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1. 6. Spatial Vision

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

5. 7. Color Vision

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

9. 11. Vision in Dim Light

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

12. General Index

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

13. References

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

14. Index of Names

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

15. 1. Introduction

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

16. Glossary

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

17. 8. Polarization Vision

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

18. List of Illustrations

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

19. Contents

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

20. Title Page, Copyright

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

21. Preface

Author

Thomas W. Cronin, Sönke Johnsen, N. Justin Marshall, and Eric J. Warrant

Published
2014

22. Dynamic polarization vision in mantis shrimps

Author

Ilse M. Daly, Martin J. How, Julian C. Partridge, Shelby E. Temple, N. Justin Marshall, Thomas W. Cronin, and Nicholas W. Roberts

Subjects
Science
Abstract

Mantis shrimps are known to display large pitch, yaw and torsional eye rotations. Here, the authors show that these eye movements allow mantis shrimp to orientate particular photoreceptors in order to better discriminate the polarization of light.

Published
2016
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23. Colour vision in stomatopod crustaceans

Author

Thomas W. Cronin, Megan L. Porter, Michael J. Bok, Roy L. Caldwell, and Justin Marshall

Subjects
Color Vision, Crustacea, Animals, Humans, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology
Abstract

The stomatopod crustaceans, or mantis shrimps, are colourful marine invertebrate predators. Their unusual compound eyes have dorsal and ventral regions resembling typical crustacean apposition designs separated by a unique region called the midband that consists of from two to six parallel rows of ommatidia. In species with six-row midbands, the dorsal four rows are themselves uniquely specialized for colour analysis. Rhabdoms of ommatidia in these rows are longitudinally divided into three distinct regions: an apical ultraviolet (UV) receptor, a shorter-wavelength middle tier receptor and a longer-wavelength proximal tier receptor. Each of the total of 12 photoreceptors has a different spectral sensitivity, potentially contributing to a colour-vision system with 12 channels. Mantis shrimps can discriminate both human-visible and UV colours, but with limited precision compared to other colour-vision systems. Here, we review the structure and function of stomatopod colour vision, examining the types of receptors present in a species, the spectral tuning of photoreceptors both within and across species, the neural analysis of colour and the genetics underlying the multiple visual pigments used for colour vision. Even today, after many decades of research into the colour vision of stomatopods, much of its operation and its use in nature remain a mystery. This article is part of the theme issue ‘Understanding colour vision: molecular, physiological, neuronal and behavioural studies in arthropods’.

Published
2023

26. Michael F. Land (1942–2020)

Author

Thomas W. Cronin and Justin Marshall

Subjects
Art history, Obituary, General Agricultural and Biological Sciences, Psychology, General Biochemistry, Genetics and Molecular Biology
Abstract

Obituary of visual neurobiologist Michael Land, whose studies pioneered the fields of animal and human vision, optics and behavioural psychology.

Published
2021
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27. Neuroanatomy of stomatopod central complexes offers putative neural substrate for oriented behaviors in crustaceans

Author

Alice Chou, Marcel E. Sayre, Chan Lin, and Thomas W. Cronin

Abstract

All insects studied to date possess a centrally located group of neuropils, known collectively as the central complex, that has been implicated in sensory integration and motor action selection. Among the functions prescribed to the central complex, none is perhaps as intriguing as its role in orientation and navigation. Neurobiological correlates of both current and desired headings have been described in insect CXs. Despite the diversity of arthropods, understanding of the CX as a navigational center originates entirely from terrestrial insects. Stomatopod crustaceans, commonly referred to as mantis shrimps, form an order of predatory marine crustaceans with intricate and diverse visual systems that maintain the distinction of being the only fully aquatic animal known to utilize the navigational strategy of path integration. They utilize idiothetic, celestial, and landmark cues to orient in the benthos. Here, we investigate the neuroanatomy of adult and developing mantis shrimp central complexes and associated neuropils to begin understanding this brain region in a sensorially and behaviorally complex crustacean.

