Intermittent fasting (IF) has been shown to promote metabolic health in several organisms. Two recent papers show that IF induces white adipose tissue beiging and increases thermogenesis, which improves metabolic health in mice.
The incidence of obesity and type 2 diabetes is sharply increasing globally. White adipose tissue (WAT) serves primarily as an energy storage depot during overnutrition, but emerging evidence suggests that WAT can be converted towards energy-using tissue, when white adipocytes acquire features of beige/brown adipocytes. Rather than storing energy, these cells then start to use extra energy for heat production, which could be a promising therapeutic approach to treat obesity-related metabolic disorders. In a study recently published by Cell Research, Kim et al.1 demonstrate that IF increases vascular endothelial growth factor (VEGF) levels in WAT, which induced angiogenesis, adipose tissue macrophage polarization and WAT browning/beiging. This led to improved insulin sensitivity, which counteracted obesity, and alleviated metabolic syndrome in the mice. Another mechanism mediating the effects of IF was recently proposed by Li et al.2, who showed that IF promotes WAT browning via modulating gut microbiota and providing its fermentation products acetate and lactate.
In mice, VEGF-induced angiogenesis in adipose tissue has been shown to increase thermogenesis and decrease tissue inflammation, counteracting obesity and insulin resistance induced by diet3,4. However, targeted delivery of VEGF to adipose tissue is challenging, as systemic delivery of VEGF leads to vascular leakiness in several organs. VEGF-VEGFR2 pathway activation is induced indirectly by VEGF-B, which displaces VEGF from VEGFR1. An excess of VEGF-B was recently shown to result in increased adipose vasculature, beiging of WAT and increased energy expenditure, leading to improved metabolic health in mice5. These effects of VEGF-B were limited by the endogenous VEGF levels; thus, it appears to be a safer approach than VEGF delivery for VEGFR2 activation in vivo. However, it is still unclear, how activation of VEGFR2 in WAT could be achieved for the development of effective and safe treatment for humans. Kim et al.1 demonstrate that by allowing mice to fast every three days, VEGF levels were significantly increased in WAT. This was associated with angiogenesis, macrophage polarization towards anti-inflammatory M2 type, and beiging of the WAT. The importance of adipocyte-derived VEGF was demonstrated using adipocyte-specific VEGF-deficient mice (aP2-Cre;Vegfaflox/flox), which did not show any of the abovementioned changes in WAT or improvement in whole body metabolism.
An almost simultaneously published paper in Cell Metabolism reported a similar WAT beiging phenotype and reversal of high-fat-diet-induced obesity and metabolic disorders using a similar diet regimen (this case every-other-day fasting)2. In this study, IF was shown to increase small intestine length and to affect the composition of gut microbiota. The importance of gut microbiota was demonstrated by fecal transplantation from the IF-treated and control mice to microbiota-depleted (antibiotic-treated) mice. The WAT beiging effect was induced by microbiota transplantation from IF-treated mice into microbiota-depleted mice, whereas the IF effects on WAT were absent in the microbiota-depleted mice. Li et al. suggest that the beiging stimulus was mediated by the fermentation products acetate and lactate, which were strongly increased in the gut and serum after IF. In addition, monocarboxylate transporter 1 (Mct1) mRNA was increased several fold in adipose tissue, suggesting that the uptake of monocarboxylates (e.g., lactate) into adipocytes was increased.
These data show that in mice, IF induces beiging of subcutaneous WAT, which increases thermogenesis and improves metabolic health upon diet-induced obesity. Interestingly, the effects seem to be specific for the beiging of subcutaneous WAT as BAT activation was not observed. The study by Kim et al. provides evidence for the importance of adipose tissue VEGF, while Li et al. demonstrate the essential role of microbiota in the IF-induced effects (Figure 1). These findings raise several interesting questions. First, are the mechanisms presented in these two studies connected? For example, could the increased acetate or lactate induce VEGF production by adipocytes? Does the increased vasculature contribute essential angiocrine signals from activated endothelial cells to adipocytes? Could macrophage polarization be induced in adipose tissue by other non-invasive means that could be applied to humans? Importantly, the IF program used in these studies could in principle be applied to humans. In fact, some religious communities already adhere to certain types of intermittent fasting regimens. However, rigorous adherence to fasting in the fast-growing population of obese and overweight patients would be unrealistic. It would be important to find out whether less stringent restrictions of dietary habits would result in similar effects that are beneficial also in humans.
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Kivelä, R., Alitalo, K. White adipose tissue coloring by intermittent fasting. Cell Res 27, 1300–1301 (2017). https://doi.org/10.1038/cr.2017.130