Ni-Huiping Son

Cardiomyocyte expression of PPARγ leads to cardiac dysfunction in mice

Three forms of PPARs are expressed in the heart. In animal models, PPARgamma agonist treatment improves lipotoxic cardiomyopathy; however, PPARgamma agonist treatment of humans is associated with peripheral edema and increased heart failure. To directly assess effects of increased PPARgamma on heart function, we created transgenic mice expressing PPARgamma1 in the heart via the cardiac alpha-myosin heavy chain (alpha-MHC) promoter. PPARgamma1-transgenic mice had increased cardiac expression of fatty acid oxidation genes and increased lipoprotein triglyceride (TG) uptake. Unlike in cardiac PPARalpha-transgenic mice, heart glucose transporter 4 (GLUT4) mRNA expression and glucose uptake were not decreased. PPARgamma1-transgenic mice developed a dilated cardiomyopathy associated with increased lipid and glycogen stores, distorted architecture of the mitochondrial inner matrix, and disrupted cristae. Thus, while PPARgamma agonists appear to have multiple beneficial effects, their direct actions on the myocardium have the potential to lead to deterioration in heart function.

ApoC-III inhibits clearance of triglyceride-rich lipoproteins through LDL family receptors

Hypertriglyceridemia is an independent risk factor for cardiovascular disease, and plasma triglycerides (TGs) correlate strongly with plasma apolipoprotein C-III (ApoC-III) levels. Antisense oligonucleotides (ASOs) for ApoC-III reduce plasma TGs in primates and mice, but the underlying mechanism of action remains controversial. We determined that a murine-specific ApoC-III-targeting ASO reduces fasting TG levels through a mechanism that is dependent on low-density lipoprotein receptors (LDLRs) and LDLR-related protein 1 (LRP1). ApoC-III ASO treatment lowered plasma TGs in mice lacking lipoprotein lipase (LPL), hepatic heparan sulfate proteoglycan (HSPG) receptors, LDLR, or LRP1 and in animals with combined deletion of the genes encoding HSPG receptors and LDLRs or LRP1. However, the ApoC-III ASO did not lower TG levels in mice lacking both LDLR and LRP1. LDLR and LRP1 were also required for ApoC-III ASO-induced reduction of plasma TGs in mice fed a high-fat diet, in postprandial clearance studies, and when ApoC-III-rich or ApoC-III-depleted lipoproteins were injected into mice. ASO reduction of ApoC-III had no effect on VLDL secretion, heparin-induced TG reduction, or uptake of lipids into heart and skeletal muscle. Our data indicate that ApoC-III inhibits turnover of TG-rich lipoproteins primarily through a hepatic clearance mechanism mediated by the LDLR/LRP1 axis.

Mice With Cardiac Overexpression of Peroxisome Proliferator–Activated Receptor γ Have Impaired Repolarization and Spontaneous Fatal Ventricular Arrhythmias

Background— Diabetes mellitus and obesity, which confer an increased risk of sudden cardiac death, are associated with cardiomyocyte lipid accumulation and altered cardiac electric properties, manifested by prolongation of the QRS duration and QT interval. It is difficult to distinguish the contribution of cardiomyocyte lipid accumulation from the contribution of global metabolic defects to the increased incidence of sudden death and electric abnormalities. Methods and Results— In order to study the effects of metabolic abnormalities on arrhythmias without the complex systemic effects of diabetes mellitus and obesity, we studied transgenic mice with cardiac-specific overexpression of peroxisome proliferator–activated receptor &ggr; 1 (PPAR&ggr;1) via the cardiac &agr;-myosin heavy-chain promoter. The PPAR&ggr; transgenic mice develop abnormal accumulation of intracellular lipids and die as young adults before any significant reduction in systolic function. Using implantable ECG telemeters, we found that these mice have prolongation of the QRS and QT intervals and spontaneous ventricular arrhythmias, including polymorphic ventricular tachycardia and ventricular fibrillation. Isolated cardiomyocytes demonstrated prolonged action potential duration caused by reduced expression and function of the potassium channels responsible for repolarization. Short-term exposure to pioglitazone, a PPAR&ggr; agonist, had no effect on mortality or rhythm in WT mice but further exacerbated the arrhythmic phenotype and increased the mortality in the PPAR&ggr; transgenic mice. Conclusions— Our findings support an important link between PPAR&ggr; activation, cardiomyocyte lipid accumulation, ion channel remodeling, and increased cardiac mortality.Background Diabetes and obesity, which confer an increased risk of sudden cardiac death, are associated with cardiomyocyte lipid accumulation and altered cardiac electrical properties, manifested by prolongation of the QRS duration and QT interval. It is difficult to distinguish the contribution of cardiomyocyte lipid accumulation versus the contribution of global metabolic defects to the increased incidence of sudden death and electrical abnormalities.

