Cycles of a diet that mimics fasting appear to reduce signs of Alzheimer's in mice genetically engineered to develop the illness, according to a new USC Leonard Davis School of Gerontology-led study.

 

The researchers, led by Professor Valter Longo in collaboration with Professors Christian Pike and Pinchas Cohen, found that mice that had undergone several cycles of the fasting-mimicking diet showed less Alzheimer's pathology. The researchers found lower levels of two major hallmarks of the disease: amyloid beta -- the primary driver of plaque buildup in the brain -- and hyperphosphorylated tau protein, which forms tangles in the brain. They also found that brain inflammation lessened and better performance on cognitive tests compared to the mice that were fed a standard diet.

 

The fasting-mimicking diet (FMD) is high in unsaturated fats and low in overall calories, protein, and carbohydrates and is designed to mimic the effects of a water-only fast while still providing necessary nutrients. Previous research led by Longo has indicated that brief, periodic FMD cycles are associated with a range of beneficial effects, including the promotion of stem cell regeneration, lessening of chemotherapy side effects, and lowering risk factors for cancer, diabetes, heart disease and other age-related diseases in mice and humans.

 

Alongside healthy mice, the team investigated two mouse models of Alzheimer's, E4FAD and 3xTg. During the study, mice were fed the fasting-mimicking diet for 4 or 5 days twice per month and were allowed to eat normally between FMD cycles. In a long-term experiment to see the effects in aged mice, 3xTg mice were placed on the diet for 30 cycles in 15 months. Shorter-term experiments in both 3xTg and E4FAD mice ranged from a single FMD cycle to 12 cycles in 6 months.

 

In both models, mice who underwent FMD cycles showed promising reductions in amyloid beta -- which form the sticky, disruptive plaques in the brain -- and tau pathology compared to mice eating a standard diet. The FMD mice also showed lower levels of brain inflammation, including a reduction in the number of active microglia, the immune cells that seek and destroy pathogens and damaged cells in the brain. In addition, mice on the diet demonstrated a lower level of oxidative stress, which plays a role in Alzheimer's pathology by damaging neurons and contributing to the accumulation of amyloid in the brain. The study specifically pointed to the free radical "superoxide" as a central culprit in the damage occurring in these Alzheimer's mouse models, Longo explained.

 

Outwardly, mice of both Alzheimer's models who underwent the FMD showed less cognitive decline than their standard diet counterparts. Cognitive behavior, including exploration and performance within mazes, was tested in young mice before the dietary regimen began and again after several months of either a standard diet or twice-monthly FMD cycles. The Alzheimer's mice given the FMD significantly outperformed the Alzheimer's mice given standard diets and in some instances performed similarly to the non-Alzheimer's-prone control mice, indicating that cognitive decline had been significantly slowed.

 

The FMD cycles appeared effective in reversing a range of pathology markers but also cognitive defects in two of the major mouse models for Alzheimer's disease. Longo said that the results are promising.