Wen-Liang Song

Obesity in mice with adipocyte-specific deletion of clock component Arntl

Adipocytes store excess energy in the form of triglycerides and signal the levels of stored energy to the brain. Here we show that adipocyte-specific deletion of Arntl (also known as Bmal1), a gene encoding a core molecular clock component, results in obesity in mice with a shift in the diurnal rhythm of food intake, a result that is not seen when the gene is disrupted in hepatocytes or pancreatic islets. Changes in the expression of hypothalamic neuropeptides that regulate appetite are consistent with feedback from the adipocyte to the central nervous system to time feeding behavior. Ablation of the adipocyte clock is associated with a reduced number of polyunsaturated fatty acids in adipocyte triglycerides. This difference between mutant and wild-type mice is reflected in the circulating concentrations of polyunsaturated fatty acids and nonesterified polyunsaturated fatty acids in hypothalamic neurons that regulate food intake. Thus, this study reveals a role for the adipocyte clock in the temporal organization of energy regulation, highlights timing as a modulator of the adipocyte-hypothalamic axis and shows the impact of timing of food intake on body weight.

Microsomal Prostaglandin E Synthase-1 Deletion Suppresses Oxidative Stress and Angiotensin II–Induced Abdominal Aortic Aneurysm Formation

Background— Microsomal prostaglandin (PG) E2 synthase-1 (mPGES-1) catalyzes isomerization of the cyclooxygenase product PGH2 into PGE2. Deletion of mPGES-1 modulates experimentally evoked pain and inflammation and retards atherogenesis. The role of mPGES-1 in abdominal aortic aneurysm is unknown. Methods and Results— The impact of mPGES-1 deletion on formation of angiotensin II–induced abdominal aortic aneurysm was studied in mice lacking low-density lipoprotein receptor (LDLR−/−). Male mice deficient in both mPGES-1 and LDLR (mPGES-1−/− LDLR−/−) and littermate LDLR−/− mice were initiated on a high-fat diet at 6 months of age, followed 1 week later by continuous infusion of angiotensin II (1 &mgr;g/kg per minute) for an additional 4 weeks. Angiotensin II infusion upregulated aortic expression of cyclooxygenase-2 and mPGES-1, increased aortic macrophage recruitment and vascular nitrotyrosine staining (which reflects local oxidative stress), and augmented urinary excretion of the isoprostane 8,12-iso-iPF2&agr;-VI (which reflects lipid peroxidation in vivo) and the major metabolite of PGE2 (PGE-M). Deletion of mPGES-1 decreased both the incidence (87.5% versus 27.3%; P=0.02) and the severity of abdominal aortic aneurysm and depressed the aortic and systemic indices of oxidative stress. Deletion of mPGES-1 also depressed urinary PGE-M, whereas it augmented excretion of PGD2 and PGI2 metabolites, reflecting rediversion of the accumulated PGH2 substrate in the double knockouts. Conclusions— Deletion of mPGES-1 protects against abdominal aortic aneurysm formation induced by angiotensin II in hyperlipidemic mice, coincident with a reduction in oxidative stress. The potential efficacy of selective inhibition of mPGES-1 in preventing or retarding aneurysm formation warrants further investigation.

Timing of expression of the core clock gene Bmal1 influences its effects on aging and survival

