Your search keyword '"Retinal topography"' showing total 134 results

1. Functional differences between the extraordinary eyes of deep-sea hyperiid amphipods.

Author

Jessop, Anna-Lee, Bagheri, Zahra M., Partridge, Julian C., Osborn, Karen J., and Hemmi, Jan M.

Subjects

*VISUAL fields, *LOW vision, *VISUAL accommodation, *X-ray computed microtomography, *AMPHIPODA

Abstract

The ocean's midwater is a uniquely challenging yet predictable and simple visual environment. The need to see without being seen in this dim, open habitat has led to extraordinary visual adaptations. To understand these adaptations, we compared the morphological and functional differences between the eyes of three hyperiid amphipods—Hyperia galba, Streetsia challengeri and Phronima sedentaria. Combining micro-CT data with computational modelling, we mapped visual field topography and predicted detection distances for visual targets viewed in different directions through mesopelagic depths. Hyperia's eyes provide a wide visual field optimized for spatial vision over short distances, while Phronima's and Streetsia's eyes have the potential to achieve greater sensitivity and longer detection distances using spatial summation. These improvements come at the cost of smaller visual fields, but this loss is compensated for by a second pair of eyes in Phronima and by behaviour in Streetsia. The need to improve sensitivity while minimizing visible eye size to maintain crypsis has likely driven the evolution of hyperiid eye diversity. Our results provide an integrative look at how these elusive animals have adapted to the unique visual challenges of the mesopelagic. [ABSTRACT FROM AUTHOR]

Published

2024

2. Sex differences in behavioural and anatomical estimates of visual acuity in the green swordtail Xiphophorus helleri

Author

Caves, Eleanor M, de Busserolles, Fanny, and Kelley, Laura A

Subjects

Zoology, Ecology, Biological Sciences, Eye Disease and Disorders of Vision, Eye, Animals, Cyprinodontiformes, Female, Humans, Male, Retina, Retinal Ganglion Cells, Sex Characteristics, Visual Acuity, Visual signal, Retinal topography, Spatial resolution, Sensory ecology, Optomotor, Medical and Health Sciences, Physiology, Biological sciences

Abstract

Among fishes in the family Poeciliidae, signals such as colour patterns, ornaments and courtship displays play important roles in mate choice and male-male competition. Despite this, visual capabilities in poeciliids are understudied, in particular, visual acuity, the ability to resolve detail. We used three methods to quantify visual acuity in male and female green swordtails (Xiphophorus helleri), a species in which body size and the length of the male's extended caudal fin ('sword') serve as assessment signals during mate choice and agonistic encounters. Topographic distribution of retinal ganglion cells (RGCs) was similar in all individuals and was characterized by areas of high cell densities located centro-temporally and nasally, as well as a weak horizontal streak. Based on the peak density of RGCs in the centro-temporal area, anatomical acuity was estimated to be approximately 3 cycles per degree (cpd) in both sexes. However, a behavioural optomotor assay found significantly lower mean acuity in males (0.8 cpd) than females (3.0 cpd), which was not explained by differences in eye size between males and females. An additional behavioural assay, in which we trained individuals to discriminate striped gratings from grey stimuli of the same mean luminance, also showed lower acuity in males (1-2 cpd) than females (2-3 cpd). Thus, although retinal anatomy predicts identical acuity in males and females, two behavioural assays found higher acuity in females than males, a sexual dimorphism that is rare outside of invertebrates. Overall, our results have implications for understanding how poeciliids perceive visual signals during mate choice and agonistic encounters.

Published

2021

3. How viewing objects with the dorsal or ventral retina affects colour-related behaviour in guppies (Poecilia reticulata)

Author

Sibeaux, Adélaïde, Keser, Madison L, Cole, Gemma L, Kranz, Alexandrea M, and Endler, John A

Subjects

Biomedical and Clinical Sciences, Ophthalmology and Optometry, Eye Disease and Disorders of Vision, Eye, Animals, Behavior, Animal, Color Perception, Female, Male, Motion Perception, Opsins, Photoreceptor Cells, Vertebrate, Poecilia, Retina, Retinal topography, Spectral sensitivity, Coloured stimuli, Photoreceptors, Opsin sex differences, Medical and Health Sciences, Psychology and Cognitive Sciences, Experimental Psychology, Ophthalmology and optometry

Abstract

Visual pigments can vary across the retina in many vertebrates, but the behavioural consequences of this retinal heterogeneity are unknown. Guppies (Poecilia reticulata) vary dorsoventrally in visual pigments and forage both on the ground and at the water surface, exposing different retinal regions to two very different visual environments. We tested guppy behaviour towards a moving stimulus presented below or above the guppy. We used 12 different narrow-band wavelength stimuli matching each of the opsin peak sensitivities presented either at the top or the bottom of our experimental apparatus. We analysed behaviours of 50 male and 50 female guppies over 4800 trials where a moving stimulus pattern was presented to each guppy. We found that wavelength, position and speed of the stimuli influenced male and female behaviour and seems to be mediated by the long wavelength sensitive photoreceptors. Males also had stronger behavioural responses than females whereas females performed more foraging-related pecking behaviour. Our results suggest that the spatial requirement of visual tasks and their ecological context are important and appear to be partly correlated with photoreceptor arrangement in the retina.

Published

2019

4. Morphological Plasticity of the Retina of Viperidae Snakes Is Associated With Ontogenetic Changes in Ecology and Behavior.

Author

Tashiro, Juliana H., Ventura, Dora F., and Hauzman, Einat

Subjects

PHOTORECEPTORS, VIPERIDAE, SNAKES, VISUAL fields, RETINA, COLUBRIDAE, CROTALUS

Abstract

Snakes of the Viperidae family have retinas adapted to low light conditions, with high packaging of rod-photoreceptors containing the rhodopsin photopigment (RH1), and three types of cone-photoreceptors, large single and double cones with long-wavelength sensitive opsins (LWS), and small single cones with short-wavelength sensitive opsins (SWS1). In this study, we compared the density and distribution of photoreceptors and ganglion cell layer (GCL) cells in whole-mounted retinas of two viperid snakes, the lancehead Bothrops jararaca and the rattlesnake Crotalus durissus , and we estimated the upper limits of spatial resolving power based on anatomical data. The ground-dwelling C. durissus inhabits savannah-like habitats and actively searches for places to hide before using the sit-and-wait hunting strategy to ambush rodents. B. jararaca inhabits forested areas and has ontogenetic changes in ecology and behavior. Adults are terrestrial and use similar hunting strategies to those used by rattlesnakes to prey on rodents. Juveniles are semi-arboreal and use the sit-and-wait strategy and caudal luring to attract ectothermic prey. Our analyses showed that neuronal densities were similar for the two species, but their patterns of distribution were different between and within species. In adults and juveniles of C. durissus , cones were distributed in poorly defined visual streaks and rods were concentrated in the dorsal retina, indicating higher sensitivity in the lower visual field. In adults of B. jararaca , both cones and rods were distributed in poorly defined visual streaks, while in juveniles, rods were concentrated in the dorsal retina and cones in the ventral retina, enhancing sensitivity in the lower visual field and visual acuity in the upper field. The GCL cells had peak densities in the temporal retina of C. durissus and adults of B. jararaca , indicating higher acuity in the frontal field. In juveniles of B. jararaca , the peak density of GCL cells in the ventral retina indicates better acuity in the upper field. The estimated visual acuity varied from 2.3 to 2.8 cycles per degree. Our results showed interspecific differences and suggest ontogenetic plasticity of the retinal architecture associated with changes in the niche occupied by viperid snakes, and highlight the importance of the retinal topography for visual ecology and behavior of snakes. [ABSTRACT FROM AUTHOR]

Published

2022

5. Ganglion Cell Topography and Retinal Resolution in an Irrawaddy Dolphin (Orcaella brevirostris).

Author

Mass, Alla M. and Supin, Alexander Ya.

Subjects

*RETINAL ganglion cells, *VISUAL fields, *RETINA, *PTERYGOPALATINE ganglion

Abstract

The topographic distribution of retinal ganglion cells was investigated in a retinal wholemount of an Irrawaddy dolphin (Orcaella brevirostris). Two zones of increased concentration of ganglion cells were observed--one in the temporal segment and the other in the nasal segment of the retina. The maximal cell concentration was 250 cell/mm2 in the temporal area and 194 cell/mm2 in the nasal area. Based on the posterior nodal distance of 11 mm, the resolution was evaluated as 19.8 arc min in the temporal retinal area (the frontal visual field) and 22.4 arc min in the nasal retinal area (the temporal visual field). Among retinal ganglion cells, a group of giant cells that ranged from 42 to 52 μm in diameter were observed; these cells represented 8% of the total population. The obtained data allowed us to suggest that the presence of two areas of concentrated ganglion cells is characteristic of many delphinids inhabiting both clear oceanic waters or turbid river waters, whereas low ganglion cell density is associated with optic properties of the media. [ABSTRACT FROM AUTHOR]

Published

2022

6. Retinal topography in two species of flamingo (Phoenicopteriformes: Phoenicopteridae).

Author

Lisney, Thomas J., Potier, Simon, Isard, Pierre‐François, Mentek, Marielle, Mitkus, Mindaugas, and Collin, Shaun P.

Abstract

In this study, we assessed eye morphology and retinal topography in two flamingo species, the Caribbean flamingo (Phoenicopterus ruber) and the Chilean flamingo (P. chilensis). Eye morphology is similar in both species and cornea size relative to eye size (C:A ratio) is intermediate between those previously reported for diurnal and nocturnal birds. Using stereology and retinal whole mounts, we estimate that the total number of Nissl‐stained neurons in the retinal ganglion cell (RGC) layer in the Caribbean and Chilean flamingo is ~1.70 and 1.38 million, respectively. Both species have a well‐defined visual streak with a peak neuron density of between 13,000 and 16,000 cells mm−2 located in a small central area. Neurons in the high‐density regions are smaller and more homogeneous compared to those in medium‐ and low‐density regions. Peak anatomical spatial resolving power in both species is approximately 10–11 cycles/deg. En‐face images of the fundus in live Caribbean flamingos acquired using spectral domain optical coherence tomography (SD‐OCT) revealed a thin, dark band running nasotemporally just dorsal to the pecten, which aligned with the visual streak in the retinal topography maps. Cross‐sectional images (B‐scans) obtained with SD‐OCT showed that this dark band corresponds with an area of retinal thickening compared to adjacent areas. Neither the retinal whole mounts, nor the SD‐OCT imaging revealed any evidence of a central fovea in either species. Overall, we suggest that eye morphology and retinal topography in flamingos reflects their cathemeral activity pattern and the physical nature of the habitats in which they live. [ABSTRACT FROM AUTHOR]

Published

2020

7. Visual system diversity in coral reef fishes.

Author

Cortesi, Fabio, Mitchell, Laurie J., Tettamanti, Valerio, Fogg, Lily G., de Busserolles, Fanny, Cheney, Karen L., and Marshall, N. Justin

Subjects

*CORAL reef fishes, *EYE, *RHODOPSIN, *REEF fishes, *SPECTRAL sensitivity, *VISUAL pigments, *RETINA, *MELANOPSIN

