Detailed electroretinographic findings in rd8 mice.

PURPOSE: Previous work has suggested that the retinal degeneration mutant rd8 mouse lacks an electroretinographic (ERG) phenotype until about 9 months of age. We evaluated the ERG phenotype of these mice by measuring both conventional ERG responses and scotopic threshold responses. METHODS: Groups of 4-month-old wild-type (WT) and mutant (rd8) mice were anesthetized and tested for mass retinal responses (ERGs) to several types of visual stimuli. Scotopic threshold responses were accumulated with brief scotopic flashes at a series of very dim intensities. Dark-adapted (scotopic) and light-adapted (photopic) responses to brief flashes at a series of higher intensities were recorded, along with long flashes and random modulations of light levels under photopic conditions. RESULTS: Negative scotopic threshold responses (nSTRs) had lower amplitudes in rd8 mice compared to WTs. Positive scotopic threshold responses were similar in the two groups. With the more intense stimuli, a- and c-wave amplitudes were smaller in rd8 mice. Both scotopic and photopic b-wave amplitudes tended to be larger in rd8 mice, though generally not significantly. CONCLUSIONS: The striking decrease in nSTR amplitudes was surprising, given that the main retinal effects of the rd8 mutation occur in the outer retina, at the external limiting membrane. The primary source of nSTRs in mice is thought to be at the amacrine cell level in the inner retina. Investigation of how this mutation leads to inner retinal dysfunction might reveal unexpected aspects of retinal cell biology and circuitry.

A case of mistaken identity: CD11c-eYFP(+) cells in the normal mouse brain parenchyma and neural retina display the phenotype of microglia, not dendritic cells.

Under steady-state conditions the central nervous system (CNS) is traditionally thought to be devoid of antigen presenting cells; however, putative dendritic cells (DCs) expressing enhanced yellow fluorescent protein (eYFP) are present in the retina and brain parenchyma of CD11c-eYFP mice. We previously showed that these mice carry the Crb1(rd8) mutation, which causes retinal dystrophic lesions; therefore we hypothesized that the presence of CD11c-eYFP(+) cells within the CNS may be due to pathology associated with the Crb1(rd8) mutation. We generated CD11c-eYFP Crb1(wt/wt) mice and compared the distribution and immunophenotype of CD11c-eYFP(+) cells in CD11c-eYFP mice with and without the Crb1(rd8) mutation. The number and distribution of CD11c-eYFP(+) cells in the CNS was similar between CD11c-eYFP Crb1(wt/wt) and CD11c-eYFP Crb1(rd8/rd8) mice. CD11c-eYFP(+) cells were distributed throughout the inner retina, and clustered in brain regions that receive input from the external environment or lack a blood-brain barrier. CD11c-eYFP(+) cells within the retina and cerebral cortex of CD11c-eYFP Crb1(wt/wt) mice expressed CD11b, F4/80, CD115 and Iba-1, but not DC or antigen presentation markers, whereas CD11c-eYFP(+) cells within the choroid plexus and pia mater expressed CD11c, I-A/I-E, CD80, CD86, CD103, DEC205, CD8α and CD135. The immunophenotype of CD11c-eYFP(+) cells and microglia within the CNS was similar between CD11c-eYFP Crb1(wt/wt) and CD11c-eYFP Crb1(rd8/rd8) mice; however, CD11c and I-A/I-E expression was significantly increased in CD11c-eYFP Crb1(rd8/rd8) mice. This study demonstrates that the overwhelming majority of CNS CD11c-eYFP(+) cells do not display the phenotype of DCs or their precursors and are most likely a subpopulation of microglia. GLIA 2016. GLIA 2016;64:1331-1349.