Published
2022
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28. Sensory Ecology: In Sea Snake Vision, One Plus One Makes Three

Author

Thomas W. Cronin

Subjects
0301 basic medicine, Opsin, 2019-20 coronavirus outbreak, genetic structures, Coronavirus disease 2019 (COVID-19), Color vision, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Biology, complex mixtures, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Sensory ecology, Animals, Alleles, Color Vision, Opsins, Limiting, eye diseases, Retinal Cones, Hydrophiidae, 030104 developmental biology, Evolutionary biology, Retinal Cone Photoreceptor Cells, sense organs, General Agricultural and Biological Sciences, 030217 neurology & neurosurgery
Abstract

Snake genomes encode only two opsins for use in retinal cones, limiting their adaptive flexibility and color vision. Research now shows that, by using alternative opsin alleles, some sea snakes may add a third opsin spectral class to their retinas.

Published
2020
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30. An Unexpected Diversity of Photoreceptor Classes in the Longfin Squid, Doryteuthis pealeii.

Author

Alexandra C N Kingston, Trevor J Wardill, Roger T Hanlon, and Thomas W Cronin

Subjects
Medicine, Science
Abstract

Cephalopods are famous for their ability to change color and pattern rapidly for signaling and camouflage. They have keen eyes and remarkable vision, made possible by photoreceptors in their retinas. External to the eyes, photoreceptors also exist in parolfactory vesicles and some light organs, where they function using a rhodopsin protein that is identical to that expressed in the retina. Furthermore, dermal chromatophore organs contain rhodopsin and other components of phototransduction (including retinochrome, a photoisomerase first found in the retina), suggesting that they are photoreceptive. In this study, we used a modified whole-mount immunohistochemical technique to explore rhodopsin and retinochrome expression in a number of tissues and organs in the longfin squid, Doryteuthis pealeii. We found that fin central muscles, hair cells (epithelial primary sensory neurons), arm axial ganglia, and sucker peduncle nerves all express rhodopsin and retinochrome proteins. Our findings indicate that these animals possess an unexpected diversity of extraocular photoreceptors and suggest that extraocular photoreception using visual opsins and visual phototransduction machinery is far more widespread throughout cephalopod tissues than previously recognized.

Published
2015
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31. Mantis shrimp identify an object by its shape rather than its color during visual recognition

Author

Rickesh N. Patel, Olivia Pettyjohn-Robin, Laylo Abdurahmonova, Tamar Goldwasser, Veniamin Khil, Thomas W. Cronin, Benjamin Sparklin, Holland Driscoll, Sarina Patel, and Ahmad Shah

Subjects
0106 biological sciences, Physiology, Computer science, Short Communication, Stomatopod, Mantodea, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Mantis shrimp, Neogonodactylus oerstedii, Memory, Crustacea, Visual guidance, Animals, Learning, Animal behavior, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Marine biology, 0303 health sciences, biology, business.industry, Cognitive neuroscience of visual object recognition, Ethology, Pattern recognition, Object recognition, Object (computer science), biology.organism_classification, Visual recognition, Pattern Recognition, Visual, Insect Science, Animal Science and Zoology, Identification (biology), Pavlovian conditioning, Artificial intelligence, business
Abstract

Mantis shrimp commonly inhabit seafloor environments with an abundance of visual features including conspecifics, predators, prey and landmarks used for navigation. Although these animals are capable of discriminating color and polarization, it is unknown what specific attributes of a visual object are important during recognition. Here, we show that mantis shrimp of the species Neogonodactylus oerstedii are able to learn the shape of a trained target. Further, when the shape and color of a target that they had been trained to identify were placed in conflict, N. oerstedii tended to choose the target of the trained shape over the target of the trained color. Thus, we conclude that the shape of the target was more salient than its color during recognition by N. oerstedii, suggesting that the shapes of objects, such as landmarks or other animals, are important for their identification by the species., Summary: Mantis shrimp can identify an object by its shape and seem to use the shape of an object over its color when recognizing it.

Published
2021
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33. Evolutionary Optics: How Mantis Shrimps Enhance Photoreception and Signaling Effectiveness

Author

Thomas W. Cronin

Subjects
biology, Evolutionary biology, Chemistry, Mantis, biology.organism_classification
Abstract

Mantis shrimps (stomatopod crustaceans) have evolved numerous adaptations in their photoreceptors and in body structures used to produce visual signals. Novel optical structures exist at microscales and nanoscales, often operating by previously unknown optical mechanisms.