Abstract

Coral reefs are one of the most species rich and colourful habitats on earth and for many coral reef teleosts, vision is central to their survival and reproduction. The diversity of reef fish visual systems arises from variations in ocular and retinal anatomy, neural processing and, perhaps most easily revealed by, the peak spectral absorbance of visual pigments. This review examines the interplay between retinal morphology and light environment across a number of reef fish species, but mainly focusses on visual adaptations at the molecular level (i.e. visual pigment structure). Generally, visual pigments tend to match the overall light environment or micro-habitat, with fish inhabiting greener, inshore waters possessing longer wavelength-shifted visual pigments than open water blue-shifted species. In marine fishes, particularly those that live on the reef, most species have between two (likely dichromatic) to four (possible tetrachromatic) cone spectral sensitivities and a single rod for crepuscular vision; however, most are trichromatic with three spectral sensitivities. In addition to variation in spectral sensitivity number, spectral placement of the absorbance maximum (λ max) also has a surprising degree of variability. Variation in ocular and retinal anatomy is also observed at several levels in reef fishes but is best represented by differences in arrangement, density and distribution of neural cell types across the retina (i.e. retinal topography). Here, we focus on the seven reef fish families most comprehensively studied to date to examine and compare how behaviour, environment, activity period, ontogeny and phylogeny might interact to generate the exceptional diversity in visual system design that we observe. [ABSTRACT FROM AUTHOR]

Published

2020

8. Microhabitat partitioning correlates with opsin gene expression in coral reef cardinalfishes (Apogonidae).

Author

Luehrmann, Martin, Cortesi, Fabio, Cheney, Karen L., Busserolles, Fanny, Marshall, N. Justin, and Miller, Christine

Subjects

*CORAL reefs & islands, *ECOLOGICAL niche, *GENE expression, *EYE, *CORAL reef fishes, *GENE expression in fishes

Abstract

Fish are the most diverse vertebrate group, and they have evolved equally diverse visual systems, varying in terms of eye morphology, number and distribution of spectrally distinct photoreceptor types, visual opsin genes and opsin gene expression levels.This variation is mainly due to adaptations driven by two factors: differences in the light environments and behavioural tasks. However, while the effects of large‐scale habitat differences are well described, it is less clear whether visual systems also adapt to differences in environmental light at the microhabitat level.To address this, we assessed the relationship between microhabitat use and visual system features in fishes inhabiting coral reefs, where habitat partitioning is particularly common.We suggest that differences in microhabitat use by cardinalfishes (Apogonidae) drive morphological and molecular adaptations in their visual systems. To test this, we investigated diurnal microhabitat use in 17 cardinalfish species and assessed whether this correlated with differences in visual opsin gene expression and eye morphology.We found that cardinalfishes display six types of microhabitat partitioning behaviours during the day, ranging from specialists found exclusively in the water column to species that are always hidden inside the reef matrix.Species predominantly found in exposed microhabitats had higher expression of the short‐wavelength‐sensitive violet opsin (SWS2B) and lower expression of the dim‐light active rod opsin (RH1). Species of intermediate exposure, on the other hand, expressed opsins that are mostly sensitive to the blue‐green central part of the light spectrum (SWS2As and RH2s), while fishes entirely hidden in the reef substrate had a higher expression of the long‐wavelength‐sensitive red opsin.We also found that eye size relative to body size differed between cardinalfish species, and relative eye size decreased with an increase in habitat exposure.Retinal topography did not show co‐adaptation with microhabitat use, but data suggested co‐adaptation with feeding mode.We suggest that, although most cardinalfishes are nocturnal foragers, their visual systems—and possibly those of other (reef) fishes—have also adapted to the light intensity and the light spectrum of their preferred diurnal microhabitats. A free Plain Language Summary can be found within the Supporting Information of this article. [ABSTRACT FROM AUTHOR]

Published

2020

9. Retinal topography and microhabitat diversity in a group of dragon lizards.

Author

Nagloo, Nicolas, Coimbra, João Paulo, Hoops, Daniel, Hart, Nathan S., Collin, Shaun P., and Hemmi, Jan M.

Abstract

The well‐studied phylogeny and ecology of dragon lizards and their range of visually mediated behaviors provide an opportunity to examine the factors that shape retinal organization. Dragon lizards consist of three evolutionarily stable groups based on their shelter type, including burrows, shrubs, and rocks. This allows us to test whether microhabitat changes are reflected in their retinal organization. We examined the retinae of three burrowing species (Ctenophorus pictus, C. gibba, and C. nuchalis), and three species that shelter in rock crevices (C. ornatus, C. decresii, and C. vadnappa). We used design‐based stereology to sample both the photoreceptor array and neurons within the retinal ganglion cell layer to estimate areas specialized for acute vision. All species had two retinal specializations mediating enhanced spatial acuity: a fovea in the retinal center and a visual streak across the retinal equator. Furthermore, all species featured a dorsoventrally asymmetric photoreceptor distribution with higher photoreceptor densities in the ventral retina. This dorsoventral asymmetry may provide greater spatial summation of visual information in the dorsal visual field. Burrow‐dwelling species had significantly larger eyes, higher total numbers of retinal cells, higher photoreceptor densities in the ventral retina, and higher spatial resolving power than rock‐dwelling species. C. pictus, a secondary burrow‐dwelling species, was the only species that changed burrow usage over evolutionary time, and its retinal organization revealed features more similar to rock‐dwelling species than other burrow‐dwelling species. This suggests that phylogeny may play a substantial role in shaping retinal organization in Ctenophorus species compared to microhabitat occupation. [ABSTRACT FROM AUTHOR]

Published

2020

10. Retinal Ganglion Cell Topography and Spatial Resolving Power in Echolocating and Non-Echolocating Bats.

Author

Cechetto, Clément, de Busserolles, Fanny, Jakobsen, Lasse, and Warrant, Eric J.

Subjects

*RETINAL ganglion cells, *BATS, *VESPERTILIONIDAE, *TOPOGRAPHY

Abstract

Bats are nocturnal mammals known for their ability to echolocate, yet all bats can see, and most bats of the family Pteropodidae (fruit bats) do not echolocate – instead they rely mainly on vision and olfaction to forage. We investigated whether echolocating bats, given their limited reliance on vision, have poorer spatial resolving power (SRP) than pteropodids and whether tongue click echolocating fruit bats differ from non-echolocating fruit bats in terms of visual performance. We compared the number and distribution of retinal ganglion cells (RGCs) as well as the maximum anatomical SRP derived from these distributions in 4 species of bats: Myotis daubentonii, a laryngeal echolocating bat from the family Vespertilionidae, Rousettus aegyptiacus, a tongue clicking echolocating bat from the family Pteropodidae, and Pteropus alecto and P. poliocephalus, 2 non-echolocating bats (also from the Pteropodidae). We find that all 3 pteropodids have a similar number (≈200,000 cells) and distribution of RGCs and a similar maximum SRP (≈4 cycles/degree). M. daubentonii has fewer (∼6,000 cells) and sparser RGCs than the pteropodids and thus a significantly lower SRP (0.6 cycles/degree). M. daubentonii also differs in terms of the distribution of RGCs by having a unique dorsal area of specialization in the retina. Our findings are consistent with the existing literature and suggest that M. daubentonii likely only uses vision for orientation, while for pteropodids vision is also important for foraging. [ABSTRACT FROM AUTHOR]

Published

2020

11. Unusual topographic specializations of retinal ganglion cell density and spatial resolution in a cliff‐dwelling artiodactyl, the Nubian ibex (Capra nubiana).

Author

Coimbra, João Paulo, Alagaili, Abdulaziz N., Bennett, Nigel C., Mohammed, Osama B., and Manger, Paul R.

Abstract

The Nubian ibex (Capra nubiana) occurs in information‐rich visual habitats including the edges of cliffs and escarpments. In addition to needing enhanced spatial resolution to find food and detect predators, enhanced visual sampling of the lower visual field would be advantageous for the control of locomotion in such precarious terrains. Using retinal wholemounts and stereology, we sought to measure how the ganglion cell density varies across the retina of the Nubian ibex to reveal which portions of its surroundings are sampled with high resolution. We estimated a total of ~1 million ganglion cells in the Nubian ibex retinal ganglion cell layer. Topographic variations of ganglion cell density reveal a temporal area, a horizontal streak, and a dorsotemporal extension, which are topographic retinal features also found in other artiodactyls. In contrast to savannah‐dwelling artiodactyls, the horizontal streak of the Nubian ibex appears loosely organized possibly reflecting a reduced predation risk in mountainous habitats. Estimates of spatial resolving power (~17 cycles/degree) for the temporal area would be reasonable to facilitate foraging in the frontal visual field. Embedded in the dorsotemporal extension, we also found an unusual dorsotemporal area not yet reported in any other mammal. Given its location and spatial resolving power (~6 cycles/degree), this specialization enhances visual sampling toward the lower visual field, which would be advantageous for visually guided locomotion. This study expands our understanding of the retinal organization in artiodactyls and offers insights on the importance of vision for the Nubian ibex ecology. [ABSTRACT FROM AUTHOR]

Published

2019

12. Anatomical Analysis of the Retinal Specializations to a Crypto-Benthic, Micro-Predatory Lifestyle in the Mediterranean Triplefin Blenny Tripterygion delaisi

Author

Roland Fritsch, Shaun P. Collin, and Nico K. Michiels

Subjects

Tripterygion delaisi, visual ecology, retinal wholemount technique, retinal specializations, retinal topography, visual acuity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

The environment and lifestyle of a species are known to exert selective pressure on the visual system, often demonstrating a tight link between visual morphology and ecology. Many studies have predicted the visual requirements of a species by examining the anatomical features of the eye. However, among the vast number of studies on visual specializations in aquatic animals, only a few have focused on small benthic fishes that occupy a heterogeneous and spatially complex visual environment. This study investigates the general retinal anatomy including the topography of both the photoreceptor and ganglion cell populations and estimates the spatial resolving power (SRP) of the eye of the Mediterranean triplefin Tripterygion delaisi. Retinal wholemounts were prepared to systematically and quantitatively analyze photoreceptor and retinal ganglion cell (RGC) densities using design-based stereology. To further examine the retinal structure, we also used magnetic resonance imaging (MRI) and histological examination of retinal cross sections. Observations of the triplefin’s eyes revealed them to be highly mobile, allowing them to view the surroundings without body movements. A rostral aphakic gap and the elliptical shape of the eye extend its visual field rostrally and allow for a rostro-caudal accommodatory axis, enabling this species to focus on prey at close range. Single and twin cones dominate the retina and are consistently arranged in one of two regular patterns, which may enhance motion detection and color vision. The retina features a prominent, dorso-temporal, convexiclivate fovea with an average density of 104,400 double and 30,800 single cones per mm2, and 81,000 RGCs per mm2. Based on photoreceptor spacing, SRP was calculated to be between 6.7 and 9.0 cycles per degree. Location and resolving power of the fovea would benefit the detection and identification of small prey in the lower frontal region of the visual field.

