Cellular and molecular mechanisms of photoreceptor tuning for prey capture in larval zebrafish

Yoshimatsu, Takeshi; Schröder, Cornelius; Ne, Nevala; Berens, Philipp; Baden, Tom

doi:10.1101/744615

Cited by 11 publications

(56 citation statements)

References 119 publications

(185 reference statements)

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“…As predicted from work on photoreceptors (Yoshimatsu et al, 2019;Zimmermann et al, 2018), the density of RGCs was elevated in the SZ (Figs. 1C1).…”

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Insupporting

confidence: 76%

“…For efficient coding (Attneave, 1954;Barlow, 1961;Simoncelli and Olshausen, 2001) zebrafish should therefore invest in different sets of functional RGC types to support different aspects of vision across their retinal surface. In agreement, both photoreceptor (Yoshimatsu et al, 2019) and retinal bipolar cell functions (Zimmermann et al, 2018) are asymmetrically distributed across the eye, and feature pronounced reorganisations in the area temporalis (dubbed Strike Zone, SZ (Zimmermann et al, 2018)), which is used for visual prey capture (Bianco et al, 2011;Mearns et al, 2019;Semmelhack et al, 2014;Yoshimatsu et al, 2019;Zimmermann et al, 2018). In contrast, data on structural and functional retinal anisotropies in zebrafish RGCs remains largely outstanding (but see (Robles et al, 2014)).…”

Section: Introductionmentioning

confidence: 90%

“…Larval zebrafish use a highly asymmetrical retina to process distinct sets of visual features across different parts of visual space (Robles et al, 2014;Yoshimatsu et al, 2019;Zimmermann et al, 2018). In particular, they feature a pronounced acute zone (area temporalis (Schmitt and Dowling, 1999), dubbed "strike zone", SZ; (Zimmermann et al, 2018)) which is used in conjunction with fixational eye movements for visual guided prey capture (Antinucci et al, 2019;Mearns et al, 2019;Semmelhack et al, 2014;Yoshimatsu et al, 2019). However, the anatomical distribution of RGCs across the eye has never been quantified.…”

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Inmentioning

confidence: 99%

“…Conceptually reminiscent, a reduced inhibitory tone in the primate fovea is thought to aid signal-to-noise in low-convergence circuits (Baden et al, 2020;Sinha et al, 2017). In view of their need to process the signal from small numbers of cones for visual prey detection (Yoshimatsu et al, 2019), larval zebrafish RGCs might also be expected to benefit from a low-inhibition arrangement in their SZ.…”

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Inmentioning

confidence: 99%

“…In fact, wavelength is strongly associated with specific behaviours in zebrafish. For example, the optomotor response is best driven by long wavelength light (Orger and Baier, 2005), while visual guided prey capture capitalises on short-wavelength vision (Yoshimatsu et al, 2019). However, if and how zebrafish visual behaviours build on signals from spectrally selective RGC circuits remains unknown.…”

Section: Introductionmentioning

confidence: 99%

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What the Zebrafish’s Eye Tells the Zebrafish’s Brain: Retinal Ganglion Cells for Prey Capture and Colour Vision