Published
2021
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34. Landmark navigation in a mantis shrimp

Author

Rickesh N. Patel and Thomas W. Cronin

Subjects
Computer science, Foraging, Tropical waters, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Neogonodactylus oerstedii, Mantis shrimp, 0302 clinical medicine, Crustacea, Orientation, Path integration, Animals, Computer vision, Behaviour, 030304 developmental biology, General Environmental Science, 0303 health sciences, Landmark, General Immunology and Microbiology, biology, business.industry, Navigational system, General Medicine, biology.organism_classification, Burrow, Fishery, Geography, Benthic zone, Artificial intelligence, Cues, General Agricultural and Biological Sciences, business, 030217 neurology & neurosurgery, Spatial Navigation
Abstract

SummaryMantis shrimp are predatory crustaceans that commonly occupy burrows in shallow, tropical waters worldwide. Most of these animals inhabit structurally complex, benthic environments where many potential landmarks are available. Mantis shrimp of the species Neogonodactylus oerstedii return to their burrows between foraging excursions using path integration, a vector-based navigational strategy that is prone to accumulated error. Here we show that N. oerstedii can navigate using landmarks in parallel with their path integration system, offseting error generated when navigating using solely path integration. We also report that when the path integration and landmark navigation systems are placed in conflict, N. oerstedii will orient using either system or even switch systems enroute. How they make the decision to trust one navigational system over another is unclear. These findings add to our understanding of the refined navigational toolkit N. oerstedii relies upon to efficiently navigate back to its burrow, complementing its robust, yet error prone, path integration system with landmark guidance.

Published
2020

35. Mantis shrimp rank the shape of an object over its color during recognition

Author

Benjamin Sparklin, Sarina Patel, Ahmad Shah, Holland Driscoll, Veniamin Khil, Laylo Abdurahmonova, Olivia Pettyjohn-Robin, Tamar Goldwasser, Thomas W. Cronin, and Rickesh N. Patel

Subjects
Mantis shrimp, Neogonodactylus oerstedii, biology, business.industry, Cognitive neuroscience of visual object recognition, Pattern recognition, Artificial intelligence, biology.organism_classification, business, Tropical waters
Abstract

SummaryMantis shrimp are predatory crustaceans that commonly occupy burrows in shallow, tropical waters worldwide. Most of these animals inhabit structurally complex, benthic environments with an abundance of visual features that are regularly observed, including conspecifics, predators, prey, and landmarks for use in navigation. While these animals are capable of learning and discriminating color and polarization, it is unknown what specific attributes of a visual object are important for its recognition. Here we show that mantis shrimp of the speciesNeogonodactylus oerstediican learn the shape of a trained target. Furthermore, when the shape and color of a target which they had been trained to identify were placed in conflict,N. oerstediisignificantly chose the target of the trained shape over the target of the trained color. Thus, we conclude that the shape of a target is more important than its color for its recognition byN. oerstedii. Our findings suggest that the shapes of learned structures, such as landmarks or other animals, are important forN. oerstediiduring object recognition.

Published
2020
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36. Visual system characterization of the obligate bat ectoparasite Trichobius frequens (Diptera: Streblidae)

Author

Noah Simon, Megan L. Porter, Thomas W. Cronin, Katharina Dittmar, and Carl W. Dick

Subjects
0106 biological sciences, 0301 basic medicine, Male, Opsin, Spatial vision, Period (gene), Zoology, Gene Expression, Biology, Nocturnal, Streblidae, 010603 evolutionary biology, 01 natural sciences, Host-Parasite Interactions, 03 medical and health sciences, Chiroptera, Animals, Compound Eye, Arthropod, Ecology, Evolution, Behavior and Systematics, Microscopy, Confocal, Obligate, Opsins, Diptera, General Medicine, biology.organism_classification, Pupa, 030104 developmental biology, Insect Science, Microscopy, Electron, Scanning, Insect Proteins, Female, Photoreceptor Cells, Invertebrate, Trichobius, Developmental Biology
Abstract

As an obligate ectoparasite of bats, the bat fly Trichobius frequens (Diptera: Streblidae) inhabits the same subterranean environment as their nocturnal bat hosts. In this study, we characterize the macromorphology, optical architecture, rhabdom anatomy, photoreceptor absorbance, and opsin expression of the significantly reduced visual system in T. frequens resulting from evolution in the dark. The eyes develop over a 21–22 day pupal developmental period, with pigmentation appearing on pupal day 11. After eclosion as an adult, T. frequens eyes consist of on average 8 facets, each overlying a fused rhabdom consisting of anywhere from 11 to 18 estimated retinula cells. The dimensions of the facets and fused rhabdoms are similar to those measured in other nocturnal insects. T. frequens eyes are functional as shown by expression of a Rh1 opsin forming a visual pigment with a peak sensitivity to 487 nm, similar to other dipteran Rh1 opsins. Future studies will evaluate how individuals with such reduced capabilities for spatial vision as well as sensitivity still capture enough visual information to use flight to maneuver through dark habitats.