Published

2017

13. Retinal dysfunction characterizes subtypes of dominant optic atrophy.

Author

Cascavilla, Maria Lucia, Triolo, Giacinto, Borrelli, Enrico, Darvizeh, Fatima, Bandello, Francesco, Barboni, Piero, Parisi, Vincenzo, Ziccardi, Lucia, Di Renzo, Antonio, Balducci, Nicole, Lamperti, Costanza, Bianchi Marzoli, Stefania, Sadun, Alfredo A., and Carelli, Valerio

Subjects

*RETINAL diseases, *ATROPHY, *PHOTORECEPTORS, *GENETIC mutation, *TOPOGRAPHY

Abstract

Abstract: Purpose: To assess preganglionic retinal function using multifocal electroretinogram (mfERG) in patients affected by dominant optic atrophy (DOA) stratified by OPA1 gene mutation. Methods: Multifocal electroretinogram (mfERG) was recorded in 18 DOA patients (DOA group, 35 eyes) and 25 age‐matched healthy subjects (control group, 25 eyes). Patients were stratified in two groups based on gene mutation: missense mutation (DOA‐M group, 11 eyes) and mutation causing haploinsufficiency (DOA‐H group, 24 eyes). The mfERG N1‐P1 response amplitude density (RAD) has been evaluated in five annular retinal areas with different eccentricity from the fovea (ring 1: 0–5 degrees, R1; ring 2: 5–10 degrees, R2; ring 3: 10–15 degrees, R3; ring 4: 15–20 degrees, R4; and ring 5: 20–25 degrees, R5) and in eight sectors on the basis of the retinal topography: temporal–superior (TS), temporal–inferior (TI), nasal–superior (NS) and nasal–inferior (NI), temporal (T), superior (S), nasal (N) and inferior (I). Results: Compared to controls, DOA group revealed a significant reduction in N1‐P1 RADs values in R1‐R4 rings and in TI, NS and N sectors [analysis of variance (ANOVA), p < 0.01). DOA‐M group showed a significant reduction in N1‐P1 RADs values in R1‐R5 rings and in TI, NS, NI, T, N and I sectors (p < 0.01). Dominant optic atrophy‐H (DOA‐H) group displayed only a significant (p < 0.01) reduction in N1‐P1 RADs values, exclusively in R1 and in the NS sector. Conclusion: Preganglionic retinal impairment occurs in DOA with a clear genotype to retinal dysfunction association. Missense mutations are characterized by a far more severe functional impairment. [ABSTRACT FROM AUTHOR]

Published

2018

14. Anatomical Analysis of the Retinal Specializations to a Crypto-Benthic, Micro-Predatory Lifestyle in the Mediterranean Triplefin Blenny Tripterygion delaisi.

Author

Fritsch, Roland, Collin, Shaun P., and Michiels, Nico K.

Subjects

EYE anatomy, PHOTORECEPTORS, COLOR vision, RETINAL ganglion cells, STEREOLOGY

Abstract

The environment and lifestyle of a species are known to exert selective pressure on the visual system, often demonstrating a tight link between visual morphology and ecology. Many studies have predicted the visual requirements of a species by examining the anatomical features of the eye. However, among the vast number of studies on visual specializations in aquatic animals, only a few have focused on small benthic fishes that occupy a heterogeneous and spatially complex visual environment. This study investigates the general retinal anatomy including the topography of both the photoreceptor and ganglion cell populations and estimates the spatial resolving power (SRP) of the eye of the Mediterranean triplefin Tripterygion delaisi. Retinal wholemounts were prepared to systematically and quantitatively analyze photoreceptor and retinal ganglion cell (RGC) densities using design-based stereology. To further examine the retinal structure, we also used magnetic resonance imaging (MRI) and histological examination of retinal cross sections. Observations of the triplefin's eyes revealed them to be highly mobile, allowing them to view the surroundings without body movements. A rostral aphakic gap and the elliptical shape of the eye extend its visual field rostrally and allow for a rostro-caudal accommodatory axis, enabling this species to focus on prey at close range. Single and twin cones dominate the retina and are consistently arranged in one of two regular patterns, which may enhance motion detection and color vision. The retina features a prominent, dorso-temporal, convexiclivate fovea with an average density of 104,400 double and 30,800 single cones per mm², and 81,000 RGCs per mm². Based on photoreceptor spacing, SRP was calculated to be between 6.7 and 9.0 cycles per degree. Location and resolving power of the fovea would benefit the detection and identification of small prey in the lower frontal region of the visual field. [ABSTRACT FROM AUTHOR]

Published

2017

15. Retinal ganglion cell topography and spatial resolving power in the river hippopotamus ( Hippopotamus amphibius).

Author

Coimbra, João Paulo, Bertelsen, Mads F., and Manger, Paul R.

Abstract

The river hippopotamus ( Hippopotamus amphibius), one of the closest extant relatives to cetaceans, is a large African even-toed ungulate (Artiodactyla) that grazes and has a semiaquatic lifestyle. Given its unusual phenotype, ecology, and evolutionary history, we sought to measure the topographic distribution of retinal ganglion cell density using stereology and retinal wholemounts. We estimated a total of 243,000 ganglion cells of which 3.4% (8,300) comprise alpha cells. The topographic distribution of both total and alpha cells reveal a dual topographic organization of a temporal and nasal area embedded within a well-defined horizontal streak. Using maximum density of total ganglion cells and eye size (35 mm, axial length), we estimated upper limits of spatial resolving power of 8 cycles/deg (temporal area, 1,800 cells/mm2), 7.7 cycles/deg (nasal area, 1,700 cells/mm2), and 4.2 cycles/deg (horizontal streak, 250 cells/mm2). Enhanced resolution of the temporal area toward the frontal visual field may facilitate grazing, while resolution of the horizontal streak and nasal area may help the discrimination of objects (predators, conspecifics) in the lateral and posterior visual fields, respectively. Given the presumed role of alpha cells to detect brisk transient stimuli, their similar distribution to the total ganglion cell population may facilitate the detection of approaching objects in equivalent portions of the visual field. Our finding of a nasal area in the river hippopotamus retina supports the notion that this specialization may enhance visual sampling in the posterior visual field to compensate for limited neck mobility as suggested for rhinoceroses and cetaceans. [ABSTRACT FROM AUTHOR]

Published

2017

16. Retinal ganglion cell topography and spatial resolving power in the white rhinoceros ( Ceratotherium simum).

Author

Coimbra, João Paulo and Manger, Paul R.

Abstract

ABSTRACT This study sought to determine whether the retinal organization of the white rhinoceros ( Ceratotherium simum), a large African herbivore with lips specialized for grazing in open savannahs, relates to its foraging ecology and habitat. Using stereology and retinal wholemounts, we estimated a total of 353,000 retinal ganglion cells. Their density distribution reveals an unusual topographic organization of a temporal (2,000 cells/mm2) and a nasal (1,800 cells/mm2) area embedded within a well-defined horizontal visual streak (800 cells/mm2), which is remarkably similar to the retinal organization in the black rhinoceros. Alpha ganglion cells comprise 3.5% (12,300) of the total population of ganglion cells and show a similar distribution pattern with maximum densities also occurring in the temporal (44 cells/mm2) and nasal (40 cells/mm2) areas. We found higher proportions of alpha cells in the dorsal and ventral retinas. Given their role in the detection of brisk transient stimuli, these higher proportions may facilitate the detection of approaching objects from the front and behind while grazing with the head at 45 °. Using ganglion cell peak density and eye size (29 mm, axial length), we estimated upper limits of spatial resolving power of 7 cycles/deg (temporal area), 6.6 cycles/deg (nasal area), and 4.4 cycles/deg (horizontal streak). The resolution of the temporal area potentially assists with grazing, while the resolution of the streak may be used for panoramic surveillance of the horizon. The nasal area may assist with detection of approaching objects from behind, potentially representing an adaptation compensating for limited neck and head mobility. J. Comp. Neurol., 525:2484-2498, 2017. © 2017 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2017

17. Comparison of functional and anatomical estimations of visual acuity in two species of coral reef fish.

Author

Parker, Amira N., Fritsches, Kerstin A., Newport, Cait, Wallis, Guy, and Siebeck, Ulrike E.

Subjects

*CORAL reef ecology, *VISUAL acuity, *CAMOUFLAGE (Biology), *FUNCTIONAL analysis, *HERBIVORES

Abstract

The high-contrast, complex patterns typical of many reef fish serve several purposes, including providing disruptive camouflage and a basis for vision-based communication. In trying to understand the role of a specific pattern, it is important to first assess the extent to which an observer can resolve the pattern, itself determined, at least in part, by the observer's visual acuity. Here, we studied the visual acuity of two species of reef fish - Pomacentrus amboinensis and Pseudochromis fuscus - using both anatomical and behavioural estimates. The two species share a common habitat but are members of different trophic levels (predator versus herbivore/omnivore) and perform different visual tasks. On the basis of the anatomical study, we estimated visual acuity to lie between 4.1 and 4.6 cycles deg-1 for P. amboinensis and 3.2 and 3.6 cycles deg-1 for P. fuscus. Behavioural acuity estimates were considerably lower, ranging between 1.29 and 1.36 cycles deg-1 for P. amboinensis and 1.61 and 1.71 cycles deg-1 for P. fuscus. Our results show that two species from the same habitat have only moderately divergent visual capabilities, despite differences in their general life histories. The difference between anatomical and behavioural estimates is an important finding as the majority of our current knowledge on the resolution capabilities of reef fish comes from anatomical measurements. Our findings suggest that anatomical estimates may represent the highest potential acuity of fish but are not indicative of actual performance, and that there is unlikely to be a simple scaling factor to link the two measures across all fish species. [ABSTRACT FROM AUTHOR]

Published

2017

18. Retinal ganglion cell topography and spatial resolving power in African megachiropterans: Influence of roosting microhabitat and foraging.

Author

Coimbra, João Paulo, Pettigrew, John D., Kaswera‐Kyamakya, Consolate, Gilissen, Emmanuel, Collin, Shaun P., and Manger, Paul R.

Abstract

ABSTRACT Megachiropteran bats (megabats) show remarkable diversity in microhabitat occupation and trophic specializations, but information on how vision relates to their behavioral ecology is scarce. Using stereology and retinal wholemounts, we measured the topographic distribution of retinal ganglion cells and determined the spatial resolution of eight African megachiropterans with distinct roosting and feeding ecologies. We found that species roosting in open microhabitats have a pronounced streak of high retinal ganglion cell density, whereas those favoring more enclosed microhabitats have a less pronounced streak (or its absence in Hypsignathus monstrosus). An exception is the cave-dwelling Rousettus aegyptiacus, which has a pronounced horizontal streak that potentially correlates with its occurrence in more open environments during foraging. In all species, we found a temporal area with maximum retinal ganglion cell density (∼5,000-7,000 cells/mm2) that affords enhanced resolution in the frontal visual field. Our estimates of spatial resolution based on peak retinal ganglion cell density and eye size (∼6-12 mm in axial length) range between ∼2 and 4 cycles/degree. Species that occur in more enclosed microhabitats and feed on plant material have lower spatial resolution (∼2 cycles/degree) compared with those that roost in open and semiopen areas (∼3-3.8 cycles/degree). We suggest that the larger eye and concomitant higher spatial resolution (∼4 cycles/degree) in H. monstrosus may have facilitated the carnivorous aspect of its diet. In conclusion, variations in the topographic organization and magnitude of retinal ganglion density reflect the specific ecological needs to detect food/predators and the structural complexity of the environments. J. Comp. Neurol. 525:186-203, 2017. © 2016 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2017

19. Sex differences in behavioural and anatomical estimates of visual acuity in the green swordtail, Xiphophorus helleri

Author

Eleanor M. Caves, Fanny de Busserolles, and Laura A. Kelley

Subjects

Male, Retinal Ganglion Cells, 0106 biological sciences, Sensory ecology, Visual acuity, genetic structures, Physiology, media_common.quotation_subject, Visual Acuity, Zoology, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, Retinal ganglion, Retina, Retinal topography, Courtship, Cyprinodontiformes, 03 medical and health sciences, 0302 clinical medicine, Optomotor, Agonistic behaviour, medicine, Animals, Humans, 14. Life underwater, Molecular Biology, Ecology, Evolution, Behavior and Systematics, media_common, Poeciliidae, Sex Characteristics, Spatial resolution, biology, Visual signal, Xiphophorus, biology.organism_classification, Sexual dimorphism, Mate choice, Insect Science, Female, Animal Science and Zoology, medicine.symptom, 030217 neurology & neurosurgery, Research Article

Abstract

Among fishes in the family Poeciliidae, signals such as colour patterns, ornaments and courtship displays play important roles in mate choice and male–male competition. Despite this, visual capabilities in poeciliids are understudied, in particular, visual acuity, the ability to resolve detail. We used three methods to quantify visual acuity in male and female green swordtails (Xiphophorus helleri), a species in which body size and the length of the male's extended caudal fin (‘sword’) serve as assessment signals during mate choice and agonistic encounters. Topographic distribution of retinal ganglion cells (RGCs) was similar in all individuals and was characterized by areas of high cell densities located centro-temporally and nasally, as well as a weak horizontal streak. Based on the peak density of RGCs in the centro-temporal area, anatomical acuity was estimated to be approximately 3 cycles per degree (cpd) in both sexes. However, a behavioural optomotor assay found significantly lower mean acuity in males (0.8 cpd) than females (3.0 cpd), which was not explained by differences in eye size between males and females. An additional behavioural assay, in which we trained individuals to discriminate striped gratings from grey stimuli of the same mean luminance, also showed lower acuity in males (1–2 cpd) than females (2–3 cpd). Thus, although retinal anatomy predicts identical acuity in males and females, two behavioural assays found higher acuity in females than males, a sexual dimorphism that is rare outside of invertebrates. Overall, our results have implications for understanding how poeciliids perceive visual signals during mate choice and agonistic encounters., Summary: Anatomical and behavioural quantification of visual acuity (spatial resolving power) in green swordtails indicates that acuity was anatomically identical in both sexes, but behaviourally higher in females, with implications for signalling.

