Exploring the Origin and Physiological Significance of DNA Double Strand Breaks in the Developing Neuroretina.

Genetic mosaicism is an intriguing physiological feature of the mammalian brain that generates altered genetic information and provides cellular, and prospectively functional, diversity in a manner similar to that of the immune system. However, both its origin and its physiological significance remain poorly characterized. Most, if not all, cases of somatic mosaicism require prior generation and repair of DNA double strand breaks (DSBs). The relationship between DSB generation, neurogenesis, and early neuronal cell death revealed by our studies in the developing retina provides new perspectives on the different mechanisms that contribute to DNA rearrangements in the developing brain. Here, we speculate on the physiological significance of these findings.

RAG-2 deficiency results in fewer phosphorylated histone H2AX foci, but increased retinal ganglion cell death and altered axonal growth.

DNA double-strand breaks (DSBs), selectively visualized as γ-H2AX+ foci, occur during the development of the central nervous system, including the retina, although their origin and biological significance are poorly understood. Mutant mice with DSB repair mechanism defects exhibit increased numbers of γ-H2AX+ foci, increased cell death during neural development, and alterations in axonogenesis in the embryonic retina. The aim of this study was to identify putative sources of DSBs. One of the identified DSBs sources is LINE-1 retrotransposition. While we did not detect changes in LINE-1 DNA content during the early period of cell death associated with retinal neurogenesis, retinal development was altered in mice lacking RAG-2, a component of the RAG-1,2-complex responsible for initiating somatic recombination in lymphocytes. Although γ-H2AX+ foci were less abundant in the rag2-/- mouse retina, retinal ganglion cell death was increased and axonal growth and navigation were impaired in the RAG-2 deficient mice, a phenotype shared with mutant mice with defective DNA repair mechanisms. These findings demonstrate that RAG-2 is necessary for proper retinal development, and suggest that both DSB generation and repair are genuine processes intrinsic to neural development.

Increased neuronal death and disturbed axonal growth in the Polµ-deficient mouse embryonic retina.

Programmed cell death occurs naturally at different stages of neural development, including neurogenesis. The functional role of this early phase of neural cell death, which affects recently differentiated neurons among other cell types, remains undefined. Some mouse models defective in DNA double-strand break (DSB) repair present massive cell death during neural development, occasionally provoking embryonic lethality, while other organs and tissues remain unaffected. This suggests that DSBs occur frequently and selectively in the developing nervous system. We analyzed the embryonic retina of a mouse model deficient in the error-prone DNA polymerase µ (Polµ), a key component of the non-homologous end-joining (NHEJ) repair system. DNA DSBs were increased in the mutant mouse at embryonic day 13.5 (E13.5), as well as the incidence of cell death that affected young neurons, including retinal ganglion cells (RGCs). Polµ(-/-) mice also showed disturbed RGC axonal growth and navigation, and altered distribution of the axonal guidance molecules L1-CAM and Bravo (also known as Nr-CAM). These findings demonstrate that Polµ is necessary for proper retinal development, and support that the generation of DSBs and their repair via the NHEJ pathway are genuine processes involved in neural development.

Microglia-Müller glia crosstalk in the rd10 mouse model of retinitis pigmentosa.

Retinitis pigmentosa refers to a large, genetically heterogeneous group of retinal dystrophies. This condition is characterized by the gradual onset of blindness due to progressive deterioration of the retina, a process that includes photoreceptor and retinal-pigmented-epithelium cell decay and death, microglial recruitment, reactive gliosis, and vascular disorganization and regression. We found that early in the degenerative process, the rd10 mouse retina exhibits high levels of photoreceptor cell death and reactive Müller gliosis. In explant cultures, both degenerative processes were abrogated by IGF-I treatment. Moreover, the beneficial effect of IGF-I was diminished by microglial depletion using clodronate-containing liposomes. Interestingly, in the absence of IGF-I, microglial depletion partially prevented cell death without affecting Müller gliosis. These findings strongly suggest a role for microglia-Müller glia crosstalk in neuroprotection. However, a subpopulation of microglial cells appears to promote neurodegeneration in the dystrophic retina. Our findings indicate that beneficial neuroprotective effects may be achieved through strategies that modulate microglial cell responses.

Microglia-mediated IGF-I neuroprotection in the rd10 mouse model of retinitis pigmentosa.

PURPOSE: To characterize the effect of IGF-I in the rd10 mouse model of retinitis pigmentosa at the cellular level, focusing on the role of microglia in the neurodegenerative process. METHODS: Both organotypic retinal explants and intravitreal injections were used to assess the effect of IGF-I on photoreceptor cell death in the Pde6b(rd10) mice. Cell death was determined by TUNEL in retinal sections and by ELISA of free nucleosomes in retinal extracts. The number and distribution of microglial cells was visualized by immunolabeling with Cd11b and Iba1 antibodies. Depletion of microglia in culture was achieved by treatment with liposomes containing clodronate. RESULTS: Both ex vivo and in vivo IGF-I treatment reduced the number of TUNEL-positive nuclei in rd10 mouse retinas. In addition, IGF-I treatment in explants increased the number of microglial cells in the ONL. Depletion of microglia in explants with liposomes containing clodronate diminished the neuroprotective effect of IGF-I but also moderately reduced photoreceptor cell death in rd10 retinas cultured in the absence of IGF-I. CONCLUSIONS: IGF-I is able to attenuate photoreceptor cell death both ex vivo and in vivo in the rd10 mouse retina. Microglia is required for the neuroprotective effect of IGF-I in the dystrophic retina. In addition, microglial cells play a detrimental role, seemingly led to neuroprotection by IGF-I.