A diet-induced animal model of non-alcoholic fatty liver disease and hepatocellular cancer
Background & AimsThe lack of a preclinical model of progressive non-alcoholic steatohepatitis (NASH) that recapitulates human disease is a barrier to therapeutic development.MethodsA stable isogenic cross between C57BL/6J (B6) and 129S1/SvImJ (S129) mice were fed a high fat diet with ad libitum consumption of glucose and fructose in physiologically relevant concentrations and compared to mice fed a chow diet and also to both parent strains.ResultsFollowing initiation of the obesogenic diet, B6/129 mice developed obesity, insulin resistance, hypertriglyceridemia and increased LDL-cholesterol. They sequentially also developed steatosis (4–8 weeks), steatohepatitis (16–24 weeks), progressive fibrosis (16 weeks onwards) and spontaneous hepatocellular cancer (HCC). There was a strong concordance between the pattern of pathway activation at a transcriptomic level between humans and mice with similar histological phenotypes (FDR 0.02 for early and 0.08 for late time points). Lipogenic, inflammatory and apoptotic signaling pathways activated in human NASH were also activated in these mice. The HCC gene signature resembled the S1 and S2 human subclasses of HCC (FDR 0.01 for both). Only the B6/129 mouse but not the parent strains recapitulated all of these aspects of human NAFLD.ConclusionsWe here describe a diet-induced animal model of non-alcoholic fatty liver disease (DIAMOND) that recapitulates the key physiological, metabolic, histologic, transcriptomic and cell-signaling changes seen in humans with progressive NASH.Lay summaryWe have developed a diet-induced mouse model of non-alcoholic steatohepatitis (NASH) and hepatic cancers in a cross between two mouse strains (129S1/SvImJ and C57Bl/6J). This model mimics all the physiological, metabolic, histological, transcriptomic gene signature and clinical endpoints of human NASH and can facilitate preclinical development of therapeutic targets for NASH.
Ceramide 1-Phosphate Is a Direct Activator of Cytosolic Phospholipase A2
Recently, we demonstrated that ceramide kinase, and its product, ceramide 1-phosphate (Cer-1-P), were mediators of arachidonic acid released in cells in response to interleukin-1 and calcium ionophore (Pettus, B. J., Bielawska, A., Spiegel, S., Roddy, P., Hannun, Y. A., and Chalfant, C. E. (2003) J. Biol. Chem. 278, 38206 -38213). In this study, we demonstrate that down-regulation of cytosolic phospholipase A 2 (cPLA 2 ) using RNA interference technology abolished the ability of Cer-1-P to induce arachidonic acid release in A549 cells, demonstrating that cPLA 2 is the key phospholipase A 2 downstream of Cer-1-P. Treatment of A549 cells with Cer-1-P (2.5 M) induced the translocation of full-length cPLA 2 from the cytosol to the Golgi apparatus/perinuclear regions, which are known sites of translocation in response to agonists. Cer-1-P also induced the translocation of the CaLB/C2 domain of cPLA 2 in the same manner, suggesting that this domain is responsive to Cer-1-P either directly or indirectly. In vitro studies were then conducted to distinguish these two possibilities. In vitro binding studies disclosed that Cer-1-P interacts directly with full-length cPLA 2 and with the CaLB domain in a calcium-and lipid-specific manner with a K Ca of 1.54 M. Furthermore, Cer-1-P induced a calcium-dependent increase in cPLA 2 enzymatic activity as well as lowering the EC 50 of calcium for the enzyme from 191 to 31 nM. This study identifies Cer-1-P as an anionic lipid that translocates and directly activates cPLA 2 , demonstrating a role for this bioactive lipid in the mediation of inflammatory responses.