Published

2021

20. Spatial resolving power and spectral sensitivity of the saltwater crocodile, Crocodylus porosus, and the freshwater crocodile, Crocodylus johnstoni.

Author

Nagloo, Nicolas, Collin, Shaun P., Hemmi, Jan M., and Hart, Nathan S.

Subjects

*SPECTRAL sensitivity, *CROCODYLUS porosus, *MICROSPECTROPHOTOMETRY, *PHOTORECEPTORS, *REPTILE ecology

Abstract

Crocodilians are apex amphibious predators that occupy a range of tropical habitats. In this study, we examined whether their semiaquatic lifestyle and ambush hunting mode are reflected in specific adaptations in the peripheral visual system. Design-based stereology and microspectrophotometry were used to assess spatial resolving power and spectral sensitivity of saltwater (Crocodylus porosus) and freshwater crocodiles (Crocodylus johnstoni). Both species possess a foveal streak that spans the naso-temporal axis and mediates high spatial acuity across the central visual field. The saltwater crocodile and freshwater crocodile have a peak spatial resolving power of 8.8 and 8.0 cycles deg-1, respectively. Measurement of the outer segment dimensions and spectral absorbance revealed five distinct photoreceptor types consisting of three single cones, one twin cone and a rod. The three single cones (saltwater/freshwater crocodile) are violet (424/426 nm λmax), green (502/510 nm λmax) and red (546/ 554 nm λmax) sensitive, indicating the potential for trichromatic colour vision. The visual pigments of both members of the twin cones have the same λmax as the red-sensitive single cone and the rod has a λmax at 503/510 nm (saltwater/freshwater). The λmax values of all types of visual pigment occur at longer wavelengths in the freshwater crocodile compared with the saltwater crocodile. Given that there is a greater abundance of long wavelength light in freshwater compared with a saltwater environment, the photoreceptors would be more effective at detecting light in their respective habitats. This suggests that the visual systems of both species are adapted to the photic conditions of their respective ecological niche. [ABSTRACT FROM AUTHOR]

Published

2016

21. Comparison of the Visual Capabilities of an Amphibious and an Aquatic Goby That Inhabit Tidal Mudflats.

Author

Takiyama, Tomo, Hamasaki, Sawako, and Yoshida, Masayuki

Subjects

*GOBIIDAE, *TIDAL flats, *RETINAL ganglion cells, *VISUALIZATION, *FISH feeds, *PHYSIOLOGY

Abstract

The mudskipper Periophthalmus modestus and the yellowfin goby Acanthogobius flavimanus are gobiid teleosts that both inhabit the intertidal mudflats in estuaries. While P. modestus has an amphibious lifestyle and forages on the exposed mudflat during low tide, the aquatic A. flavimanus can be found at the same mudflat at high tide. This study primarily aimed to elucidate the differential adaptations of these organisms to their respective habitats by comparing visual capacities and motor control in orienting behavior during prey capture. Analyses of retinal ganglion cell topography demonstrated that both species possess an area in the dorsotemporal region of the retina, indicating high acuity in the lower frontal visual field. Additionally, P. modestus has a minor area in the nasal portion of the retina near the optic disc. The horizontally extended specialized area in P. modestus possibly reflects the need for optimized horizontal sight on the exposed mudflat. Behavioral experiments to determine postural and eye direction control when orienting toward the object of interest revealed that these species direct their visual axes to the target situated below eye level just before a rapid approach toward it. A characteristic feature of the orienting behavior of P. modestus was that they aimed at the target by using the specialized retinal area by rotating the eye and lifting the head before jumping to attack the target located above eye level. This behavior could be an adaptation to a terrestrial feeding habitat in which buoyancy is irrelevant. This study provides insights into the adaptive mechanisms of gobiid species and the evolutionary changes enabling them to forage on land. [ABSTRACT FROM AUTHOR]

Published

2016

22. The Topographic Organization of Retinal Ganglion Cell Density and Spatial Resolving Power in an Unusual Arboreal and Slow-Moving Strepsirhine Primate, the Potto (Perodicticus potto).

Author

Coimbra, João Paulo, Kaswera-Kyamakya, Consolate, Gilissen, Emmanuel, Manger, Paul R., and Collin, Shaun P.

Subjects

*PERODICTICUS potto, *RETINAL ganglion cells, *STEREOLOGY, *ANIMAL locomotion, *PROSIMIANS

Abstract

potto (Perodicticus potto) is an arboreal strepsirhine found in the rainforests of central Africa. In contrast to most primates, the potto shows slow-moving locomotion over the upper surface of branches, where it forages for exudates and crawling invertebrates with its head held very close to the substrate. Here, we asked whether the retina of the potto displays topographic specializations in neuronal density that correlate with its unusual lifestyle. Using stereology and retinal wholemounts, we measured the total number and topographic distribution of retinal ganglion cells (total and presumed parasol), as well as estimating the upper limits of the spatial resolution of the potto eye. We estimated ~ 210,000 retinal ganglion cells, of which ~ 7% (~ 14,000) comprise presumed parasol ganglion cells. The topographic distribution of both total and parasol ganglion cells reveals a concentric centroperipheral organization with a nasoventral asymmetry. Combined with the upwardly shifted orbits of the potto, this nasoventral increase in parasol ganglion cell density enhances contrast sensitivity and motion detection skywards, which potentially assists with the detection of predators in the high canopy. The central area of the potto occurs ~ 2.5 mm temporal to the optic disc and contains a maximum ganglion cell density of ~ 4,300 cells/mm 2 . We found no anatomical evidence of a fovea within this region. Using maximum ganglion cell density and eye size (~ 14 mm), we estimated upper limits of spatial resolving power between 4.1 and 4.4 cycles/degree. Despite their reported reliance on olfaction to detect exudates, this level of spatial resolution potentially assists pottos with foraging for small invertebrates and in the detection of predators. [ABSTRACT FROM AUTHOR]

Published

2016

23. Retinal specialisations in the dogfish Centroscymnus coelolepis from the Mediterranean deep-sea

Author

Anna Bozzano

Subjects

deep-sea shark, retinal morphology, retinal topography, large ganglion cells, visual axes, diet, Aquaculture. Fisheries. Angling, SH1-691

Abstract

The present work attempted to study the importance of vision in Centroscymnuscoelolepis, the most abundant shark in the Mediterranean beyond a depthof 1000 m, by using anatomical and histological data. C.coelolepis exhibited large lateral eyes with a large pupil, spherical lens and a tapetum lucidum that gave the eye a strong greenish-golden “eye shine”. In the outer retinal layer, a uniform population of rod-like photoreceptors was observed while in the vitreal retina a thick inner plexiform layer comprised up to 30% of the whole retinal thickness. The cell distribution of the ganglion cell layer formed a thin elongated visual streak in the central plane of the eye that provided a horizontal panoramic field of view. A specialised area of higher visual acuity was located caudally at 32-44º from the geometric centre of the retina and 5-10º above the horizontal plane of the eye. This position indicated that the visual axis pointed in a slightly outward-forward direction with respect to the fish body axis. A non-uniform distribution of large ganglion cells was also found in the horizontal plane of the retina that practically coincided with the distribution of the total cell population in the ganglion cell layer. This is the first time that this type of retinal specialisation has been observed in the elasmobranchs. These characteristics indicate that the retina of C.coelolepis is designed not only to increase sensitivity in the horizontal field of view, as was also observed in other sharks, but also to improve motion detection in the same plane. The visual capacities evolved by C.coelolepis make this species adapted for discriminating the horizontal gradation of light that exists in the mesopelagic environment. Similarly, the large ganglion cell distribution observed in its retina seems to be related to its predatory behaviour, since it allows this shark to perceive the movement of bioluminescent prey against a totally dark background.

Published

2004

24. Distribution of melanopsin positive neurons in pigmented and albino mice: Evidence for melanopsin interneurons in the mouse retina

Author

Francisco Javier Valiente-Soriano, Diego eGarcía-Ayuso, Arturo eOrtín-Martínez, Manuel eJiménez-López, Caridad eGalindo-Romero, María Paz Villegas-Pérez, Marta eAgudo-Barriuso, Anthony Alexander Vugler, and Manuel eVidal-Sanz

Subjects

interneuron, spatial distribution, Brn3a, melanopsin retinal ganglion cells, retinal topography, ciliary marginal zone, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

Here we have studied the population of intrinsically photosensitive retinal ganglion cells (ipRGCs) in adult pigmented and albino mice. Our data show that although pigmented (C57Bl/6) and albino (Swiss) mice have a similar total number of ipRGCs, their distribution is slightly different: while in pigmented mice ipRGCs are more abundant in the temporal retina, in albinos the ipRGCs are more abundant in superior retina. In both strains, ipRGCs are located in the retinal periphery, in the areas of lower Brn3a+RGC density. Both strains also contain displaced ipRGCs (d-ipRGCs) in the inner nuclear layer that account for 14% of total ipRGCs in pigmented mice and 5% in albinos. Tracing from both superior colliculli shows that 98% (pigmented) and 97% (albino) of the total ipRGCs, become retrogradely labelled, while double immunodetection of melanopsin and Brn3a confirm that few ipRGCs express this transcription factor in mice. Rather surprisingly, application of a retrograde tracer to the optic nerve labels all ipRGCs, except for a sub-population of the d-ipRGCs (14% in pigmented and 28% in albino, respectively) and melanopsin positive cells residing in the ciliary marginal zone (CMZ) of the retina. In the CMZ, between 20% (pigmented) and 24% (albino) of the melanopsin positive cells are unlabelled by the tracer and we suggest that this may be because they fail to send an axon into the optic nerve. As such, this study provides the first evidence for a population of melanopsin interneurons in the mammalian retina.

Published

2014

25. The Retina of Ansorge's Cusimanse (Crossarchus ansorgei): Number, Topography and Convergence of Photoreceptors and Ganglion Cells in Relation to Ecology and Behavior.

Author

Coimbra, João Paulo, Kaswera-Kyamakya, Consolate, Gilissen, Emmanuel, Manger, Paul R., and Collin, Shaun P.

