Explore the vast range of titles available.

Plasma high‐density lipoprotein (HDL) levels show a strong inverse correlation with atherosclerotic vascular disease. Previous studies have demonstrated that antagonism of miR‐33 in vivo increases circulating HDL and reverse cholesterol transport (RCT), thereby reducing the progression and enhancing the regression of atherosclerosis. While the efficacy of short‐term anti‐miR‐33 treatment has been previously studied, the long‐term effect of miR‐33 antagonism in vivo remains to be elucidated. Here, we show that long‐term therapeutic silencing of miR‐33 increases circulating triglyceride (TG) levels and lipid accumulation in the liver. These adverse effects were only found when mice were fed a high‐fat diet (HFD). Mechanistically, we demonstrate that chronic inhibition of miR‐33 increases the expression of genes involved in fatty acid synthesis such as acetyl‐CoA carboxylase (ACC) and fatty acid synthase (FAS) in the livers of mice treated with miR‐33 antisense oligonucleotides. We also report that anti‐miR‐33 therapy enhances the expression of nuclear transcription Y subunit gamma (NFYC), a transcriptional regulator required for DNA binding and full transcriptional activation of SREBP‐responsive genes, including ACC and FAS. Taken together, these results suggest that persistent inhibition of miR‐33 when mice are fed a high‐fat diet (HFD) might cause deleterious effects such as moderate hepatic steatosis and hypertriglyceridemia. These unexpected findings highlight the importance of assessing the effect of chronic inhibition of miR‐33 in non‐human primates before we can translate this therapy to humans. Synopsis Although short‐term anti‐miR‐33 therapy was reported to increase circulating HDL‐cholesterol and reduce atherosclerosis, long‐term adverse effects are here shown for the first time in mice fed a high‐fat diet to result in hypertriglyceridemia and moderate hepatic steatosis. The effect of long‐term inhibition of miR‐33 was determined in mice fed a chow diet and high‐fat diet. Chronic therapeutic silencing of miR‐33 increased circulating triglycerides and lipid accumulation in the livers of mice fed a high‐fat diet. miR‐33 inhibition raised the expression of genes involved in fatty acid synthesis and lipid metabolism. Further studies are warranted to understand the complex gene regulatory network controlled by miR‐33. Graphical Abstract Although short‐term anti‐miR‐33 therapy was reported to increase circulating HDL‐cholesterol and reduce atherosclerosis, long‐term adverse effects are here shown for the 1st time in mice fed a high‐fat‐diet to result in hypertriglyerimedia and moderate hepatic steatosis.

The sterol regulatory element binding protein 2 (SREBP-2) and the liver X receptor (LXR) control antagonistic transcriptional programs that stimulate cellular cholesterol uptake and synthesis, and cholesterol efflux, respectively. The clinical importance of SREBP-2 is revealed in patients with hypercholesterolemia treated with statins, which reduce low-density lipoprotein (LDL) cholesterol levels by increasing hepatic expression of SREBP-2 and its target, the LDL receptor. Here we show that miR-33 is encoded within SREBP-2 and that both mRNAs are coexpressed. We also identify sequences in the 3′ UTR of ABCA1 and ABCG1, sterol transporter genes both previously shown to be regulated by LXR, as targets for miR-33—mediated silencing. Our data show that LXR-dependent cholesterol efflux to both ApoAI and serum is ameliorated by miR-33 overexpression and, conversely, stimulated by miR-33 silencing. Finally, we show that ABCA1 mRNA and protein and plasma HDL levels decline after hepatic overexpression of miR-33, whereas they increase after hepatic miR-33 silencing. These results suggest novel ways to manage hypercholesterolemic patients.

Bile secretion is essential for whole body sterol homeostasis. Loss‐of‐function mutations in specific canalicular transporters in the hepatocyte disrupt bile flow and result in cholestasis. We show that two of these transporters, ABCB11 and ATP8B1, are functional targets of miR‐33, a micro‐RNA that is expressed from within an intron of SREBP‐2 . Consequently, manipulation of miR‐33 levels in vivo with adenovirus or with antisense oligonucleotides results in changes in bile secretion and bile recovery from the gallbladder. Using radiolabelled cholesterol, we show that systemic silencing of miR‐33 leads to increased sterols in bile and enhanced reverse cholesterol transport in vivo . Finally, we report that simvastatin causes, in a dose‐dependent manner, profound hepatotoxicity and lethality in mice fed a lithogenic diet. These latter results are reminiscent of the recurrent cholestasis found in some patients prescribed statins. Importantly, pretreatment of mice with anti‐miR‐33 oligonucleotides rescues the hepatotoxic phenotype. Therefore, we conclude that miR‐33 mediates some of the undesired, hepatotoxic effects of statins. →See accompanying article http://dx.doi.org/10.1002/emmm.201201565

Hutchinson‐Gilford Progeria Syndrome (HGPS) is a devastating premature aging disease. Mouse models have been instrumental for understanding HGPS mechanisms and for testing therapies, which to date have had only marginal benefits in mice and patients. Barriers to developing effective therapies include the unknown etiology of progeria mice early death, seemingly unrelated to the reported atherosclerosis contributing to HGPS patient mortality, and mice not recapitulating the severity of human disease. Here, we show that progeria mice die from starvation and cachexia. Switching progeria mice approaching death from regular diet to high‐fat diet (HFD) rescues early lethality and ameliorates morbidity. Critically, feeding the mice only HFD delays aging and nearly doubles lifespan, which is the greatest lifespan extension recorded in progeria mice. The extended lifespan allows for progeria mice to develop degenerative aging pathologies of a severity that emulates the human disease. We propose that starvation and cachexia greatly influence progeria phenotypes and that nutritional/nutraceutical strategies might help modulate disease progression. Importantly, progeria mice on HFD provide a more clinically relevant animal model to study mechanisms of HGPS pathology and to test therapies.

