Intermittent fasting promotes anxiolytic-like effects unrelated to synaptic mitochondrial function and BDNF support.

Anxiety disorders are linked to mitochondrial dysfunction and decreased neurotrophic support. Since anxiolytic drugs target mitochondria, non-pharmacological approaches to improve mitochondrial metabolism such as intermittent fasting (IF) may cause parallel behavioral benefits against anxiety disorders. Here, we investigated whether a chronic IF regimen could induce anxiolytic-like effects concomitantly to modulation in mitochondrial bioenergetics and trophic signaling in mice brain. A total of 44 Male C57BL/6 J mice (180 days old) were assigned to two dietary regimens: a normal, ad libitum diet (AL group) and an alternate-day fasting (IF group), where animals underwent 10 cycles of 24 h food restriction followed by 24 h ad libitum access. Animals underwent the open field test, dark/light box and elevated plus maze tasks. Isolated nerve terminals were obtained from mice brain and used for mitochondrial respirometry, hydrogen peroxide production and assessment of membrane potential dynamics, calcium handling and western blotting. We showed that IF significantly alters total daily food intake and food consumption patterns but not body weight. There were no differences in the exploratory and locomotory parameters. Remarkably, animals from IF showed decreased anxiety-like behavior. Mitochondrial metabolic responses in different coupling states and parameters linked with H2O2 production, Ca2+ buffering and electric gradient were not different between groups. Finally, no alterations in molecular indicators of apoptotic death (Bax/Bcl-2 ratio) and neuroplasticity (proBDNF/BDNF and synaptophysin were observed). In conclusion, IF exerts anxiolytic-like effect not associated with modulation in synaptic neuronergetics or expression of neurotrophic proteins. These results highlight a potential benefit of intermittent fasting as a nutritional intervention in anxiety-related disorders.

Anabolic-androgen steroids effects on bioenergetics responsiveness of synaptic and extrasynaptic mitochondria.

We hypothesized that supraphysiological administration of the anabolic-androgenic steroids (AAS) like testosterone (TEST) and nandrolone decanoate (NAND) might differentially affect synaptic and extrasynaptic components of mitochondrial bioenergetics, thereby resulting in memory impairment. Oil (VEH), NAND or TEST (15 mg/Kg) were daily administered to male CF-1 albino mice for 19-days. We evaluated in the synaptosomes and extrasynaptic mitochondria, Ca2+ influx/efflux, membrane potential ΔÑ°m, oxidative respiratory states, dehydrogenases activity, H2O2 production, Tau phosphorylation, and spatial memory in the Morris water maze (MWM). In synaptosomes, both AAS increased Ca2+ influx and Na+ dependent efflux. In extrasynaptic mitochondria, NAND increased the Ca2+ influx. NAND prominently impaired ΔÑ°m formation and dissipation in synaptosomal and extrasynaptic mitochondria, while the effect of TEST was less pronounced. TEST increased the Reserve Respiratory Capacity in synaptosomes, and NAND decreased dehydrogenases activity in synaptic and extrasynaptic mitochondria. Also, NAND increased H2O2 production by synaptosomes and extrasynaptic mitochondria. NAND increased pTauSer396 in synaptosomes. Both AAS did not impair memory performance on MWM. We highlight that high doses of NAND cause neurotoxic effects to components of synaptic and extrasynaptic mitochondrial bioenergetics, like calcium influx, membrane potential and H2O2 production. TEST was less neurotoxic to synaptic and extrasynaptic mitochondrial bioenergetics responses.