Subjects

*HERPESTIDAE, *ECOLOGICAL niche, *NEURONS, *RETINAL ganglion cells, *CHOROID diseases, *OPTIC disc

Abstract

The family Herpestidae (cusimanses and mongooses) is a monophyletic radiation of carnivores with remarkable variation in microhabitat occupation and diel activity, but virtually nothing is known about how they use vision in the context of their behavioral ecology. In this paper, we measured the number and topographic distribution of neurons (rods, cones and retinal ganglion cells) and estimated the spatial resolving power of the eye of the diurnal, forest-dwelling Ansorge's cusimanse (Crossarchus ansorgei). Using retinal wholemounts and stereology, we found that rods are more numerous (42,500,000; 92%) than cones (3,900,000; 8%). Rod densities form a concentric and dorsotemporally asymmetric plateau that matches the location and shape of a bright yellow tapetum lucidum located within the dorsal aspect of the eye. Maximum rod density (340,300 cells/mm2) occurs within an elongated plateau below the optic disc that corresponds to a transitional region between the tapetum lucidum and the pigmented choroid. Cone densities form a temporal area with a peak density of 44,500 cells/mm2 embedded in a weak horizontal streak that matches the topographic distribution of retinal ganglion cells. Convergence ratios of cones to retinal ganglion cells vary from 50:1 in the far periphery to 3:1 in the temporal area. With a ganglion cell peak density of 13,400 cells/mm2 and an eye size of 11 mm in axial length, we estimated upper limits of spatial resolution of 7.5-8 cycles/degree, which is comparable to other carnivores such as hyenas. In conclusion, we suggest that the topographic retinal traits described for Ansorge's cusimanse conform to a presumed carnivore retinal blueprint but also show variations that reflect its specific ecological needs. © 2015 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2015

26. Variations in retinal photoreceptor topography and the organization of the rod-free zone reflect behavioral diversity in Australian passerines.

Author

Coimbra, João Paulo, Collin, Shaun P., and Hart, Nathan S.

Abstract

ABSTRACT The avian retina possesses one of the most diverse complements of photoreceptor types among vertebrates but little is known about their spatial distribution. Here we used retinal wholemounts and stereological methods to present the first complete maps of the topographic distribution of rods and cones in four species of Australian passerines with diverse trophic specializations. All species studied have one central and one temporal rod-free zone. In the insectivorous yellow-rumped thornbill, the central rod-free zone is unusually large, occupying ∼17% (56°) of the retinal area (angular subtense), whereas in nectarivorous and frugivorous species it represents only ∼0.1% (5-7°) to 0.3% (10°) of the retinal area (angular subtense). In contrast, the temporal rod-free zone varies little between species (∼0.02-0.4%; 2-10°). In all species, rods follow a pronounced dorsoventral gradient with highest densities in the ventral retina. The topographic distribution of cones is concentric and reveals a central fovea and a temporal area. In the yellow-rumped thornbill, cone densities form an extended plateau surrounding the fovea, beyond which densities fall rapidly towards the retinal periphery. For the other species, cone densities decline gradually along a foveal to peripheral gradient. Estimates of spatial resolving power calculated using cone peak densities are higher in the central fovea (19-41 cycles/degree) than in the temporal area (9-15 cycles/degree). In conclusion, we suggest that the unusual organization of the rod-free zone and the distinct topographic distribution of rods and cones correlate with specific ecological needs for enhanced visual sensitivity and spatial resolution in these birds. J. Comp. Neurol. 523:1073-1094, 2015. © 2015 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2015

27. Retinal Ganglion Cell Distribution and Spatial Resolving Power in Deep-Sea Lanternfishes (Myctophidae).

Author

de Busserolles, Fanny, Marshall, N. Justin, and Collin, Shaun P.

Subjects

*RETINAL ganglion cells, *LANTERNFISHES, *TOPOGRAPHY, *CELL populations, *STEREOLOGY

Abstract

Topographic analyses of retinal ganglion cell density are very useful in providing information about the visual ecology of a species by identifying areas of acute vision within the visual field (i.e. areas of high cell density). In this study, we investigated the neural cell distribution in the ganglion cell layer of a range of lanternfish species belonging to 10 genera. Analyses were performed on wholemounted retinas using stereology. Topographic maps were constructed of the distribution of all neurons and both ganglion and amacrine cell populations in 5 different species from Nissl-stained retinas using cytological criteria. Amacrine cell distribution was also examined immunohistochemically in 2 of the 5 species using anti-parvalbumin antibody. The distributions of both the total neuron and the amacrine cell populations were aligned in all of the species examined, showing a general increase in cell density toward the retinal periphery. However, when the ganglion cell population was topographically isolated from the amacrine cell population, which comprised up to 80% of the total neurons within the ganglion cell layer, a different distribution was revealed. Topographic maps of the true ganglion cell distribution in 18 species of lanternfishes revealed well-defined specializations in different regions of the retina. Different species possessed distinct areas of high ganglion cell density with respect to both peak density and the location and/or shape of the specialized acute zone (i.e. elongated areae ventro-temporales, areae temporales and large areae centrales). The spatial resolving power was calculated to be relatively low (varying from 1.6 to 4.4 cycles per degree), indicating that myctophids may constitute one of the less visually acute groups of deep-sea teleosts. The diversity in retinal specializations and spatial resolving power within the family is assessed in terms of possible ecological functions and evolutionary history. © 2014 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2014

28. Topographic specializations in the retinal ganglion cell layer of Australian passerines.

Author

Coimbra, João Paulo, Collin, Shaun P., and Hart, Nathan S.

Abstract

ABSTRACT Thornbills, honeyeaters, and silvereyes represent an abundant group of Australian passerines, whose diversity in niche differentiation suggests a pivotal role for vision. Using stereological methods and retinal wholemounts, we studied the topographic distribution of neurons in the ganglion cell layer of insectivorous, nectarivorous, and frugivorous species occupying terrestrial and arboreal microhabitats. All species studied have a central convexiclivate fovea (peak densities from 130,000 to 160,000 cells/mm2), which is shallow in the terrestrial/insectivorous yellow-rumped thornbill and deep in the arboreal/nectarivorous honeyeaters and frugivorous silvereye. Surrounding the fovea, neuronal densities in the ganglion cell layer form a broadly ovoid and asymmetric plateau in the yellow-rumped thornbill and a more restricted, circular and symmetric plateau in the other species. These differences in the plateau organization may reflect specific needs to locate food on the ground or among dense vegetation. We also found a temporal area (peak densities from 43,000 to 54,000 cells/mm2) across species, which increases spatial resolution in the frontal visual field and assists with foraging. Using microtubule-associated protein 2 (MAP2) immunohistochemistry, we detected a higher concentration of giant ganglion cells forming an area gigantocellularis in the temporal retina of all species. Giant ganglion cell densities also form a horizontal streak in all species, except in the yellow-rumped thornbill, which has an unusual increase toward the retinal periphery. In the yellow-rumped thornbill and silvereye, giant ganglion cells also peak in the nasal retina. We suggest that these topographic variations afford differential sampling of motion signals for the detection of predators. J. Comp. Neurol. 522:3609-3628, 2014. © 2014 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014

29. Distribution of melanopsin positive neurons in pigmented and albino mice: evidence for melanopsin interneurons in the mouse retina.

Author

Valiente-Soriano, Francisco J., García-Ayuso, Diego, Ortín-Martínez, Arturo, Jiménez-López, Manuel, Galindo-Romero, Caridad, Villegas-Pérez, Maria Paz, Agudo-Barriuso, Marta, Vugler, Anthony A., and Vidal-Sanz, Manuel

Subjects

MELANOPSIN, INTERNEURONS, RETINAL ganglion cells, LABORATORY mice, HOMEOBOX proteins

Abstract

Here we have studied the population of intrinsically photosensitive retinal ganglion cells (ipRGCs) in adult pigmented and albino mice. Our data show that although pigmented (C57Bl/6) and albino (Swiss) mice have a similar total number of ipRGCs, their distribution is slightly different: while in pigmented mice ipRGCs are more abundant in the temporal retina, in albinos the ipRGCs are more abundant in superior retina. In both strains, ipRGCs are located in the retinal periphery, in the areas of lower Brn3a+RGC density. Both strains also contain displaced ipRGCs (d-ipRGCs) in the inner nuclear layer (INL) that account for 14% of total ipRGCs in pigmented mice and 5% in albinos. Tracing from both superior colliculli shows that 98% (pigmented) and 97% (albino) of the total ipRGCs, become retrogradely labeled, while double immunodetection of melanopsin and Brn3a confirms that few ipRGCs express this transcription factor in mice. Rather surprisingly, application of a retrograde tracer to the optic nerve (ON) labels all ipRGCs, except for a sub-population of the d-ipRGCs (14% in pigmented and 28% in albino, respectively) and melanopsin positive cells residing in the ciliary marginal zone (CMZ) of the retina. In the CMZ, between 20% (pigmented) and 24% (albino) of the melanopsin positive cells are unlabeled by the tracer and we suggest that this may be because they fail to send an axon into the ON. As such, this study provides the first evidence for a population of melanopsin interneurons in the mammalian retina. [ABSTRACT FROM AUTHOR]

Published

2014

30. Topographic specializations in the retinal ganglion cell layer correlate with lateralized visual behavior, ecology, and evolution in cockatoos.

Author

Coimbra, João Paulo, Collin, Shaun P., and Hart, Nathan S.

Abstract

ABSTRACT Cockatoos are a unique avian group inhabiting a diversity of arboreal and terrestrial microhabitats. Most species display strong lateralized visual behaviors using their left eye/foot to assist with food manipulation during foraging. In this study, we used retinal wholemounts and stereological methods to investigate whether the topographic distribution of retinal ganglion cells in cockatoos reflects their lateralized behaviors and microhabitat diversity. We found that all species studied possess a horizontal visual streak and a shallow central fovea that afford increased spatial resolution in the lateral visual field. Arboreal cockatoos have a well-defined dorsotemporal area, in contrast to terrestrial cockatoos, in which this specialization is inconspicuous or absent. Terrestrial cockatoos also have a triangular extension of increased ganglion cell density directed toward the dorsotemporal retinal periphery. Both the dorsotemporal area and the triangular extension enhance spatial resolution in the frontal and inferior visual fields, which potentially assists with binocular coordination during foraging. We found significantly higher ganglion cell densities in the left (52,000-72,000 cells/mm2) compared with the right (42,500-50,000 cells/mm2) perifoveal region of species that have strong left eye-left foot lateralized behaviors. In contrast, cockatoo species that show no lateralized behaviors have equivalent retinal ganglion cell densities in both left and right perifoveal regions (42,500-52,500 cells/mm2). Retinal ganglion cell peak densities in the dorsotemporal area showed no significant difference between left and right eyes for any species, suggesting that cockatoos use both eyes to extract information in the binocular visual field, independent of the degree of lateralization. J. Comp. Neurol. 522:3363-3385, 2014. © 2014 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014

31. Do American Goldfinches See Their World Like Passive Prey Foragers? A Study on Visual Fields, Retinal Topography, and Sensitivity of Photoreceptors.

