Li Dan, Shao Ning-Yi, Moonen Jan-Renier, Zhao Zhixin, Shi Minyi, Otsuki Shoichiro, Wang Lingli, Nguyen Tiffany, Yan Elaine, Marciano David P, Contrepois Kévin, Li Caiyun G, Wu Joseph C, Snyder Michael P, Rabinovitch Marlene
Vera Moulton Wall Center for Pulmonary Vascular Diseases (D.L., J-R.M., S.O., L.W., T.N., E.Y., M.R.), Stanford University School of Medicine, CA.
Cardiovascular Institute (D.L., N-Y.S., J-R.M., S.O., L.W., T.N., E.Y., J.C.W., M.P.S., M.R.), Stanford University School of Medicine, CA.
Circulation. 2021 May 25;143(21):2074-2090. doi: 10.1161/CIRCULATIONAHA.120.048845. Epub 2021 Mar 25.
Metabolic alterations provide substrates that influence chromatin structure to regulate gene expression that determines cell function in health and disease. Heightened proliferation of smooth muscle cells (SMC) leading to the formation of a neointima is a feature of pulmonary arterial hypertension (PAH) and systemic vascular disease. Increased glycolysis is linked to the proliferative phenotype of these SMC.
RNA sequencing was applied to pulmonary arterial SMC (PASMC) from PAH patients with and without a BMPR2 (bone morphogenetic receptor 2) mutation versus control PASMC to uncover genes required for their heightened proliferation and glycolytic metabolism. Assessment of differentially expressed genes established metabolism as a major pathway, and the most highly upregulated metabolic gene in PAH PASMC was aldehyde dehydrogenase family 1 member 3 (, an enzyme previously linked to glycolysis and proliferation in cancer cells and systemic vascular SMC. We determined if these functions are ALDH1A3-dependent in PAH PASMC, and if ALDH1A3 is required for the development of pulmonary hypertension in a transgenic mouse. Nuclear localization of ALDH1A3 in PAH PASMC led us to determine whether and how this enzyme coordinately regulates gene expression and metabolism in PAH PASMC.
mRNA and protein were increased in PAH versus control PASMC, and ALDH1A3 was required for their highly proliferative and glycolytic properties. Mice with deleted in SMC did not develop hypoxia-induced pulmonary arterial muscularization or pulmonary hypertension. Nuclear ALDH1A3 converted acetaldehyde to acetate to produce acetyl coenzyme A to acetylate H3K27, marking active enhancers. This allowed for chromatin modification at NFYA (nuclear transcription factor Y subunit α) binding sites via the acetyltransferase KAT2B (lysine acetyltransferase 2B) and permitted NFY-mediated transcription of cell cycle and metabolic genes that is required for ALDH1A3-dependent proliferation and glycolysis. Loss of BMPR2 in PAH SMC with or without a mutation upregulated ALDH1A3, and transcription of and in PAH PASMC was β-catenin dependent.
Our studies have uncovered a metabolic-transcriptional axis explaining how dividing cells use ALDH1A3 to coordinate their energy needs with the epigenetic and transcriptional regulation of genes required for SMC proliferation. They suggest that selectively disrupting the pivotal role of ALDH1A3 in PAH SMC, but not endothelial cells, is an important therapeutic consideration.
代谢改变提供影响染色质结构的底物,以调节决定健康和疾病中细胞功能的基因表达。平滑肌细胞(SMC)增殖增强导致新生内膜形成是肺动脉高压(PAH)和系统性血管疾病的一个特征。糖酵解增加与这些SMC的增殖表型相关。
对有和无骨形态发生蛋白受体2(BMPR2)突变的PAH患者的肺动脉SMC(PASMC)与对照PASMC进行RNA测序,以揭示其增殖增强和糖酵解代谢所需的基因。对差异表达基因的评估确定代谢为主要途径,PAH PASMC中上调最显著的代谢基因是醛脱氢酶家族1成员3(ALDH1A3),该酶先前与癌细胞和系统性血管SMC的糖酵解及增殖有关。我们确定这些功能在PAH PASMC中是否依赖于ALDH1A3,以及在转基因小鼠中肺动脉高压的发展是否需要ALDH1A3。PAH PASMC中ALDH1A3的核定位使我们确定该酶是否以及如何在PAH PASMC中协调调节基因表达和代谢。
与对照PASMC相比,PAH患者的PASMC中ALDH1A3的mRNA和蛋白增加,且其高度增殖和糖酵解特性需要ALDH1A3。SMC中缺失ALDH1A3的小鼠未发生低氧诱导的肺动脉肌化或肺动脉高压。核内ALDH1A3将乙醛转化为乙酸以产生乙酰辅酶A,从而使组蛋白H3第27位赖氨酸乙酰化,标记活跃的增强子。这允许通过乙酰转移酶KAT2B(赖氨酸乙酰转移酶2B)在核转录因子Y亚基α(NFYA)结合位点进行染色质修饰,并允许NFY介导细胞周期和代谢基因的转录,这是ALDH1A3依赖性增殖和糖酵解所必需的。有或无突变的PAH SMC中BMPR2的缺失上调了ALDH1A3,且PAH PASMC中ALDH1A3和NFYA的转录依赖于β-连环蛋白。
我们的研究发现了一个代谢-转录轴,解释了分裂细胞如何利用ALDH1A3协调其能量需求与SMC增殖所需基因的表观遗传和转录调控。这些研究表明,选择性破坏ALDH1A3在PAH SMC而非内皮细胞中的关键作用是一个重要的治疗考虑因素。