Genome-Wide mRNA Expression Analysis of Hepatic Adaptation to High-Fat Diets Reveals Switch from an Inflammatory to Steatotic Transcriptional Program

Radonjić, Marijana; Haan, Jorn R. de; Erk, Marjan J. van; Dijk, Ko Willems van; Berg, Sjoerd A.A. van den; Groot, Philip J. de; Müller, Michael; Ommen, Ben van

doi:10.1371/journal.pone.0006646

Cited by 53 publications

(66 citation statements)

References 75 publications

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“…Upon prolonged caloric overload, these adaptive processes may reach their limit, and compensating mechanisms may cause the damage shown by the derailment of the core metabolic processes, resulting in insulin resistance, plaque formation, and low-grade inflammation. This notion is in line with what has been shown in mice, in which integrated systems biology approaches were applied to study the time-resolved effect of a high-fat diet on the switch from normal health toward development of pathologies resulting from this dietary regimen (33)(34)(35)(36).…”

Section: An Integrated Model Of Adaptive Challenge Responsessupporting

confidence: 81%

Quantifying phenotypic flexibility as the response to a high‐fat challenge test in different states of metabolic health

et al. 2015

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Metabolism maintains homeostasis at chronic hypercaloric conditions, activating postprandial response mechanisms, which come at the cost of adaptation processes such as energy storage, eventually with negative health consequences. This study quantified the metabolic adaptation capacity by studying challenge response curves. After a high-fat challenge, the 8 h response curves of 61 biomarkers related to adipose tissue mass and function, systemic stress, metabolic flexibility, vascular health, and glucose metabolism was compared between 3 metabolic health stages: 10 healthy men, before and after 4 wk of highfat, high-calorie diet (1300 kcal/d extra), and 9 men with metabolic syndrome (MetS). The MetS subjects had increased fasting concentrations of biomarkers representing the 3 core processes, glucose, TG, and inflammation control, and the challenge response curves of most biomarkers were altered. After the 4 wk hypercaloric dietary intervention, these 3 processes were not changed, as compared with the preintervention state in the healthy subjects, whereas the challenge response curves of almost all endocrine, metabolic, and inflammatory processes regulating these core processes were altered, demonstrating major molecular physiologic efforts to maintain homeostasis. This study thus demonstrates that change in challenge response is a more sensitive biomarker of metabolic resilience than are changes in fasting concentrations.-Kardinaal, A. F. M., van Erk, M. J., Dutman, A. E., Stroeve, J. H. M., van de Steeg, E., Bijlsma, S., Kooistra, T., van Ommen, B., Wopereis, S. Quantifying phenotypic flexibility as the response to a highfat challenge test in different states of metabolic health. FASEB J. 29, 4600-4613 (2015). www.fasebj.org

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Section: An Integrated Model Of Adaptive Challenge Responsessupporting

confidence: 81%

Quantifying phenotypic flexibility as the response to a high‐fat challenge test in different states of metabolic health

et al. 2015

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“…23 By microarray and qRT-PCR, we found numerous examples of adipocyte-associated genes that were up-regulated in the livers of 9-month-old AB6F1 mice with NAFLD compared with B6AF1 controls. As mesenchymal cells, adipocytes express a number of canonical genes not typically expressed in hepatocytes and other epithelial tissues.…”

Section: Insulin Resistance Invokes Adipogenic Transition Of Hepatocymentioning

confidence: 86%

Insulin Resistance and Metabolic Hepatocarcinogenesis with Parent-of-Origin Effects in A×B Mice