Postnatal knockout of a core clock gene in mice prompts reevaluation of the systemic role of the molecular clock in the biology of aging. For clock ticking, timing matters Ironically, antiaging product advertisements often promise to “slow down the clock.” But abolishing the circadian clock—for example, by knocking out Bmal1, a core clock gene—accelerates aging and shortens the life span in mice. As a result, Bmal1 knockout mice often serve as a model system in studies of the role of circadian rhythms in the aging process. Now Yang et al. show that the developmental timing of Bmal1 expression influences the circadian clock’s effects on aging and survival. To assess the role of circadian rhythms in the aging process, the authors made conditional Bmal1 knockout mice that are missing the BMAL1 protein only during adult life. Unlike knockout mice that perpetually lack Bmal1 expression, the new conditional Bmal1 knockout mice displayed loss of circadian rhythm in wheel-running activity, heart rate, and blood pressure, but exhibited normal life spans, fertility, body weight, blood glucose levels, and age-dependent arthropathy; in fact, atherosclerosis and hair growth actually improved, despite obliteration of clock function. Another surprising observation was little changes in overall gene expression in the livers of adult-life Bmal1 knockout mice, even though there’s a quelling of expression of oscillating genes. Both prenatal and postnatal knockout mice displayed similar ocular abnormalities and brain astrogliosis. Taken together, these findings reveal that many phenotypes thought to be caused by circadian rhythm disruption in conventional Bmal1 knockout mice apparently manifest as a result of clock-independent BMAL1 functions. Thus, the systemic role of the molecular clock in the biology of aging requires reinvestigation in order to increase the likelihood of translation for preclinical studies of the aging process. The absence of Bmal1, a core clock gene, results in a loss of circadian rhythms, an acceleration of aging, and a shortened life span in mice. To address the importance of circadian rhythms in the aging process, we generated conditional Bmal1 knockout mice that lacked the BMAL1 protein during adult life and found that wild-type circadian variations in wheel-running activity, heart rate, and blood pressure were abolished. Ocular abnormalities and brain astrogliosis were conserved irrespective of the timing of Bmal1 deletion. However, life span, fertility, body weight, blood glucose levels, and age-dependent arthropathy, which are altered in standard Bmal1 knockout mice, remained unaltered, whereas atherosclerosis and hair growth improved, in the conditional adult-life Bmal1 knockout mice, despite abolition of clock function. Hepatic RNA-Seq revealed that expression of oscillatory genes was dampened in the adult-life Bmal1 knockout mice, whereas overall gene expression was largely unchanged. Thus, many phenotypes in conventional Bmal1 knockout mice, hitherto attributed to disruption of circadian rhythms, reflect the loss of properties of BMAL1 that are independent of its role in the clock. These findings prompt reevaluation of the systemic consequences of disruption of the molecular clock.

Neurofurans, Novel Indices of Oxidant Stress Derived from Docosahexaenoic Acid

Isoeicosanoids are free radical-catalyzed isomers of the enzymatic products of arachidonic acid. They are formed in situ in cell membranes, are cleaved, circulate, and are excreted in urine. Isomers of prostaglandin F2α, the F2-isoprostanes, have emerged as sensitive indices of lipid peroxidation in vivo. Analogous compounds formed from docosahexaenoic acid (DHA) are termed neuroprostanes and are more abundant than isoprostanes (iPs) in brain. Isofurans are another class of isoeicosanoids characterized by a substituted tetrahydrofuran ring. They are preferentially formed, relative to iPs, under conditions of elevated oxygen tension. Here, we report the discovery of neurofurans (nFs), the analogous family of compounds formed from DHA. Formation of nFs is characterized by mass spectrometry and confirmed by oxidation of DHA in vitro and following CCl4 administration in liver in vivo. It is demonstrated that the levels of nFs are elevated in the brain cortex of a mouse model of Alzheimer disease and are depressed in mouse brain cortex by deletion of p47phox, an essential component of the phagocyte NADPH oxidase. Measurement of the nFs may ultimately prove useful in diagnosis, timing, and selection of dose in the treatment and chemoprevention of neurodegenerative disease.

Microsomal prostaglandin E synthase-1 inhibition in cardiovascular inflammatory disease

Prostaglandins (PGs), particularly PGE2 and prostacyclin (PGI2), are potent mediators of pain and inflammation. Both atherosclerosis and aortic aneurysm exhibit the hallmarks of inflammation. However, randomized trials of inhibitors of PG synthesis – nonsteroidal anti‐inflammatory drugs – reveal that they predispose to cardiovascular risk. This appears to be consequent to inhibition of PGI2 and PGE2 formed by cyclooxygenase‐2 (COX‐2). Inhibitors of microsomal PGE synthase‐1 (mPGES‐1) are being developed for relief of pain and interest has focused on their potential impact on the cardiovascular system. Deletion of mPGES‐1 retards atherogenesis and limits aortic aneurysm formation in hyperlipidaemic mice. However, it does not predispose to thrombogenesis and has a limited impact on blood pressure compared to inhibition of COX‐2. This occurs despite the potential of the suppressed PGE2 in affording cardioprotection via its EP2 and EP4 receptors. However, deletion of mPGES‐1 permits rediversion of the PGH2 substrate to other PG synthases and augmented formation of PGI2 and PGD2 mitigates this effect. However, increased PGI2 may also attenuate relief of pain. Pain relief seems likely to be a nuanced indication for mPGES‐1 inhibitors, but they have therapeutic potential in syndromes of cardiovascular inflammation, cancer and perhaps in neurodegenerative disease. However, as the products of substrate rediversion vary according to cell type, these drugs may have contrasting impact amongst individuals at varied stages of disease evolution.

