Michèle Teboul

Adipose angiotensinogen is involved in adipose tissue growth and blood pressure regulation

White adipose tissue and liver are important angiotensinogen (AGT) production sites. Until now, plasma AGT was considered to be a reflection of hepatic production. Because plasma AGT concentration has been reported to correlate with blood pressure, and to be associated with body mass index, we investigated whether adipose AGT is released locally and into the blood stream. For this purpose, we have generated transgenic mice either in which adipose AGT is overexpressed or in which AGT expression is restricted to adipose tissue. This was achieved by the use of the aP2 adipocyte‐specific promoter driving the expression of rat agt cDNA in both wild‐type and hypotensive AGT‐deficient mice. Our results show that in both genotypes, targeted expression of AGT in adipose tissue increases fat mass. Mice whose AGT expression is restricted to adipose tissue have AGT circulating in the blood stream, are normotensive, and exhibit restored renal function compared with AGT‐deficient mice. Moreover, mice that overexpress adipose AGT have increased levels of circulating AGT, compared with wild‐type mice, and are hypertensive. These animal models demonstrate that AGT produced by adipose tissue plays a role in both local adipose tissue development and in the endocrine system, which supports a role of adipose AGT in hypertensive obese patients.

The circadian clock component BMAL1 is a critical regulator of p21WAF1/CIP1 expression and hepatocyte proliferation.

Most living organisms show circadian (∼24 h) rhythms in physiology and behavior. These oscillations are generated by endogenous circadian clocks, present in virtually all cells where they control key biological processes. Although circadian gating of mitosis has been reported for many years in some peripheral tissues, the underlying molecular mechanisms have remained poorly understood. Here we show that the cell cycle inhibitor p21WAF1/CIP1 is rhythmically expressed in mouse peripheral organs. This rhythmic pattern of mRNA and protein expression was recapitulated in vitro in serum-shocked differentiated skeletal muscle cells. p21WAF1/CIP1 circadian expression is dramatically increased and no longer rhythmic in clock-deficient Bmal1–/– knock-out mice. Biochemical and genetic data show that oscillation of p21WAF1/CIP1 gene transcription is regulated by the antagonistic activities of the orphan nuclear receptors REV-ERBα/β and RORα4/γ, which are core clock regulators. Importantly, p21WAF1/CIP1 overexpressing Bmal1–/– primary hepatocytes exhibit a decreased proliferation rate. This phenotype could be reversed using small interfering RNA-mediated knockdown of p21WAF1/CIP1. These data establish a novel molecular link between clock and cell cycle genes and suggest that the G1 progression phase is a target of the circadian clock during liver cell proliferation.

The nuclear receptor REV-ERBα is required for the daily balance of carbohydrate and lipid metabolism

Mutations of clock genes can lead to diabetes and obesity. REV‐ERBα, a nuclear receptor involved in the circadian clockwork, has been shown to control lipid metabolism. To gain insight into the role of REV‐ERBα in energy homeostasis in vivo, we explored daily metabolism of carbohydrates and lipids in chow‐fed, unfed, or high‐fat‐fed Rev‐erbα−/− mice and their wild‐type littermates. Chow‐fed Rev‐erbα−/− mice displayed increased adiposity (2.5‐fold) and mild hyperglycemia (∼10%) without insulin resistance. Indirect calorimetry indicates that chow‐fed Rev‐erbα−/− mice utilize more fatty acids during daytime. A 24‐h nonfeeding period in Rev‐erbα−/− animals favors further fatty acid mobilization at the expense of glycogen utilization and gluconeogenesis, without triggering hypoglycemia and hypothermia. High‐fat feeding in Rev‐erbα−/− mice amplified metabolic disturbances, including expression of lipogenic factors. Lipoprotein lipase (Lpl) gene, critical in lipid utilization/storage, is triggered in liver at night and constitutively up‐regulated (∼ 2‐fold) in muscle and adipose tissue of Rev‐erbα−/− mice. We show that CLOCK, up‐regulated (2‐fold) at night in Rev‐erbα−/− mice, can transactivate Lpl. Thus, overexpression of Lpl facilitates muscle fatty acid utilization and contributes to fat overload. This study demonstrates the importance of clock‐driven Lpl expression in energy balance and highlights circadian disruption as a potential cause for the metabolic syndrome.—Delezie, J., Dumont, S., Dardente, H., Oudart, H., Gréchez‐Cassiau, A., Klosen, P., Teboul, M., Delaunay, F., Pévet, P., Challet, E. The nuclear receptor REV‐ERBα is required for the daily balance of carbohydrate and lipid metabolism. FASEB J. 26, 3321–3335 (2012). www.fasebj.org

