Intermittent food deprivation (fasting, IF) improves mood and cognition and protects neurons against excitotoxic degeneration in animal models of epilepsy and Alzheimer’s disease (AD). The mechanisms by which neuronal networks adapt to IF and how such adaptations impact neuropathological processes are unknown. We show that hippocampal neuronal networks adapt to IF by enhancing GABAergic tone, which is associated with reduced anxiety-like behaviors and improved hippocampus-dependent memory. These neuronal network and behavioral adaptations require the mitochondrial protein deacetylase SIRT3 as they are abolished in SIRT3-deficient mice and wild type mice in which SIRT3 is selectively depleted from hippocampal neurons. In the App NL-G-F mouse model of AD, IF reduces neuronal network hyperexcitability and ameliorates deficits in hippocampal synaptic plasticity in a SIRT3-dependent manner. These findings demonstrate a role for a mitochondrial protein deacetylase in hippocampal neurons in behavioral and GABAergic synaptic adaptations to IF.
Traumatic brain injury (TBI) places enormous early energy demand on brain tissue to reinstate normal ionic balance. Clinical studies have demonstrated a decline in extracellular fluid (ECF) glucose and an increase in lactate after TBI. In vitro studies suggest that this increase in lactate is mediated by increased glutamate and may provide a metabolic substrate for neurons, to aid in ionic restoration. This led us to hypothesize that high ECF lactate may be beneficial in recovery following TBI, where major ionic flux has been shown to occur. In this study, we measured cerebral dialysate lactate and glucose, and arterial lactate and glucose, before and after rat lateral fluid percussion brain injury (FPI; 2.06 +/- 0.13 atm) with and without IV lactate infusion (100 mM X 0.65 mL/h X 5 h) to test the hypothesis that arterial lactate can influence ECF lactate. Dialysate lactate increased within 10 min following FPI, with higher values in the lactate infusion group. Following FPI, the dialysate lactate increase was 238% with lactate infusion versus 171% increase with saline infusion. Dialysate glucose fell immediately following FPI, with a more severe decline in the saline group. The glucose decrease was 231% greater in the IV saline group. Furthermore, in the lactate infusion group, the dialysate glucose levels recovered to baseline levels by 4 h after injury, whereas they remained depressed through out the experiment, in the saline infusion group. We conclude that arterial lactate augmentation can increase brain dialysate lactate, and result in more rapid recovery of dialysate glucose after FPI. This may indicate a beneficial role for lactate, that may be potentially useful in the clinical situation, after TBI.
Mammalian target of rapamycin (mTOR) signaling plays essential roles in brain development. Hyperactive mTOR is an essential pathological mechanism in autism spectrum disorder (ASD). Here, we show that tripartite motif protein 32 (TRIM32), as a maintainer of mTOR activity through promoting the proteasomal degradation of G protein signaling protein 10 (RGS10), regulates the proliferation of medial/lateral ganglionic eminence (M/LGE) progenitors. Deficiency of TRIM32 results in an impaired generation of GABAergic interneurons and autism-like behaviors in mice, concomitant with an elevated autophagy, which can be rescued by treatment embryonically with 3BDO, an mTOR activator. Transplantation of M/LGE progenitors or treatment postnatally with clonazepam, an agonist of the GABAA receptor, rescues the hyperexcitability and the autistic behaviors of TRIM32−/− mice, indicating a causal contribution of GABAergic disinhibition. Thus, the present study suggests a novel mechanism for ASD etiology in that TRIM32 deficiency-caused hypoactive mTOR, which is linked to an elevated autophagy, leads to autism-like behaviors via impairing generation of GABAergic interneurons. TRIM32−/− mouse is a novel autism model mouse.
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