Published
2020

37. Exceptional diversity of opsin expression patterns in

Author

Megan L, Porter, Hiroko, Awata, Michael J, Bok, and Thomas W, Cronin

Subjects
genetic structures, Color Vision, Crustacea, Gene Duplication, Gene Expression Profiling, Rod Opsins, Animals, Photoreceptor Cells, Invertebrate, sense organs, Biological Sciences, eye diseases, Phylogeny, Retina
Abstract

Stomatopod crustaceans possess some of the most complex animal visual systems, including at least 16 spectrally distinct types of photoreceptive units (e.g., assemblages of photoreceptor cells). Here we fully characterize the set of opsin genes expressed in retinal tissues and determine expression patterns of each in the stomatopod Neogonodactylus oerstedii. Using a combination of transcriptome and RACE sequencing, we identified 33 opsin transcripts expressed in each N. oerstedii eye, which are predicted to form 20 long-wavelength–sensitive, 10 middle-wavelength–sensitive, and three UV-sensitive visual pigments. Observed expression patterns of these 33 transcripts were highly unusual in five respects: 1) All long-wavelength and short/middle-wavelength photoreceptive units expressed multiple opsins, while UV photoreceptor cells expressed single opsins; 2) most of the long-wavelength photoreceptive units expressed at least one middle-wavelength–sensitive opsin transcript; 3) the photoreceptors involved in spatial, motion, and polarization vision expressed more transcripts than those involved in color vision; 4) there is a unique opsin transcript that is expressed in all eight of the photoreceptive units devoted to color vision; and 5) expression patterns in the peripheral hemispheres of the eyes suggest visual specializations not previously recognized in stomatopods. Elucidating the expression patterns of all opsin transcripts expressed in the N. oerstedii retina reveals the potential for previously undocumented functional diversity in the already complex stomatopod eye and is a first step toward understanding the functional significance of the unusual abundance of opsins found in many arthropod species’ visual systems.

Published
2020

38. Exceptional diversity of opsin expression patterns in Neogonodactylus oerstedii (Stomatopoda) retinas

Author

Michael J. Bok, Thomas W. Cronin, Hiroko Awata, and Megan L. Porter

Subjects
0106 biological sciences, Opsin, genetic structures, Color vision, 010603 evolutionary biology, 01 natural sciences, Transcriptome, 03 medical and health sciences, chemistry.chemical_compound, opsin, evolution, medicine, Gene, 030304 developmental biology, Stomatopoda, 0303 health sciences, Retina, Multidisciplinary, biology, Retinal, biology.organism_classification, eye diseases, Gene expression profiling, medicine.anatomical_structure, chemistry, retinal expression, Evolutionary biology, Arthropod, sense organs, in situ hybridization
Abstract

Stomatopod crustaceans possess some of the most complex animal visual systems, including at least 16 spectrally distinct types of photoreceptive units (e.g., assemblages of photoreceptor cells). Here we fully characterize the set of opsin genes expressed in retinal tissues and determine expression patterns of each in the stomatopod Neogonodactylus oerstedii . Using a combination of transcriptome and RACE sequencing, we identified 33 opsin transcripts expressed in each N. oerstedii eye, which are predicted to form 20 long-wavelength–sensitive, 10 middle-wavelength–sensitive, and three UV-sensitive visual pigments. Observed expression patterns of these 33 transcripts were highly unusual in five respects: 1) All long-wavelength and short/middle-wavelength photoreceptive units expressed multiple opsins, while UV photoreceptor cells expressed single opsins; 2) most of the long-wavelength photoreceptive units expressed at least one middle-wavelength–sensitive opsin transcript; 3) the photoreceptors involved in spatial, motion, and polarization vision expressed more transcripts than those involved in color vision; 4) there is a unique opsin transcript that is expressed in all eight of the photoreceptive units devoted to color vision; and 5) expression patterns in the peripheral hemispheres of the eyes suggest visual specializations not previously recognized in stomatopods. Elucidating the expression patterns of all opsin transcripts expressed in the N. oerstedii retina reveals the potential for previously undocumented functional diversity in the already complex stomatopod eye and is a first step toward understanding the functional significance of the unusual abundance of opsins found in many arthropod species’ visual systems.

