AI Article Synopsis
- Most deep-sea fish typically have a visual pigment sensitive to short wavelengths, aligning with sunlight and bioluminescent light, but Malcosteus niger has adaptations for far-red bioluminescence, including special visual pigments and a unique photosensitizer derived from bacteriochlorophyll.
- Research aimed to identify whether this photosensitizer originated from endosymbiotic bacteria next to photoreceptors but found no evidence of localized bacteria; instead, the photosensitizer was dispersed throughout the retina.
- Comparisons of mRNA from Malacosteus niger and its relative Pachystomias microdon showed no bacterial genes up-regulated in Malacosteus, but highlighted genes related to photosensitivity that may
Article Abstract
Most deep-sea fish have a single visual pigment maximally sensitive at short wavelengths, approximately matching the spectrum of both downwelling sunlight and bioluminescence. However, Malcosteus niger produces far-red bioluminescence and its longwave retinal sensitivity is enhanced by red-shifted visual pigments, a longwave reflecting tapetum and, uniquely, a bacteriochlorophyll-derived photosensitizer. The origin of the photosensitizer, however, remains unclear. We investigated whether the bacteriochlorophyll was produced by endosymbiotic bacteria within unusual structures adjacent to the photoreceptors that had previously been described in this species. However, microscopy, elemental analysis and SYTOX green staining provided no evidence for such localised retinal bacteria, instead the photosensitizer was shown to be distributed throughout the retina. Furthermore, comparison of mRNA from the retina of Malacosteus to that of the closely related Pachystomias microdon (which does not contain a bacterichlorophyll-derived photosensitzer) revealed no genes of bacterial origin that were specifically up-regulated in Malacosteus. Instead up-regulated Malacosteus genes were associated with photosensitivity and may relate to its unique visual ecology and the chlorophyll-based visual system. We also suggest that the unusual longwave-reflecting, astaxanthin-based, tapetum of Malacosteus may protect the retina from the potential cytotoxicity of such a system.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5171636 | PMC |
| http://dx.doi.org/10.1038/srep39395 | DOI Listing |
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Article Synopsis
- Most deep-sea fish typically have a visual pigment sensitive to short wavelengths, aligning with sunlight and bioluminescent light, but Malcosteus niger has adaptations for far-red bioluminescence, including special visual pigments and a unique photosensitizer derived from bacteriochlorophyll.
- Research aimed to identify whether this photosensitizer originated from endosymbiotic bacteria next to photoreceptors but found no evidence of localized bacteria; instead, the photosensitizer was dispersed throughout the retina.
- Comparisons of mRNA from Malacosteus niger and its relative Pachystomias microdon showed no bacterial genes up-regulated in Malacosteus, but highlighted genes related to photosensitivity that may
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