Phase locking and multiple oscillating attractors for the coupled mammalian clock and cell cycle

Significance In tissues such as bone marrow, intestinal mucosa, or regenerating liver, the daily rhythm of cell division is controlled by the cell’s circadian clock. Determining how this clock organizes important processes such as cell division, apoptosis, and DNA damage repair is key to understanding the links between circadian dysfunction and malignant cell proliferation. We show that in proliferating mouse fibroblasts there is more than one way in which the clock and cell cycle synchronize their oscillations and that one of them is the biological equivalent of the phase locking first discovered by Huygens in the 17th century when he coupled two clocks together. When phase-locked two coupled oscillators have a fixed relative phase and oscillate with a common frequency. Daily synchronous rhythms of cell division at the tissue or organism level are observed in many species and suggest that the circadian clock and cell cycle oscillators are coupled. For mammals, despite known mechanistic interactions, the effect of such coupling on clock and cell cycle progression, and hence its biological relevance, is not understood. In particular, we do not know how the temporal organization of cell division at the single-cell level produces this daily rhythm at the tissue level. Here we use multispectral imaging of single live cells, computational methods, and mathematical modeling to address this question in proliferating mouse fibroblasts. We show that in unsynchronized cells the cell cycle and circadian clock robustly phase lock each other in a 1:1 fashion so that in an expanding cell population the two oscillators oscillate in a synchronized way with a common frequency. Dexamethasone-induced synchronization reveals additional clock states. As well as the low-period phase-locked state there are distinct coexisting states with a significantly higher period clock. Cells transition to these states after dexamethasone synchronization. The temporal coordination of cell division by phase locking to the clock at a single-cell level has significant implications because disordered circadian function is increasingly being linked to the pathogenesis of many diseases, including cancer.

The Adipose Renin-Angiotensin System Modulates Systemic Markers of Insulin Sensitivity and Activates the Intrarenal Renin-Angiotensin System

Background. The adipose tissue renin-angiotensin system (RAS) contributes to regulation of fat mass and may also impact systemic functions such as blood pressure and metabolism. Methods and results. A panel of mouse models including mice lacking angiotensinogen, Agt (Agt-KO), mice expressing Agt solely in adipose tissue (aP2-Agt/Agt-KO), and mice overexpressing Agt in adipose tissue (aP2-Agt) was studied. Total body weight, epididymal fat pad weight, and circulating levels of leptin, insulin, and resistin were significantly decreased in Agt-KO mice, while plasma adiponectin levels were increased. aP2-Agt mice exhibited increased adiposity and plasma leptin and insulin levels compared to wild type (WT) controls. Angiotensinogen and type I Ang II receptor protein levels were also elevated in kidney of aP2-Agt mice. Conclusion. These findings demonstrate that alterations in adipose RAS activity significantly impact both local and systemic physiology in a way that may contribute to the detrimental health effects of obesity.

