Tamer Sallam scite author profile

Summary Mitochondria are known to be functional organelles, but their role as a signaling unit is increasingly being appreciated. The identification of a short open reading frame (sORF) in the mitochondrial DNA (mtDNA) that encodes a signaling peptide, humanin, suggests the possible existence of additional sORFs in the mtDNA. Here we report a sORF within the mitochondrial 12S rRNA encoding a 16 amino acid peptide named MOTS-c (mitochondrial open-reading-frame of the twelve S rRNA -c) that regulates insulin sensitivity and metabolic homeostasis. Its primary target organ appears to be the skeletal muscle and its cellular actions inhibit the folate cycle and its tethered de novo purine biosynthesis, leading to AMPK activation. MOTS-c treatment in mice prevented age-dependent and high-fat diet-induced insulin resistance, as well as diet-induced obesity. These results suggest that mitochondria may actively regulate metabolic homeostasis at the cellular and organismal level via peptides encoded within their genome.

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Genetic Architecture of Insulin Resistance in the Mouse

Parks

et al. 2015

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SUMMARY Insulin Resistance (IR) is a complex trait with multiple genetic and environmental components. Confounded by large differences between the sexes, environment and disease pathology, the genetic basis of IR has been difficult to dissect. Here we examine IR and related traits in a diverse population of more than 100 unique male and female inbred mouse strains after feeding a diet rich in fat and refined carbohydrates. Our results show dramatic variation in IR among strains of mice and widespread differences between sexes that is dependent on genotype. We uncover more than 15 genome-wide significant loci and validate a gene, Agpat5, associated with IR. We also integrate plasma metabolite levels and global gene expression from liver and adipose tissue to identify metabolite Quantitative Trait Loci (mQTL) and expression QTL (eQTL), respectively. Our results provide a resource for analysis of interactions between diet, sex and genetic background in IR.

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Feedback modulation of cholesterol metabolism by the lipid-responsive non-coding RNA LeXis

Sallam

Jones

Gilliland

et al. 2016

Nature

182

187

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The liver X receptors (LXRs) are transcriptional regulators of cellular and systemic cholesterol homeostasis. In the setting of cholesterol excess, LXR activation induces the expression of a battery of genes involved in cholesterol efflux 1, facilities cholesterol esterification by promoting fatty acid synthesis 2, and inhibits cholesterol uptake by the low-density lipoprotein receptor (LDLR)3. The fact that sterol content is maintained in a narrow range in most cell types and in the organism as a whole suggests that extensive crosstalk between regulatory pathways must exist. However, the molecular mechanisms that integrate LXRs with other lipid metabolic pathways, are incompletely understood. Here we show that ligand activation of LXRs in liver not only promotes cholesterol efflux, but also simultaneously inhibits cholesterol biosynthesis. We further identify the long non-coding RNA LeXis as one mediator of this effect. Hepatic LeXis expression is robustly induced in response to western diet feeding or pharmacologic LXR activation. Raising or lowering the levels of LeXis in liver affects the expression of cholesterol biosynthetic genes, and the levels of cholesterol in the liver and plasma. LeXis interacts with and affects the DNA interactions of Raly, a heterogeneous ribonucleoprotein that is required for the maximal expression of cholesterologenic genes in mouse liver. These studies outline a regulatory role for a non-coding RNA in lipid metabolism and advance our understanding of the mechanisms orchestrating sterol homeostasis.

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Long Noncoding RNA Discovery in Cardiovascular Disease

Sallam

Sandhu

Tontonoz

2018

Circulation Research

227

157

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Despite significant improvements during the past 3 decades, cardiovascular disease remains a leading worldwide health epidemic. The recent identification of a fascinating group of mediators known as long noncoding RNAs (lncRNAs) has provided a wealth of new biology to explore for cardiovascular risk mitigation. lncRNAs are expressed in a highly context-specific fashion, and multiple lines of evidence implicated them in diverse biological processes. Indeed, abnormalities of lncRNAs have been directly linked with human ailments, including cardiovascular biology and disease. Of particular interest to the cardiovascular research community, dysregulation in lncRNA regulatory circuits have been associated with cardiac pathological hypertrophy, vascular disease, cell fate programming and development, atherosclerosis, dyslipidemia, and metabolic syndrome. Although techniques in interrogating noncoding RNAs are rapidly evolving, a major challenge in studying lncRNAs remains navigating through multiple technical constraints. In this review, we provide a road map for lncRNA discovery and interrogation in biological systems relevant to cardiovascular disease and highlight approaches to decipher their modes of action.

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Tamer Sallam

The Mitochondrial-Derived Peptide MOTS-c Promotes Metabolic Homeostasis and Reduces Obesity and Insulin Resistance

Genetic Architecture of Insulin Resistance in the Mouse

Feedback modulation of cholesterol metabolism by the lipid-responsive non-coding RNA LeXis

Long Noncoding RNA Discovery in Cardiovascular Disease

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