Objectives: The objectives of the study were to investigate the responses of different retinal ganglion cell (RGC) populations to diverse injuries [transient ischemia induced by acute ocular hypertension (AOH), excitotoxicity induced by intravitreal injection of 100 mM N‐methyl D‐aspartate (NMDA) or intra‐orbital optic nerve transection (IONT)] and protection with selective agonists of the tropomyosin related kinase B (TrkB) receptor, brain‐derived neurotrophic factor (BDNF) or 7,8‐Dihydroxyflavone (DHF) or with a voltage‐dependent calcium channel blocker (ITH12657).Methods: Adult Sprague–Dawley rats were used. In the first group, the left eye received a single intravitreal injection of 5 μL vehicle or 5 μg BDNF and was connected to a saline reservoir elevated above the eye to induce an acute ocular hypertension (AOH) and transient ischemia for 75 min. These rats were analysed at different survival intervals from 3 to 45 days.A second group were treated daily subcutaneously with vehicle or ITH5263 (10 mg/kg), or intraperitoneally with vehicle or DHF (5 mg/kg), starting 12 h prior to an intraocular injection of 100 mM N‐methyl‐D‐aspartate (NMDA) to induce retinal excitotoxicity. These rats were analysed at different survival intervals from 3 to 21 days.A third group received a left intra‐orbital optic nerve transection (IONT) to induce axotomy of the RGC population and were treated daily with an intraperitoneal injection of vehicle (0.9% NaCl containing 1% DMSO) or DHF (5 mg/kg diluted in vehicle). These rats were analysed at survival intervals from 3 to 60 days.The retinas were prepared as wholemounts and immunolabelled for Brn3a, melanopsin (m), Osteopontin (OPN) and the T‐box transcription factor T‐brain‐2 (Tbr2) to identify the following retinal ganglion cell populations: Brn3a+, melanopsin+, α‐like (OPN+), α‐ON sustained RGCs (OPN+Tbr2+), α‐ON transient RGCs (OPN+ Brn3a− Tbr2−) and α‐OFF like (OPN+Brn3a+). The labelled RGCs were quantified automatically (Brn3a) or dotted manually and quantified with a graphic software, and distribution of the different populations were represented on topographical maps.Results: Our studies document that:(i) AOH induces progressive loss of Brn3a+RGCs and a significant but not progressive loss of m+RGCs. Treatment with BDNF afforded significant long‐lasting protection for both RGC populations.(ii) Intravitreal injection of NMDA resulted at 7 days in the abrupt significant loss of Brn3a+RGCs, αRGC and αONs‐RGCs without further progression, whereas αOFF‐RGCs died massively. Both m+RGCs and αONtRGCs appear fully resistant to NMDA‐induced excitotoxicity. Both ITH12657 or DHF protect Brn3a+RGC, αRGCs and αONs‐RGCs, but not αOFF‐RGCs.(iii) IONT and vehicle treatment result in a characteristic rapid loss of Brn3a, melanopsin RGCs, αRGCs, αONs‐RGCs and αOFF‐RGCs. DHFs protect Brn3a + RGC, m + RGCs, αRGCs and αONs‐RGCs, but not αOFF‐RGCs.Conclusions: Thus, three different RGC populations (Brn3a+, m+ and α‐like) respond distinctly to different injuries and neuroprotective agents, further adding to the idea that each type of RGC has a unique response to injury and protection. Deciphering the molecular mechanisms of each RGC type will help understand neuronal responses to injury and its possible prevention.
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