Cancer Inhibition through Circadian Reprogramming of Tumor Transcriptome with Meal Timing

Circadian disruption accelerates cancer progression, whereas circadian reinforcement could halt it. Mice with P03 pancreatic adenocarcinoma (n = 77) were synchronized and fed ad libitum (AL) or with meal timing (MT) from Zeitgeber time (ZT) 2 to ZT6 with normal or fat diet. Tumor gene expression profiling was determined with DNA microarrays at endogenous circadian time (CT) 4 and CT16. Circadian mRNA expression patterns were determined for clock genes Rev-erbalpha, Per2, and Bmal1, cellular stress genes Hspa8 and Cirbp, and cyclin A2 gene Ccna2 in liver and tumor. The 24-hour patterns in telemetered rest-activity and body temperature and plasma corticosterone and insulin-like growth factor-I (IGF-I) were assessed. We showed that MT inhibited cancer growth by approximately 40% as compared with AL (P = 0.011) irrespective of calorie intake. Clock gene transcription remained arrhythmic in tumors irrespective of feeding schedule or diet. Yet, MT upregulated or downregulated the expression of 423 tumor genes, according to CT. Moreover, 36 genes involved in cellular stress, cell cycle, and metabolism were upregulated at one CT and downregulated 12 h apart. MT induced >10-fold circadian expression of Hspa8, Cirbp, and Ccna2 in tumors. Corticosterone or IGF-I patterns played no role in tumor growth inhibition. In contrast, MT consistently doubled the circadian amplitude of body temperature. Peak and trough respectively corresponded to peak expressions of Hspa8 and Cirbp in tumors. The reinforcement of the host circadian timing system with MT induced 24-hour rhythmic expression of critical genes in clock-deficient tumors, which translated into cancer growth inhibition. Targeting circadian clocks represents a novel potential challenge for cancer therapeutics.

Expression Levels of Estrogen Receptor β Are Modulated by Components of the Molecular Clock

ABSTRACT Circadian regulation of gene expression plays a major role in health and disease. The precise role of the circadian system remains to be clarified, but it is known that circadian proteins generate physiological rhythms in organisms by regulating clock-controlled target genes. The estrogen receptor beta (ERβ) is, together with ERα, a member of the nuclear receptor superfamily and a key mediator of estrogen action. Interestingly, recent studies show that disturbed circadian rhythmicity in humans can increase the risk of reproductive malfunctions, suggesting a link between the circadian system and ER-mediated transcription pathways. Here, we identify a novel level of regulation of estrogen signaling where ERβ, but not ERα, is controlled by circadian clock proteins. We show that ERβ mRNA levels fluctuate in different peripheral tissues following a robust circadian pattern, with a peak at the light-dark transition, which is maintained under free-running conditions. Interestingly, this oscillation is abolished in clock-deficient BMAL1 knockout mice. Circadian control of ERβ expression is exerted through a conserved E-box element in the ERβ promoter region that recruits circadian regulatory factors. Furthermore, using small interfering RNA-mediated knockdown assays, we show that the expression levels of the circadian regulatory factors directly influence estrogen signaling by regulating the intracellular levels of endogenous ERβ.

Kruppel-like factor KLF10 is a link between the circadian clock and metabolism in liver.

ABSTRACT The circadian timing system coordinates many aspects of mammalian physiology and behavior in synchrony with the external light/dark cycle. These rhythms are driven by endogenous molecular clocks present in most body cells. Many clock outputs are transcriptional regulators, suggesting that clock genes primarily control physiology through indirect pathways. Here, we show that Krüppel-like factor 10 (KLF10) displays a robust circadian expression pattern in wild-type mouse liver but not in clock-deficient Bmal1 knockout mice. Consistently, the Klf10 promoter recruited the BMAL1 core clock protein and was transactivated by the CLOCK-BMAL1 heterodimer through a conserved E-box response element. Profiling the liver transcriptome from Klf10−/− mice identified 158 regulated genes with significant enrichment for transcripts involved in lipid and carbohydrate metabolism. Importantly, approximately 56% of these metabolic genes are clock controlled. Male Klf10−/− mice displayed postprandial and fasting hyperglycemia, a phenotype accompanied by a significant time-of-day-dependent upregulation of the gluconeogenic gene Pepck and increased hepatic glucose production. Consistently, functional data showed that the proximal Pepck promoter is repressed directly by KLF10. Klf10−/− females were normoglycemic but displayed higher plasma triglycerides. Correspondingly, rhythmic gene expression of components of the lipogenic pathway, including Srebp1c, Fas, and Elovl6, was altered in females. Collectively, these data establish KLF10 as a required circadian transcriptional regulator that links the molecular clock to energy metabolism in the liver.

