Regenerative neurogenic response from glia requires insulin driven neuron-glia communication

Understanding how injury to the Central Nervous System (CNS) induces de novo neurogenesis in animals would help promote regeneration in humans. Regenerative neurogenesis could originate from glia and glial Neuron-Glia antigen-2 (NG2) may sense injury-induced neuronal signals, but these are unknown. Here, we used Drosophila to search for genes functionally related the NG2 homologue kon-tiki (kon), and identified Islet Antigen-2 (Ia-2), required in neurons for insulin secretion. Alterations in Ia-2 function induced neural stem cell gene expression, injury increased ia-2 expression and induced ectopic neural stem cells. Using genetic analysis and lineage tracing, we demonstrate that Ia-2 and Kon regulate Drosophila insulin-like peptide 6 (Dilp-6), to induce glial proliferation and neural stem cells from glia. Ectopic neural stem cells can divide, and limited de novo neurogenesis could be traced back to glial cells. Altogether, Ia-2 and Dilp-6 drive a neuron-glia relay that restores glia, and reprograms glia into neural stem cells for regeneration.

EXTH-52. GLIOBLASTOMA-TARGETING AUTOLOGOUS INDUCED NEURAL STEM CELL THERAPY: EVALUATING SAFETY, TOXICITY, PERSISTENCE, AND TRANSPLANT METHODS IN A POST-SURGICAL CANINE MODEL

BACKGROUND Glioblastoma patient survival statistics have remained unchanged for more than three decades. Despite tumor resection and chemoradiotherapy, recurrence is inevitable. Moreover, the invasive behavior of glioblastoma confounds treatment. To improve patient survival statistics, a targeted therapy that can home to distant tumor foci is desperately needed. Induced neural stem cells (iNSCs) armed with cytotoxic payloads have proven efficacious against human xenograft models of glioblastoma. To further propel iNSCs to human clinical trials, we investigated the safety, toxicity, and persistence of iNSCs in a canine model. METHODS Autologous iNSCs generated from the skin of four non-tumor-bearing, purpose-bred, male beagles were engineered to express TRAIL and thymidine kinase (TK). iNSCs were loaded with ferumoxytol to facilitate MRI-tracking. Canines were divided into two cohorts to denote iNSC administration route: scaffold encapsulation or intracerebroventricular (ICV). Two dose levels were investigated: 1′106 iNSCs/kg or 3′106 iNSCs/kg. The scaffold cohort received a single dose of iNSCs while the ICV cohort received three doses of iNSCs via a Rickham reservoir. To activate TK, canines were administered valganciclovir. Canine health was assessed via neurological exams, MRI, and serial blood, urine, and CSF analyses. RESULTS No acute injection reactions were observed. Three of four canines exhibited surgery-induced blindness. Urine and CSF analyses were unremarkable. Unexpectedly, blood analyses showed transient neutropenia. Hypodense signal was observed on all MRI sequences through endpoint. Post-mortem histopathology of the spleen, liver, and lung were unremarkable. As expected, brain tissues exhibited gliosis, fibrous thickening, and inflammation. Spinal cords exhibited acute hemorrhaging, attributed to perimortem CSF draws. Surprisingly, significant testicular degeneration was observed; this was confirmed to be caused by valganciclovir. In conclusion, iNSCs exhibit limited toxicity and warrant further exploration. FUTURE DIRECTIONS Prospective studies will investigate the efficacy of autologous iNSCs in a spontaneous canine glioma model in preparation for human clinical trials.

Toll-Like Receptor 2 Attenuates Traumatic Brain Injury-Induced Neural Stem Cell Proliferation in Dentate Gyrus of Rats

It was not clear how and whether neural stem cells (NSCs) responded to toll-like receptor 2 (TLR2) in the inflammatory environment after traumatic brain injury (TBI). The current study investigated the correlation of TLR2 and NSC proliferation in the dentate gyrus (DG) using the TBI model of rats. Immunofluorescence (IF) was used to observe the expression of BrdU, nestin, and TLR2 in the DG in morphology. Proliferating cells in the DG were labelled by thymidine analog 5-bromo-2-deoxyuridine (BrdU). Three-labelled BrdU, nestin, and DAPI was used for the identification of newly generated NSCs. Western blotting and real-time polymerase chain reaction (PCR) were used to observe the expression of TLR2 from the level of protein and mRNA. We observed that BrdU+/nestin+/DAPI+ cells accounted for 84.30%±6.54% among BrdU+ cells; BrdU+ and nestin+ cells in the DG were also TLR2+ cells. BrdU+ cells and the expression of TLR2 (both protein and mRNA levels) both elevated immediately at 6 hours (h), 24 h, 3 days (d), and 7 d posttrauma and peaked in 3 d. Results indicated that TLR2 was expressed on proliferating cells in the DG (NSCs possibly) and there was a potential correlation between increased TLR2 and proliferated NSCs after TBI. Taken together, these findings suggested that TLR2 was involved in endogenous neurogenesis in the DG after TBI.