ablation reduces the efficiency of NeuroD1 gene-based therapy and aggravates the brain damage following ischemic stroke.

INTRODUCTION

Hypoxia-inducible factor 1α [HIF1α] regulates gene expression, allowing the organism to respond to low oxygen levels. Meanwhile, astrocytes participate in inflammatory processes and are associated with neurotoxic chemicals that can increase stroke volume, contributing considerably to the devastating effects of a stroke.

OBJECTIVE

To evaluate whether ablation from the central nervous system is implicated in motor dysfunction and ischemic brain damage following stroke. Furthermore, to explore if ablation affects the therapeutic impact of NeuroD1 gene-based therapy.

METHODS

Endothelin-1 [ET-1] was injected to induce ischemic stroke in mice. Both wild-type and Hypoxia-inducible factor 1α conditional knockout [ CKO] mice were used. The effect of ablation was assessed by the neuron numbers, astrocyte activity, vascular endothelial growth factor [VEGF] expression, and behavioral tests. Moreover, western blot, ELISA, and RNA sequencing were used. Then, we used pAAV2/9-GfaABC1D-NeuroD1-P2A-EGFP-WPRE injection to examine the impact of NeuroD1 in CKO mice following ischemic stroke.

RESULTS

We found that following stroke, motor dysfunction significantly increased in CKO mice. Furthermore, elevation of apoptosis and activation in both microglia and astrocytes were observed, consequently up-regulating neuroinflammation. Meanwhile, ablation significantly decreased the efficiency of NeuroD1 gene-based therapy.

CONCLUSION

Our findings demonstrate that ablation from the nervous system is implicated in ischemic stroke pathogenesis mainly by increasing neuron cell death and inducing astrocytes as well as decreasing the efficiency of NeuroD1. These data support the idea that manipulating HIF-1α is a viable therapeutic for ischemic stroke.