Phosphorylated sphingolipids [ceramide-1-phosphate (C1P) and sphingosine-1-phosphate (S1P)] have emerged as key regulators of cell growth, survival, migration, and inflammation1–5. C1P (Fig. 1a) produced by ceramide kinase is an activator of group IVA cytosolic phospholipase A2α (cPLA2α), the rate-limiting releaser of arachidonic acid used for pro-inflammatory eicosanoid production3,6–9, which contributes to disease pathogenesis in asthma/airway hyper-responsiveness, cancer, atherosclerosis, and thrombosis. To modulate eicosanoid action and avoid the damaging effects of chronic inflammation, cells require efficient targeting, trafficking, and presentation of C1P to specific cellular sites. Vesicular trafficking is likely10 but nonvesicular mechanisms for C1P sensing, transfer, and presentation remain unexplored11,12. Moreover, the molecular basis for selective recognition and binding among signaling lipids with phosphate headgroups, namely C1P, phosphatidic acid (PA) or their lyso-derivatives, remains unclear. Herein, an ubiquitously-expressed lipid transfer protein (CPTP) is shown to specifically transfer C1P between membranes. Crystal structures establish C1P binding via a novel surface-localized, phosphate headgroup recognition center connected to an interior hydrophobic pocket that adaptively expands to ensheath differing-length lipid chains using a cleft-like gating mechanism. The two-layer, α-helically-dominated ‘sandwich’ topology identifies CPTP as the prototype for a new GLTP-fold13 subfamily. CPTP resides in the cell cytosol but associates with the trans-Golgi/TGN, nucleus, and plasma membrane. RNAi-induced CPTP depletion elevates C1P steady-state levels and alters Golgi cisternae stack morphology. The resulting C1P decrease in plasma membranes and increase in the Golgi complex stimulates cPLA2α release of arachidonic acid, triggering pro-inflammatory eicosanoid generation.
Metabolic Gene Remodeling and Mitochondrial Dysfunction in Failing Right Ventricular Hypertrophy Secondary to Pulmonary Arterial Hypertension
Background Right ventricular dysfunction (RVD) is the most frequent cause of death in patients with pulmonary arterial hypertension. Whereas abnormal energy substrate utilization has been implicated in the development of chronic left heart failure, data describing such metabolic remodeling in RVD remain incomplete. Thus, we sought to characterize metabolic gene expression changes and mitochondrial dysfunction in functional and dysfunctional RV hypertrophy. Methods and Results Two different rat models of RV hypertrophy were studied. The model of RVD (SU5416/hypoxia) exhibited a significantly decreased gene expression of PPAR-gamma coactivator-1 alpha (PGC-1α), PPAR-α and ERR-α. The expression of multiple PCG-1α target genes required for fatty acid oxidation (FAO) was similarly decreased. Decreased PGC-1α expression was also associated with a net loss of mitochondrial protein and oxidative capacity. Reduced mitochondrial number was associated with a downregulation of TFAM and other genes required for mitochondrial biogenesis. Electron microscopy demonstrated that in RVD tissue, mitochondria had abnormal shape and size. Lastly, respirometric analysis demonstrated that mitochondria isolated from RVD-tissue had a significantly reduced ADP-stimulated (state 3) rate for complex I. Conversely, functional RV hypertrophy in the pulmonary artery banding (PAB) model showed normal expression of PGC-1α, whereas the expression of FAO genes was either preserved or unregulated. Moreover, PAB-RV tissue exhibited preserved TFAM expression and mitochondrial respiration despite elevated RV pressure-overload. Conclusions Right ventricular dysfunction, but not functional RV hypertrophy in rats, demonstrates a gene expression profile compatible with a multilevel impairment of fatty acid metabolism and significant mitochondrial dysfunction, partially independent of chronic pressure-overload.
