Modeling Activity and Target-Dependent Developmental Cell Death of Mouse Retinal Ganglion Cells Ex Vivo

Programmed cell death is widespread during the development of the central nervous system and serves multiple purposes including the establishment of neural connections. In the mouse retina a substantial reduction of retinal ganglion cells (RGCs) occurs during the first postnatal week, coinciding with the formation of retinotopic maps in the superior colliculus (SC). We previously established a retino-collicular culture preparation which recapitulates the progressive topographic ordering of RGC projections during early post-natal life. Here, we questioned whether this model could also be suitable to examine the mechanisms underlying developmental cell death of RGCs. Brn3a was used as a marker of the RGCs. A developmental decline in the number of Brn3a-immunolabelled neurons was found in the retinal explant with a timing that paralleled that observed in vivo. In contrast, the density of photoreceptors or of starburst amacrine cells increased, mimicking the evolution of these cell populations in vivo. Blockade of neural activity with tetrodotoxin increased the number of surviving Brn3a-labelled neurons in the retinal explant, as did the increase in target availability when one retinal explant was confronted with 2 or 4 collicular slices. Thus, this ex vivo model reproduces the developmental reduction of RGCs and recapitulates its regulation by neural activity and target availability. It therefore offers a simple way to analyze developmental cell death in this classic system. Using this model, we show that ephrin-A signaling does not participate to the regulation of the Brn3a population size in the retina, indicating that eprhin-A-mediated elimination of exuberant projections does not involve developmental cell death

The life, death and regenerative ability of immature and mature rat retinal ganglion cells are influenced by their birthdate.

The extensive period of retinal ganglion cell (RGC) neurogenesis in the rat is associated with a protracted sequence of arrival of their axons into central targets such as the superior colliculus (SC) (Dallimore et al., 2002). Using in utero 5-bromo-2'-deoxyrudine (BrdU) injections to label early (embryonic day (E) 15) or late (E18 or E19) born RGCs, we now show that E15 RGCs with axons that enter the SC prenatally undergo programmed cell death earlier than late-born RGCs whose axons only reach the SC late in the first postnatal week. These late-born RGCs do not begin to die until postnatal day (P) 5/6. Removal of retrograde trophic support by P1 SC ablation initially only affects E15 RGCs; however by P5 death of late-born RGCs is increased, confirming that a switch to target dependency is delayed in this cohort. In a further experiment it was found that, following complete rostral SC transection at P2, the proportion of post-lesion axons originating from E19 RGCs was significantly greater than the proportion that normally makes up the retinotectal projection. Thus, even in neonatal brain, uninjured late-arriving axons are more likely to grow across a lesion site than injured axons undergoing regeneration. To study if birth date also affects regenerative potential in adulthood, autologous peripheral nerve (PN) was grafted onto the cut optic nerve in mature BrdU labelled rats. We found that, compared to E15 RGCs, a significantly greater proportion of late-born RGCs survived axotomy, but comparatively fewer of these surviving E19 RGCs regrew an axon into a graft. In summary, this research shows that the birthdate of RGCs significantly impacts on their subsequent life history and response to injury. Understanding how developing central nervous system (CNS) neurons acquire dependency on target-derived trophic support may lead to new strategies for enhancing survival and regeneration in adult CNS