Author

Baumhardt, Patrice E., Moore, Bret A., Doppler, Megan, and Fernández-Juricic, Esteban

Subjects

*AMERICAN goldfinch, *GOLDFINCHES, *PREDATION, *VISUAL fields, *RETINA physiology, *PHOTORECEPTORS, *PHYSIOLOGY

Abstract

Several species of the most diverse avian order, Passeriformes, specialize in foraging on passive prey, although relatively little is known about their visual systems. We tested whether some components of the visual system of the American goldfinch (Spinus tristis), a granivorous bird, followed the profile of species seeking passive food items (small eye size relative to body mass, narrow binocular fields and blind areas, centrally located retinal specialization projecting laterally, ultraviolet-sensitive vision). We measured eye size, visual field configuration, the degree of eye movement, variations in the density of ganglion cells and cone photoreceptors, and the sensitivity of photoreceptor visual pigments and oil droplets. Goldfinches had relatively large binocular (46°) and lateral (134°) visual fields with a high degree of eye movement (66° at the plane of the bill). They had a single centrotemporally located fovea that projects laterally, but can be moved closer to the edge of the binocular field by converging the eyes. Goldfinches could also increase their panoramic vision by diverging their eyes while handling food items in head-up positions. The distribution of photoreceptors indicated that the highest density of single and double cones was surrounding the fovea, making it the center of chromatic and achromatic vision and motion detection. Goldfinches possessed a tetrachromatic ultraviolet visual system with visual pigment peak sensitivities of 399 nm (ultraviolet-sensitive cone), 442 nm (short-wavelength-sensitive cone), 512 nm (medium-wavelength-sensitive cone), and 580 nm (long-wavelength-sensitive cone). Overall, the visual system of American goldfinches showed characteristics of passive as well as active prey foragers, with a single-fovea configuration and a large degree of eye movement that would enhance food searching and handling with their relatively wide binocular fields. © 2014 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2014

32. Visual Acuity in a Species of Coral Reef Fish: Rhinecanthus aculeatus.

Author

Champ, Connor, Wallis, Guy, Vorobyev, Misha, Siebeck, Ulrike, and Marshall, Justin

Subjects

*MARINE fishes, *CORAL reef fishes, *VISUAL acuity, *CELLS

Abstract

Coral reef fish present the human observer with an array of bold and contrasting patterns; however, the ability of such fish to perceive these patterns is largely unexamined. To understand this, the visual acuity of these animals - the degree to which they can resolve fine detail - must be ascertained. Behavioural studies are few in number and anatomical analysis has largely focused on estimates of ganglion cell density to predict the visual acuity in coral reef fish. Here, we report visual acuity measures for the triggerfish Rhinecanthus aculeatus. Acuity was first assessed using a series of behavioural paradigms and the figures were then contrasted with those obtained anatomically, based on photoreceptor and ganglion cell counts. Behavioural testing indicated an upper behavioural acuity of 1.75 cycles·degree-1, which is approximately the same level of acuity as that of the goldfish (Carassiusauratus). Anatomical estimates were then calculated from wholemount analysis of the photoreceptor layer and Nissl staining of cells within the ganglion cell layer. Both of these anatomical measures gave estimates that were substantially larger (7.75 and 3.4 cycles·degree-1 for the photoreceptor cells and ganglion cells, respectively) than the level of acuity indicated by the behavioural tests. This indicates that in this teleost species spatial resolution is poor compared to humans (30-70 cycles·degree-1) and it is also not well indicated by anatomical estimates. © 2014 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2014

33. Retinal Ganglion Cell Topography and Spatial Resolving Power in Echolocating and Non-Echolocating Bats

Author

Fanny de Busserolles, Lasse Hjort Jakobsen, Clément Cechetto, and Eric J. Warrant

Subjects

Retinal Ganglion Cells, Stereology, Foraging, Zoology, Olfaction, Nocturnal, Retinal ganglion cells, Retinal ganglion, Pteropodidae, Retinal topography, Behavioral Neuroscience, Species Specificity, Developmental Neuroscience, Chiroptera, Bats, medicine, Animals, Spatial resolving power, Retina, biology, biology.organism_classification, medicine.anatomical_structure, Echolocation, Space Perception, Visual Perception, Pteropus alecto, Rousettus

Abstract

Bats are nocturnal mammals known for their ability to echolocate, yet all bats can see, and most bats of the family Pteropodidae (fruit bats) do not echolocate – instead they rely mainly on vision and olfaction to forage. We investigated whether echolocating bats, given their limited reliance on vision, have poorer spatial resolving power (SRP) than pteropodids and whether tongue click echolocating fruit bats differ from non-echolocating fruit bats in terms of visual performance. We compared the number and distribution of retinal ganglion cells (RGCs) as well as the maximum anatomical SRP derived from these distributions in 4 species of bats: Myotis daubentonii, a laryngeal echolocating bat from the family Vespertilionidae, Rousettus aegyptiacus, a tongue clicking echolocating bat from the family Pteropodidae, and Pteropus alecto and P. poliocephalus, 2 non-echolocating bats (also from the Pteropodidae). We find that all 3 pteropodids have a similar number (≈200,000 cells) and distribution of RGCs and a similar maximum SRP (≈4 cycles/degree). M. daubentonii has fewer (∼6,000 cells) and sparser RGCs than the pteropodids and thus a significantly lower SRP (0.6 cycles/degree). M. daubentonii also differs in terms of the distribution of RGCs by having a unique dorsal area of specialization in the retina. Our findings are consistent with the existing literature and suggest that M. daubentonii likely only uses vision for orientation, while for pteropodids vision is also important for foraging.

Published

2020

34. Visual Eyes: A Quantitative Analysis of the Photoreceptor Layer in Deep-Sea Sharks.

Author

Newman, amy S., Marshall, Justin N., and Collin, Shaun P.

Subjects

*VISUAL fields, *QUANTITATIVE research, *SHARKS, *PHOTORECEPTORS, *LIGHT absorption

Abstract

The marine environment presents unique visual challenges for a range of organisms, particularly those dwelling at great depths, where sunlight may either be absent or drop to very low levels. Under these environmental conditions, the visual system must maximise light absorption in order to enhance the detection of prey, predators and potential mates. Using stereological analysis of retinal wholemounts, the distribution and number of photoreceptors (rods) was determined for 5 deep-sea shark species from a range of depths (46-1,500 m). All species possessed areas of increased photoreceptor density (with peaks between 41,000 and 82,000 rods/mm2) within discrete regions of the retina. The total number of rods in the photoreceptor layer also varied between 17 × 106 and 63 × 106. It is evident that increasing sensitivity of the retina is an important adaptation to life in the deep sea. The location of discrete areas of high cell density within the photoreceptor layer of the retina corresponds to discrete areas of the visual field that are sampled at a higher intensity, hence increasing sensitivity. The location of these areas of increased sensitivity differed between the species of this study. The disparity of areas of increased sensitivity seen between species is thought to reflect distinctive predator avoidance and prey capture strategies. This study reveals that the visual demands of deep-sea sharks vary interspecifically and that sampling of each species' visual field is not solely determined by its habitat. © 2013 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2013

35. Scene from above: Retinal ganglion cell topography and spatial resolving power in the giraffe ( Giraffa camelopardalis).

Author

Coimbra, João Paulo, Hart, Nathan S., Collin, Shaun P., and Manger, Paul R.

Abstract

The giraffe ( Giraffa camelopardalis) is a browser that uses its extensible tongue to selectively collect leaves during foraging. As the tallest extant terrestrial mammal, its elevated head height provides panoramic surveillance of the environment. These aspects of the giraffe's ecology and phenotype suggest that vision is of prime importance. Using Nissl-stained retinal wholemounts and stereological methods, we quantitatively assessed the retinal specializations in the ganglion cell layer of the giraffe. The mean total number of retinal ganglion cells was 1,393,779 and their topographic distribution revealed the presence of a horizontal visual streak and a temporal area. With a mean peak of 14,271 cells/mm2, upper limits of spatial resolving power in the temporal area ranged from 25 to 27 cycles/degree. We also observed a dorsotemporal extension (anakatabatic area) that tapers toward the nasal retina giving rise to a complete dorsal arch. Using neurofilament-200 immunohistochemistry, we also detected a dorsal arch formed by alpha ganglion cells with density peaks in the temporal (14-15 cells/mm2) and dorsonasal (10 cells/mm2) regions. As with other artiodactyls, the giraffe shares the presence of a horizontal streak and a temporal area which, respectively, improve resolution along the horizon and in the frontal visual field. The dorsal arch is related to the giraffe's head height and affords enhanced resolution in the inferior visual field. The alpha ganglion cell distribution pattern is unique to the giraffe and enhances acquisition of motion information for the control of tongue movement during foraging and the detection of predators. J. Comp. Neurol. 521:2042-2057, 2013. © 2012 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2013

36. Retinal Ganglion Cell Topography and Spatial Resolving Power in Penguins.

Author

Coimbra, João Paulo, Nolan, Paul M., Collin, Shaun P., and Hart, Nathan S.

Subjects

*RETINAL ganglion cells, *ECOLOGY of penguins, *LITTLE blue penguin, *KING penguin, *IMMUNOHISTOCHEMISTRY, *PROCELLARIIFORMES

Abstract

Penguins are a group of flightless seabirds that exhibit numerous morphological, behavioral and ecological adaptations to their amphibious lifestyle, but little is known about the topographic organization of neurons in their retinas. In this study, we used retinal wholemounts and stereological methods to estimate the total number and topographic distribution of retinal ganglion cells in addition to an anatomical estimate of spatial resolving power in two species of penguins: the little penguin, Eudyptula minor, and the king penguin, Aptenodytes patagonicus. The total number of ganglion cells per retina was approximately 1,200,000 in the little penguin and 1,110,000 in the king penguin. The topographic distribution of retinal ganglion cells in both species revealed the presence of a prominent horizontal visual streak with steeper gradients in the little penguin. The little penguin retinas showed ganglion cell density peaks of 21,867 cells/mm2, affording spatial resolution in water of 17.07-17.46 cycles/degree (12.81-13.09 cycles/degree in air). In contrast, the king penguin showed a relatively lower peak density of ganglion cells of 14,222 cells/mm2, but - due to its larger eye - slightly higher spatial resolution in water of 20.40 cycles/degree (15.30 cycles/degree in air). In addition, we mapped the distribution of giant ganglion cells in both penguin species using Nissl-stained wholemounts. In both species, topographic mapping of this cell type revealed the presence of an area gigantocellularis with a concentric organization of isodensity contours showing a peak in the far temporal retina of approximately 70 cells/mm2 in the little penguin and 39 cells/mm2 in the king penguin. Giant ganglion cell densities gradually fall towards the outermost isodensity contours revealing the presence of a vertically organized streak. In the little penguin, we confirmed our cytological characterization of giant ganglion cells using immunohistochemistry for microtubule-associated protein 2. This suite of retinal specializations, which is also observed in the closely related procellariiform seabirds, affords the eyes of the little and king penguins panoramic surveillance of the horizon and motion detection in the frontal visual field. Copyright © 2012 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2012

37. How viewing objects with the dorsal or ventral retina affects colour-related behaviour in guppies (Poecilia reticulata)

Author

Sibeaux, Adelaide Marie Colette, Keser, Madison L, Cole, Gemma L, Kranz, Alexandrea M, Endler, John A, Sibeaux, Adelaide Marie Colette, Keser, Madison L, Cole, Gemma L, Kranz, Alexandrea M, and Endler, John A

Published

2019

38. Testing the Terrain Hypothesis: Canada Geese See Their World Laterally and Obliquely.

Author

Fernández-Juricic, Esteban, Moore, Bret A., Doppler, Megan, Freeman, Joseph, Blackwell, Bradley F., Lima, Steven L., and DeVault, Travis L.