Cardiomyocyte-specific Loss of Diacylglycerol Acyltransferase 1 (DGAT1) Reproduces the Abnormalities in Lipids Found in Severe Heart Failure

Background: Total body DGAT1 mice have no cardiac phenotype. Results: Cardiomyocyte DGAT1 knock-out mice have increased mortality and accumulation of potentially toxic lipids, which were corrected by intestinal DGAT1 deletion and GLP-1 receptor agonists. Conclusion: Cardiomyocyte DGAT1 deletion produces heart dysfunction and lipid abnormalities. Significance: Lipotoxicity in the heart can be alleviated by changes in intestinal metabolism. Diacylglycerol acyltransferase 1 (DGAT1) catalyzes the final step in triglyceride synthesis, the conversion of diacylglycerol (DAG) to triglyceride. Dgat1−/− mice exhibit a number of beneficial metabolic effects including reduced obesity and improved insulin sensitivity and no known cardiac dysfunction. In contrast, failing human hearts have severely reduced DGAT1 expression associated with accumulation of DAGs and ceramides. To test whether DGAT1 loss alone affects heart function, we created cardiomyocyte-specific DGAT1 knock-out (hDgat1−/−) mice. hDgat1−/− mouse hearts had 95% increased DAG and 85% increased ceramides compared with floxed controls. 50% of these mice died by 9 months of age. The heart failure marker brain natriuretic peptide increased 5-fold in hDgat1−/− hearts, and fractional shortening (FS) was reduced. This was associated with increased expression of peroxisome proliferator-activated receptor α and cluster of differentiation 36. We crossed hDgat1−/− mice with previously described enterocyte-specific Dgat1 knock-out mice (hiDgat1−/−). This corrected the early mortality, improved FS, and reduced cardiac ceramide and DAG content. Treatment of hDgat1−/− mice with the glucagon-like peptide 1 receptor agonist exenatide also improved FS and reduced heart DAG and ceramide content. Increased fatty acid uptake into hDgat1−/− hearts was normalized by exenatide. Reduced activation of protein kinase Cα (PKCα), which is increased by DAG and ceramides, paralleled the reductions in these lipids. Our mouse studies show that loss of DGAT1 reproduces the lipid abnormalities seen in severe human heart failure.

Cardiomyocyte Aldose Reductase Causes Heart Failure and Impairs Recovery from Ischemia

Aldose reductase (AR), an enzyme mediating the first step in the polyol pathway of glucose metabolism, is associated with complications of diabetes mellitus and increased cardiac ischemic injury. We investigated whether deleterious effects of AR are due to its actions specifically in cardiomyocytes. We created mice with cardiac specific expression of human AR (hAR) using the α–myosin heavy chain (MHC) promoter and studied these animals during aging and with reduced fatty acid (FA) oxidation. hAR transgenic expression did not alter cardiac function or glucose and FA oxidation gene expression in young mice. However, cardiac overexpression of hAR caused cardiac dysfunction in older mice. We then assessed whether hAR altered heart function during ischemia reperfusion. hAR transgenic mice had greater infarct area and reduced functional recovery than non-transgenic littermates. When the hAR transgene was crossed onto the PPAR alpha knockout background, another example of greater heart glucose oxidation, hAR expressing mice had increased heart fructose content, cardiac fibrosis, ROS, and apoptosis. In conclusion, overexpression of hAR in cardiomyocytes leads to cardiac dysfunction with aging and in the setting of reduced FA and increased glucose metabolism. These results suggest that pharmacological inhibition of AR will be beneficial during ischemia and in some forms of heart failure.

CD36 Deficiency Impairs the Small Intestinal Barrier and Induces Subclinical Inflammation in Mice

Background & Aims CD36 has immunometabolic actions and is abundant in the small intestine on epithelial, endothelial, and immune cells. We examined the role of CD36 in gut homeostasis by using mice null for CD36 (CD36KO) and with CD36 deletion specific to enterocytes (Ent-CD36KO) or endothelial cells (EC-CD36KO). Methods Intestinal morphology was evaluated by using immunohistochemistry and electron microscopy. Intestinal inflammation was determined from neutrophil infiltration and expression of cytokines, toll-like receptors, and cyclooxygenase-2. Barrier integrity was assessed from circulating lipopolysaccharide and dextran administered intragastrically. Epithelial permeability to luminal dextran was visualized by using two-photon microscopy. Results The small intestines of CD36KO mice fed a chow diet showed several abnormalities including extracellular matrix accumulation with increased expression of extracellular matrix proteins, evidence of neutrophil infiltration, inflammation, and compromised barrier function. Electron microscopy showed shortened desmosomes with decreased desmocollin 2 expression. Systemically, leukocytosis and neutrophilia were present together with 80% reduction of anti-inflammatory Ly6Clow monocytes. Bone marrow transplants supported the primary contribution of non-hematopoietic cells to the inflammatory phenotype. Specific deletion of endothelial but not of enterocyte CD36 reproduced many of the gut phenotypes of germline CD36KO mice including fibronectin deposition, increased interleukin 6, neutrophil infiltration, desmosome shortening, and impaired epithelial barrier function. Conclusions CD36 loss results in chronic neutrophil infiltration of the gut, impairs barrier integrity, and systemically causes subclinical inflammation. Endothelial cell CD36 deletion reproduces the major intestinal phenotypes. The findings suggest an important role of the endothelium in etiology of gut inflammation and loss of epithelial barrier integrity.