Tetranor PGDM, an Abundant Urinary Metabolite Reflects Biosynthesis of Prostaglandin D2 in Mice and Humans

Prostaglandin D2 (PGD2) is a cyclooxygenase (COX) product of arachidonic acid that activates D prostanoid receptors to modulate vascular, platelet, and leukocyte function in vitro. However, little is known about its enzymatic origin or its formation in vivo in cardiovascular or inflammatory disease. 11,15-Dioxo-9α-hydroxy-2,3,4,5-tetranorprostan-1,20-dioic acid (tetranor PGDM) was identified by mass spectrometry as a metabolite of infused PGD2 that is detectable in mouse and human urine. Using liquid chromatography-tandem mass spectrometry, tetranor PGDM was much more abundant than the PGD2 metabolites, 11β-PGF2α and 2,3-dinor-11β-PGF2α, in human urine and was the only endogenous metabolite detectable in mouse urine. Infusion of PGD2 dose dependently increased urinary tetranor PGDM > 2,3-dinor-11β-PGF2α > 11β-PGF2α in mice. Deletion of either lipocalin-type or hemopoietic PGD synthase enzymes decreased urinary tetranor PGDM. Deletion or knockdown of COX-1, but not deletion of COX-2, decreased urinary tetranor PGDM in mice. Correspondingly, both PGDM and 2,3-dinor-11β-PGF2α were suppressed by inhibition of COX-1 and COX-2, but not by selective inhibition of COX-2 in humans. PGD2 has been implicated in both the development and resolution of inflammation. Administration of bacterial lipopolysaccharide coordinately elevated tetranor PGDM and 2,3-dinor-11β-PGF2α in volunteers, coincident with a pyrexial and systemic inflammatory response, but both metabolites fell during the resolution phase. Niacin increased tetranor PGDM and 2,3-dinor-11β-PGF2α in humans coincident with facial flushing. Tetranor PGDM is an abundant metabolite in urine that reflects modulated biosynthesis of PGD2 in humans and mice.

Novel Eicosapentaenoic Acid-derived F3-isoprostanes as Biomarkers of Lipid Peroxidation

Isoprostanes (iPs) are prostaglandin (PG) isomers generated by free radical-catalyzed peroxidation of polyunsaturated fatty acids (PUFAs). Urinary F2-iPs, PGF2α isomers derived from arachidonic acid (AA) are used as indices of lipid peroxidation in vivo. We now report the characterization of two major F3-iPs, 5-epi-8,12-iso-iPF3α-VI and 8,12-iso-iPF3α-VI, derived from the ω-3 fatty acid, eicosapentaenoic acid (EPA). Although the potential therapeutic benefits of EPA receive much attention, a shift toward a diet rich in ω-3 PUFAs may also predispose to enhanced lipid peroxidation. Urinary 5-epi-8,12-iso-iPF3α-VI and 8,12-iso-iPF3α-VI are highly correlated and unaltered by cyclooxygenase inhibition in humans. Fish oil dose-dependently elevates urinary F3-iPs in mice and a shift in dietary ω-3/ω-6 PUFAs is reflected by an increasing slope [m] of the line relating urinary 8, 12-iso-iPF3α-VI and 8,12-iso-iPF2α-VI. Administration of bacterial lipopolysaccharide evokes a reversible increase in both urinary 8,12-iso-iPF3α-VI and 8,12-iso-iPF2α-VI in humans on an ad lib diet. However, while excretion of the iPs is highly correlated (R2 median = 0.8), [m] varies by an order of magnitude, reflecting marked inter-individual variability in the relative peroxidation of ω-3 versus ω-6 substrates. Clustered analysis of F2- and F3-iPs refines assessment of the oxidant stress response to an inflammatory stimulus in vivo by integrating variability in dietary intake of ω-3/ω-6 PUFAs.