Zhou

Bear

Roberts

et al. 2020

Preprint

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In vertebrate vision, the tetrachromatic larval zebrafish permits non-invasive monitoring and manipulating of neural activity across the nervous system in vivo during ongoing behaviour. However, despite a perhaps unparalleled understanding of links between zebrafish brain circuits and visual behaviours, comparatively little is known about what their eyes send to the brain in the first place via retinal ganglion cells (RGCs). Major gaps in knowledge include any information on spectral coding, and information on potentially critical variations in RGC properties across the retinal surface to acknowledge asymmetries in the statistics of natural visual space and behavioural demands.Here, we use in vivo two photon (2P) imaging during hyperspectral visual stimulation as well as photolabeling of RGCs to provide the first eye-wide functional and anatomical census of RGCs in larval zebrafish.We find that RGCs' functional and structural properties differ across the eye and include a notable population of UV-responsive On-sustained RGCs that are only found in the acute zone, likely to support visual prey capture of UV-bright zooplankton. Next, approximately half of RGCs display diverse forms of colour opponency -long in excess of what would be required to satisfy traditional models of colour vision. However, most information on spectral contrast was intermixed with temporal information. To consolidate this series of unexpected findings, we propose that zebrafish may use a novel "dual-achromatic" strategy segregated by a spectrally intermediate background subtraction system. Specifically, our data is consistent with a model where traditional achromatic image-forming vision is mainly driven by longwavelength sensitive circuits, while in parallel UV-sensitive circuits serve a second achromatic system of foreground-vision that serves prey capture and, potentially, predator evasion.

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“…As predicted from work on photoreceptors (Yoshimatsu et al, 2019;Zimmermann et al, 2018), the density of RGCs was elevated in the SZ (Figs. 1C1).…”

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Insupporting

confidence: 76%

Section: Introductionmentioning

confidence: 90%

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Inmentioning

confidence: 99%

Section: The Density Of Rgcs But Not Of Acs Is Locally Increased Inmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

What the Zebrafish’s Eye Tells the Zebrafish’s Brain: Retinal Ganglion Cells for Prey Capture and Colour Vision

Zhou

Bear

Roberts

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

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Chromatic organization of retinal photoreceptors during eye migration of Atlantic halibut (Hippoglossus hippoglossus)

Bolstad

Flamarique

2022

J of Comparative Neurology

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The retinas of fishes often have single and double cone photoreceptors that are organized in lattice‐like mosaics. In flatfishes experiencing eye migration (i.e., the metamorphic process whereby one eye migrates to the other side of the head), the hexagonal lattice of single cones present in the larva undergoes major restructuring resulting in a dominant square mosaic postmetamorphosis consisting of four double cones surrounding each single cone. The expression of different opsin types during eye migration has not been examined despite its importance in understanding photoreceptor plasticity and whether cell fate (in terms of spectral phenotype) could influence square mosaic formation. Here, we probed the retina of Atlantic halibut undergoing eye migration for opsin expression using two antibodies, AHblue and AB5407, that labeled short wavelength sensitive 2 (SWS2) opsin and longer wavelength (predominantly middle wavelength sensitive, RH2) opsins, respectively. Throughout the retina, double and triple cones labeled with AB5407 exclusively, whereas the vast majority of single cones labeled with AHblue. A minority (<5%) of single cones in the square mosaic of the centroventral retina labeled with AB5407. In regions of mosaic transition and near peripheral growth zones, some single cones co‐expressed at least two opsins as they labeled with both antibodies. Short wavelength (SWS2 expressing, or S) cones formed a nonrandom mosaic gradient from central to dorsal retina in a region dominated by the larval single cone mosaic. Our results demonstrate the expression of at least two opsins throughout the postmetamorphic retina and suggest opsin switching as a mechanism to create new cone spectral phenotypes. In addition, the S cone gradient at the onset of eye migration may underlie a plastic, cell induction mechanism by which a cone's phenotype determines that of its neighbors and the formation of the square mosaic.

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Deconstructing Hunting Behavior Reveals a Tightly Coupled Stimulus-Response Loop

et al. 2020

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Cellular and molecular mechanisms of photoreceptor tuning for prey capture in larval zebrafish

Cited by 11 publications

References 119 publications

What the Zebrafish’s Eye Tells the Zebrafish’s Brain: Retinal Ganglion Cells for Prey Capture and Colour Vision

What the Zebrafish’s Eye Tells the Zebrafish’s Brain: Retinal Ganglion Cells for Prey Capture and Colour Vision

Chromatic organization of retinal photoreceptors during eye migration of Atlantic halibut (Hippoglossus hippoglossus)

Deconstructing Hunting Behavior Reveals a Tightly Coupled Stimulus-Response Loop

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