Kidney triglyceride accumulation in the fasted mouse is dependent upon serum free fatty acids

Lipid accumulation is a pathological feature of every type of kidney injury. Despite this striking histological feature, physiological accumulation of lipids in the kidney is poorly understood. We studied whether the accumulation of lipids in the fasted kidney are derived from lipoproteins or NEFAs. With overnight fasting, kidneys accumulated triglyceride, but had reduced levels of ceramide and glycosphingolipid species. Fasting led to a nearly 5-fold increase in kidney uptake of plasma [14C]oleic acid. Increasing circulating NEFAs using a β adrenergic receptor agonist caused a 15-fold greater accumulation of lipid in the kidney, while mice with reduced NEFAs due to adipose tissue deficiency of adipose triglyceride lipase had reduced triglycerides. Cluster of differentiation (Cd)36 mRNA increased 2-fold, and angiopoietin-like 4 (Angptl4), an LPL inhibitor, increased 10-fold. Fasting-induced kidney lipid accumulation was not affected by inhibition of LPL with poloxamer 407 or by use of mice with induced genetic LPL deletion. Despite the increase in CD36 expression with fasting, genetic loss of CD36 did not alter fatty acid uptake or triglyceride accumulation. Our data demonstrate that fasting-induced triglyceride accumulation in the kidney correlates with the plasma concentrations of NEFAs, but is not due to uptake of lipoprotein lipids and does not involve the fatty acid transporter, CD36.

Endothelial cell CD36 optimizes tissue fatty acid uptake

Movement of circulating fatty acids (FAs) to parenchymal cells requires their transfer across the endothelial cell (EC) barrier. The multiligand receptor cluster of differentiation 36 (CD36) facilitates tissue FA uptake and is expressed in ECs and parenchymal cells such as myocytes and adipocytes. Whether tissue uptake of FAs is dependent on EC or parenchymal cell CD36, or both, is unknown. Using a cell-specific deletion approach, we show that EC, but not parenchymal cell, CD36 deletion increased fasting plasma FAs and postprandial triglycerides. EC-Cd36–KO mice had reduced uptake of radiolabeled long-chain FAs into heart, skeletal muscle, and brown adipose tissue; these uptake studies were replicated using [11C]palmitate PET scans. High-fat diet–fed EC-CD36–deficient mice had improved glucose tolerance and insulin sensitivity. Both EC and cardiomyocyte (CM) deletion of CD36 reduced heart lipid droplet accumulation after fasting, but CM deletion did not affect heart glucose or FA uptake. Expression in the heart of several genes modulating glucose metabolism and insulin action increased with EC-CD36 deletion but decreased with CM deletion. In conclusion, EC CD36 acts as a gatekeeper for parenchymal cell FA uptake, with important downstream effects on glucose utilization and insulin action.

Regulation of Insulin Receptor Pathway and Glucose Metabolism by CD36 Signaling

During reduced energy intake, skeletal muscle maintains homeostasis by rapidly suppressing insulin-stimulated glucose utilization. Loss of this adaptation is observed with deficiency of the fatty acid transporter CD36. A similar loss is also characteristic of the insulin-resistant state where CD36 is dysfunctional. To elucidate what links CD36 to muscle glucose utilization, we examined whether CD36 signaling might influence insulin action. First, we show that CD36 deletion specific to skeletal muscle reduces expression of insulin signaling and glucose metabolism genes. It decreases muscle ceramides but impairs glucose disposal during a meal. Second, depletion of CD36 suppresses insulin signaling in primary-derived human myotubes, and the mechanism is shown to involve functional CD36 interaction with the insulin receptor (IR). CD36 promotes tyrosine phosphorylation of IR by the Fyn kinase and enhances IR recruitment of P85 and downstream signaling. Third, pretreatment for 15 min with saturated fatty acids suppresses CD36-Fyn enhancement of IR phosphorylation, whereas unsaturated fatty acids are neutral or stimulatory. These findings define mechanisms important for muscle glucose metabolism and optimal insulin responsiveness. Potential human relevance is suggested by genome-wide analysis and RNA sequencing data that associate genetically determined low muscle CD36 expression to incidence of type 2 diabetes.

