Summary Prolonged fasting (PF) promotes stress resistance but its effects on longevity are poorly understood. We show that alternating PF and nutrient-rich medium extended yeast lifespan independently of established pro-longevity genes. In mice, four days of a diet that mimics fasting (FMD), developed to minimize the burden of PF, decreased the size of multiple organs/systems; an effect followed upon re-feeding by an elevated number of progenitor and stem cells and regeneration. Bi-monthly FMD cycles started at middle age extended longevity, lowered visceral fat, reduced cancer incidence and skin lesions, rejuvenated the immune system, and retarded bone mineral density loss. In old mice, FMD cycles promoted hippocampal neurogenesis, lowered IGF-1 levels and PKA activity, elevated NeuroD1, and improved cognitive performance. In a pilot clinical trial, three FMD cycles decreased risk factors/biomarkers for aging, diabetes, cardiovascular disease and cancer without major adverse effects, providing support for the use of FMDs to promote healthspan.
Approximately 75% of all breast cancers express the oestrogen and/or progesterone receptors. Endocrine therapy is usually effective in these hormone-receptor-positive tumours, but primary and acquired resistance limits its long-term benefit 1,2 . Here we show that in mouse models of hormone-receptor-positive breast cancer, periodic fasting or a fasting-mimicking diet 3-5 enhances the activity of the endocrine therapeutics tamoxifen and fulvestrant by lowering circulating IGF1, insulin and leptin and by inhibiting AKT-mTOR signalling via upregulation of EGR1 and PTEN. When fulvestrant is combined with palbociclib (a cyclin-dependent kinase 4/6 inhibitor), adding periodic cycles of a fasting-mimicking diet promotes long-lasting tumour regression and reverts acquired resistance to drug treatment. Moreover, both fasting and a fasting-mimicking diet prevent tamoxifen-induced endometrial hyperplasia. In patients with hormone-receptor-positive breast cancer receiving oestrogen therapy, cycles of a fasting-mimicking diet cause metabolic changes analogous to those observed in mice, including reduced levels of insulin, leptin and IGF1, with the last two remaining low for extended periods. In mice, these long-lasting effects are associated with long-term anti-cancer activity. These results support further clinical studies of a fasting-mimicking diet as an adjuvant to oestrogen therapy in hormone-receptor-positive breast cancer.Growth factor signalling through the phosphoinositide 3-kinase (PI3K)-AKT-mammalian target of rapamycin (mTOR) and mitogen-activated protein kinase (MAP kinase) axes enhances oestrogen receptor activity and frequently underlies endocrine resistance in breast tumours 1,2,6 . Water-only fasting or plant-based diets that are simultaneously low in calories, sugar and protein and proportionally high in fat (fasting-mimicking diets (FMDs)) reduce circulating growth factors such as insulin and IGF1 2,6,7 . Therefore, we hypothesized that these dietary interventions could be used to enhance the activity of oestrogen therapy (ET) and delay endocrine resistance.Low-serum, low-glucose cell culture conditions designed to mimic the effects of fasting or FMD (referred to as short-term starvation, STS) increased the anti-tumour activities of tamoxifen and fulvestrant in HR + /HER2breast cancer (BC) cell lines, and similar results were obtained in mouse xenografts of the same cell lines subjected to weekly cycles of fasting or FMD (Fig. 1a, Extended Data Figs. 1, 2a, b). STS also increased the anti-tumour activity of tamoxifen in tumour organoids from patients with HR + BC 8 , and weekly FMD cycles prevented acquired resistance to tamoxifen in mice (Extended Data Fig. 2c, d). Enhancement of ET activity through STS was dependent on the reduction in serum, but not glucose, as adding back glucose to the growth medium did not affect the observed potentiation (Extended Data Fig. 3a).In mice, besides increasing β-hydroxybutyrate levels (Extended Data Fig. 3b) and lowering blood glucose (from 6.3 ± 0.6 mmol l −1 to 4.1 ± 0....
Recent progress in structure elucidation of products of the advanced Maillard reaction now allows probing specifically for the role of this reaction in the pathogenesis of age- and diabetes-related complications. Pyrraline is a glucose-derived advanced glycation end product against which polyclonal and monoclonal antibodies have been raised. Immunohistochemical localization studies revealed that pyrraline is found predominantly in the sclerosed extracellular matrix of glomerular and arteriolar renal tissues from both diabetic and aged nondiabetic individuals. Pentosidine and carboxymethyllysine are Maillard end products derived from both glucose and ascorbate. In addition, pentosidine can be formed from several other sugars under oxidative conditions, and in vitro studies suggest that a common intermediate involving a pentose is a necessary precursor molecule. The highest levels of these advanced Maillard products are generally found in the extracellular matrix, but these products are also present in lens proteins and in proteins with a fast turnover such as plasma proteins. Diabetes, and especially uremia, greatly catalyzes pentosidine formation. Both conditions are characterized by accelerated cataractogenesis, atherosclerosis, and neuropathy, suggesting that molecular damage by advanced Maillard reaction products may be a common mechanism in their development.
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