Low nephron endowment at birth is a risk factor for chronic kidney disease. The prevalence of this condition is increasing due to higher survival rates of preterm infants and children with multi- organ birth defect syndromes that affect the kidney and urinary tract. We created a mouse model of congenital low nephron number due to deletion of in nephron progenitor cells. is a core component of the Nucleosome Remodeling and Deacetylase (NuRD) chromatin remodeling complex. These mice developed albuminuria at 4 weeks of age followed by focal segmental glomerulosclerosis (FSGS) at 8 weeks, with progressive kidney injury and fibrosis. Our studies reveal that altered mitochondrial metabolism in the post-natal period leads to accumulation of neutral lipids in glomeruli at 4 weeks of age followed by reduced mitochondrial oxygen consumption. We found that NuRD cooperated with Zbtb7a/7b to regulate a large number of metabolic genes required for fatty acid oxidation and oxidative phosphorylation. Analysis of human kidney tissue also supported a role for reduced mitochondrial lipid metabolism and ZBTB7A/7B in FSGS and CKD. We propose that an inability to meet the physiological and metabolic demands of post-natal somatic growth of the kidney promotes the transition to CKD in the setting of glomerular hypertrophy due to low nephron endowment.

Abstract Increasing the availability of hepatic low-density lipoprotein receptors (LDLR) remains a major clinical target for reducing circulating plasma LDL cholesterol (LDL-C) levels. Here, we identify the molecular mechanism underlying genome-wide significant associations in the GOLIATH locus with plasma LDL-C levels. We demonstrate that GOLIATH is an E3 ubiquitin ligase that ubiquitinates the LDL Receptor resulting in redistribution away from the plasma membrane. Overexpression of GOLIATH decreases hepatic LDLR and increases plasma LDL-C levels. Silencing of Goliath using antisense oligonucleotides, germline deletion, or AAV-CRISPR in vivo strategies increases hepatic LDLR abundance and availability, thus decreasing plasma LDL-C. In vitro ubiquitination assays demonstrate RING-dependent regulation of LDLR abundance at the plasma membrane. Our studies identify GOLIATH as a novel post-translational regulator of LDL-C levels via modulation of LDLR availability, which is likely important for understanding the complex regulation of hepatic LDLR. Competing Interest Statement The authors have declared no competing interest.

Statins are the most common pharmacologic intervention in hypercholesterolemic patients, and their use is recognized as a key medical advance leading to a 50% decrease in deaths from heart attack or stroke over the past 30 years. The atheroprotective outcomes of statins are largely attributable to the accelerated hepatic clearance of low-density lipoprotein (LDL)-cholesterol from circulation, following the induction of the LDL receptor. However, multiple studies suggest that these drugs exert additional LDL–independent effects. The molecular mechanisms behind these so-called pleiotropic effects of statins, either beneficial or undesired, remain largely unknown. Here we determined the coding transcriptome, miRNome, and RISCome of livers from mice dosed with saline or atorvastatin to define a novel in vivo epitranscriptional regulatory pathway that links statins to hepatic gluconeogenesis, via the SREBP2–miR-183/96/182–TCF7L2 axis. Notably, multiple genome-wide association studies identified TCF7L2 (transcription factor 7 like 2) as a candidate gene for type 2 diabetes, independent of ethnicity. Conclusion: our data reveal an unexpected link between cholesterol and glucose metabolism, provides a mechanistic explanation to the elevated risk of diabetes recently observed in patients taking statins, and identifies the miR-183/96/182 cluster as an attractive pharmacological candidate to modulate non-canonical effects of statins.

Background and objectivesPrimary objectives: to compare the rates of sustained clinical remission at 12 months in patients treated with antitumour necrosis factor (anti-TNF) and immunomodulators who withdraw anti-TNF treatment versus those who maintain it. Secondary objectives: to evaluate the effect of anti-TNF withdrawal on relapse-free time, endoscopic and radiological activity, safety, quality of life and work productivity; and to identify predictive factors for relapse.DesignProspective, quadruple-blind, multicentre, randomised, controlled trial. Patients with ulcerative colitis or Crohn’s disease in clinical remission for >6 months and absence of severe endoscopic (and radiological in Crohn’s disease) lesions were randomised to maintain anti-TNF treatment (maintenance arm (MA)) or to withdraw it (withdrawal arm (WA)). All patients maintained immunomodulators. Patients were followed-up until month 12 or up to clinical relapse.ResultsOne-hundred forty patients were randomised: 70 were allocated to the MA and 70 to the WA. The proportion of patients with sustained clinical remission at 12 months was similar in the MA and WA: 59/70 (84%), 95% CI=74% to 92% versus 53/70 (76%), 95% CI=64% to 85%. The proportion of patients with significant endoscopic lesions at the end of follow-up was 8.5% in the MA and 19% in the WA (p=0.1); a higher proportion of patients had faecal calprotectin >250 µg/g at the end of follow-up in the WA (p=0.01). The same percentage of patients in both groups had at least one adverse event (69%). The proportion of patients with serious adverse events was also similar in both groups (4% in MA vs 7% in WA).ConclusionAnti-TNF withdrawal in selected patients with IBD in clinical, endoscopic and radiological remission has no impact on sustained clinical remission at 1 year although objective markers of activity were higher in patients who withdrew treatment.Trial registration number https://www.clinicaltrialsregister.eu/ctr-search/search?query=2015-001410-10 https://clinicaltrials.gov/study/NCT02994836