Retinal Topographic Maps: A Glimpse into the Animals’ Visual World

The vertebrates’ retina has a highly conserved laminar organization of 10 alternating nuclear and plexiform layers. Species differences in the retinal specializations, i.e., areas of higher cell density, among the species, represent specific regions of the visual field of higher importance for a better spatial resolution and indicate distinct evolutionary pressures on the structures of the visual system, which can be related to many aspects of the species evolutionary history. In this chapter, we analyzed the density and distribution of cells of the retinal ganglion cell layer (GCL) and estimated the upper limits of the spatial resolving power of 12 species of snakes from the Colubridae family, 6 diurnal and 6 nocturnal, which inhabit different habitats. Our results revealed lower visual acuity in nocturnal species, compared to diurnal, and we observed different types of retinal specialization, horizontal streak, area centralis, or scattered distribution, with higher cell density in different retinal regions, depending on the species. These variations may be related to ecological and behavioral features, such as daily activity pattern, habitat, and substrate preferentially occupied, hunting strategies and diet. This comparative study indicates the complexity of the adaptive strategies of the snakes’ visual system

Simultaneous expression of UV and violet SWS1 opsins expands the visual palette in a group of freshwater snakes

Snakes are known to express a rod visual opsin and two cone opsins, only (SWS1, LWS), a reduced palette resulting from their supposedly fossorial origins. Dipsadid snakes in the genus Helicops are highly visual predators that successfully invaded freshwater habitats from ancestral terrestrial-only habitats. Here we report the first case of multiple SWS1 visual pigments in a vertebrate, simultaneously expressed in different photoreceptors and conferring both UV and violet sensitivity to Helicops snakes. Molecular analysis and in vitro expression confirmed the presence of two functional SWS1 opsins, likely the result of recent gene duplication. Evolutionary analyses indicate that each sws1 variant has undergone different evolutionary paths, with strong purifying selection acting on the UV-sensitive copy and dN/dS ∼1 on the violet-sensitive copy. Site-directed mutagenesis points to the functional role of a single amino acid substitution, Phe86Val, in the large spectral shift between UV and violet opsins. In addition, higher densities of photoreceptors and SWS1 cones in the ventral retina suggest improved acuity in the upper visual field possibly correlated with visually-guided behaviors. The expanded visual opsin repertoire and specialized retinal architecture are likely to improve photon uptake in underwater and terrestrial environments, and provide the neural substrate for a gain in chromatic discrimination, potentially conferring unique color vision in the UV-violet range. Our findings highlight the innovative solutions undertaken by a highly specialized lineage to tackle the challenges imposed by the invasion of novel photic environments and the extraordinary diversity of evolutionary trajectories taken by visual opsin-based perception in vertebrates

Effect of the Decrease in Luminance Noise Range on Color Discrimination of Dichromats and Trichromats

Color vision assessment can be done using pseudoisochromatic stimuli, which has a luminance noise to eliminate brightness differences between the target and background of the stimulus. It is not clear the influence of the luminance noise on color discrimination. We investigated the effect of change in the luminance noise limits on color discrimination. Eighteen trichromats and ten congenital dichromats (eight protans, two deutans) had their color vision evaluated by the Cambridge Colour Test, and were genetically tested for diagnostic confirmation. The stimuli were composed of a mosaic of circles in a 5° circular field. A subset of the circles differed in chromaticity from the remaining field, forming a letter C. Color discrimination was estimated in stimulus conditions differing in luminance noise range: (i) 6–20 cd/m2; (ii) 8–18 cd/m2; (iii) 10–16 cd/m2; and (iv) 12–14 cd/m2. Six equidistant luminance values were used within the luminance noise limits with the mean stimulus luminance maintained constant under all conditions. A four-alternative, forced-choice method was applied to feed a staircase procedure to estimate color discrimination thresholds along eight chromatic axes. An ellipse model was adjusted to the eight color discrimination thresholds. The parameters of performance were threshold vector lengths and the ellipse area. Results were compared using the Kruskal-Wallis test with a significance level of 5%. The linear function model was applied to analyze the dependence of the discrimination parameters on the noise luminance limits. The first derivative of linear function was used as an indicator of the rate of change in color discrimination as a function of luminance noise changes. The rate of change of the ellipse area as a function of the luminance range in dichromats was higher than in trichromats (p < 0.05). Significant difference was also found for individual thresholds in half of the axes we tested. Luminance noise had a greater effect on color discrimination ability of dichromats than the trichromats, especially when the chromaticities were close to their protan and deutan color confusion lines

