Diets low in carbohydrates and proteins and enriched in fat stimulate the hepatic synthesis of ketone bodies (KB). These molecules are used as alternative fuel for energy production in target tissues. The synthesis and utilization of KB are tightly regulated both at transcriptional and hormonal levels. The nuclear receptor peroxisome proliferator activated receptor α (PPARα), currently recognized as one of the master regulators of ketogenesis, integrates nutritional signals to the activation of transcriptional networks regulating fatty acid β-oxidation and ketogenesis. New factors, such as circadian rhythms and paracrine signals, are emerging as important aspects of this metabolic regulation. However, KB are currently considered not only as energy substrates but also as signaling molecules. β-hydroxybutyrate has been identified as class I histone deacetylase inhibitor, thus establishing a connection between products of hepatic lipid metabolism and epigenetics. Ketogenic diets (KD) are currently used to treat different forms of infantile epilepsy, also caused by genetic defects such as Glut1 and Pyruvate Dehydrogenase Deficiency Syndromes. However, several researchers are now focusing on the possibility to use KD in other diseases, such as cancer, neurological and metabolic disorders. Nonetheless, clear-cut evidence of the efficacy of KD in other disorders remains to be provided in order to suggest the adoption of such diets to metabolic-related pathologies.
Metabolism is the central engine of living organisms as it provides energy and building blocks for many essential components of each cell, which are required for specific functions in different tissues. Mitochondria are the main site for energy production in living organisms and they also provide intermediate metabolites required for the synthesis of other biologically relevant molecules. Such cellular processes are finely tuned at different levels, including allosteric regulation, posttranslational modifications, and transcription of genes encoding key proteins in metabolic pathways. Peroxisome proliferator activated receptor γ coactivator 1 (PGC1) proteins are transcriptional coactivators involved in the regulation of many cellular processes, mostly ascribable to metabolic pathways. Here, we will discuss some aspects of the cellular processes regulated by PGC1s, bringing up some examples of their role in mitochondrial and cellular metabolism, and how metabolic regulation in mitochondria by members of the PGC1 family affects the immune system. We will analyze how PGC1 proteins are regulated at the transcriptional and posttranslational level and will also examine other regulators of mitochondrial metabolism and the related cellular functions, considering approaches to identify novel mitochondrial regulators and their role in physiology and disease. Finally, we will analyze possible therapeutical perspectives currently under assessment that are applicable to different disease states.
Obesity is a condition characterized by uncontrolled expansion of adipose tissue mass resulting in pathological weight gain. Histone deacetylases (HDACs) have emerged as crucial players in epigenetic regulation of adipocyte metabolism. Previously, we demonstrated that selective inhibition of class I HDACs improves white adipocyte functionality and promotes the browning phenotype of murine mesenchymal stem cells (MSCs) C3H/10T1/2 differentiated to adipocytes. These effects were also observed in db/db and diet induced obesity mouse models and in mice with adipose-selective inactivation of HDAC3, a member of class I HDACs. The molecular basis of class I HDACs action in adipose tissue is not deeply characterized and it is not known whether the effects of their inhibition are exerted on adipocyte precursors or mature adipocytes. Therefore, the aim of the present work was to explore the molecular mechanism of class I HDAC action in adipocytes by evaluating the effects of HDAC3-specific silencing at different stages of differentiation. HDAC3 was silenced in C3H/10T1/2 MSCs at different stages of differentiation to adipocytes. shRNA targeting HDAC3 was used to generate the knock-down model. Proper HDAC3 silencing was assessed by measuring both mRNA and protein levels of mouse HDAC3 via qPCR and western blot, respectively. Mitochondrial DNA content and gene expression were quantified via qPCR. HDAC3 silencing at the beginning of differentiation enhanced adipocyte functionality by amplifying the expression of genes regulating differentiation, oxidative metabolism, browning and mitochondrial activity, starting from 72 h after induction of differentiation and silencing. Insulin signaling was enhanced as demonstrated by increased AKT phosphorylation following HDAC3 silencing. Mitochondrial content/density did not change, while the increased expression of the transcriptional co-activator Ppargc1b suggests the observed phenotype was related to enhanced mitochondrial activity, which was confirmed by increased maximal respiration and proton leak linked to reduced coupling efficiency. Moreover, the expression of pro-inflammatory markers increased with HDAC3 early silencing. To the contrary, no differences in terms of gene expression were found when HDAC3 silencing occurred in terminally differentiated adipocyte. Our data demonstrated that early epigenetic events mediated by class I HDAC inhibition/silencing are crucial to commit adipocyte precursors towards the above-mentioned metabolic phenotype. Moreover, our data suggest that these effects are exerted on adipocyte precursors.
Introduction: Obesity is associated with comorbidities such as cardiovascular disease and type 2 diabetes. HDAC3 regulates adipose tissue physiology (WAT), and its genetic inactivation causes metabolic reprogramming of white adipocytes toward browning. The aim of this work is to evaluate the effect of HDAC3 silencing at different stages of differentiation and investigate the influence of adipocyte metabolism on the immunophenotype of WAT. Materials and Methods: Following HDAC3 silencing in mesenchymal stem cells and mature adipocytes, adipocyte function, RNA, DNA and protein levels, and proliferation at the end of differentiation were analyzed. Visceral WAT immunophenotype (vWAT) of Hdac3 KO mice in WAT (Hdac3fatKO) and controls (FL) was performed by FACS. Results: Silencing HDAC3 in precursors amplifies the expression of genes and proteins that regulate differentiation, oxidative metabolism, browning and mitochondrial activity. Following silencing, we found increased 1)phosphorylation of AKT (1.64 fold change, P<0.0001), indicative of increased insulin signaling, and 2)proliferation, characteristic of the early phase of differentiation. Mitochondrial content was unchanged, but increased mitochondrial activity was observed in terms of maximal respiration (1.42 fold change, P=0.0151) and uncoupling of the electron transport chain (+11.6%, P<0.0001). No difference was observed following HDAC3 silencing in mature adipocytes. We hypothesized that the enhancement of oxidative metabolism may cause cellular damage or senescence and, consequently, the immunophenotype of vWAT might be affected by HDAC3 ablation. Analysis reveals an increase of macrophages (2.48 fold change, P=0.0311) in the vWAT of Hdac3fatKO mice polarizing toward the M2 population. Coculture of adipocytes with macrophages from bone marrow indicates that HDAC3 silencing in adipocytes stimulates macrophage activation. Conclusions: HDAC3 is a key factor in the WAT phenotype, and its inactivation triggers mechanisms that support browning. Early epigenetic events mediated by HDAC3 silencing are crucial in directing adipocyte precursors toward the oxidative phenotype. Finally, results obtained from ex vivo and in vitro studies suggest that specific factors produced by KO adipocytes may be involved in determining the observed immunophenotype. [FONDAZIONE CARIPLO 2015-0641]
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