Hines

Hartwell

Feng

et al. 2011

The American Journal of Pathology

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Insulin resistance is a defining feature of metabolic syndrome and type 2 diabetes mellitus but also may occur independently of these conditions. Nonalcoholic fatty liver disease (NAFLD), the hepatic manifestation of these disorders, increases the risk of hepatocellular carcinoma (HCC). However, mechanisms linking hyperinsulinemia to NAFLD and HCC require clarification. We describe a novel model of primary insulin resistance and HCC with strong parent-of-origin effects. Male AB6F1 (A/JCr dam ؋ C57BL/6 sire) but not B6AF1 (B6 dam ؋ A/J sire) mice developed spontaneous insulin resistance, NAFLD, and HCC without obesity or diabetes. A survey of mitochondrial, imprinted, and sex-linked traits revealed modest associations with X-linked genes. However, a dietinduced obesity study, including B6.A chromosome substitution-strain (consomic) mice, showed no segregation by sex chromosome. Thus, parent-of-origin effects were specified within the autosomal genome. Next, we interrogated mechanisms of insulin-associated hepatocarcinogenesis. Steatotic hepatocytes exhibited adipogenic transition characterized by vacuolar metaplasia and up-regulation of vimentin, adipsin, fatty acid translocase (CD36), peroxisome proliferator-activated receptor-␥, and related products. This profile was largely recapitulated in insulin-supplemented primary mouse hepatocyte cultures. Importantly, pyruvate kinase M2, a fetal anabolic enzyme implicated in the Warburg effect, was activated by insulin in vivo and in vitro. Thus, our study reveals parent-of-origin effects in heritable insulin resistance, implicating adipogenic transition with acquired anabolic metabolism in the progression from NAFLD to HCC.

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“…The PPAR signaling pathway is known to be involved in chronic inflammation and the cirrhotic process of obesity-induced NAFLD (Radonjic et al 2009). Moreover, retinoids are anti-inflammatory molecules that promote cellular differentiation.…”

Section: Differential Immune Response Against An Inflammatory Stimulumentioning

confidence: 99%

Liver immune responses to inflammatory stimuli in a diet-induced obesity model of zebrafish

Forn-Cuní¹,

Varela²,

Fernández-Rodrı́guez³

et al. 2014

Journal of Endocrinology

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Obesity-and metabolic syndrome-related diseases are becoming important medical challenges for the western world. Non-alcoholic fatty liver disease (NAFLD) is a manifestation of these altered conditions in the liver, and inflammation appears to be a factor that is tightly connected to its evolution. In this study, we used a diet-induced obesity approach in zebrafish (Danio rerio) based on overfeeding to analyze liver transcriptomic modulation in the disease and to determine how obesity affects the immune response against an acute inflammatory stimulus such as lipopolysaccharide (LPS). Overfed zebrafish developed an obese phenotype, showed signs of liver steatosis, and its modulation profile resembled that observed in humans, with overexpression of tac4, col4a3, col4a5, lysyl oxidases, and genes involved in retinoid metabolism. In response to LPS, healthy fish exhibited a typical host defense reaction comparable to that which occurs in mammals, whereas there was no significant gene modulation when comparing expression in the liver of LPS-stimulated and non-stimulated obese zebrafish at the same statistical level. The stimulation of obese fish represents a double-hit to the already damaged liver and can help understand the evolution of the disease. Finally, a comparison of the differential gene activation between stimulated healthy and obese zebrafish revealed the expected difference in the metabolic state between healthy and diseased liver. The differentially modulated genes are currently being studied as putative new pathological markers in NAFLD-stimulated liver in humans.

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Genome-Wide mRNA Expression Analysis of Hepatic Adaptation to High-Fat Diets Reveals Switch from an Inflammatory to Steatotic Transcriptional Program

Cited by 53 publications

References 75 publications

Quantifying phenotypic flexibility as the response to a high‐fat challenge test in different states of metabolic health

Quantifying phenotypic flexibility as the response to a high‐fat challenge test in different states of metabolic health

Insulin Resistance and Metabolic Hepatocarcinogenesis with Parent-of-Origin Effects in A×B Mice

Liver immune responses to inflammatory stimuli in a diet-induced obesity model of zebrafish

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