Estudo comparativo da densidade e topografia de neurônios de retinas de Philodryas olfesii e P. patagoniensis (serpentes, colubridae)

As serpentes são um grupo altamente diversificado, encontradas em praticamente todas as regiões do planeta, ocupando diferentes ambientes. Sua diversidade adaptativa indica a grande variabilidade dos órgãos sensoriais, adaptados ao hábitat e hábitos de cada espécie. Estudos sobre o sistema visual das serpentes são escassos e tem grande importância na compreensão de caracteres ecológicos, comportamentais e filogenéticos. Nos vertebrados as informações visuais são projetadas na retina e inicialmente processadas nessa camada neural, antes do processamento que ocorre no sistema nervoso central. Os tipos de células encontradas na retina, bem como sua densidade e distribuição variam entre as espécies e determinam especializações do sistema visual. Neste trabalho foi feita uma quantificaçao comparativa de fotorreceptores e neurônios da camada de células ganglionares (CCG) de duas espécies de serpentes colubrídeas diurnas, Philodryas olfersii e P. patagoniensis. Para tanto foram utilizadas técnicas de imunohistoquímica de opsinas e de marcação de Nissl. Serpentes adultas obtidas no Instituto Butantan foram anestesiadas com tiopental (30mg/kg) e sacrificadas com CO2. Os olhos foram enucleados e as retinas dissecadas e fixadas em paraformaldeido 4%. Um olho de cada serpente foi utilizado para fazer cortes radiais e testar diferentes tipos e concentrações de anticorpos. Para a preparação das retinas planas foram utilizados o anticorpo JH455, produzido em coelhos contra opsinas sensíveis aos comprimentos de onda curto de humanos (cones S) e o anticorpo JH492, produzido em coelhos contra opsinas sensíveis aos comprimentos de onda médio e longo de humanos (cones L/M). Foi utilizado anticorpo secundário biotinilado (gt -rb biot) e a revelação feita com estreptavidina acoplada a molécula florescente CY3. Os cortes radiais e as retinas planas foram observadas em microscópio fluorescente equipado com câmara digital conectada a microcomputador dotado de programa para captura de imagens. A partir de imagens da retina obtidas com espaçamento mínimo de 0,5 mm foram feitas as contagens das células e os mapas de isodensidade celular. A densidade média dos fotorreceptores foi semelhante nas duas espécies (11.183,1 ± 1.107,4 células/mm2 em P. olfersii e 11.531,2 ± 1.054,9 células/mm2 em P. patagoniensis), assim como a proporção dos diferentes tipos de cones (3% cones S e 83% cones L/M em P. olfersii, e 5% cones S e 85% cones L/M em P. patagoniensis). As densidades de células da CCG também foram semelhantes (10.117,5 ± 1.026 células/mm2 em P. olfersii e 9.834,9 ± 2.772,2 células/mm2 em P. patagoniensis). Entretanto, os mapas de isodensidade mostraram diferentes regiões de especialização. P. olfersii apresentou uma faixa horizontal e duas areas centralis de maior densidade celular, uma na região central e uma na região caudal, indicando a melhor acuidade visual nos campos de visão frontal e lateral, o que possivelmente auxilia na locomoção e forrageamento no extrato arbóreo. P. patagoniensis apresentou maior densidade celular na região ventral e rostral, indicando a maior acuidade no campo visual superior e posterior, auxiliando na percepção da aproximação de predadores e animais maiores, importante para a sobrevivência de serpentes terrestres e possivelmente para a percepção de presas localizadas em estrato arbustivo.Snakes are a diversified group found in almost all regions of the planet, occupying different habitats, with exception to Polar Regions, a few islands and the deeper ocean waters. Its diversity indicates the high variability of sensory organs, which are adapted to the habits and habitats of each species. Studies about snakes visual system are scarce and have a great importance for the understanding of their ecology, behavior and phylogeny. In vertebrates the visual information is projected in the retina and initially processed in this neural tissue, before its processing in the central nervous system. The different kinds of cells present, as well as its density and distribution in the retina, vary between species and determinate specializations of the visual system. In this study we compared the density and distribution of photoreceptors and neurons of the ganglion cells layer (GCL) of two diurnal colubridae snakes, the arboreal Philodryas olfersii and the terrestrial P. patagoniensis, with opsins immunohistochemistry and Nissl staining. Adult snakes obtained in Instituto Butantan were anesthetized with thiopental (30mg/Kg) and the euthanasia was done with CO2. The eyes were enucleated and the retinas dissected and fixed in paraformaldeid 4%. One eye of each species was sectioned to test different antibodies and the counting for the determination of topographic distribution of density was made in flattened wholemount retinas. In the wholemounts retinas it was utilized the antibodies JH455 produced in rabbit against human S cone opsins and JH492 produced in rabbit against human L/M cone opsins. The photoreceptors density were similar in the two species (11,1831 ± 1,107.4 cells/mm2 in P. olfersii and 11,531.2 ± 1,054.9 cells/mm2 in P. patagoniensis), as well as the proportion of the different types of cells (3% S cones and 83% L/M cones in P. olfersii, and 5% S cones and 85% L/M cones in P. patagoniensis). The GCL cells density were also similar (10,117.5 ± 1,026 cells/mm2 in P. olfersii and 9,834.9 ± 2,772.2 cells/mm2 in P. patagoniensis). However, the isodensity maps showed different specializations regions. P. olfersii showed a horizontal streak and two areae (area centralis) with higher density, in the central and in the caudal regions, indicating a better visual acuity in the lateral and in the frontal visual field, what is possibly very important for locomotion and searching for preys (foraging) in the arboreal layer. P. patagoniensis showed a higher cell density in the ventral and rostral regions of the retina, indicating a better visual acuity in the superior and posterior visual field, what is important to perceive the approaching of predators and terrestrial animals and preys located in underbushes above the snake