Subjects

*CANADA goose, *AVIAN anatomy, *RETINAL ganglion cells, *ANTIPREDATOR behavior, *VISUAL fields

Abstract

The distribution of ganglion cells in the retina determines the specific regions of the visual field with high visual acuity, and thus reflects the perception of a species' visual environment. The terrain hypothesis proposes that animals living in open areas should have a horizontal visual streak across the retina with high ganglion cell density to increase visual acuity along the horizon. We tested this hypothesis in Canada geese (Branta canadensis) by assessing retinal topography, visual field configuration, and scanning behavior. We found that geese have an oblique rather than a horizontal visual streak across the retina: from a dorsal-nasal to a ventral-temporal position. Geese showed narrow blind areas, which increased the range of their lateral vision, and a relatively large degree of eye movement. Canada geese have relatively wide binocular fields and can see their bill tips. Goose head movement rates were low compared to species with a single fovea, and head movement rates increased in visually obstructed habitats. Canada geese have high acuity across their retina, which would allow them to simultaneously scan the ground and the sky when the head is up and parallel to the ground, as well as align the visual streak with the horizon when the head is tilted downwards. Their visual streak, along with their large eye size, may reduce the need for large amplitude head movements during vigilance bouts in visually unobstructed habitats. Overall, the visual system of geese combines features related to the detection of predators/conspecifics in open areas (visual streak, large lateral field, reduced head movements) as well as visual specializations that would allow for monitoring both the ground and sky (oblique streak) and for extracting and handling of food items (wide binocular fields, visualization of the bill tip). Copyright © 2011 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2011

39. Visual systems and vigilance behaviour of two ground-foraging avian prey species: white-crowned sparrows and California towhees

Author

Fernández-Juricic, Esteban, Gall, Megan D., Dolan, Tracy, O’Rourke, Colleen, Thomas, Sarah, and Lynch, Jacqueline R.

Subjects

*WHITE-crowned sparrow, *CALIFORNIA towhee, *ANTIPREDATOR behavior, *FORAGING behavior, *ANIMAL species, *PREDATION, *VISUAL fields, *VISUAL acuity, *ANIMAL behavior

Abstract

Predator–prey interactions are regulated by the ability of individuals to detect, and then approach or avoid, each other. In visually guided organisms, the prevalent view is that predators have large binocular visual fields and high acuity, whereas prey have wide lateral areas and low acuity, which could affect vigilance behaviour. We characterized the configuration of the visual system (visual fields, retinal topography, visual acuity) and vigilance behaviour (head movement rate) of two ground-foraging avian prey (white-crowned sparrow, Zonotrichia leucophrys, California towhee, Pipilo crissalis) with laterally placed eyes. We found that the binocular field of both species (45°) was actually wider than those of some of their avian predators. Both species also had a single retinal specialization (high ganglion cell density area) located in the centro-temporal sector of the retina, which projected into the lateral and frontal part of the head. Wide binocular fields may increase binocular contrast to detect and visually guide the bill towards prey items. Both species had wider lateral visual fields and faster head movement rates than some of their predators, probably to enhance detection and visual tracking of predators. California towhees made faster sideways movements of the head than did white-crowned sparrows, probably to cover visual space more quickly with their retinal specialization because of the comparatively lower spatial resolution of their retinal periphery. Alternatively, California towhees might move their heads more rapidly to monitor for potential risks (e.g. competitors, predators), as they rely mostly on personal information because of their degree of territoriality. Our findings suggest that the visual system and vigilance behaviour of these two avian prey species combine traits to enhance predator detection through large visual coverage and fast head movements, but also to enhance food detection at close range through enhanced binocular vision. [Copyright &y& Elsevier]

Published

2011

40. Interspecific Visual Adaptations among Wobbegong Sharks (Orectolobidae).

Author

Theiss, Susan M., Collin, Shaun P., and Hart, Nathan S.

Subjects

*ORECTOLOBIDAE, *RETINA, *EYE, *RETINAL ganglion cells, *PHYLOGENY, *BIOLOGICAL evolution, *WOBBEGONG

Abstract

Several visual traits have previously been assessed in elasmobranchs; however, few studies have examined and compared multiple visual attributes within a particular genus. The primary advantage of studying closely related species is that any differences between them are more likely to reflect functional ecological adaptations rather than the effects of phylogenetic separation. In this study, the visual capabilities of 4 wobbegong shark species, which vary in life-history and/or habitat, were examined: the western wobbegong (Orectolobus hutchinsi), the spotted wobbegong (O. maculatus), the ornate wobbegong (O. ornatus) and the dwarf spotted wobbegong (O. parvimaculatus). The retinae of all 4 wobbegong species are duplex; rod and cone photoreceptors can be distinguished easily on the basis of morphology. Some variation in relative eye size exists, with O. parvimaculatus possessing the largest eyes. The topographic distribution of cells within the ganglion cell layer of O. hutchinsi reveals a weakly elongated central visual streak of increased cell density, mediating a higher spatial resolving power of 2.06 cycles deg-1 in the frontal visual field. Retinal topography of O. maculatus and O. parvimaculatus is similar, with both possessing a dorsal horizontal streak facilitating an increased spatial resolving power of 3.51 cycles deg-1 and 3.91 cycles deg-1, respectively, in the lower visual field. O. parvimaculatus also possesses an area of increased cell density in the naso-ventral region of the retina, mediating acute vision in the upper caudal region of the visual field. While all 4 species have visual systems optimised for increased visual sensitivity, O. maculatus and O. parvimaculatus appear to be particularly well suited to activity under low light conditions. Copyright © 2010 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2011

41. Retinal Ganglion Cell Topography of Five Species of Ground-Foraging Birds.

Author

Dolan, Tracy and Fernández-Juricic, Esteban

Subjects

*BIRD behavior, *CORNEAL topography, *RETINAL ganglion cells, *FORAGING behavior, *VISUAL acuity, *PASSERIFORMES

Abstract

Birds that forage on the ground have been studied extensively in relation to behavioral trade-offs between foraging and scanning for predators; however, we know little about the topography of their retinas, which can influence how they gather visual information. We characterized the density of retinal ganglion cells across the retina and estimated visual acuity of four Passeriformes (European starling Sturnus vulgaris, brown-headed cowbird Molothrus ater, house sparrow Passer domesticus, house finch Carpodacus mexicanus) and one Columbiforme (mourning dove Zenaida macroura) that forage on the ground. We used cresyl violet to stain retinal ganglion cells and estimated visual acuity based on cell density and eye size. All species contained a single area centralis, where cell densities were >20,000 cells/mm2. The proportion of the retina that fell in each of five cell density ranges varied between species. European starlings and house finches had the largest area of high cell density, mourning doves had the smallest. The largest proportion of the retina (>35%) of brown-headed cowbird and house sparrow was in the second-lowest cell density range. Considering the 25th percentile of highest cell densities, house finches and European starlings showed the highest cell densities and mourning doves the lowest. Estimated visual acuity increased from house finch, house sparrow, brown-headed cowbird, European starling to mourning dove, and was associated with both retinal area and cell density. Our findings suggest that these ground foragers do not have highly specialized retinas in relation to other types of foragers (e.g. tree foragers), probably because foraging on seeds and insects from the ground is not as visually demanding; however, the studied species showed variability in retinal topography that may be related to foraging techniques, eye size constraints, and size of the area centralis. Copyright © 2010 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2010

42. Topography of retinal damage in light-exposed albino rats

Author

Tanito, Masaki, Kaidzu, Sachiko, Ohira, Akihiro, and Anderson, Robert E.

Subjects

*RETINA abnormalities, *LABORATORY rats, *OPTIC nerve, *TOPOGRAPHIC maps, *CRANIAL nerves, *POSTERIOR segment (Eye)

Abstract

Abstract: Previous studies have shown that retinal damage induced by damaging light exposure is more severe in superior retina than inferior retina when measured along the vertical meridian of eyes. However, the extent of retinal damage over all retinal regions is not clear. Albino rats were exposed to bright light (5000lux for 6h) and eyes removed 7 days later. Outer nuclear layer (ONL) thickness was measured along four different meridians; temporal-to-nasal (T–N), superior-to-inferior (S–I), superiotemporal-to-inferionasal (ST–IN), and superionasal-to-inferiotemporal (SN–IT). As reported previously, superior retina is more severely damaged than inferior retina along the S–I meridian. In addition, we found that the temporal retina is more severely damaged than nasal retina on the T–N meridian. Color-coded topographic maps clearly revealed that thinning of ONL was greatest at 1–1.5mm superior and superiotemporal to the optic nerve head and that most damage was in the superiotemporal region of the fundus. For consistency in quantification of ONL thickness, using retinal sections cut along the S–I meridian is preferable to using those along the T–N meridian, since minor orientations to superior or inferior directions along the T–N meridian may cause greater variations in measured ONL thickness values in this experimental model. [Copyright &y& Elsevier]

Published

2008

43. Retinal Ganglion Cell Distribution and Spatial Resolving Power in Elasmobranchs.

Author

Lisney, Thomas J. and Collin, Shaun P.

Subjects

*RETINAL ganglion cells, *SHARKS, *CHONDRICHTHYES, *OPTIC nerve cytology, *SPATIAL behavior in animals, *NISSL bodies, *OPTICAL resolution, *RAJIFORMES

Abstract

The total number, distribution and peak density of presumed retinal ganglion cells was assessed in 10 species of elasmobranch (nine species of shark and one species of batoid) using counts of Nissl-stained cells in retinal wholemounts. The species sampled include a number of active, predatory benthopelagic and pelagic sharks that are found in a variety of coastal and oceanic habitats and represent elasmobranch groups for which information of this nature is currently lacking. The topographic distribution of cells was heterogeneous in all species. Two benthic species, the shark Chiloscyllium punctatum and the batoid Taeniura lymma, have a dorsal or dorso-central horizontal streak of increased cell density, whereas the majority of the benthopelagic and pelagic sharks examined exhibit a more concentric pattern of increasing cell density, culminating in a central area centralis of higher cell density located close to the optic nerve head. The exception is the shark Alopias superciliosus, which possesses a ventral horizontal streak. Variation in retinal ganglion cell topography appears to be related to the visual demands of different habitats and lifestyles, as well as the positioning of the eyes in the head. The upper limits of spatial resolving power were calculated for all 10 species, using peak ganglion cell densities and estimates of focal length taken from cryo-sectioned eyes in combination with information from the literature. Spatial resolving power ranged from 2.02 to 10.56 cycles deg–1, which is in accordance with previous studies. Species with a lower spatial resolving power tend to be benthic and/or coastal species that feed on benthic invertebrates and fishes. Active, benthopelagic and pelagic species from more oceanic habitats which feed on larger, more active prey, possess a higher resolving power. Additionally, ganglion cells in a juvenile of C. punctatum, were retrogradely-labeled from the optic nerve with biotinylated dextran amine (BDA). A comparison of the BDA- labeled material and tissue stained for Nissl substance indicates that 76% of the cells in the retinal ganglion cell and inner plexiform layers of the central retina in this species are non-ganglion cells. Copyright © 2008 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2008

44. A web-based archive for topographic maps of retinal cell distribution in vertebrates.

Author

Collin, Shaun P.

