Your search keyword '"Scott, Ethan"' showing total 9 results

1. Altered brain-wide auditory networks in a zebrafish model of fragile X syndrome

Author

Constantin, Lena, Poulsen, Rebecca E., Scholz, Leandro A., Favre-Bulle, Itia A., Taylor, Michael A., Sun, Biao, Goodhill, Geoffrey J., Vanwalleghem, Gilles C., and Scott, Ethan K.

Published

2020

2. Contributions of Luminance and Motion to Visual Escape and Habituation in Larval Zebrafish.

Author

Mancienne, Tessa, Marquez-Legorreta, Emmanuel, Wilde, Maya, Piber, Marielle, Favre-Bulle, Itia, Vanwalleghem, Gilles, and Scott, Ethan K.

Subjects

ZEBRA danio, BEHAVIORAL assessment, STARTLE reaction, EFFERENT pathways, BRACHYDANIO, VISUAL perception

Abstract

Animals from insects to humans perform visual escape behavior in response to looming stimuli, and these responses habituate if looms are presented repeatedly without consequence. While the basic visual processing and motor pathways involved in this behavior have been described, many of the nuances of predator perception and sensorimotor gating have not. Here, we have performed both behavioral analyses and brain-wide cellular-resolution calcium imaging in larval zebrafish while presenting them with visual loom stimuli or stimuli that selectively deliver either the movement or the dimming properties of full loom stimuli. Behaviorally, we find that, while responses to repeated loom stimuli habituate, no such habituation occurs when repeated movement stimuli (in the absence of luminance changes) are presented. Dim stimuli seldom elicit escape responses, and therefore cannot habituate. Neither repeated movement stimuli nor repeated dimming stimuli habituate the responses to subsequent full loom stimuli, suggesting that full looms are required for habituation. Our calcium imaging reveals that motion-sensitive neurons are abundant in the brain, that dim-sensitive neurons are present but more rare, and that neurons responsive to both stimuli (and to full loom stimuli) are concentrated in the tectum. Neurons selective to full loom stimuli (but not to movement or dimming) were not evident. Finally, we explored whether movement- or dim-sensitive neurons have characteristic response profiles during habituation to full looms. Such functional links between baseline responsiveness and habituation rate could suggest a specific role in the brain-wide habituation network, but no such relationships were found in our data. Overall, our results suggest that, while both movement- and dim-sensitive neurons contribute to predator escape behavior, neither plays a specific role in brain-wide visual habituation networks or in behavioral habituation. [ABSTRACT FROM AUTHOR]

Published

2021

3. Calcium Imaging and the Curse of Negativity.

Author

Vanwalleghem, Gilles, Constantin, Lena, and Scott, Ethan K.

Subjects

CALCIUM, IMAGE analysis, DATA analysis

Abstract

The imaging of neuronal activity using calcium indicators has become a staple of modern neuroscience. However, without ground truths, there is a real risk of missing a significant portion of the real responses. Here, we show that a common assumption, the non-negativity of the neuronal responses as detected by calcium indicators, biases all levels of the frequently used analytical methods for these data. From the extraction of meaningful fluorescence changes to spike inference and the analysis of inferred spikes, each step risks missing real responses because of the assumption of non-negativity. We first show that negative deviations from baseline can exist in calcium imaging of neuronal activity. Then, we use simulated data to test three popular algorithms for image analysis, CaImAn, suite2p, and CellSort, finding that suite2p may be the best suited to large datasets. We also tested the spike inference algorithms included in CaImAn, suite2p, and Cellsort, as well as the dedicated inference algorithms MLspike and CASCADE, and found each to have limitations in dealing with inhibited neurons. Among these spike inference algorithms, FOOPSI, from CaImAn, performed the best on inhibited neurons, but even this algorithm inferred spurious spikes upon the return of the fluorescence signal to baseline. As such, new approaches will be needed before spikes can be sensitively and accurately inferred from calcium data in inhibited neurons. We further suggest avoiding data analysis approaches that, by assuming non-negativity, ignore inhibited responses. Instead, we suggest a first exploratory step, using k-means or PCA for example, to detect whether meaningful negative deviations are present. Taking these steps will ensure that inhibition, as well as excitation, is detected in calcium imaging datasets. [ABSTRACT FROM AUTHOR]

Published

2021

4. Brain-Wide Mapping of Water Flow Perception in Zebrafish.

Author

Vanwalleghem, Gilles, Schuster, Kevin, Taylor, Michael A., Favre-Bulle, Itia A., and Scott, Ethan K.