Not informed by the author

As estruturas oculares dos vertebrados apresentam diversas adaptações relacionadas aos hábitats e atividades das espécies. A infra-ordem Serpentes possui amplo número de espécies distribuídas em quase todas as regiões da Terra e seu sistema visual apresenta variações que apontam para adaptações ecológicas. O presente estudo teve por objetivo fazer uma análise comparativa do sistema visual de diferentes espécies de serpentes Caenophidia, das famílias Dipsadidae e Colubridae, centrada no potencial de visão de cores, na densidade e topografia celular da retina e na acuidade visual. Para tanto, foram identificados os genes de opsinas expressos nas retinas, e analisadas a densidade e distribuição dos diferentes tipos de fotorreceptores e das células da camada de células ganglionares (CCG). As serpentes obtidas junto ao Laboratório de Herpetologia do Instituto Butantan foram sacrificadas com dose letal do anestésico thiopental. Os olhos foram enucleados e as retinas dissecadas para estudos genéticos e morfológicos, com imunohistoquímica e coloração de Nissl. Para sequenciamento dos genes das opsinas SWS1, Rh1 e LWS, dois olhos de 17 espécies foram utilizados. A amplificação por PCR mostrou que os três genes são expressos nas retinas de todas as espécies analisadas; o pico de sensibilidade espectral (max) de cada opsina foi estimado a partir das sequências de aminoácidos. O max do fotopigmento SWS1 foi estimado em 360 nm (UV), para todas as espécies. O fotopigmento Rh1, apresentou três diferentes combinações de aminoácidos que geram picos de sensibilidade em 500 nm, 494 nm e 484 nm. Todas as espécies de serpentes diurnas apresentaram a combinação de aminoácidos que gerou o max 484 nm. O fotopigmento LWS apresentou 4 diferentes combinações de aminoácidos, com max variando entre 543 nm e 560 nm. Para os estudos morfológicos foram utilizadas 86 retinas de 20 diferentes espécies. Retinas íntegras foram marcadas com anticorpos específicos para quantificação e análise topográfica de fotorreceptores. A coloração de Nissl foi empregada em retinas planas para quantificação de células da CCG e cálculo da acuidade visual. As análises morfológicas em retinas de serpentes noturnas mostraram uma grande densidade média de fotorreceptores (82.042 ± 37.945 células/mm2), com predominância de bastonetes, enquanto espécies diurnas apresentaram baixa densidade média de fotorreceptores (11.290 ± 2.810 células/mm2) e ausência de bastonetes. Serpentes noturnas apresentaram densidade média mais baixa de células da CCG (7.653 ± 1.636 4 células/mm2) comparada às diurnas (9.575 ± 2.301 células/mm2). O poder de resolução espacial também foi maior em espécies diurnas (2,3 ± 0,7 cpg) do que nas noturnas (1,45 ± 0,4 cpg). A distribuição de fotorreceptores e células da CCG nas retinas mostrou a presença de area centralis em diferentes regiões das retinas de espécies noturnas, e faixa horizontal em retinas das espécies diurnas, com exceção da serpente aquática e diurna Helicops modestus, que apresentou area centralis. As diferenças de localização das areae centralis variaram de acordo com hábitat e características comportamentais das espécies. Serpentes fossoriais do gênero Atractus, por exemplo, apresentaram area centralis na região dorsal da retina, que favorece o campo de visão inferior e auxilia no comportamento de escavar. Os resultados obtidos neste abrangente estudo apontam para a complexidade das adaptações do sistema visual deste grupo de vertebrados. As variações do padrão de atividade (diurna ou noturna) e uso de hábitat parecem ser fatores de