[HTML][HTML] Death by color: differential cone loss in the aging mouse retina

A Cunea, MB Powner, G Jeffery - Neurobiology of aging, 2014 - Elsevier
Neurobiology of aging, 2014Elsevier
Differential cell death is a common feature of aging and age-related disease. In the retina,
30% of rod photoreceptors are lost over life in humans and rodents. However, studies have
failed to show age-related cell death in mouse cone photoreceptors, which is surprising
because cone physiological function declines with age. Moreover in human, differential loss
of short wavelength cone function is an aspect of age-related retinal disease. Here, cones
are examined in young (3-month-old) and aged (12-month-old) C57 mice and also in …
Abstract
Differential cell death is a common feature of aging and age-related disease. In the retina, 30% of rod photoreceptors are lost over life in humans and rodents. However, studies have failed to show age-related cell death in mouse cone photoreceptors, which is surprising because cone physiological function declines with age. Moreover in human, differential loss of short wavelength cone function is an aspect of age-related retinal disease. Here, cones are examined in young (3-month-old) and aged (12-month-old) C57 mice and also in complement factor H knock out mice (CFH−/−) that have been proposed as a murine model of age-related macular degeneration. In vivo imaging showed significant age-related reductions in outer retinal thickness in both groups over this period. Immunostaining for opsins revealed a specific significant decline of >20% for the medium/long (M/L)-wavelength cones but only in the periphery. S cones numbers were not significantly affected by age. This differential cell loss was backed up with quantitative real-time polymerase chain reaction for the 2 opsins, again showing S opsin was unaffected, but that M/L opsin was reduced particularly in CFH−/− mice. These results demonstrate aged cone loss, but surprisingly, in both genotypes, it is only significant in the peripheral ventral retina and focused on the M/L population and not S cones. We speculate that there may be fundamental differences in differential cone loss between human and mouse that may question the validity of mouse models of human outer retinal aging and pathology.
Elsevier