Noninvasive Assessment of the Role of Cyclooxygenases in Cardiovascular Health: A Detailed HPLC/MS/MS Method

A robust method for the routine quantitation of a selected group of urinary eicosanoid metabolites of interest to cardiovascular research in human and mouse is described and discussed. Included are the addition of stable isotope-labeled internal standards, solid phase extraction, and quantitation by liquid chromatography/tandem mass spectrometry using selected reaction monitoring (SRM) techniques.

Niacin and biosynthesis of PGD2 by platelet COX-1 in mice and humans

The clinical use of niacin to treat dyslipidemic conditions is limited by noxious side effects, most commonly facial flushing. In mice, niacin-induced flushing results from COX-1-dependent formation of PGD₂ and PGE₂ followed by COX-2-dependent production of PGE₂. Consistent with this, niacin-induced flushing in humans is attenuated when niacin is combined with an antagonist of the PGD₂ receptor DP1. NSAID-mediated suppression of COX-2-derived PGI₂ has negative cardiovascular consequences, yet little is known about the cardiovascular biology of PGD₂. Here, we show that PGD₂ biosynthesis is augmented during platelet activation in humans and, although vascular expression of DP1 is conserved between humans and mice, platelet DP1 is not present in mice. Despite this, DP1 deletion in mice augmented aneurysm formation and the hypertensive response to Ang II and accelerated atherogenesis and thrombogenesis. Furthermore, COX inhibitors in humans, as well as platelet depletion, COX-1 knockdown, and COX-2 deletion in mice, revealed that niacin evoked platelet COX-1-derived PGD₂ biosynthesis. Finally, ADP-induced spreading on fibrinogen was augmented by niacin in washed human platelets, coincident with increased thromboxane (Tx) formation. However, in platelet-rich plasma, where formation of both Tx and PGD₂ was increased, spreading was not as pronounced and was inhibited by DP1 activation. Thus, PGD₂, like PGI₂, may function as a homeostatic response to thrombogenic and hypertensive stimuli and may have particular relevance as a constraint on platelets during niacin therapy.

Dietary α-linolenic acid diminishes experimental atherogenesis and restricts T cell-driven inflammation

Aims Epidemiological studies report an inverse association between plant-derived dietary α-linolenic acid (ALA) and cardiovascular events. However, little is known about the mechanism of this protection. We assessed the cellular and molecular mechanisms of dietary ALA (flaxseed) on atherosclerosis in a mouse model. Methods and results Eight-week-old male apolipoprotein E knockout (ApoE−/−) mice were fed a 0.21 % (w/w) cholesterol diet for 16 weeks containing either a high ALA [7.3 % (w/w); n = 10] or low ALA content [0.03 % (w/w); n = 10]. Bioavailability, chain elongation, and fatty acid metabolism were measured by gas chromatography of tissue lysates and urine. Plaques were assessed using immunohistochemistry. T cell proliferation was investigated in primary murine CD3-positive lymphocytes. T cell differentiation and activation was assessed by expression analyses of interferon-γ, interleukin-4, and tumour necrosis factor α (TNFα) using quantitative PCR and ELISA. Dietary ALA increased aortic tissue levels of ALA as well as of the n−3 long chain fatty acids (LC n−3 FA) eicosapentaenoic acid, docosapentaenoic acid, and docosahexaenoic acid. The high ALA diet reduced plaque area by 50% and decreased plaque T cell content as well as expression of vascular cell adhesion molecule-1 and TNFα. Both dietary ALA and direct ALA exposure restricted T cell proliferation, differentiation, and inflammatory activity. Dietary ALA shifted prostaglandin and isoprostane formation towards 3-series compounds, potentially contributing to the atheroprotective effects of ALA. Conclusion Dietary ALA diminishes experimental atherogenesis and restricts T cell-driven inflammation, thus providing the proof-of-principle that plant-derived ALA may provide a valuable alternative to marine LC n−3 FA.