forte influência sobre as características do sistema visual, como a sensibilidade espectral dos pigmentos visuais, a densidade e distribuição de neurônios nas retinas e o poder de resolução espacial do olhoThe structures of vertebrate eyes have many adaptations related to the habitats and activities of the species. The infra-order Serpentes has a large number of species distributed in almost all regions of the Earth and its visual system presents variations that point to ecological adaptations. This study aimed to compare the visual system of different species of Caenophidian snakes, from the Dipsadidae and Colubridae families. To do so, the opsin genes expressed in the retinas were identified and the density and distribution of the different types of photoreceptors and the cells of the ganglion cell layer (GCC) were analyzed. The snakes were colected from Butantan Institute and were sacrificed with a lethal dose of the anesthetic thiopental. The eyes were enucleated and the retinas dissected for genetic and morphological studies, using Nissl stainig technique and immunohistochemistry. For the sequencing the opsins genes SWS1, Rh1 and LWS, two eyes of 17 species were colected. PCR amplification showed that the three opsin genes are expressed in the retinas of all species analyzed; the maximum spectral sensitivity (max) of each opsin was estimated based on the amino acid sequences. The max of the SWS1 photopigment was estimated at 360 nm (UV), for all species. The photopigment Rh1 had three different combinations of amino acids that generate max at 500 nm, 494 nm and 484 nm. All diurnal species had the amino acid combination that generate the max at 484 nm. The photopigment LWS had 4 different combinations of amino acids with max ranging from 543 nm to 560 nm. For morphological studies, 86 retinas of 20 different species were analyzed. Wholemounted retinas were stained with specific antibodies for analysis of the photoreceptors density and topography. The Nissl stainig technique was used for quantification of GCL cells in flatmounted retinas and estimation of the spatial resolving power. Nocturnal snakes had retinas with higher photoreceptor densities (82,042 ± 37,945 cells/mm2), with predominance of rods, compared to diurnal species that had low photoreceptors density (11,290 ± 2,810 cells/mm2) and the absence of rods. On the other hand, diurnal snakes had higher density of GCL cells (9,575 ± 2,301 cells/mm2) and spatial resolving power (2.3 ± 0.7 cpd), compared to nocturnal (7,653 ± 1,636 cells/mm2 and 1.45 ± 0.4 cpg). The distribution of cells in the retinas had variations related to the circadian rhythm of the species, with the presence of area centralis in retinas of nocturnal species and horizontal streak in retinas of diurnal snakes, except for the diurnal and aquatic Helicops 6 modestus, that had an area centralis in the ventral retina. The location of the area centralis varies according the habitat and specific behavior of each species. The fossorial snake Atractus, for example, had an area in the dorsal retina, which improves the resolution of the inferior visual field and benefits the digging habit in this snake. The results of this comprehensive study point to the complexity of adaptations of the visual system of this group of vertebrates. The differences in the activity pattern (diurnal or nocturnal) and habitat seem to be of great influence on the characteristics of the visual system, such as the spectral sensitivity of the visual pigments, the density and distribution of neurons in the retina and the spatial resolving power of ey

