Project description:miR-33 is an intronic miRNA within the gene encoding the SREBP2 transcription factor. Like its host gene, miR-33 has been shown to be an important regulator of lipid metabolism. Inhibition of miR-33 has been shown to promote cholesterol efflux in macrophages by targeting the cholesterol transporter ABCA1, thus reducing atherosclerotic plaque burden. Inhibition of miR-33 has also been shown to improve HDL biogenesis in the liver and increase circulating HDL-C levels in both rodents and non-human primates. However, evaluating the extent to which these changes in HDL metabolism contribute to atherogenesis has been hindered by the obesity and metabolic dysfunction observed in whole body miR-33 knockout mice. To determine the impact of hepatic miR-33 deficiency on obesity, metabolic function and atherosclerosis, we have generated a conditional knockout mouse model that lacks miR-33 only in the liver. Characterization of this model demonstrates that loss of miR-33 in the liver does not lead to increased body weight or adiposity. Hepatic miR-33 deficiency actually improves regulation of glucose homeostasis and impedes the development of fibrosis and inflammation. We further demonstrate that hepatic miR-33 deficiency increases circulating HDL-C levels and reverse cholesterol transport capacity in mice fed a chow diet, but these changes are not sufficient to reduce atherosclerotic plaque size under hyperlipidemic conditions. By elucidating the role of miR-33 in the liver, and the impact of hepatic miR-33 deficiency on obesity and atherosclerosis, this work will help inform ongoing efforts to develop novel targeted therapies against cardio-metabolic diseases.

Project description:miRNA-33a/b provides a critical link between the regulation of cholesterol and fatty acid biosynthesis by SREBPs, and cholesterol efflux, high-density lipoprotein (HDL) biogenesis and fatty acid oxidation pathways. Notably, pharmacological inhibition of miR-33 elevates hepatic ABCA1 expression, thereby increasing circulating HDL-C and attenuating the progression of atherosclerosis, highlighting the therapeutic potential of miR-33 inhibitors for the treatment of cardiovascular disease. However, work with genetic models of miR-33 deficiency has clearly demonstrated that global loss of miR-33 promotes the development of obesity and metabolic dysfunction. We sought to determine if miR-33 is directly involved in regulating the activity of the AgRP and POMC neurons that promote signals of hunger and satiety, respectively. We have generated AgRP conditional KO mouse to analyze the effect of removing miR-33 in these neurons. After miR-33 removal, mice were fed a HFD and then the expression of different markers related to activiation or inhibition of AgRP neurons was analyzed by scRNAseq.

Project description:Inhibition of miR-33 results in increased cholesterol efflux and HDL-cholesterol levels in mice. In this study we examined the effect of miR-33 inhibition in a mouse model of atherosclerosis and observed significant reduction in atherosclerotic plaque size. At the end of the study, gene expression in macrophages from the atherosclerotic plaques was assessed. The results demonstrated a reduction in inflammatory gene expression and increased levels of mRNAs containing miR-33 binding sites.

Project description:Inhibition of miR-33 results in increased cholesterol efflux and HDL-cholesterol levels in mice. In this study we examined the effect of miR-33 inhibition in a mouse model of atherosclerosis and observed significant reduction in atherosclerotic plaque size. At the end of the study, gene expression in macrophages from the atherosclerotic plaques was assessed. The results demonstrated a reduction in inflammatory gene expression and increased levels of mRNAs containing miR-33 binding sites. LDLR-/- mice on a Western diet with established atherosclerosis were switched to normal chow and treated with anti-miR-33, control anti-miR, or saline (n=4/group) for 4 weeks. Gene expression profiling was performed on macrophages in aortic plaques isolated at the end of the treatment period by laser capture microdissection.

Project description:In this study the effect of anti-miR-33 treatment on plasma and liver lipid profiles was examined in non-human primates. A significant increase in plasma HDL-C, and a significant decrease in plasma triglyceride levels were observed. African green monkeys on a Normal chow diet were treated with anti-miR-33 or control anti-miR for 4 weeks and were then switched to a High Carb/Med. Cholesterol diet and treated with anti-miR-33 or control anti-miR for 8 more weeks (n=6/group). Gene expression profiling was performed on liver biopsies obtained at -5 weeks (baseline), 4 weeks and 12 weeks.

Project description:Deoxycholic acid (DCA) is a secondary bile acid produced by a small number of commensal species of bacteria present in the mammalian gut. Elevated DCA concentration correlates with disease states including colon cancer and cholesterol gallstones, but the associated mechanisms are not fully understood. Both primary and secondary bile acids are also capable of affecting gene expression through nuclear receptors such as FXR. To better understand the impact of a commensal-derived secondary bile acid on host metabolism we fed DCA to germ-free (GF) mice, which normally lack DCA, and compared the hepatic transcriptomes of bile acid fed GF mice to GF mice receiving a control diet, as well as to those of conventionally housed control animals. Interestingly, the feeding of DCA to GF mice, but not the feeding of cholic acid (CA) from which DCA is derived, results in an up-regulation of genes of cholesterol biosynthetic pathways. GF mice normally have elevated hepatic cholesterol compared to conventionally housed mice. Despite increase in the expression of cholesterol biosynthetic genes, the DCA fed GF mice showed a markedly decreased level of hepatic cholesterol equivalent to the hepatic cholesterol concentration of conventionally colonized animals. Total cholesterol in the serum was unaffected by DCA, but there was a decrease in the HDL lipoprotein fraction as well as an increase in the non-HDL lipoprotein fraction of the serum cholesterol. DCA, but not CA, is sufficient to modulate host lipoprotein metabolism. Taken together, these results suggests that a minor component of the gut microbiome has a significant impact on cholesterol homeostasis through secondary metabolism of bile acids and suggests a possible therapeutic intervention route through the microbial metabolic pathways. two mouse strains, three diets, one time point

