Apelin is highly expressed in the lungs, especially in the pulmonary vasculature, but the functional role of apelin under pathological conditions is still undefined. Hypoxic pulmonary hypertension is the most common cause of acute right heart failure, which may involve the remodeling of artery and regulation of autophagy. In this study, we determined whether treatment with apelin regulated the proliferation and migration of rat pulmonary arterial smooth muscle cells (SMCs) under hypoxia, and investigated the underlying mechanism and the relationship with autophagy. Our data showed that hypoxia activated autophagy significantly at 24 hrs. The addition of exogenous apelin decreased the level of autophagy and further inhibited pulmonary arterial SMC (PASMC) proliferation via activating downstream phosphatidylinositol-3-kinase (PI3K)/protein kinase B (Akt)/the mammalian target of Rapamycin (mTOR) signal pathways. The inhibition of the apelin receptor (APJ) system by siRNA abolished the inhibitory effect of apelin in PASMCs under hypoxia. This study provides the evidence that exogenous apelin treatment contributes to inhibit the proliferation and migration of PASMCs by regulating the level of autophagy.
Recent studies reported some long noncoding RNAs (lncRNAs)-mediated vascular smooth muscle cells (VSMCs) phenotypic switch, which was a common pathophysiological process of vascular diseases. However, whether human-specific expressed lncRNAs would modulate VSMCs phenotype and participate into the pathogenesis of essential hypertension remains unclear. By comparing the circulating lncRNAs expression profiles between hypertensive patients and healthy controls, we identified a lncRNA-AK098656, strongly upregulated in the plasma of hypertensive patients, and predominantly expressed in VSMCs. AK098656 promoted VSMCs synthetic phenotype evidenced by increasing VSMC proliferation and migration, elevating extracellular matrix proteins, whereas lowering contractile proteins. Furthermore, AK098656 was demonstrated to directly bind with the VSMCs-specific contractile protein, myosin heavy chain-11, and an essential component of extracellular matrix, fibronectin-1, and finally lowered these protein levels through protein degradation. AK098656 was also shown to bind with 26S proteasome non-ATPase regulatory subunit 11 and facilitated myosin heavy chain-11 to interact with this protein. In vivo, AK098656 transgenic rats showed spontaneous development of hypertension, with elevated VSMCs synthetic phenotype and narrowed resistant arteries. Transgenic rats also showed slight cardiac hypertrophy without other complications, which was similar with early pathophysiological changes of hypertension. All these data indicated AK098656 as a new human VSMC-dominant lncRNA, which could promote hypertension through accelerating contractile protein degradation, increasing VSMC synthetic phenotype, and finally narrowed resistance arteries.
ObjectiveTo assess the global changes in and characteristics of the transcriptome of long noncoding RNAs (LncRNAs) in heart tissue, whole blood and plasma during heart failure (HF) and association with expression of paired coding genes.MethodsHere we used microarray assay to examine the transcriptome of LncRNAs deregulated in the heart, whole blood, and plasma during HF in mice. We confirmed the changes in LncRNAs by quantitative PCR.ResultsWe revealed and confirmed a number of LncRNAs that were deregulated during HF, which suggests a potential role of LncRNAs in HF. Strikingly, the patterns of expression of LncRNA differed between plasma and other tissue during HF. LncRNA expression was associated with LncRNA length in all samples but not in plasma during HF, which suggests that the global association of LncRNA expression and LncRNA length in plasma could be biomarkers for HF. In total, 32 LncRNAs all expressed in the heart, whole blood and plasma showed changed expression with HF, so they may be biomarkers in HF. In addition, sense-overlapped LncRNAs tended to show consistent expression with their paired coding genes, whereas antisense-overlapped LncRNAs tended to show the opposite expression in plasma; so different types of LncRNAs may have different characteristics in HF. Interestingly, we revealed an inverse correlation between changes in expression of LncRNAs in plasma and in heart, so circulating levels of LncRNAs may not represent just passive leakage from the HF heart but also active regulation or release of circulatory cells or other cells during HF.ConclusionsWe reveal stable expression of LncRNAs in plasma during HF, which suggests a newly described component in plasma. The distinct expression patterns of circulatory LncRNAs during HF indicate that LncRNAs may actively respond to stress and thus serve as biomarkers of HF diagnosis and treatment.
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