Published
2020
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39. Scanning eye movements of the stomatopod crustacean,Neogonodactylus oerstedii, in polarized light fields

Author

Thomas W. Cronin, Mary F. Durham, and Chan Lin

Subjects
0301 basic medicine, Visual search, biology, Physiology, business.industry, Linear polarization, Aquatic Science, Oceanography, Rotation, biology.organism_classification, Visual field, 03 medical and health sciences, Mantis shrimp, 030104 developmental biology, 0302 clinical medicine, Optics, Ommatidium, Perpendicular, business, 030217 neurology & neurosurgery, Circular polarization
Abstract

Stomatopod crustaceans have highly mobile, independently moving compound eyes that are sensitive to both linearly and circularly polarized light. They rotate their eyes to predictable angles when viewing a linearly polarized target, and they scan their eyes frequently to sample the visual field. Angles of scans are roughly perpendicular to the plane of the midband (a set of specialized parallel rows of equatorial ommatidia). We investigated scanning eye movements in one Caribbean stomatopod species (Neogonodactylus oerstedii) in uniform visual fields that were vertically polarized, horizontally polarized, or depolarized. We found that mean eye rotation and scan angles differed significantly among these different treatments. Average scan angles differed by 12°, being more horizontal in a vertically polarized field than in a horizontally polarized one, and also more horizontal in a vertically polarized field than in a depolarized field. Thus, these stomatopods adjusted visual scanning to the polariz...

Published
2018
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40. Cerebral photoreception in mantis shrimp

Author

Mary W Donohue, Thomas W. Cronin, and Jonathan H. Cohen

Subjects
0301 basic medicine, Opsin, genetic structures, Central nervous system, lcsh:Medicine, Article, 03 medical and health sciences, Mantis shrimp, Decapoda, medicine, Animals, Carapace, Mantis, Cephalothorax, lcsh:Science, Ganglion Cysts, Multidisciplinary, Opsins, biology, fungi, lcsh:R, Brain, biology.organism_classification, Crustacean, eye diseases, 030104 developmental biology, medicine.anatomical_structure, lcsh:Q, Arthropod, sense organs, Neuroscience, Histamine, Photoreceptor Cells, Vertebrate
Abstract

The currently unsurpassed diversity of photoreceptors found in the eyes of stomatopods, or mantis shrimps, is achieved through a variety of opsin-based visual pigments and optical filters. However, the presence of extraocular photoreceptors in these crustaceans is undescribed. Opsins have been found in extraocular tissues across animal taxa, but their functions are often unknown. Here, we show that the mantis shrimp Neogonodactylus oerstedii has functional cerebral photoreceptors, which expands the suite of mechanisms by which mantis shrimp sense light. Illumination of extraocular photoreceptors elicits behaviors akin to common arthropod escape responses, which persist in blinded individuals. The anterior central nervous system, which is illuminated when a mantis shrimp’s cephalothorax protrudes from its burrow to search for predators, prey, or mates, appears to be photosensitive and to feature two types of opsin-based, potentially histaminergic photoreceptors. A pigmented ventral eye that may be capable of color discrimination extends from the cerebral ganglion, or brain, against the transparent outer carapace, and exhibits a rapid electrical response when illuminated. Additionally, opsins and histamine are expressed in several locations of the eyestalks and cerebral ganglion, where any photoresponses could contribute to shelter-seeking behaviors and other functions.

Published
2018
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41. The eyes have it: regulatory and structural changes both underlie cichlid visual pigment diversity.

