Intermittent calorie restriction alters T cell subsets and metabolic markers in people with multiple sclerosis

Background: Intermittent fasting or calorie restriction (CR) diets provide anti-inflammatory and neuroprotective advantages in models of multiple sclerosis (MS); data in humans are sparse. Methods: We conducted a randomized-controlled feeding study of different CR diets in 36 people with MS over 8 weeks. Patients were randomized to receive either: a daily CR diet (22% reduction in calories, 7 days/week), an intermittent CR diet (75% reduction, 2 days/week; 100%, 5 days/week), or a weight-stable diet (100%, 7 days/week). Untargeted metabolomics was performed on plasma samples at weeks 0, 4 and 8 at Metabolon Inc (Durham, NC). Flow cytometry of cryopreserved peripheral blood mononuclear cells at weeks 0 and 8 were used to identify CD4+ and CD8+ T cell subsets including effector memory, central memory, and naïve cells. Results: 31 (86%) completed the trial. Over time, individuals randomized to intermittent CR had significant reductions in CD4+CM -4.87%; 95%CI: -8.59%, -1.15%; p=0.01), CD4+EM (-3.82%; 95%CI: -7.44, -0.21; p=0.04), and CD8+EM (-6.96%; 95%CI: -11.96, -1.97; p=0.006) with proportional increases in naïve subsets (CD4+Naïve: 5.81%; 95%CI: -0.01, 11.63%; p=0.05; CD8+Naïve: 10.11%; 95%CI: 3.30, 16.92%; p=0.006). No changes were observed for daily CR or weight-stable diets. Larger within-person changes in lysophospholipid and lysoplasmalogen metabolites in intermittent CR were associated with larger reductions in memory T cell subsets and larger increases in naïve T cell subsets. Conclusions: In people with MS, an intermittent CR diet was associated with reduction in memory T cell subsets. The observed changes may be mediated by changes in specific classes of lipid metabolites. Trial Registration: This study is registered on Clinicaltrials.gov with identifier NCT02647502. Funding: National MS Society, NIH, Johns Hopkins Catalyst Award

Phosphoglycolate phosphatase homologs act as glycerol-3-phosphate phosphatase to control stress and healthspan in C. elegans

Metabolic stress due to nutrient excess and lipid accumulation is at the root of many age-associated disorders and the identification of therapeutic targets that mimic the beneficial effects of calorie restriction has clinical importance. Here, using C. elegans as a model organism, we study the roles of a recently discovered enzyme at the heart of metabolism in mammalian cells, glycerol-3-phosphate phosphatase (G3PP) (gene name Pgp) that hydrolyzes glucose-derived glycerol-3-phosphate to glycerol. We identify three Pgp homologues in C. elegans (pgph) and demonstrate in vivo that their protein products have G3PP activity, essential for glycerol synthesis. We demonstrate that PGPH/G3PP regulates the adaptation to various stresses, in particular hyperosmolarity and glucotoxicity. Enhanced G3PP activity reduces fat accumulation, promotes healthy aging and acts as a calorie restriction mimetic at normal food intake without altering fertility. Thus, PGP/G3PP can be considered as a target for age-related metabolic disorders.