Elias T. Lunsford scite author profile

Accurate sensory processing during movement requires the animal to distinguish between external (exafferent) and self-generated (reafferent) stimuli to maintain sensitivity to biologically relevant cues. The lateral line system in fishes is a mechanosensory organ that experiences reafferent sensory feedback, via detection of fluid motion relative to the body generated during behaviors such as swimming. For the first time in larval zebrafish ( Danio rerio), we employed simultaneous recordings of lateral line and motor activity to reveal the activity of afferent neurons arising from endogenous feedback from hindbrain efferent neurons during locomotion. Frequency of spontaneous spiking in posterior lateral line afferent neurons decreased during motor activity and was absent for more than half of swimming trials. Targeted photoablation of efferent neurons abolished the afferent inhibition that was correlated to swimming, indicating that inhibitory efferent neurons are necessary for modulating lateral line sensitivity during locomotion. We monitored calcium activity with Tg(elav13:GCaMP6s) fish and found synchronous activity between putative cholinergic efferent neurons and motor neurons. We examined correlates of motor activity to determine which may best predict the attenuation of afferent activity and therefore what components of the motor signal are translated through the corollary discharge. Swim duration was most strongly correlated to the change in afferent spike frequency. Attenuated spike frequency persisted past the end of the fictive swim bout, suggesting that corollary discharge also affects the glide phase of burst and glide locomotion. The duration of the glide in which spike frequency was attenuated increased with swim duration but decreased with motor frequency. Our results detail a neuromodulatory mechanism in larval zebrafish that adaptively filters self-generated flow stimuli during both the active and passive phases of locomotion. NEW & NOTEWORTHY For the first time in vivo, we quantify the endogenous effect of efferent activity on afferent gain control in a vertebrate hair cell system during and after locomotion. We believe that this pervasive effect has been underestimated when afferent activity of octavolateralis systems is characterized in the current literature. We further identify a refractory period out of phase with efferent control and place this gain mechanism in the context of gliding behavior of freely moving animals.

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Evolutionary convergence of a neural mechanism in the cavefish lateral line system

Lunsford

Paz

Keene

et al. 2022

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Animals can evolve dramatic sensory functions in response to environmental constraints, but little is known about the neural mechanisms underlying these changes. The Mexican tetra, Astyanax mexicanus, is a leading model to study genetic, behavioral, and physiological evolution by comparing eyed surface populations and blind cave populations. We compared neurophysiological responses of posterior lateral line afferent neurons and motor neurons across A. mexicanus populations to reveal how shifts in sensory function may shape behavioral diversity. These studies indicate differences in intrinsic afferent signaling and gain control across populations. Elevated endogenous afferent activity identified a lower response threshold in the lateral line of blind cavefish relative to surface fish leading to increased evoked potentials during hair cell deflection in cavefish.. We next measured the effect of inhibitory corollary discharges from hindbrain efferent neurons onto afferents during locomotion. We discovered that three independently-derived cavefish populations have evolved persistent afferent activity during locomotion, suggesting for the first time that partial loss of function in the efferent system can be an evolutionary mechanism for neural adaptation of a vertebrate sensory system.

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Efferent Modulation of Spontaneous Lateral Line Activity During and after Zebrafish Motor Commands

Lunsford

Skandalis

Liao

2019

Preprint

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1Accurate sensory processing during movement requires the animal to distinguish between 2 2 3 1 that inhibitory efferent neurons are necessary for modulating lateral line sensitivity during 3 2 locomotion. We monitored calcium activity with Tg(elav13:GCaMP6s) fish and found 3 3 synchronous activity between putative cholinergic efferent neurons and motor neurons. We 3 4 examined correlates of motor activity to determine which may best predict the attenuation of 3 5 afferent activity and therefore what components of the motor signal are translated through the 3 6 corollary discharge. Swim duration was most strongly correlated to the change in afferent spike 3 7 frequency. Attenuated spike frequency persisted past the end of the fictive swim bout, suggesting 3 8 that corollary discharge also affects the glide phase of burst and glide locomotion. The duration 3 9of the glide in which spike frequency was attenuated increased with swim duration but decreased 4 0 with motor frequency. Our results detail a neuromodulatory mechanism in larval zebrafish that 4 1 adaptively filters self-generated flow stimuli during both the active and passive phases of 4 2 locomotion. 4 3 4 4

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Saxitoxin and the Ochre Sea Star: Molecule of Keystone Significance and a Classic Keystone Species

Ferrer

Lunsford

Candido

et al. 2015

Integr. Comp. Biol.

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Saxitoxins (STXs) are paralytic alkaloids produced by marine dinoflagellates in response to biotic and abiotic stressors yielding harmful algal blooms. Because STX impacts coastal, near-shore communities to a greater extent than would be predicted by its relative abundance, it has been referred to as a "molecule of keystone significance" in reference to Robert Paine's Keystone Species Concept. Pisaster ochraceus, the predator upon which Paine's concept was founded, inhabits waters regularly plagued by harmful algal blooms, but the effects of STX on Pisaster have not yet been investigated. Here, we used laboratory and field experiments to examine the potential consequences of exposure to STX on sea stars' feeding, attachment to the substrate, and success in fertilization. Pisaster exhibited similar feeding behaviors when offered non-toxic prey, STX-containing prey, or a combination of the two. Although feeding behavior is unaffected, consumption of STX poses a physiological tradeoff. Sea stars in the laboratory and field had significantly lower thresholds of the force needed to detach them from their substrates after either being exposed to, or consuming, STX. High pressure (or high performance) liquid chromatography analysis indicated an accumulation of STX (and structural analogues) in sea stars' viscera, likely due to trophic transfer from toxic prey. Incidence of fertilization tended to decrease when gametes were exposed to high, yet ecologically relevant, STX concentrations of STX. These findings suggest that the molecule of keystone significance, STX, produced during harmful algal blooms extends its impacts to rocky intertidal communities by way of the keystone predator P. ochraceus.

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Elias T. Lunsford

Efferent modulation of spontaneous lateral line activity during and after zebrafish motor commands

Evolutionary convergence of a neural mechanism in the cavefish lateral line system

Efferent Modulation of Spontaneous Lateral Line Activity During and after Zebrafish Motor Commands

Saxitoxin and the Ochre Sea Star: Molecule of Keystone Significance and a Classic Keystone Species

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