Subjects

HYDRAULICS, BRACHYDANIO, FLOW velocity, SENSORY perception, INFORMATION networks

Abstract

Information about water flow, detected by lateral line organs, is critical to the behavior and survival of fish and amphibians. While certain aspects of water flow processing have been revealed through electrophysiology, we lack a comprehensive description of the neurons that respond to water flow and the network that they form. Here, we use brain-wide calcium imaging in combination with microfluidic stimulation to map out, at cellular resolution, neuronal responses involved in perceiving and processing water flow information in larval zebrafish. We find a diverse array of neurons responding to head-totail (h-t) flow, tail-to-head (t-h) flow, or both. Early in this pathway, in the lateral line ganglia, neurons respond almost exclusively to the simple presence of h-t or t-h flow, but later processing includes neurons responding specifically to flow onset, representing the accumulated displacement of flow during a stimulus, or encoding the speed of the flow. The neurons reporting on these more nuanced details are located across numerous brain regions, including some not previously implicated in water flow processing. A graph theory-based analysis of the brain-wide water flow network shows that a majority of this processing is dedicated to h-t flow detection, and this is reinforced by our finding that details like flow velocity and the total accumulated flow are only encoded for the h-t direction. The results represent the first brain-wide description of processing for this important modality, and provide a departure point for more detailed studies of the flow of information through this network. [ABSTRACT FROM AUTHOR]

Published

2020

5. Diffuse light‐sheet microscopy for stripe‐free calcium imaging of neural populations.

Author

Taylor, Michael A., Vanwalleghem, Gilles C., Favre‐Bulle, Itia A., and Scott, Ethan K.

Abstract

Light‐sheet microscopy is used extensively in developmental biology and neuroscience. One limitation of this approach is that absorption and scattering produces shadows in the illuminating light sheet, resulting in stripe artifacts. Here, we introduce diffuse light‐sheet microscopes that use a line diffuser to randomize the light propagation within the image plane, allowing the light sheets to reform after obstacles. We incorporate diffuse light sheets in two existing configurations: selective plane illumination microscopy in which the sample is illuminated with a static sheet of light, and digitally scanned light sheet (DSLS) in which a thin Gaussian beam is scanned across the image plane during each acquisition. We compare diffuse light‐sheet microscopes to their conventional counterparts for calcium imaging of neural activity in larval zebrafish. We show that stripe artifacts can cast deep shadows that conceal some neurons, and that the stripes can flicker, producing spurious signals that could be interpreted as biological activity. Diffuse light‐sheets mitigate these problems, illuminating the blind spots produced by stripes and removing artifacts produced by the stripes' movements. The upgrade to diffuse light sheets is simple and inexpensive, especially in the case of DSLS, where it requires the addition of one optical element. A common problem in light‐sheet microscopes is that shadows cast in the illumination lead stripes in the recorded images. When imaging brain activity in larval zebrafish, we show that stripes can both hide neurons and can flicker to produce spurious signals that could be misinterpreted as brain activity. We introduce a simple new method to eliminate stripes and which mitigates these problems. [ABSTRACT FROM AUTHOR]

Published

2018

6. Broad frequency sensitivity and complex neural coding in the larval zebrafish auditory system.

Author

Poulsen, Rebecca E., Scholz, Leandro A., Constantin, Lena, Favre-Bulle, Itia, Vanwalleghem, Gilles C., and Scott, Ethan K.

Subjects

*AUDITORY pathways, *NEURAL codes, *AUDITORY neurons, *BRACHYDANIO, *FISH larvae, *AUDITORY perception

Abstract

Most animals have complex auditory systems that identify salient features of the acoustic landscape to direct appropriate responses. In fish, these features include the volume, frequency, complexity, and temporal structure of acoustic stimuli transmitted through water. Larval fish have simple brains compared to adults but swim freely and depend on sophisticated sensory processing for survival. 1–5 Zebrafish larvae, an important model for studying brain-wide neural networks, have thus far been found to possess a rudimentary auditory system, sensitive to a narrow range of frequencies and without evident sensitivity to acoustic features that are salient and ethologically important to adult fish. 6,7 Here, we have combined a novel method for delivering water-borne sounds, a diverse assembly of acoustic stimuli, and whole-brain calcium imaging to describe the responses of individual auditory-responsive neurons across the brains of zebrafish larvae. Our results reveal responses to frequencies ranging from 100 Hz to 4 kHz, with evidence of frequency discrimination from 100 Hz to 2.5 kHz. Frequency-selective neurons are located in numerous regions of the brain, and neurons responsive to the same frequency are spatially grouped in some regions. Using functional clustering, we identified categories of neurons that are selective for a single pure-tone frequency, white noise, the sharp onset of acoustic stimuli, and stimuli involving a gradual crescendo. These results suggest a more nuanced auditory system than has previously been described in larval fish and provide insights into how a young animal's auditory system can both function acutely and serve as the scaffold for a more complex adult system. [Display omitted] • Larval zebrafish have neural responses to auditory stimuli up to 4 kHz • Different frequencies elicit distinct responses for frequencies below 2.5 kHz • Responses distinguish pure versus complex stimuli and gradual versus sharp onset • Frequency-selective neurons are organized spatially but are not clearly tonotopic Larval fish are thought to have rudimentary auditory systems sensitive to low frequency. Using calcium imaging, Poulsen et al. show neural responses in zebrafish larvae up to 4 kHz, frequency discrimination up to 2.5 kHz, and unique signatures for simple and complex sounds. The particular responses are located in specific locations across the brain. [ABSTRACT FROM AUTHOR]

Published

2021

7. Cellular-Resolution Imaging of Vestibular Processing across the Larval Zebrafish Brain.

Author

Favre-Bulle, Itia A., Vanwalleghem, Gilles, Taylor, Michael A., Rubinsztein-Dunlop, Halina, and Scott, Ethan K.