Not informed by the author

As estruturas oculares dos vertebrados apresentam diversas adaptações relacionadas aos hábitats e atividades das espécies. A infra-ordem Serpentes possui amplo número de espécies distribuídas em quase todas as regiões da Terra e seu sistema visual apresenta variações que apontam para adaptações ecológicas. O presente estudo teve por objetivo fazer uma análise comparativa do sistema visual de diferentes espécies de serpentes Caenophidia, das famílias Dipsadidae e Colubridae, centrada no potencial de visão de cores, na densidade e topografia celular da retina e na acuidade visual. Para tanto, foram identificados os genes de opsinas expressos nas retinas, e analisadas a densidade e distribuição dos diferentes tipos de fotorreceptores e das células da camada de células ganglionares (CCG). As serpentes obtidas junto ao Laboratório de Herpetologia do Instituto Butantan foram sacrificadas com dose letal do anestésico thiopental. Os olhos foram enucleados e as retinas dissecadas para estudos genéticos e morfológicos, com imunohistoquímica e coloração de Nissl. Para sequenciamento dos genes das opsinas SWS1, Rh1 e LWS, dois olhos de 17 espécies foram utilizados. A amplificação por PCR mostrou que os três genes são expressos nas retinas de todas as espécies analisadas; o pico de sensibilidade espectral (max) de cada opsina foi estimado a partir das sequências de aminoácidos. O max do fotopigmento SWS1 foi estimado em 360 nm (UV), para todas as espécies. O fotopigmento Rh1, apresentou três diferentes combinações de aminoácidos que geram picos de sensibilidade em 500 nm, 494 nm e 484 nm. Todas as espécies de serpentes diurnas apresentaram a combinação de aminoácidos que gerou o max 484 nm. O fotopigmento LWS apresentou 4 diferentes combinações de aminoácidos, com max variando entre 543 nm e 560 nm. Para os estudos morfológicos foram utilizadas 86 retinas de 20 diferentes espécies. Retinas íntegras foram marcadas com anticorpos específicos para quantificação e análise topográfica de fotorreceptores. A coloração de Nissl foi empregada em retinas planas para quantificação de células da CCG e cálculo da acuidade visual. As análises morfológicas em retinas de serpentes noturnas mostraram uma grande densidade média de fotorreceptores (82.042 ± 37.945 células/mm2), com predominância de bastonetes, enquanto espécies diurnas apresentaram baixa densidade média de fotorreceptores (11.290 ± 2.810 células/mm2) e ausência de bastonetes. Serpentes noturnas apresentaram densidade média mais baixa de células da CCG (7.653 ± 1.636 4 células/mm2) comparada às diurnas (9.575 ± 2.301 células/mm2). O poder de resolução espacial também foi maior em espécies diurnas (2,3 ± 0,7 cpg) do que nas noturnas (1,45 ± 0,4 cpg). A distribuição de fotorreceptores e células da CCG nas retinas mostrou a presença de area centralis em diferentes regiões das retinas de espécies noturnas, e faixa horizontal em retinas das espécies diurnas, com exceção da serpente aquática e diurna Helicops modestus, que apresentou area centralis. As diferenças de localização das areae centralis variaram de acordo com hábitat e características comportamentais das espécies. Serpentes fossoriais do gênero Atractus, por exemplo, apresentaram area centralis na região dorsal da retina, que favorece o campo de visão inferior e auxilia no comportamento de escavar. Os resultados obtidos neste abrangente estudo apontam para a complexidade das adaptações do sistema visual deste grupo de vertebrados. As variações do padrão de atividade (diurna ou noturna) e uso de hábitat parecem ser fatores de