Embark, H., Hawryshyn, C. (2014). Aquatic Environments and Spectral Sensitivity of Rod Visual Pigments in the Retina of Rainbow Trout (Oncorhynchus mykiss): A Microspectrophotometric Study. Suez Canal Veterinary Medical Journal. SCVMJ, 19(2), 309-319. doi: 10.21608/scvmj.2014.65859
H. Embark; C. Hawryshyn. "Aquatic Environments and Spectral Sensitivity of Rod Visual Pigments in the Retina of Rainbow Trout (Oncorhynchus mykiss): A Microspectrophotometric Study". Suez Canal Veterinary Medical Journal. SCVMJ, 19, 2, 2014, 309-319. doi: 10.21608/scvmj.2014.65859
Embark, H., Hawryshyn, C. (2014). 'Aquatic Environments and Spectral Sensitivity of Rod Visual Pigments in the Retina of Rainbow Trout (Oncorhynchus mykiss): A Microspectrophotometric Study', Suez Canal Veterinary Medical Journal. SCVMJ, 19(2), pp. 309-319. doi: 10.21608/scvmj.2014.65859
Embark, H., Hawryshyn, C. Aquatic Environments and Spectral Sensitivity of Rod Visual Pigments in the Retina of Rainbow Trout (Oncorhynchus mykiss): A Microspectrophotometric Study. Suez Canal Veterinary Medical Journal. SCVMJ, 2014; 19(2): 309-319. doi: 10.21608/scvmj.2014.65859
Aquatic Environments and Spectral Sensitivity of Rod Visual Pigments in the Retina of Rainbow Trout (Oncorhynchus mykiss): A Microspectrophotometric Study
1Department of Animal Physiology, Faculty of Vet. Medicine, South Valley University, Qena, Egypt
2Department of Biology, Queen’s University, Kingston, Ontario, Canada
Abstract
The vertebrate retina is a part of the central nervous system (CNS) that can be visualized in a non-invasive manner. The retina is a thin multi-layered sensory tissue of neural cells that contains millions of photoreceptors. There are two physiologically distinct types of photoreceptors across the retina, the cones and the rods. The light sensitivity of the photoreceptors results from the presence of visual pigment molecules in the outer segment of the cone and rod cells. All visual pigments are composed of two components: retinal (vitamin A aldehyde), termed a chromophore, bound to a protein called opsin. The spectral absorption properties of a visual pigment are mainly determined by the amino acid sequence of the opsin protein and the type of chromophore (A1 or A2 or mixed) bound to the opsin. There is a shifting from A1- to A2-based chromophores in the same opsin due to different environmental factors, e.g. aquatic environments. A1/A2 visual pigment ratios play a dominant role in determining rod λmax in rainbow trout (Oncorhynchus mykiss), shifting the λmax of the visual pigment and spectral bandwidth of absorbance (HBW, half-band width). The spectral absorption characteristics of the retinal rod photoreceptors in the Rainbow Trout (Oncorhynchus mykiss) were measured using the charge-coupled device (CCD)- based microspectrophotometer (MSP) system. We investigated retina preparations of juvenile rainbow trout (Oncorhynchus mykiss) using 54 rod photoreceptors. The spectral sensitivity of each rod photoreceptor was calculated using λmax (wavelength of maximum absorbance) and HBW. The mean wavelength of maximum absorbance values for the alpha-bands were 503.5±2.5nm for rhodopsin- dominated rods, 523.1±7.9nm for porphyropsin-dominated rods, and 509.6±1.9nm for rhodopsin porphyropsin mixed rods. The half-band width (HBW) of the main absorption bands was 4567±771 cm-1 for vitamin A1-based visual pigments and 4697±487 cm-1 for vitamin A2-based visual pigments. Our results provide the evidence of shifting the λmax of the visual pigment to a longer wavelength, broadening spectral bandwidth of absorbance, and presence three fundamentally different classes of rod photoreceptors in the retina of the rainbow trout depending on A1/A2 visual pigment ratios due to different environmental variables, e.g. aquatic environments.