Gengze Wu

BACKGROUND: Long noncoding RNAs (lncRNAs) have recently been implicated in many biological processes and diseases. Atherosclerosis is a major risk factor for cardiovascular disease. However, the functional role of lncRNAs in atherosclerosis is largely unknown. METHODS AND RESULTS: We identified lincRNA-p21 as a key regulator of cell proliferation and apoptosis during atherosclerosis. The expression of lincRNA-p21 was dramatically downregulated in atherosclerotic plaques of ApoE(-/-) mice, an animal model for atherosclerosis. Through loss- and gain-of-function approaches, we showed that lincRNA-p21 represses cell proliferation and induces apoptosis in vascular smooth muscle cells and mouse mononuclear macrophage cells in vitro. Moreover, we found that inhibition of lincRNA-p21 results in neointimal hyperplasia in vivo in a carotid artery injury model. Genome-wide analysis revealed that lincRNA-p21 inhibition dysregulated many p53 targets. Furthermore, lincRNA-p21, a transcriptional target of p53, feeds back to enhance p53 transcriptional activity, at least in part, via binding to mouse double minute 2 (MDM2), an E3 ubiquitin-protein ligase. The association of lincRNA-p21 and MDM2 releases MDM2 repression of p53, enabling p53 to interact with p300 and to bind to the promoters/enhancers of its target genes. Finally, we show that lincRNA-p21 expression is decreased in patients with coronary artery disease. CONCLUSIONS: Our studies identify lincRNA-p21 as a novel regulator of cell proliferation and apoptosis and suggest that this lncRNA could serve as a therapeutic target to treat atherosclerosis and related cardiovascular disorders.

Long non-coding RNAs (lncRNAs) have been reported to be involved in the pathogenesis of cardiovascular disease (CVD), but whether circulating lncRNAs can serve as a coronary artery disease (CAD), biomarker is not known. The present study screened lncRNAs by microarray analysis in the plasma from CAD patients and control individuals and found that 265 lncRNAs were differentially expressed. To find specific lncRNAs as possible CAD biomarker candidates, we used the following criteria for 174 up-regulated lncRNAs: signal intensity ≥8, fold change >2.5 and P<0.005. According to these criteria, five intergenic lncRNAs were identified. After validation by quantitative PCR (qPCR), one lncRNA was excluded from the candidate list. The remaining four lncRNAs were independently validated in another population of 20 CAD patients and 20 control individuals. Receiver operating characteristic (ROC) curve analysis showed that lncRNA AC100865.1 (referred to as CoroMarker) was the best of these lncRNAs. CoroMarker levels were also stable in plasma. The predictive value of CoroMarker was further assessed in a larger cohort with 221 CAD patients and 187 control individuals. Using a diagnostic model with Fisher's criteria, taking the risk factors into account, the optimal sensitivity of CoroMarker for CAD increased from 68.29% to 78.05%, whereas the specificity decreased slightly from 91.89% to 86.49%. CoroMarker was stable in plasma because it was mainly in the extracellular vesicles (EVs), probably from monocytes. We conclude that CoroMarker is a stable, sensitive and specific biomarker for CAD.