Author

Christopher M Hofmann, Kelly E O'Quin, N Justin Marshall, Thomas W Cronin, Ole Seehausen, and Karen L Carleton

Subjects
Biology (General), QH301-705.5
Abstract

A major goal of evolutionary biology is to unravel the molecular genetic mechanisms that underlie functional diversification and adaptation. We investigated how changes in gene regulation and coding sequence contribute to sensory diversification in two replicate radiations of cichlid fishes. In the clear waters of Lake Malawi, differential opsin expression generates diverse visual systems, with sensitivities extending from the ultraviolet to the red regions of the spectrum. These sensitivities fall into three distinct clusters and are correlated with foraging habits. In the turbid waters of Lake Victoria, visual sensitivity is constrained to longer wavelengths, and opsin expression is correlated with ambient light. In addition to regulatory changes, we found that the opsins coding for the shortest- and longest-wavelength visual pigments have elevated numbers of potentially functional substitutions. Thus, we present a model of sensory evolution in which both molecular genetic mechanisms work in concert. Changes in gene expression generate large shifts in visual pigment sensitivity across the collective opsin spectral range, but changes in coding sequence appear to fine-tune visual pigment sensitivity at the short- and long-wavelength ends of this range, where differential opsin expression can no longer extend visual pigment sensitivity.

Published
2009
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42. Two visual systems in one eyestalk: The unusual optic lobe metamorphosis in the stomatopod Alima pacifica

Author

Thomas W. Cronin and Chan Lin

Subjects
0301 basic medicine, genetic structures, media_common.quotation_subject, Visual system, Biology, Eye, Visual processing, 03 medical and health sciences, Cellular and Molecular Neuroscience, Imaging, Three-Dimensional, 0302 clinical medicine, Developmental Neuroscience, Crustacea, medicine, Animals, Visual Pathways, Metamorphosis, Medulla, media_common, Retina, Microscopy, Confocal, Optic Lobe, Nonmammalian, fungi, Metamorphosis, Biological, Compound eye, Anatomy, eye diseases, Lobe, Eyestalk, 030104 developmental biology, medicine.anatomical_structure, Larva, sense organs, 030217 neurology & neurosurgery
Abstract

The compound eyes of adult stomatopod crustaceans have two to six ommatidial rows at the equator, called the midband, that are often specialized for color and polarization vision. Beneath the retina, this midband specialization is represented as enlarged optic lobe lamina cartridges and a hernia-like expansion in the medulla. We studied how the optic lobe transforms from the larvae, which possess typical crustacean larval compound eyes without a specialized midband, through metamorphosis into the adults with the midband in a two midband-row species Alima pacifica. Using histological staining, immunolabeling, and 3D reconstruction, we show that the last-stage stomatopod larvae possess double-retina eyes, in which the developing adult visual system forms adjacent to, but separate from, the larval visual system. Beneath the two retinas, the optic lobe also contains two sets of optic neuropils, comprising of a larval lamina, medulla, and lobula, as well as an adult lamina, medulla, and lobula. The larval eye and all larval optic neuropils degenerate and disappear approximately a week after metamorphosis. In stomatopods, the unique adult visual system and all optic neuropils develop alongside the larval system in the eyestalk of last-stage larvae, where two visual systems and two independent visual processing pathways coexist. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 78: 3-14, 2018.

Published
2017
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43. Crustacean Larvae—Vision in the Plankton

Author

Michael J. Bok, Chan Lin, and Thomas W. Cronin

Subjects
0106 biological sciences, 0301 basic medicine, Crustacean larvae, vision, animal structures, Visual perception, genetic structures, Zoology, Plant Science, crustacean larvae, 010603 evolutionary biology, 01 natural sciences, Zooplankton, 03 medical and health sciences, Crustacea, Decapoda, Journal Article, medicine, Animals, Vision, Ocular, Retina, Larva, decapod larvae, biology, fungi, Plankton, biology.organism_classification, Crustacean, eye diseases, 030104 developmental biology, medicine.anatomical_structure, stomatopod larvae, Visual Perception, Animal Science and Zoology, sense organs, Background light
Abstract

