A comparison of the ultrastructure of the cornea of the pre- and post-metamorphic axolotl (Ambystoma mexicanum, Amphibia).

The corneal ultrastructure of the pre- and post-metamorphic stages of the neotenic axolotl Ambystoma mexicanum is examined using light microscopy and both scanning and transmission electron microscopy to reveal whether there are any morphological changes associated with a switch in lifestyle. Although the complement of corneal layers remains the same, there are significant quantitative changes in corneal, epithelial and stromal thickness, epithelial and endothelial cell size and density, and the thickness of Bowman's layer and Desçemet's membrane. Microholes in the epithelium and vertical sutures within the stroma are predominant features in the pre-metamorphic stage but are rarely seen in the post-metamorphic stage. There are also significant quantitative centro-peripheral differences in the thickness of the whole cornea, primarily due to differences in the thickness of the stroma in both metamorphic stages. These changes may reflect the physiological demands on the cornea as it switches from a purely aquatic to an amphibious lifestyle, which includes venturing onto land.

Eye-size variability in deep-sea lanternfishes (Myctophidae): an ecological and phylogenetic study.

One of the most common visual adaptations seen in the mesopelagic zone (200-1000 m), where the amount of light diminishes exponentially with depth and where bioluminescent organisms predominate, is the enlargement of the eye and pupil area. However, it remains unclear how eye size is influenced by depth, other environmental conditions and phylogeny. In this study, we determine the factors influencing variability in eye size and assess whether this variability is explained by ecological differences in habitat and lifestyle within a family of mesopelagic fishes characterized by broad intra- and interspecific variance in depth range and luminous patterns. We focus our study on the lanternfish family (Myctophidae) and hypothesise that lanternfishes with a deeper distribution and/or a reduction of bioluminescent emissions have smaller eyes and that ecological factors rather than phylogenetic relationships will drive the evolution of the visual system. Eye diameter and standard length were measured in 237 individuals from 61 species of lanternfishes representing all the recognised tribes within the family in addition to compiling an ecological dataset including depth distribution during night and day and the location and sexual dimorphism of luminous organs. Hypotheses were tested by investigating the relationship between the relative size of the eye (corrected for body size) and variations in depth and/or patterns of luminous-organs using phylogenetic comparative analyses. Results show a great variability in relative eye size within the Myctophidae at all taxonomic levels (from subfamily to genus), suggesting that this character may have evolved several times. However, variability in eye size within the family could not be explained by any of our ecological variables (bioluminescence and depth patterns), and appears to be driven solely by phylogenetic relationships.