Abstract
Traumatic brain injury (TBI) causes neurotransmitter disturbances contributing to neuronal cell death and neurological deficits. In humans, brain injuries impair γ-aminobutyric acid (GABA) uptake and ultimately result in cognitive impairment. GABA transporter 3 (GAT3) is a vital approach of GABA reuptake and catabolism. The contribution of GAT3 in TBI-induced cognitive impairment and its underlying mechanisms remain unknown, which were explored in the present study. Here, we found that expression of GAT3 was downregulated to increase GABA concentration in the mouse brain after TBI. And GAT3 was detected in neurons and astrocytes after TBI unexpectedly, instead of merely expressed on astrocytes in physiological states. Subsequently, activated metabotropic glutamate receptor 5 (mGluR5) reduced GABA content by elevating the expression levels of GAT3. Then, increased mGluR5 activity obviously improved cognitive impairment. Mechanistically, mGluR5 was activated to evidently induce the expression of p-ERK, CREB, and p-CREB after TBI. The inhibition of CREB decreased the expression of CREB, p-CREB, and GAT3 elevated by active mGluR5. However, the CREB inhibitor increased GABA content. Furthermore, Rab11a regulating GAT3 trafficking by endocytosis was elevated after TBI. And Rab11a downregulated by active mGluR5 was reversed by CREB inhibitor. In summary our findings elucidated that activated mGluR5 ameliorated cognitive function by upregulating GAT3 in TBI. And mGluR5 possibly regulated GAT3 by ERK/CREB/Rab11a pathway. GAT3 could serve as a potential target for TBI cognitive treatment.