This is a pre-copyedited, author-produced version of an article accepted for publication in Integrative & Compartive Biology following peer review. The version of record Thomas W. Cronin, Michael J. Bok, Chan Lin; Crustacean Larvae—Vision in the Plankton, Integrative and Comparative Biology, Volume 57, Issue 5, 1 November 2017, Pages 1139–1150, https://doi.org/10.1093/icb/icx007 is available online at: https://academic.oup.com/icb/article-abstract/57/5/1139/4067251 and https://doi.org/10.1093/icb/icx007., We review the visual systems of crustacean larvae, concentrating on the compound eyes of decapod and stomatopod larvae as well as the functional and behavioral aspects of their vision. Larval compound eyes of these macrurans are all built on fundamentally the same optical plan, the transparent apposition eye, which is eminently suitable for modification into the abundantly diverse optical systems of the adults. Many of these eyes contain a layer of reflective structures overlying the retina that produces a counterilluminating eyeshine, so they are unique in being camouflaged both by their transparency and by their reflection of light spectrally similar to background light to conceal the opaque retina. Besides the pair of compound eyes, at least some crustacean larvae have a non-imaging photoreceptor system based on a naupliar eye and possibly other frontal eyes. Larval compound-eye photoreceptors send axons to a large and well-developed optic lobe consisting of a series of neuropils that are similar to those of adult crustaceans and insects, implying sophisticated analysis of visual stimuli. The visual system fosters a number of advanced and flexible behaviors that permit crustacean larvae to survive extended periods in the plankton and allows them to reach acceptable adult habitats, within which to metamorphose.

Published
2017
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44. Opsin Expression in the Central Nervous System of the Mantis Shrimp Neogonodactylus oerstedii

Author

Karen L. Carleton, Thomas W. Cronin, and Mary W Donohue

Subjects
0301 basic medicine, Opsin, genetic structures, Central nervous system, Gene Expression, 03 medical and health sciences, Mantis shrimp, Neogonodactylus oerstedii, Decapoda, medicine, Animals, Opsins, biology, Brain, biology.organism_classification, Crustacean, eye diseases, 030104 developmental biology, medicine.anatomical_structure, Caribbean Region, Biochemistry, Evolutionary biology, Ventral nerve cord, Eye structure, Cerebral ganglion, sense organs, Transcriptome, General Agricultural and Biological Sciences
Abstract

Visual pigments, each composed of an opsin protein covalently bound to a chromophore molecule, confer light sensitivity for vision. The eyes of some species of stomatopod crustaceans, or mantis shrimp, can express dozens of different opsin genes. The opsin diversity, along with spectral filters and unique tripartite eye structure, bestow upon stomatopods unusually complex visual systems. Although opsins are found in tissues outside typical image-forming eyes in other animals, extraocular opsin expression in stomatopods, animals well known for their diversity of opsins, was unknown. Caudal photoreception in the central nervous system of decapod crustaceans, a group closely related to stomatopod crustaceans, is thought to be opsin based. However, electrophysiological data suggest that stomatopods do not have caudal photoreceptors. In this study, we identified mRNAs that could encode four different opsins and several components of a potential Gq-mediated phototransduction pathway in the central nervous system of the Caribbean mantis shrimp Neogonodactylus oerstedii. The four opsins are abundantly expressed in the cerebral ganglion, or brain, with little or no expression in the remainder of the ventral nerve cord. Our data suggest that there are previously undiscovered cerebral photoreceptors in stomatopods.

Published
2017
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45. Visual predation during springtime foraging of the North Atlantic right whale ( Eubalaena glacialis )

Author

Benjamin Nickle, Thomas W. Cronin, Lorren J. Kezmoh, Mark F. Baumgartner, and Jeffry I. Fasick

Subjects
0106 biological sciences, 0301 basic medicine, genetic structures, biology, Ecology, 010604 marine biology & hydrobiology, Calanus finmarchicus, Foraging, Aquatic Science, biology.organism_classification, 01 natural sciences, Predation, Absorbance, 03 medical and health sciences, 030104 developmental biology, Oceanography, Radiance, sense organs, Right whale, Bay, Ecology, Evolution, Behavior and Systematics, Copepod
Abstract

To assess the role that vision plays in the ability of the North Atlantic right whale (Eubalaena glacialis) to detect its primary prey species, the calanoid copepod Calanus finmarchicus, we have compared the absorbance spectrum of the E. glacialis rod visual pigment, the transmittance spectra of C. finmarchicus carotenoid pigments, as well as the downwelling irradiance and horizontal radiance spectra collected during springtime at three locations in the western Gulf of Maine. The E. glacialis rod visual pigment absorbs light maximally at 493 nm, while microspectrophotometric measurements of the C. finmarchicus carotenoid pigments reveal transmission spectra with minima matching very well with the E. glacialis rod visual pigment absorbance spectra maximum. Springtime spectral downwelling irradiance and horizontal radiance values from the surface waters of Cape Cod Bay and at all depths in Great South Channel overlap the E. glacialis rod absorbance spectrum, allowing C. finmarchicus to appear as a high-contrast dark silhouette against a bright background spacelight, thus facilitating visually guided contrast foraging. In contrast, spectral downwelling irradiance and horizontal radiance at depth in Cape Cod Bay, and all depths in Wilkinson Basin, do not overlap the E. glacialis rod absorbance spectrum, providing little if any useful light for contrast vision.