forte influência sobre as características do sistema visual, como a sensibilidade espectral dos pigmentos visuais, a densidade e distribuição de neurônios nas retinas e o poder de resolução espacial do olhoThe structures of vertebrate eyes have many adaptations related to the habitats and activities of the species. The infra-order Serpentes has a large number of species distributed in almost all regions of the Earth and its visual system presents variations that point to ecological adaptations. This study aimed to compare the visual system of different species of Caenophidian snakes, from the Dipsadidae and Colubridae families. To do so, the opsin genes expressed in the retinas were identified and the density and distribution of the different types of photoreceptors and the cells of the ganglion cell layer (GCC) were analyzed. The snakes were colected from Butantan Institute and were sacrificed with a lethal dose of the anesthetic thiopental. The eyes were enucleated and the retinas dissected for genetic and morphological studies, using Nissl stainig technique and immunohistochemistry. For the sequencing the opsins genes SWS1, Rh1 and LWS, two eyes of 17 species were colected. PCR amplification showed that the three opsin genes are expressed in the retinas of all species analyzed; the maximum spectral sensitivity (max) of each opsin was estimated based on the amino acid sequences. The max of the SWS1 photopigment was estimated at 360 nm (UV), for all species. The photopigment Rh1 had three different combinations of amino acids that generate max at 500 nm, 494 nm and 484 nm. All diurnal species had the amino acid combination that generate the max at 484 nm. The photopigment LWS had 4 different combinations of amino acids with max ranging from 543 nm to 560 nm. For morphological studies, 86 retinas of 20 different species were analyzed. Wholemounted retinas were stained with specific antibodies for analysis of the photoreceptors density and topography. The Nissl stainig technique was used for quantification of GCL cells in flatmounted retinas and estimation of the spatial resolving power. Nocturnal snakes had retinas with higher photoreceptor densities (82,042 ± 37,945 cells/mm2), with predominance of rods, compared to diurnal species that had low photoreceptors density (11,290 ± 2,810 cells/mm2) and the absence of rods. On the other hand, diurnal snakes had higher density of GCL cells (9,575 ± 2,301 cells/mm2) and spatial resolving power (2.3 ± 0.7 cpd), compared to nocturnal (7,653 ± 1,636 cells/mm2 and 1.45 ± 0.4 cpg). The distribution of cells in the retinas had variations related to the circadian rhythm of the species, with the presence of area centralis in retinas of nocturnal species and horizontal streak in retinas of diurnal snakes, except for the diurnal and aquatic Helicops 6 modestus, that had an area centralis in the ventral retina. The location of the area centralis varies according the habitat and specific behavior of each species. The fossorial snake Atractus, for example, had an area in the dorsal retina, which improves the resolution of the inferior visual field and benefits the digging habit in this snake. The results of this comprehensive study point to the complexity of adaptations of the visual system of this group of vertebrates. The differences in the activity pattern (diurnal or nocturnal) and habitat seem to be of great influence on the characteristics of the visual system, such as the spectral sensitivity of the visual pigments, the density and distribution of neurons in the retina and the spatial resolving power of ey

