2016;Walton and Moller, 2010).…”

Section: Introductionmentioning

confidence: 99%

Waveform sensitivity of electroreceptors in the pulse weakly electric fish Gymnotus omarorum

Rodríguez-Cattáneo

Aguilera

Caputi

2017

Journal of Experimental Biology

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As in most sensory systems, electrosensory images in weakly electric fish are encoded in two parallel pathways, fast and slow. From work on wave-type electric fish, these fast and slow pathways are thought to encode the time and amplitude of electrosensory signals, respectively. The present study focuses on the primary afferents giving origin to the slow path of the pulse-type weakly electric fish Gymnotus omarorum. We found that burst duration coders respond with a high-frequency train of spikes to each electric organ discharge. They also show high sensitivity to phase-frequency distortions of the self-generated local electric field. We explored this sensitivity by manipulating the longitudinal impedance of a probe cylinder to modulate the stimulus waveform, while extracellularly recording isolated primary afferents. Resistive loads only affect the amplitude of the re-afferent signals without distorting the waveform. Capacitive loads cause large waveform distortions aside from amplitude changes. Stepping from a resistive to a capacitive load in such a way that the stimulus waveform was distorted, without changing its total energy, caused strong changes in latency, inter-spike interval and number of spikes of primary afferent responses. These burst parameters are well correlated suggesting that they may contribute synergistically in driving downstream neurons. This correlation also suggests that each receptor encodes a single parameter in the stimulus waveform. The finding of waveform distortion sensitivity is relevant because it may contribute to: (a) enhance electroreceptive range in the peripheral 'electrosensory field', (b) a better identification of living prey at the 'foveal electrosensory field' and (c) detect the presence and orientation of conspecifics. Our results also suggest a revision of the classical view of amplitude and time encoding by fast and slow pathways in pulse-type electric fish.

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“…The nocturnal increase of EOD-BR is a common feature among South American weakly electric fish and coincides with a state of nocturnal arousal. In contrast to shortterm novelty responses to sudden changes in prevailing lighting [Capurro, 1994;Post and von der Emde, 1999], a nocturnal increase in EOD-BR is consistent with higher levels of attention, motivation and perceptual efficacy during the active nocturnal phase [Silva et al, 2007;Jun et al, 2014]. There are no previous reports of daily changes in EOD-BR in the wild; however, in laboratory settings, a nocturnal increase in EOD-BR that persists in conditions of constant illumination has been reported in Brachyhypopomus [Stoddard et al, 2007].…”

Section: Discussionmentioning

confidence: 76%

Melatonin Regulates Daily Variations in Electric Behavior Arousal in Two Species of Weakly Electric Fish with Different Social Structures

Migliaro

Silva²

2016

Brain Behav Evol

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Timing is crucial for social interactions. Animal behavior is synchronized with biotic and abiotic environment variables ensuring that the activity phase of conspecifics occurs during the same period of the day. As biological rhythms are embedded in the complex integrative control of the brain, it is fundamental to explore its interaction with environmental and social factors. This approach will unravel the link between external stimuli carrying information on environmental cycles and the neural commands for behavior, including social behavior, associated with precise phases of those cycles. Arousal in the solitary Gymnotus omarorum and in the gregarious Brachyhypopomus gauderio is characterized by a nocturnal increase in the basal discharge rate of electric behavior, which is mild and transient in G. omarorum and large and persistent in B. gauderio. In this study, we show that the major integrator of social behavior, AVT (arginine vasotocin), is not involved in the nocturnal increase of electric behavior basal rate in isolated animals of either species. On the other hand, endogenous melatonin, the major modulator of the circadian system, is responsible for the nocturnal increase in electric behavior in isolated individuals of both species.

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Enhanced sensory sampling precedes self-initiated locomotion in an electric fish

Cited by 36 publications

References 72 publications

Subsecond Sensory Modulation of Serotonin Levels in a Primary Sensory Area and Its Relation to Ongoing Communication Behavior in a Weakly Electric Fish

Subsecond Sensory Modulation of Serotonin Levels in a Primary Sensory Area and Its Relation to Ongoing Communication Behavior in a Weakly Electric Fish

Waveform sensitivity of electroreceptors in the pulse weakly electric fish Gymnotus omarorum

Melatonin Regulates Daily Variations in Electric Behavior Arousal in Two Species of Weakly Electric Fish with Different Social Structures

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