Subjects

*ARCHIVES, *RETINA, *VERTEBRATES, *NEURONS, *TOPOGRAPHIC maps, *OPTICAL resolution

Abstract

Clinical and Experimental Optometry, in conjunction with Optometrists Association Australia and Professor Shaun P Collin of the University of Queensland, announce the launch of a web-based archive of previously published topographic maps of retinal cell distribution in vertebrates. At present, the archive boasts more than 770 different maps of the distribution of retinal neurons (for example, photoreceptors, bipolar cells, amacrine cells, horizontal cells and ganglion cells) in nearly 200 species within all vertebrate classes (Cephalospidomorpha, Actinopterygii, Sarcopterygii, Amphibia, Reptilia, Aves and Mammalia). The distribution of retinal neurons has been studied for more than 100 years and has become a powerful means of predicting the spatial resolving power of the eye and the retinal regions containing specialisations, such as areae centrales, horizontal streaks and foveae, where increased densities of neurons define the way in which a species visually samples its environment. The location of these retinal specialisations thereby identifies the part(s) of the visual field of critical importance for localising food and mates and for predator surveillance. The distribution of sampling elements even reflects the symmetry of a species' ecological habitat. The archive is a unique collection of most of the currently available retinal maps, which also presents relevant information, where known, about eye size, retinal cell density, retinal orientation, cell number, spatial resolving power and the type of specialisation, in addition to basic physical parameters of each species (body size, weight, sex and developmental stage). The archive is accessible at and will be updated regularly. The powerful database is interactive and freely available, providing the opportunity to upload both published and unpublished topographic maps. Following a review process, previously unpublished maps will be ‘published’ and available online worldwide. It is hoped that this comprehensive new resource will provide not only an up-to-date method of accessing maps of the distribution of retinal neurons in individual species but also allow broader evolutionary comparisons of the visual capabilities, ecology, development and the type(s) of retinal specialisations found in vertebrates. [ABSTRACT FROM AUTHOR]

Published

2008

45. The Retina of Tyrant Flycatchers: Topographic Organization of Neuronal Density and Size in the Ganglion Cell Layer of the Great Kiskadee Pitangus sulphuratus and the Rusty Margined Flycatcher Myiozetetes cayanensis (Aves: Tyrannidae).

Author

Coimbra, João Paulo, Videira Marceliano, Maria Luiza, da Silveira Andrade-da-Costa, Belmira Lara, and Sumi Yamada, Elizabeth

Subjects

*FLYCATCHERS, *RETINAL ganglion cells, *RETINOIDS, *CELLS, *FORAGING behavior

Abstract

Tyrant flycatchers comprise the largest group of passerine birds of the Neotropical region but their retinal organization is unknown. The great kiskadee, Pitangus sulphuratus, is categorized as a supreme generalist and utilizes a variety of foraging strategies. The rusty margined flycatcher, Myiozetetes cayanensis, is partially frugivorous and captures insects in the air. Using retinal wholemounts, we described the topographic distribution of density and size of neurons lying in the retinal ganglion cell layer in those two species of tyrant flycatchers. Maps of neuron distribution showing isodensity contours revealed the presence of a pronounced central fovea and a temporal area in both species. Both retinal specializations were circumscribed by an inconspicuous horizontal visual streak. The highest foveal densities ranged from 48,000 to 55,000 cells/mm2 for Pitangus sulphuratus and between 62,000 and 65,000 cells/mm2 for Myiozetetes cayanensis. The peak density in the temporal area was around 40,000 cells/mm2 for Pitangus sulphuratus and 46,000 cells/mm2 for Myiozetetes cayanensis. At central, mid-peripheral and peripheral eccentricities, perikaryon size varied quite similarly in both species. A cohort of giant retinal ganglion cells with perikaryon size > 300 μm2 was observed at the temporal periphery and defines an ‘area giganto cellularis’ described previously in procellariiform seabirds. This specialization is thought to be involved in movement detection and could aid the tyrant flycatchers to capture moving prey. Functionally, the presence of a fovea associated with a temporal area would allow high spatial resolution for capturing insects by the tyrant flycatchers. Nonetheless, even though both species exhibit different foraging strategies, they shared a similar topographic arrangement of neuronal density in the ganglion cell layer. This suggests that the retinal topography did not accompany changes in the foraging ecology throughout evolutionary history for these species of tyrant flycatchers. Copyright © 2006 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2006

46. Repulsive Guidance Molecule (RGM) Gene Function Is Required for Neural Tube Closure But Not Retinal Topography in the Mouse Visual System.

Author

Niederkofler, Vera, Salie, Rishard, Sigrist, Markus, and Arber, Silvia

Subjects

*NEURAL tube, *MEDICAL geography, *AXONS, *SENSORY ganglia, *RETINA cytology, *NEUROSCIENCES

Abstract

The establishment of topographic projections in the developing visual system depends on the spatially and temporally controlled expression of axon guidance molecules. In the developing chick tectum, the graded expression of the repulsive guidance molecule (RGM) has been proposed to be involved in controlling the topography of the retinal ganglion cell (RGC) axon termination zones along the anteroposterior axis of the tectum. We now show that there are three mouse proteins homologous to chick RGM displaying similar proteolytic processing but exhibiting differential cell-surface targeting by glycosyl phosphatidylinositol anchor addition. Two members of this gene family (mRGMa and mRGMb) are expressed in complementary patterns in the nervous system, and mRGMa is expressed prominently in the superior colliculus at the time of anteroposterior targeting of RGC axons. The third member of the family (mRGMc) is expressed almost exclusively in skeletal muscles. Functional studies in the mouse reveal a role for mRGMa in controlling cephalic neural tube closure, thus defining an unexpected role for mRGMa in early embryonic development. In contrast, mRGMa mutant mice did not exhibit defects in anteroposterior targeting of RGC axons to their stereotypic termination zones in the superior colliculus. [ABSTRACT FROM AUTHOR]

Published

2004

47. Topography of Photoreceptors and Retinal Ganglion Cells in the Spotted Hyena (Crocuta crocuta).

Author

Calderone, Jack B., Reese, Benjamin E., and Jacobs, Gerald H.

Subjects

*PHOTORECEPTORS, *SPOTTED hyena

Abstract

The spatial distributions of photoreceptors and retinal ganglion cells were examined in the spotted hyena (Crocuta crocuta). Two populations of cones were identified by immunocytochemical labeling. The hyena retina contains approximately 2.3 million middle- to long-wavelength sensitive (M/L) cones that reach peak densities of about 7,500/mm[sup 2] in the vicinity of the optic nerve head. A sparser population of short-wavelength sensitive (S) cones, totaling about 0.3 million, was also detected. There is a striking disparity in the spatial distributions of the two cone types with S cones achieving peak density in a region located well below the optic nerve head. The differences in the spatial distributions of the two cone types have implications both for visual sensitivity and for color vision. Hyena rods outnumber cones by about 100:1 with rod density falling off modestly along a central-peripheral gradient. Ganglion cells were identified in retinal wholemounts by Nissl staining patterns. Their distribution defines a prominent visual streak with highest spatial packing (approx. 4,200/mm[sup 2] ) in an area centralis that is located in the temporal retina. The total number of ganglion cells is estimated at about 260,000. Using standard assumptions the maximum spatial resolution of the spotted hyena is calculated to be about 8.4 cycles/degree, a value similar to estimates obtained for other terrestrial carnivores. Copyright © 2003 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2003

48. Quantitative Analysis of the Retinal Ganglion Cell Layer in the Ostrich, Struthio camelus.

Author

Boire, Denis, Dufour, Jean-Sébastien, Théoret, Hugo, and Ptito, Maurice

Subjects

*RETINAL ganglion cells, *OSTRICHES, *VISUAL acuity, *EYE

Abstract

The total number, distribution and peak density of ganglion cells were evaluated in the Nissl-stained retina of the ostrich (Struthio camelus). The mean (n = 4) total number of retinal ganglion cells (RGC) was estimated at 2,274,128 (s.d. = 273, 152). The ostrich retina exhibited a prominent horizontal visual streak along which a central area located nasal to the pecten had a peak density of 9,500 cells/mm[sup 2] . A high concentration of cells with a peak density of 2,646 cells/mm[sup 2] was also observed in the temporal retina, slightly dorsal to the visual streak. The results further showed that the ostrich eye has a 15-mm pupil entrance diameter, its mean axial length is 39.81 mm, the estimated retinal magnification factor is 0.4075 mm/deg and the maximum visual acuity along the well-defined visual streak was estimated to be 19.32 cycles/deg. The latter component of the retina might subserve vision along the horizon while the temporal region mediates binocular processing. The data also showed that the degree of retinal illumination in this bird could be comparable to that noted in some nocturnal species. The findings in this study suggest that the ostrich might not be restricted to diurnal activity.Copyright © 2002 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2001

49. Variations in cone photoreceptor abundance and the visual ecology of birds.

Author

Hart, Nathan S.

Subjects

*PHOTORECEPTORS, *RETINA, *CLUSTER analysis (Statistics), *RETINOIDS, *MULTIVARIATE analysis, *MICROSCOPY

Abstract

The relative abundance and topographical distribution of retinal cone photoreceptors was measured in 19 bird species to identify possible correlations between photoreceptor complement and visual ecology. In contrast to previous studies, all five types of cone photoreceptor were distinguished, using bright field and epifluorescent light microscopy, in four retinal quadrants. Land birds tended to show either posterior dorsal to anterior ventral or anterior dorsal to posterior ventral gradients in cone photoreceptor distribution, fundus coloration and oil droplet pigmentation across the retina. Marine birds tended to show dorsal to ventral gradients instead. Statistical analyses showed that the proportions of the different cone types varied significantly across the retinae of all species investigated. Cluster analysis was performed on the data to identify groups or clusters of species on the basis of their oil droplet complement. Using the absolute percentages of each oil droplet type in each quadrant for the analysis produced clusters that tended to reflect phylogenetic relatedness between species rather than similarities in their visual ecology. Repeating the analysis after subtracting the mean percentage of a given oil droplet type across the whole retina (the 'eye mean') from the percentage of that oil droplet type in each quadrant, i.e. to give a measure of the variation about the mean, resulted in clusters that reflected diet, feeding behaviour and habitat to a greater extent than phylogeny. [ABSTRACT FROM AUTHOR]

Published

2001

50. Variability in the Location of the Retinal Ganglion Cell Area Centralis Is Correlated with Ontogenetic Changes in Feeding Behavior in the Black Bream, Acanthopagrus butcheri (Sparidae, Teleostei).

Author

Shand, Julia, Chin, Stephanie M., Harman, Alison M., Moore, Stephen, and Collin, Shaun P.

Subjects

*RETINAL ganglion cells, *ACANTHOPAGRUS butcheri, *ACANTHOPAGRUS, *ANIMAL feeding behavior, *FISHES, *CELLS

Abstract

The development of neural cell topography in the retinal ganglion cell layer was examined in a teleost, the black bream (Acanthopagrus butcheri). From Nissl-stained wholemounts, it was established that fish between 10 and 15 mm standard body length (SL) possess high cell densities throughout the dorso-temporal retinal quadrant, with peak cell densities located in temporal regions of the retina. However, in fish between 15 and 80 mm SL, a wide variation in the position of the peak cell density is revealed with the locations of the areae centrales (AC) ranging from exclusively temporal to periphero-dorsal retina. Fish larger than 80 mm SL always possess an AC located in the dorsal region of the dorso-temporal retinal quadrant. The topography of ganglion cells within the ganglion cell layer was determined by comparing the numbers of ganglion cells retrogradely-labeled from the optic nerve with the total population of Nissl-stained neurons (ganglion plus displaced amacrine cells) in a range of different-sized individuals. Ganglion cell topography was the same as that recorded for all Nissl-stained neurons. The feeding behavior of juveniles from metamorphosis to 80 mm SL was observed, where fish were given the choice of feeding on live food in mid-water (until 15 mm SL) or obtaining pellets from the surface or the bottom. A range of feeding patterns was recorded, with the smallest fish taking food from mid-water but individuals between 15 and 80 mm SL taking food either from the surface or the bottom or both. A correlation between the preferred mode of feeding and the position of the AC was found, such that those individuals feeding in mid-water or at the surface possess a temporal or intermediate (dorso- temporal) AC, whereas those predominantly feeding from the bottom possess a dorsal AC.Copyright © 2000 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2000