Characterization of the melanopsin gene (Opn4x) of diurnal and nocturnal snakes

Abstract Background A number of non-visual responses to light in vertebrates, such as circadian rhythm control and pupillary light reflex, are mediated by melanopsins, G-protein coupled membrane receptors, conjugated to a retinal chromophore. In non-mammalian vertebrates, melanopsin expression is variable within the retina and extra-ocular tissues. Two paralog melanopsin genes were classified in vertebrates, Opn4x and Opn4m. Snakes are highly diversified vertebrates with a wide range of daily activity patterns, which raises questions about differences in structure, function and expression pattern of their melanopsin genes. In this study, we analyzed the melanopsin genes expressed in the retinas of 18 snake species from three families (Viperidae, Elapidae, and Colubridae), and also investigated extra-retinal tissue expression. Results Phylogenetic analysis revealed that the amplified gene belongs to the Opn4x group, and no expression of the Opn4m was found. The same paralog is expressed in the iris, but no extra-ocular expression was detected. Molecular evolutionary analysis indicated that melanopsins are evolving primarily under strong purifying selection, although lower evolutionary constraint was detected in snake lineages (ω = 0.2), compared to non-snake Opn4x and Opn4m (ω = 0.1). Statistical analysis of selective constraint suggests that snake phylogenetic relationships have driven stronger effects on melanopsin evolution, than the species activity pattern. In situ hybridization revealed the presence of melanopsin within cells in the outer and inner nuclear layers, in the ganglion cell layer, and intense labeling in the optic nerve. Conclusions The loss of the Opn4m gene and extra-ocular photosensitive tissues in snakes may be associated with a prolonged nocturnal/mesopic bottleneck in the early history of snake evolution. The presence of melanopsin-containing cells in all retinal nuclear layers indicates a globally photosensitive retina, and the expression in classic photoreceptor cells suggest a regionalized co-expression of melanopsin and visual opsins

A Comparative Study of the Distribution and Density of Retinal Ganglion Cells and Visual Acuity in Bothrops Snakes with Differences in the Habitat Use

Purpose: The density and distribution of neurons in retinas of vertebrates are associated with specific behaviors and species ecology. The visual system of snakes has adaptations to the species’ habitats, circadian rhythm, and foraging strategies. A previous study revealed a ventral area centralis in a terrestrial snake and a visual streak in a close related arboreal species. In this study, we compared the distribution of ganglion cell layer (GCL) cells in retinas of Viperidae snakes from the genus Bothrops, with differences in the habitat use, namely the arboreal B. insularis, and the semi-arboreal species B. jararaca and B. sazimai. Methods: Three individuals of each species were euthanized with Thionembutal (100 mg/kg). The eyes were enucleated and retinas were dissected and fixed in 4% paraformaldehyde. Retinas were wholemounted and Nissl stained. The density of GCL cells was estimated using a stereological approach with the Stereo Investigator software (MicroBrightField), and isodensity maps were obtained using OriginPro 8.5.1. Visual acuity values were estimated based on the peak density of GCL cells and the eyes focal length. Results: We observed a poorly defined horizontal streak in retinas of the arboreal B. insularis, with higher density in the central retina, while in the semi-arboreal B. jararaca and B. sazimai there were no defined retinal specializations, and the peak cell densities were located in the temporal region. The mean cell density was 4,405 ± 735 cells/mm2 in B. insularis, 4,606 ± 335 cells/mm2 in B. sazimai, and 4,881 ± 746cells/mm2 in B. jararaca. The estimated spatial resolutions were similar among the species and varied from 2.0 to 2.2 cycles per degree. Conclusions: These findings reinforce the hypothesis that retinal specializations are associated with habitat use in snakes. A visual streak may assist in locomotion and hunting among branches, as indicated by the distribution of cells in B. insularis. On the other hand, peak GCL cell density in the temporal retina may facilitate striking behavior in the species that forage on the ground