PPARγ Activation Prevents Sepsis-Related Cardiac Dysfunction and Mortality in Mice: Drosatos et al: PPARγ Treats Septic Cardiac Dysfunction

Impaired cardiac contractility contributes to the hypotension and increased mortality that occur with sepsis1. A possible cause of sepsis-mediated cardiac dysfunction is reduced energy production due in part to compromised fatty acid oxidation (FAO)2-5 and glucose catabolism3, 6. Thus, it is likely that sepsis compromises cardiac energy production, which might be the major cause of cardiac dysfunction. Alternatively, sepsis induces the production of inflammatory cytokines, such as tumor necrosis factor (TNF) α, interleukin (IL)-1 and IL-6, and these might directly alter heart function7-9. Intraperitoneal (i.p.) injection of lipopolysaccharide (LPS) has been extensively used to model many of the clinical features of sepsis, including elevated inflammation and cardiac dysfunction10. LPS leads to production of inflammatory cytokines7-9, 11 and also reduces cardiac energy utilization2, 3, 12. Nuclear receptors, particularly peroxisomal proliferator-activated receptors (PPARs), regulate cardiac FAO. The PPAR family consists of three members, PPARα, PPARδ and PPARγ. PPARα increases FA storage in triglycerides13 and FAO in heart14 and induces expression of peroxisomal and mitochondrial enzymes. Besides PPARα, cardiac FAO can be increased by activation of PPARγ15 or PPARδ16. Cardiomyocyte-specific overexpression of PPARα14 or PPARγ17 leads to cardiac lipid accumulation, an indication that lipid uptake exceeds FAO. PPARγ-coactivator-1 (PGC-1) α and β18 enhance FAO and mitochondrial biogenesis19. Both PPARα and PGC-1 mRNA levels are markedly reduced in the heart by LPS administration2, 3, 12, 20, while PPARγ is not affected2. Our group showed that maintenance of normal cardiac FAO via c-Jun-N-terminal kinase (JNK) inhibitor-mediated prevention of PPARα downregulation rescued cardiac function in septic mice despite elevated expression of cardiac inflammatory markers. In a similar context constitutive cardiac expression of PGC-1β prevented cardiac dysfunction that was caused by LPS-mediated sepsis3, an observation that was proposed to be due to improvement in cardiac FAO and attenuation of reactive oxygen species production. In the current study we show that constitutive cardiomyocyte-specific expression of PPARγ or systemic administration of the PPARγ agonist, rosiglitazone, increased cardiac FAO and prevented cardiac dysfunction in mice with LPS-induced sepsis, despite increased expression of cardiac inflammatory markers. In addition, we show that rosiglitazone-mediated activation of PPARγ prevents the loss of cardiac mitochondria that occurs in sepsis. Moreover, we show that restoration of cardiac FAO by rosiglitazone not only prevents but also treats LPS-induced heart dysfunction and improves survival. Thus the use of rosiglitazone is proposed as a potential treatment for septic cardiac dysfunction.Background—Cardiac dysfunction with sepsis is associated with both inflammation and reduced fatty acid oxidation. We hypothesized that energy deprivation accounts for sepsis-related cardiac dysfunction. Methods and Results—Escherichia coli lipopolysaccharide (LPS) administered to C57BL/6 mice (wild type) induced cardiac dysfunction and reduced fatty acid oxidation and mRNA levels of peroxisome proliferator–activated receptor (PPAR)-&agr; and its downstream targets within 6–8 hours. Transgenic mice in which cardiomyocyte-specific expression of PPAR&ggr; is driven by the &agr;-myosin heavy chain promoter (&agr;MHC-PPAR&ggr;) were protected from LPS-induced cardiac dysfunction. Despite a reduction in PPAR&agr;, fatty acid oxidation and associated genes were not decreased in hearts of LPS-treated &agr;MHC-PPAR&ggr; mice. LPS treatment, however, continued to induce inflammation-related genes, such as interleukin-1&agr;, interleukin-1&bgr;, interleukin-6, and tumor necrosis factor-&agr; in hearts of &agr;MHC-PPAR&ggr; mice. Treatment of wild-type mice with LPS and the PPAR&ggr; agonist, rosiglitazone, but not the PPAR&agr; agonist (WY-14643), increased fatty acid oxidation, prevented LPS-mediated reduction of mitochondria, and treated cardiac dysfunction, as well as it improved survival, despite continued increases in the expression of cardiac inflammatory markers. Conclusions—Activation of PPAR&ggr; in LPS-treated mice prevented cardiac dysfunction and mortality, despite development of cardiac inflammation and PPAR&agr; downregulation.