Project description:Long-term high fat feeding leads to hepatic steatosis, dyslipidemia, and a pro-inflammatory state. In a previous study, we observed this dysregulated metabolic phenotype when C57BL/6 mice were fed a high fat diet (HFD) for sixteen weeks. Additionally, a five-fold increase in liver gene expression of serum amyloid A-1 (SAA-1), an acute phase response protein that associates with high density lipoprotein (HDL), was observed. Inflammation induced changes composition may alter HDL functions, including anti-oxidant, anti-inflammatory and reverse cholesterol transport properties. Diet-induced onset and progression of HDL dysfunction is poorly understood. To examine the relationship between high fat diet and HDL dysfunction, we performed a short-term diet study. Four-week high fat feeding caused an increase in total plasma cholesterol compared with mice fed normal control diet (ND). No change in plasma triglycerides or development of hepatic steatosis was observed. These mice did however show evidence for increase in acute phase reactants, with a 3.25-fold increase in SAA-1 expression in liver. Heavy water labelling was used to determine the turnover rates of proteins associated with HDL. High fat diet resulted in increased fractional catabolic rate (HFD vs ND) of several acute phase response proteins involved ininnate immunity , including – Complement C3 (7.06 ± 0.99 vs 5.20 ± 0.56 %/h, p < 0.005), complement factor B (6.17 ± 0.59 vs 5.09 ± 0.87 %/h, p < 0.05), complement Factor H (4.16 ± 0.41 vs 3.56 ± 0.36 %/h, p < 0.05), and Complement factor I (3.50 ± 0.26 vs 2.75 ± 0.14 %/h, p < 0.005). Our findings suggest that early immune response-induced inflammatory remodeling of HDL precedes the diet-induced steatosis and dyslipidemia. Early HDL dysfunction reflected on impaired reverse cholesterol transport likely results in increase in plasma cholesterol in the absence of other lipid abnormalities.

Project description:In this study the effect of anti-miR-33 treatment on plasma and liver lipid profiles was examined in non-human primates. A significant increase in plasma HDL-C, and a significant decrease in plasma triglyceride levels were observed.

Project description:Background: High density lipoprotein (HDL) protects the artery wall by removing cholesterol from lipid-laden macrophages. However, recent evidence suggests that it might also inhibit atherogenesis by combating inflammation. Methods and Results: To identify potential anti-inflammatory mechanisms, we challenged macrophages with lipopolysaccharide (LPS), an inflammatory microbial ligand for Toll-like receptor 4 (TLR4). HDL inhibited the expression of 33% (301 of 911) of the genes normally induced by LPS, microarray analysis revealed. One of its major targets was the type I interferon response pathway, a family of potent viral immunoregulators controlled by TLR4 and the TRAM/TRIF signaling pathway. Unexpectedly, HDL’s ability to inhibit gene expression was independent of cellular cholesterol stores. Moreover, it was unaffected by downregulation of two ATP-binding cassette transporters, ABCA1 and ABCG1, that promote cholesterol efflux. To examine the pathway’s potential in vivo relevance, we used mice deficient in apolipoprotein (apo) A-I, HDL’s major protein. After infection with Salmonella (a Gram-negative bacterium that expresses LPS), apoA-I–deficient mice had 6-fold higher plasma levels of interferon-beta-a key regulator of the type I interferon response than did wild-type mice. Conclusions: HDL inhibits a subset of LPS-stimulated macrophage genes that regulate the type I interferon response, and its action is independent of sterol metabolism. These findings raise the possibility that regulation of macrophage genes by HDL might link innate immunity and cardioprotection. 12 arrays, 3 experimental groups, mMncN (no treatment), mMncL (LPS treated, exposed for 4 h to serum-free medium or serum-free medium supplemented with 100 ng/mL of LPS), and mMwtL (HDL treated, Macrophages were treated for 4 h with serum-free medium or serum-free medium supplemented with 50 mg/mL of HDL, washed twice with PBS).

Project description:Dyslipidemia and inflammation play key roles in the pathogenesis of both nonalcoholic fatty liver disease (NAFLD) and atherosclerosis. NAFLD, particularly its severe form nonalcoholic steatohepatitis (NASH) is associated with increased cardiovascular disease (CVD) risk. HDL (high density lipoprotein- also a CVD risk) are decreased in NAFLD but whether HDL function is abnormal in NAFLD is unknown. Furthermore, it is unknown whether dyslipidemia contributes to reduced HDL function in NAFLD and whether hepatic inflammation further impairs HDL function in patients with NASH. Therefore, the aim of this study was to investigate HDL function and to examine the effect of dyslipidemia and inflammation on HDL metabolism in patients with biopsy-proven simple steatosis (SS) and NASH. RESULTS: Compared to controls, SS and NASH subjects had significantly higher levels of plasma triglyceride, insulin, and were more insulin resistant (HOMA, P<0.05) with no differences in total cholesterol, HDL cholesterol, ApoB100 and ApoAI levels. NAFLD patients had increased production and degradation rates of both HDLc and ApoAI that resulted in their levels remaining stable. The degradation rates also were increased of other HDL proteins, including ApoAII, ApoAIV, vitamin D-binding protein, and complement 3 (all P<0.05). NAFLD patients had increased activities of LCAT and CETP, indicating altered HDL lipidation. NAFLD induced alterations in HDL metabolism were associated with reduced anti-oxidant but increased pro-inflammatory activity of HDL. However, no differences were observed in either HDL function or the kinetics of HDLc and HDL proteins between SS and NASH subjects.