BackgroundHypertension is, amongst others, characterized by endothelial dysfunction and vascular remodeling. As sphingolipids have been implicated in both the regulation of vascular contractility and growth, we investigated whether sphingolipid biology is altered in hypertension and whether this is reflected in altered vascular function.Methods and FindingsIn isolated carotid arteries from spontaneously hypertensive rats (SHR) and normotensive Wistar-Kyoto (WKY) rats, shifting the ceramide/S1P ratio towards ceramide dominance by administration of a sphingosine kinase inhibitor (dimethylsphingosine) or exogenous application of sphingomyelinase, induced marked endothelium-dependent contractions in SHR vessels (DMS: 1.4±0.4 and SMase: 2.1±0.1 mN/mm; n = 10), that were virtually absent in WKY vessels (DMS: 0.0±0.0 and SMase: 0.6±0.1 mN/mm; n = 9, p<0.05). Imaging mass spectrometry and immunohistochemistry indicated that these contractions were most likely mediated by ceramide and dependent on iPLA2, cyclooxygenase-1 and thromboxane synthase. Expression levels of these enzymes were higher in SHR vessels. In concurrence, infusion of dimethylsphingosine caused a marked rise in blood pressure in anesthetized SHR (42±4%; n = 7), but not in WKY (−12±10%; n = 6). Lipidomics analysis by mass spectrometry, revealed elevated levels of ceramide in arterial tissue of SHR compared to WKY (691±42 vs. 419±27 pmol, n = 3–5 respectively, p<0.05). These pronounced alterations in SHR sphingolipid biology are also reflected in increased plasma ceramide levels (513±19 pmol WKY vs. 645±25 pmol SHR, n = 6–12, p<0.05). Interestingly, we observed similar increases in ceramide levels (correlating with hypertension grade) in plasma from humans with essential hypertension (185±8 pmol vs. 252±23 pmol; n = 18 normotensive vs. n = 19 hypertensive patients, p<0.05).ConclusionsHypertension is associated with marked alterations in vascular sphingolipid biology such as elevated ceramide levels and signaling, that contribute to increased vascular tone.
Loss of miR-29b following Acute Ischemic Stroke Contributes to Neural Cell Death and Infarct Size
Glutathione depletion and 12-lipoxygenase-dependent metabolism of arachidonic acid are known to be implicated in neurodegeneration associated with acute ischemic stroke. The objective of this study was to investigate the significance of miR-29 in neurodegeneration associated with acute ischemic stroke. Neural cell death caused by arachidonic acid insult of glutathionedeficient cells was preceded by a 12-lipoxygenase-dependent loss of miR-29b. Delivery of miR-29b mimic to blunt such loss was neuroprotective. miR-29b inhibition potentiated such neural cell death. 12-Lipoxygenase knockdown and inhibitors attenuated the loss of miR-29b in challenged cells. In vivo, stroke caused by middle-cerebral artery occlusion was followed by higher 12-lipoxygenase activity and loss of miR-29b as detected in laser-captured infarct site tissue. 12-Lipoxygenase knockout mice demonstrated protection against such miR loss. miR-29b gene delivery markedly attenuated stroke-induced brain lesion. Oral supplementation of a-tocotrienol, a vitamin E 12-lipoxygenase inhibitor, rescued stroke-induced loss of miR-29b and minimized lesion size. This work provides the first evidence demonstrating that loss of miR-29b at the infarct site is a key contributor to stroke lesion. Such loss is contributed by activity of the 12-lipoxygenase pathway providing maiden evidence linking arachidonic acid metabolism to miR-dependent mechanisms in stroke.
Increasing evidence points to the functional importance of alternative splice variations in cancer pathophysiology. Two splice variants are derived from the CASP9 gene via the inclusion (Casp9a) or exclusion (Casp9b) of a four-exon cassette. Here we show that alternative splicing of Casp9 is dysregulated in non-small cell lung cancers (NSCLC) regardless of their pathologic classification. Based on these findings we hypothesized that survival pathways activated by oncogenic mutation regulated this mechanism. In contrast to K-RasV12 expression, epidermal growth factor receptor (EGFR) overexpression or mutation dramatically lowered the Casp9a/9b splice isoform ratio. Moreover, Casp9b downregulation blocked the ability of EGFR mutations to induce anchorage-independent growth. Furthermore, Casp9b expression blocked inhibition of clonogenic colony formation by erlotinib. Interrogation of oncogenic signaling pathways showed that inhibition of phosphoinositide 3-kinase or Akt dramatically increased the Casp9a/9b ratio in NSCLC cells. Finally, Akt was found to mediate exclusion of the exon 3,4,5,6 cassette of Casp9 via the phosphorylation state of the RNA splicing factor SRp30a via serines 199, 201, 227, and 234. Taken together, our findings show that oncogenic factors activating the phosphoinositide 3-kinase/Akt pathway can regulate alternative splicing of Casp9 via a coordinated mechanism involving the phosphorylation of SRp30a. Cancer Res; 70(22); 9185-96. ©2010 AACR.