How nuclear receptors tell time.

Most organisms adapt their behavior and physiology to the daily changes in their environment through internal ( approximately 24 h) circadian clocks. In mammals, this time-keeping system is organized hierarchically, with a master clock located in the suprachiasmatic nuclei of the hypothalamus that is reset by light, and that, in turn, coordinates the oscillation of local clocks found in all cells. Central and peripheral clocks control, in a highly tissue-specific manner, hundreds of target genes, resulting in the circadian regulation of most physiological processes. A great deal of knowledge has accumulated during the last decade regarding the molecular basis of mammalian circadian clocks. These studies have collectively demonstrated how a set of clock genes and their protein products interact together in complex feedback transcriptional/translational loops to generate 24-h oscillations at the molecular, cellular, and organism levels. In recent years, a number of nuclear receptors (NRs) have been implicated as important regulators of the mammalian clock mechanism. REV-ERB and retinoid-related orphan receptor NRs regulate directly the core feedback loop and increase its robustness. The glucocorticoid receptor mediates the synchronizing effect of glucocorticoid hormones on peripheral clocks. Other NR family members, including the orphan NR EAR2, peroxisome proliferator activated receptors-alpha/gamma, estrogen receptor-alpha, and retinoic acid receptors, are also linked to the clockwork mechanism. These findings together establish nuclear hormone receptor signaling as an integral part of the circadian timing system.

Angiotensinogen, adipocyte differentiation and fat mass enlargement.

Purpose of reviewAngiotensinogen and components of the renin-angiotensin system are expressed in adipose tissue of rodents and humans, but the role of generated angiotensin II has remained intriguing. Moreover, the functional importance of angiotensin II receptor subtypes in preadipocytes and adipocytes still remains a controversial subject. Recent findingsRecent findings in transgenic mice have emphasized the upregulation of angiotensinogen expression by glucocorticoids. Furthermore, angiotensinogen products, that is angiotensin II and possibly angiotensin II-related products, have been found to act locally in modulating adipose tissue growth in an autocrine/paracrine manner. Cellularity measurements show that fat mass enlargement is associated with adipocyte hypertrophy, consistent with the upregulation of the fatty acid synthetase gene by angiotensin II depicted at the molecular level. Together, these findings suggest a mechanism by which transient or chronic overexpression of angiotensinogen in adipose tissue favors lipogenesis in adipocytes and leads to a ‘vicious’ circle whereby adipose tissue development is further increased. SummaryAdditional studies are warranted to characterize angiotensin II-related receptors, if any, and to clarify the role played by angiotensin II receptor subtypes and metabolites in various metabolic aspects of white adipose tissue. Purpose of reviewAngiotensinogen and components of the renin-angiotensin system are expressed in adipose tissue of rodents and humans, but the role of generated angiotensin II has remained intriguing. Moreover, the functional importance of angiotensin II receptor subtypes in preadipocytes and adipocytes still remains a controversial subject. Recent findingsRecent findings in transgenic mice have emphasized the upregulation of angiotensinogen expression by glucocorticoids. Furthermore, angiotensinogen products, that is angiotensin II and possibly angiotensin II-related products, have been found to act locally in modulating adipose tissue growth in an autocrine/paracrine manner. Cellularity measurements show that fat mass enlargement is associated with adipocyte hypertrophy, consistent with the upregulation of the fatty acid synthetase gene by angiotensin II depicted at the molecular level. Together, these findings suggest a mechanism by which transient or chronic overexpression of angiotensinogen in adipose tissue favors lipogenesis in adipocytes and leads to a ‘vicious’ circle whereby adipose tissue development is further increased. SummaryAdditional studies are warranted to characterize angiotensin II-related receptors, if any, and to clarify the role played by angiotensin II receptor subtypes and metabolites in various metabolic aspects of white adipose tissue.