Background: Heart failure (HF) is among the leading causes of morbidity and mortality, and its prevalence continues to rise. LARP7 (La ribonucleoprotein domain family member 7) is a master regulator that governs the DNA damage response and RNAPII (RNA polymerase II) pausing pathway, but its role in HF pathogenesis is incompletely understood. Methods: We assessed LARP7 expression in human HF and in nonhuman primate and mouse HF models. To study the function of LARP7 in heart, we generated global and cardiac-specific LARP7 knockout mice. We acutely abolished LARP7 in mature cardiomyocytes by Cas9-mediated LARP7 somatic knockout. We overexpressed LARP7 in cardiomyocytes using adeno-associated virus serotype 9 and ATM (ataxia telangiectasia mutated protein) inhibitor. The therapeutic potential of LARP7-regulated pathways in HF was tested in a mouse myocardial infarction model. Results: LARP7 was profoundly downregulated in failing human hearts and in nonhuman primate and murine hearts after myocardial infarction. Low LARP7 levels in failing hearts were linked to elevated reactive oxygen species, which activated the ATM-mediated DNA damage response pathway and promoted LARP7 ubiquitination and degradation. Constitutive LARP7 knockout in mouse resulted in impaired mitochondrial biogenesis, myocardial hypoplasia, and midgestational lethality. Cardiac-specific inactivation resulted in defective mitochondrial biogenesis, impaired oxidative phosphorylation, elevated oxidative stress, and HF by 4 months of age. These abnormalities were accompanied by reduced SIRT1 (silent mating type information regulation 2 homolog 1) stability and deacetylase activity that impaired SIRT1-mediated transcription of genes for oxidative phosphorylation and energy metabolism and dampened cardiac function. Restoring LARP7 expression after myocardial infarction by either adeno-associated virus–mediated LARP7 expression or small molecule ATM inhibitor substantially improved the function of injured heart. Conclusions: LARP7 is essential for mitochondrial biogenesis, energy production, and cardiac function by modulating SIRT1 homeostasis and activity. Reduction of LARP7 in diseased hearts owing to activation of the ATM pathway contributes to HF pathogenesis and restoring LARP7 in the injured heart confers myocardial protection. These results identify the ATM-LARP7-SIRT1 pathway as a target for therapeutic intervention in HF.

Circular RNAs (circRNAs) have been recently recognized as playing a role in the pathogenesis of vascular remodeling-related diseases by modulating the functions of miRNAs. However, the interplay between circRNAs and proteins during vascular remodeling remains poorly understood. Here, we investigated a previously identified circRNA, circEsyt2, whose expression is known to be upregulated during vascular remodeling. Loss- and gain-of‑function mutation analyses in vascular smooth muscle cells (VSMCs) revealed that circEsyt2 enhanced cell proliferation and migration and inhibited apoptosis and differentiation. Furthermore, the silencing of circEsyt2 in vivo reduced neointima formation, while circEsyt2 overexpression enhanced neointimal hyperplasia in the injured carotid artery, confirming its role in vascular remodeling. Using unbiased protein-RNA screening and molecular validation, circEsyt2 was found to directly interact with polyC-binding protein 1 (PCBP1), an RNA splicing factor, and regulate PCBP1 intracellular localization. Additionally, circEsyt2 silencing substantially enhanced p53β splicing via the PCBP1-U2AF65 interaction, leading to the altered expression of p53 target genes (cyclin D1, p21, PUMA, and NOXA) and the decreased proliferation of VSMCs. Thus, we identified a potentially novel circRNA that regulated vascular remodeling, via altered RNA splicing, in atherosclerotic mouse models.

Cellular senescence is associated with pleiotropic physiopathological processes, including aging and age-related diseases. The persistent DNA damage is a major stress leading to senescence, but the underlying molecular link remains elusive. Here, we identify La Ribonucleoprotein 7 (LARP7), a 7SK RNA binding protein, as an aging antagonist. DNA damage-mediated Ataxia Telangiectasia Mutated (ATM) activation triggers the extracellular shuttling and downregulation of LARP7, which dampens SIRT1 deacetylase activity, enhances p53 and NF-κB (p65) transcriptional activity by augmenting their acetylation, and thereby accelerates cellular senescence. Deletion of LARP7 leads to senescent cell accumulation and premature aging in rodent model. Furthermore, we show this ATM-LARP7-SIRT1-p53/p65 senescence axis is active in vascular senescence and atherogenesis, and preventing its activation substantially alleviates senescence and atherogenesis. Together, this study identifies LARP7 as a gatekeeper of senescence, and the altered ATM-LARP7-SIRT1-p53/p65 pathway plays an important role in DNA damage response (DDR)-mediated cellular senescence and atherosclerosis.