Ceramide 1-Phosphate Is Required for the Translocation of Group IVA Cytosolic Phospholipase A2 and Prostaglandin Synthesis
Little is known about the regulation of eicosanoid synthesis proximal to the activation of cytosolic phospholipase A 2 ␣ (cPLA 2 ␣), the initial rate-limiting step. The current view is that cPLA 2 ␣ associates with intracellular/phosphatidylcholine-rich membranes strictly via hydrophobic interactions in response to an increase of intracellular calcium. In opposition to this accepted mechanism of two decades, ceramide 1-phosphate (C1P) has been shown to increase the membrane association of cPLA 2 ␣ in vitro via a novel site in the cationic -groove of the C2 domain (Stahelin, R. V., Subramanian, P., Vora, M., Cho, W., and Chalfant, C. E. In this study we demonstrate that C1P is a proximal and required bioactive lipid for the translocation of cPLA 2 ␣ to intracellular membranes in response to inflammatory agonists (e.g. calcium ionophore and ATP). Last, the absolute requirement of the C1P/ cPLA 2 ␣ interaction was demonstrated for the production of eicosanoids using murine embryonic fibroblasts (cPLA 2 ␣ ؊/؊ ) coupled to "rescue" studies. Therefore, this study provides a paradigm shift in how cPLA 2 ␣ is activated during inflammation.Eicosanoids are a class of bioactive lipids derived from the 20-carbon fatty acid, arachidonic acid (AA), 2 including prostaglandins, prostacyclins, thromboxanes, and leukotrienes. The production of AA is the initial rate-limiting step in the production of eicosanoids, and the major phospholipase that regulates eicosanoids synthesis in response to agonists is group IVA cytosolic phospholipase A 2 (cPLA 2 ␣) (2, 3). Activation of cPLA 2 in cells requires the association of the enzyme with intracellular membranes in a Ca 2ϩ -dependent manner. This translocation of cPLA 2 ␣ from the cytosol to intracellular membranes is mediated by a Ca 2ϩ -dependent lipid binding domain (CaLB domain) located at the N terminus of the enzyme (4 -7). The CaLB domain is ϳ60 amino acids and binds phosphatidylcholine (PC) in a Ca 2ϩ -dependent manner (3, 8 -10). However, it is not known if physiologic calcium is sufficient to activate and translocate cPLA 2 ␣ to membranes in cells or if activation also requires the generation of other activating lipids, such as the focus of this study, ceramide 1-phosphate (C1P).One possible activating lipid, phosphatidylinositol 4,5-diphosphate, was ruled out by Balboa and co-workers (11) as a lipid co-factor required for the translocation of the enzyme. This group showed that the interaction with this lipid (via its catalytic domain) was required for full activity of cPLA 2 ␣ after the enzyme translocated to the membrane (11). Another recent report by Leslie and co-workers (12) confirmed these findings, and a recent study by our laboratory corroborated these findings utilizing biophysical approaches (1). Specifically, we showed that C1P induced a dramatic increase of cPLA 2 ␣ activity strictly by increasing the residence time of cPLA 2 ␣ to membranes, whereas phosphatidylinositol 4,5-diphosphate enhanced the enzymes catalytic activity and membrane penetration (13,14).Recent...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