Published
2017
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47. Path integration error and adaptable search behaviors in a mantis shrimp

Author

Thomas W. Cronin and Rickesh N. Patel

Subjects
0106 biological sciences, Physiology, Computer science, Distributed computing, Foraging, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Neogonodactylus oerstedii, Mantis shrimp, Homing Behavior, Crustacea, Orientation, Path integration, Animals, Animal behavior, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, biology, biology.organism_classification, Caribbean Region, Insect Science, Path (graph theory), Exploratory Behavior, Animal Science and Zoology
Abstract

Mantis shrimp of the speciesNeogonodactylus oerstediioccupy small burrows in shallow waters throughout the Caribbean. These animals use path integration, a vector-based navigation strategy, to return to their homes while foraging. Here we report that path integration inN. oerstediiis prone to error accumulated during outward foraging paths and we describe the search behavior thatN. oerstediiemploys after it fails to locate its home following the route provided by its path integrator. This search behavior forms continuously expanding, non-oriented loops that are centered near the point of search initiation. The radius of this search is apparently scaled to the animal’s accumulated error during path integration, improving the effectiveness of the search. The search behaviors exhibited byN. oerstediibear a striking resemblance to search behaviors in other animals, offering potential avenues for the comparative examination of search behaviors and how they are optimized in disparate taxa.Summary StatementMantis shrimp use path integration, an error-prone navigational strategy, when travelling home. When path integration fails, mantis shrimp employ a stereotyped yet flexible search pattern to locate their homes.

Published
2020
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50. Optic lobe organization in stomatopod crustacean species possessing different degrees of retinal complexity

Author

Alice Chou, Thomas W. Cronin, and Chan Lin

Subjects
Lamina, Physiology, 030310 physiology, Retina, 03 medical and health sciences, Behavioral Neuroscience, chemistry.chemical_compound, Immunolabeling, 0302 clinical medicine, Ommatidium, Crustacea, Pseudosquilla ciliata, medicine, Animals, Visual Pathways, Compound Eye, Arthropod, Ecology, Evolution, Behavior and Systematics, Vision, Ocular, 0303 health sciences, biology, Squilla empusa, Optic Lobe, Nonmammalian, Brain, Retinal, Compound eye, Anatomy, biology.organism_classification, Lobe, Neuroanatomical Tract-Tracing Techniques, medicine.anatomical_structure, chemistry, Visual Perception, Animal Science and Zoology, Photoreceptor Cells, Invertebrate, sense organs, 030217 neurology & neurosurgery, Photic Stimulation
Abstract

Stomatopod crustaceans possess tripartite compound eyes; upper and lower hemispheres are separated by an equatorial midband of several ommatidial rows. The organization of stomatopod retinas is well established, but their optic lobes have been studied less. We used histological staining, immunolabeling, and fluorescent tracer injections to compare optic lobes in two 6-row midband species, Neogonodactylus oerstedii and Pseudosquilla ciliata, to those in two 2-row midband species, Squilla empusa and Alima pacifica. Compared to the 6-row species, we found structural differences in all optic neuropils in both 2-row species. Photoreceptor axons from 2-row midband ommatidia supply two sets of lamina cartridges; however, conspicuous spaces lacking lamina cartridges are observed in locations corresponding to where the cartridges of the upper four ommatidial rows of 6-row species would exist. The tripartite arrangement and enlarged projections containing fibers associated with the two rows of midband ommatidia can be traced throughout the entire optic lobe. However, 2-row species lack some features of medullar and lobular neuropils in 6-row species. Our results support the hypothesis that 2-row midband species are derived from a 6-row ancestor, and suggest specializations in the medulla and lobula found solely in 6-row species are important for color and polarization analysis.

Published
2019

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