Intermittent fasting promotes adipose thermogenesis and metabolic homeostasis via VEGF-mediated alternative activation of macrophage

Kim, Kyoung-Han; Kim, Yun Hye; Son, Joe Eun; Lee, Ju Hee; Kim, Sarah; Choe, Min Seon; Moon, Joon Ho; Zhong, Jian; Fu, Kiya; Lenglin, Florine; Yoo, Jeong Ah; Bilan, Philip J.; Klip, Amira; Nagy, András; Kim, Jae Ryong; Park, Jin Gyoon; Hussein, Samer M.I.; Doh, Kyung Oh; Hui, Chi Chung; Sung, Hoon‐Ki

doi:10.1038/cr.2017.126

Cited by 168 publications

(165 citation statements)

References 71 publications

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“…Two common dieting schemes using in rodent studies include mechanisms, such as increased browning in iWAT, increased thermogenesis, increased vascularization, and switching from M1 to M2 macrophage activation in adipose tissue. 36,37 Moreover, multiple clinical and animal studies, including the present study ( Figures 1G and 2D), indicated that healthy and unhealthy diet switch induced weight cycling ultimately increases body fat gain, specifically in the visceral adipose tissue. 4,38 Notably, the present study demonstrated increased A, qPCR results of Il-6 and Il-8 in primary hepatocytes stimulated with media from indicated 3T3-L1 cells.…”

Section: Discussionsupporting

confidence: 57%

“…Second, switching between normal chow (NC) or HF and fasting is seen in intermittent fasting study, whereas NC and HF switching is used in weight cycling study with continual access to food as is commonly seen in human society, therefore, some beneficial effects of intermittent fasting may due to a reduction in total caloric intake. However, some intermittent fasting studies with matched total caloric intake also suggest that beneficial effects may due to the physiological changes during fasting, such as fasting-induced increase of VEGF dependent activation of M2 macrophage in white adipose tissue, 37 fasting-induced modifying of gut microbiota 36 or improving of overt circadian rhythms, 39 and fasting-mimicking diet induced pancreatic β-cell regeneration. 40 Weight cycling has also been reported to be accompanied by fluctuations in biochemical parameters, such as blood glucose and blood pressure, indicators of disrupted metabolic homeostasis.…”

Section: Discussionmentioning

confidence: 99%

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Lmo4‐resistin signaling contributes to adipose tissue‐liver crosstalk upon weight cycling

et al. 2020

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Repeated cycles of weight loss and regain, known as weight cycling, is often seen when people try to lose weight. The exact pathophysiological effects and the underlying mechanisms of weight cycling remain largely unclear. Here, we report that weight cycling induced by alternating feeding mice with a low‐fat diet or a high‐fat diet in a 1‐week switch protocol caused further increased epididymal white adipose tissue (eWAT) weight, preadipocyte proliferation, hepatic inflammation, fasting blood glucose level, and glucose intolerance, compared with the continuously HF‐fed mice. Combining the secretory protein database with RNA‐sequencing and quantitative PCR (qPCR) results in eWAT, the mRNA levels of several adipokines, including Retn (encoding resistin), were found altered by weight cycling. A transcriptional co‐factor Lmo4 was found regulated by weight cycling; Lmo4 enhanced preadipocyte proliferation, in vitro adipogenesis, transcription of Retn, and resistin secretion in 3T3‐L1 cells. Primary mouse hepatocytes administrated with recombinant mouse resistin (rm‐resistin), or exposed to media from Lmo4‐overexpressed 3T3‐L1 cells, showed increased inflammatory responses and gluconeogenesis. Furthermore, rm‐resistin‐injected normal chow‐fed mice showed upregulated blood glucose level by increasing gluconeogenesis, and upregulated the hepatic inflammatory responses. Together, our results suggest a regulatory role of Lmo4‐resistin signaling in weight cycling, indicating a crosstalk between the adipose tissue and liver.

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Section: Discussionsupporting

confidence: 57%

Section: Discussionmentioning

confidence: 99%

Lmo4‐resistin signaling contributes to adipose tissue‐liver crosstalk upon weight cycling

et al. 2020

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“…The advent of high-throughput omics facilitated the elucidation of some of the cellular and molecular mechanisms underlying the beneficial effects of fasting. Nonetheless, the majority of these studies focused on single organ response (i.e., the liver) and, less often, involved two or three organs [10][11][12][13][14][15][16]. The adaptation to energy deprivation, however, requires a multi-organ integration of metabolic modulations to protect the organism from an irreversible loss of resources [17].…”

Section: Introductionmentioning

confidence: 99%

Differential regulation of the immune system in a brain-liver-fats organ network during short term fasting

Huang

Makhlouf

AbouMoussa

et al. 2020

Preprint

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Different fasting regiments are known to promote health, and chronic immunological disorders and mitigate age-related pathophysiological parameters in animals and humans. Indeed, several clinicals trials are currently ongoing using fasting as a potential therapy for a wide range of conditions. Fasting alters metabolism by acting as a reset for energy homeostasis, but the molecular mechanisms underlying the beneficial effects of short-term fasting (STF) are still not-well understood, particularly at a systems/multiorgan level. We investigated the dynamic gene expression patterns associated with periods of STF in nine different mouse organs. First, we identified both unique and shared transcriptional signatures at the organ and systemic levels. Second, we discovered differential temporal effects of STF among organs. Third, using gene ontology enrichment analysis, we identified an organ network, formed by the 63 common biological pathways perturbed by STF. This network incorporates the brain, liver, interscapular brown, and perigonadal white adipose tissue, hence we name it the brain-liver-fats organ network. Fourth, we identified that the immune system, dominated by T cell regulation processes, is a central and prominent target of systemic modulations during short-term energy loss in this organ network. The changes we identified in specific immune components point to the priming of adaptive immunity and parallel the fine-tuning of innate immune signaling. In conclusion, our study provides a comprehensive multi-organ transcriptomic profiling of mice subjected to multiple periods of STF and added new insights into the molecular modulators involved in the systemic immuno-transcriptomic changes that occur during short-term energy loss.

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“…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 antiinflammatory M2 type, and beiging of the WAT.…”

Section: Intermittent Fasting (If) Has Beenmentioning

confidence: 99%

“…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.…”

Section: Intermittent Fasting (If) Has Beenmentioning

confidence: 99%

White adipose tissue coloring by intermittent fasting

Kivelä

Alitalo

2017

Cell Res

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Intermittent fasting promotes adipose thermogenesis and metabolic homeostasis via VEGF-mediated alternative activation of macrophage

Cited by 168 publications

References 71 publications

Lmo4‐resistin signaling contributes to adipose tissue‐liver crosstalk upon weight cycling

Lmo4‐resistin signaling contributes to adipose tissue‐liver crosstalk upon weight cycling

Differential regulation of the immune system in a brain-liver-fats organ network during short term fasting

White adipose tissue coloring by intermittent fasting

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