10 research outputs found
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A diurnal serum lipid integrates hepatic lipogenesis and peripheral fatty acid utilization
Food intake increases the activity of hepatic de novo lipogenesis, which mediates the conversion of glucose to fats for storage or utilization. In mice, this program follows a circadian rhythm that peaks with nocturnal feeding1,2 and is repressed by Rev-erbα/β and an HDAC3-containing complex3–5 during the day. The transcriptional activators controlling rhythmic lipid synthesis in the dark cycle remain poorly defined. Disturbances in hepatic lipogenesis are also associated with systemic metabolic phenotypes6–8, suggesting that lipogenesis in the liver communicates with peripheral tissues to control energy substrate homeostasis. Here we identify a PPARδ-dependent de novo lipogenic pathway in the liver that modulates fat utilization by muscle via a circulating lipid. The nuclear receptor PPARδ controls diurnal expression of lipogenic genes in the dark/feeding cycle. Liver-specific PPARδ activation increases, while hepatocyte-Ppard deletion reduces, muscle fatty acid (FA) uptake. Unbiased metabolite profiling identifies PC(18:0/18:1), or 1-stearoyl-2-oleoyl-sn-glycero-3-phosphocholine (SOPC), as a serum lipid regulated by diurnal hepatic PPARδ activity. PC(18:0/18:1) reduces postprandial lipid levels and increases FA utilization through muscle PPARα. High fat feeding diminishes rhythmic production of PC(18:0/18:1), whereas PC(18:0/18:1) administration in db/db mice improves metabolic homeostasis. These findings reveal an integrated regulatory circuit coupling lipid synthesis in the liver to energy utilization in muscle by coordinating the activity of two closely related nuclear receptors. These data implicate alterations in diurnal hepatic PPARδ-PC(18:0/18:1) signaling in metabolic disorders including obesity
Nuclear Receptor Corepressor SMRT Regulates Mitochondrial Oxidative Metabolism and Mediates Aging-Related Metabolic Deterioration
SummaryThe transcriptional corepressor SMRT utilizes two major receptor-interacting domains (RID1 and RID2) to mediate nuclear receptor (NR) signaling through epigenetic modification. The physiological significance of such interaction remains unclear. We find SMRT expression and its occupancy on peroxisome proliferator-activated receptor (PPAR) target gene promoters are increased with age in major metabolic tissues. Genetic manipulations to selectively disable RID1 (SMRTmRID1) demonstrate that shifting SMRT repression to RID2-associated NRs, notably PPARs, causes premature aging and related metabolic diseases accompanied by reduced mitochondrial function and antioxidant gene expression. SMRTmRID1 cells exhibit increased susceptibility to oxidative damage, which could be rescued by PPAR activation or antioxidant treatment. In concert, several human Smrt gene polymorphisms are found to nominally associate with type 2 diabetes and adiponectin levels. These data uncover a role for SMRT in mitochondrial oxidative metabolism and the aging process, which may serve as a drug target to improve health span
Discovery of Pyrazolo[1,5‑<i>a</i>]pyrimidine B‑Cell Lymphoma 6 (BCL6) Binders and Optimization to High Affinity Macrocyclic Inhibitors
Inhibition of the protein–protein
interaction between B-cell
lymphoma 6 (BCL6) and corepressors has been implicated as a therapeutic
target in diffuse large B-cell lymphoma (DLBCL) cancers and profiling
of potent and selective BCL6 inhibitors are critical to test this
hypothesis. We identified a pyrazolo[1,5-<i>a</i>]pyrimidine
series of BCL6 binders from a fragment screen in parallel with a virtual
screen. Using structure-based drug design, binding affinity was increased
100000-fold. This involved displacing crystallographic water, forming
new ligand–protein interactions and a macrocyclization to favor
the bioactive conformation of the ligands. Optimization for slow off-rate
constant kinetics was conducted as well as improving selectivity against
an off-target kinase, CK2. Potency in a cellular BCL6 assay was further
optimized to afford highly selective probe molecules. Only weak antiproliferative
effects were observed across a number of DLBCL lines and a multiple
myeloma cell line without a clear relationship to BCL6 potency. As
a result, we conclude that the BCL6 hypothesis in DLBCL cancer remains
unproven
Role of Peroxisome Proliferator-activated Receptor δ/β in Hepatic Metabolic Regulation*
Pharmacological activation of peroxisome proliferator-activated receptor δ/β (PPARδ/β) improves glucose handling and insulin sensitivity. The target tissues of drug actions remain unclear. We demonstrate here that adenovirus-mediated liver-restricted PPARδ activation reduces fasting glucose levels in chow- and high fat-fed mice. This effect is accompanied by hepatic glycogen and lipid deposition as well as up-regulation of glucose utilization and de novo lipogenesis pathways. Promoter analyses indicate that PPARδ regulates hepatic metabolic programs through both direct and indirect transcriptional mechanisms partly mediated by its co-activator, PPARγ co-activator-1β. Assessment of the lipid composition reveals that PPARδ increases the production of monounsaturated fatty acids, which are PPAR activators, and reduces that of saturated FAs. Despite the increased lipid accumulation, adeno-PPARδ-infected livers exhibit less damage and show a reduction in JNK stress signaling, suggesting that PPARδ-regulated lipogenic program may protect against lipotoxicity. The altered substrate utilization by PPARδ also results in a secondary effect on AMP-activated protein kinase activation, which likely contributes to the glucose-lowering activity. Collectively, our data suggest that PPARδ controls hepatic energy substrate homeostasis by coordinated regulation of glucose and fatty acid metabolism, which provide a molecular basis for developing PPARδ agonists to manage hyperglycemia and insulin resistance
Cigarette smoking reprograms apical junctional complex molecular architecture in the human airway epithelium in vivo
Taxpayer rights and protections in a digital global environment
This chapter explores the impact on taxpayer rights of digital developments in electronics and systems, artificial intelligence, and security.Using an integrated rights framework comprising principles of tax administration and compliance, together with legal rights, it sets out the challenges and opportunities offered by digital disruption. It addresses issues such as proportionality, discrimination, equity and fairness, transparency and bias in legal and administrative decision-making, security, privacy and confidentiality. The chapter takes a global and comparative perspective in addressing significant legal issues that require detailed research and debate. It emphasises the opportunities for government service obligations to taxpayers, using artificial intelligence and secure systems, to provide advanced assistance to taxpayers and businesses and boost economic growth and trade. The chapter concludes that the opportunities are available to enable global implementation of an integrated rights framework to protect taxpayers even more effectively through digital disruption. © Springer Nature Singapore Pte Ltd. 2020