Subjects

*ZEBRA danio, *NEURAL circuitry, *OTOLITHS, *TELENCEPHALON, *BRACHYDANIO

Abstract

Summary The vestibular system, which reports on motion and gravity, is essential to postural control, balance, and egocentric representations of movement and space. The motion needed to stimulate the vestibular system complicates studying its circuitry, so we previously developed a method for fictive vestibular stimulation in zebrafish, using optical trapping to apply physical forces to the otoliths. Here, we combine this approach with whole-brain calcium imaging at cellular resolution, delivering a comprehensive map of the brain regions and cellular responses involved in basic vestibular processing. We find responses broadly distributed across the brain, with unique profiles of cellular responses and topography in each region. The most widespread and abundant responses involve excitation that is graded to the stimulus strength. Other responses, localized to the telencephalon and habenulae, show excitation that is only weakly correlated to stimulus strength and that is sensitive to weak stimuli. Finally, numerous brain regions contain neurons that are inhibited by vestibular stimuli, and these neurons are often tightly localized spatially within their regions. By exerting separate control over the left and right otoliths, we explore the laterality of brain-wide vestibular processing, distinguishing between neurons with unilateral and bilateral vestibular sensitivity and revealing patterns whereby conflicting signals from the ears mutually cancel. Our results confirm previously identified vestibular responses in specific regions of the larval zebrafish brain while revealing a broader and more extensive network of vestibular responsive neurons than has previously been described. This provides a departure point for more targeted studies of the underlying functional circuits. Highlights • Optical traps allow brain-wide imaging of vestibular activity with SPIM and GCaMP • Vestibular stimulation drives characteristic patterns of excitation and inhibition • Consistent spatial patterns exist within and across numerous brain regions • Signals from the two ears cancel if contradictory vestibular stimuli are presented Favre-Bulle, Vanwalleghem, et al. use optical trapping to stimulate the vestibular system in stationary larval zebrafish and then use SPIM microscopy and GCaMP to describe resulting activity across the brain. The result is a brain-wide atlas of vestibular processing at cellular resolution. [ABSTRACT FROM AUTHOR]

Published

2018

8. Luminance Changes Drive Directional Startle through a Thalamic Pathway.

Author

Heap, Lucy A.L., Vanwalleghem, Gilles, Thompson, Andrew W., Favre-Bulle, Itia A., and Scott, Ethan K.

Subjects

*THALAMUS, *VISUAL perception, *STIMULUS & response (Biology), *ZEBRA danio, *VERTEBRATES

Abstract

Summary Looming visual stimuli result in escape responses that are conserved from insects to humans. Despite their importance for survival, the circuits mediating visual startle have only recently been explored in vertebrates. Here we show that the zebrafish thalamus is a luminance detector critical to visual escape. Thalamic projection neurons deliver dim-specific information to the optic tectum, and ablations of these projections disrupt normal tectal responses to looms. Without this information, larvae are less likely to escape from dark looming stimuli and lose the ability to escape away from the source of the loom. Remarkably, when paired with an isoluminant loom stimulus to the opposite eye, dimming is sufficient to increase startle probability and to reverse the direction of the escape so that it is toward the loom. We suggest that bilateral comparisons of luminance, relayed from the thalamus to the tectum, facilitate escape responses and are essential for their directionality. [ABSTRACT FROM AUTHOR]

Published

2018

9. Spontaneous Activity in the Zebrafish Tectum Reorganizes over Development and Is Influenced by Visual Experience.

Author

Avitan, Lilach, Pujic, Zac, Mölter, Jan, Van De Poll, Matthew, Sun, Biao, Teng, Haotian, Amor, Rumelo, Scott, Ethan K., and Goodhill, Geoffrey J.

Subjects

*ZEBRA danio, *FISH development, *FISH behavior, *PREDATION, *NEUROPLASTICITY

Abstract

Summary Spontaneous patterns of activity in the developing visual system may play an important role in shaping the brain for function. During the period 4–9 dpf (days post-fertilization), larval zebrafish learn to hunt prey, a behavior that is critically dependent on the optic tectum. However, how spontaneous activity develops in the tectum over this period and the effect of visual experience are unknown. Here we performed two-photon calcium imaging of GCaMP6s zebrafish larvae at all days from 4 to 9 dpf. Using recently developed graph theoretic techniques, we found significant changes in both single-cell and population activity characteristics over development. In particular, we identified days 5–6 as a critical moment in the reorganization of the underlying functional network. Altering visual experience early in development altered the statistics of tectal activity, and dark rearing also caused a long-lasting deficit in the ability to capture prey. Thus, tectal development is shaped by both intrinsic factors and visual experience. [ABSTRACT FROM AUTHOR]

Published

2017