Grilo Luís F, Zimmerman Kip D, Puppala Sobha, Chan Jeannie, Huber Hillary F, Li Ge, Jadhav Avinash Y L, Wang Benlian, Li Cun, Clarke Geoffrey D, Register Thomas C, Oliveira Paulo J, Nathanielsz Peter W, Olivier Michael, Pereira Susana P, Cox Laura A
CNC-UC, Center for Neuroscience and Cell Biology, University of Coimbra, Portugal.
CIBB, Center for Innovative Biomedicine and Biotechnology, University of Coimbra, Portugal.
bioRxiv. 2023 Nov 18:2023.11.17.567640. doi: 10.1101/2023.11.17.567640.
Age is a prominent risk factor for cardiometabolic disease, and often leads to heart structural and functional changes. However, precise molecular mechanisms underlying cardiac remodeling and dysfunction resulting from physiological aging per se remain elusive. Understanding these mechanisms requires biological models with optimal translation to humans. Previous research demonstrated that baboons undergo age-related reduction in ejection fraction and increased heart sphericity, mirroring changes observed in humans. The goal of this study was to identify early cardiac molecular alterations that precede functional adaptations, shedding light on the regulation of age-associated changes. We performed unbiased transcriptomics of left ventricle (LV) samples from female baboons aged 7.5-22.1 years (human equivalent ~30-88 years). Weighted-gene correlation network and pathway enrichment analyses were performed to identify potential age-associated mechanisms in LV, with histological validation. Myocardial modules of transcripts negatively associated with age were primarily enriched for cardiac metabolism, including oxidative phosphorylation, tricarboxylic acid cycle, glycolysis, and fatty-acid β-oxidation. Transcripts positively correlated with age suggest upregulation of glucose uptake, pentose phosphate pathway, and hexosamine biosynthetic pathway (HBP), indicating a metabolic shift towards glucose-dependent anabolic pathways. Upregulation of HBP commonly results in increased glycosaminoglycan precursor synthesis. Transcripts involved in glycosaminoglycan synthesis, modification, and intermediate metabolism were also upregulated in older animals, while glycosaminoglycan degradation transcripts were downregulated with age. These alterations would promote glycosaminoglycan accumulation, which was verified histologically. Upregulation of extracellular matrix (ECM)-induced signaling pathways temporally coincided with glycosaminoglycan accumulation. We found a subsequent upregulation of cardiac hypertrophy-related pathways and an increase in cardiomyocyte width. Overall, our findings revealed a transcriptional shift in metabolism from catabolic to anabolic pathways that leads to ECM glycosaminoglycan accumulation through HBP prior to upregulation of transcripts of cardiac hypertrophy-related pathways. This study illuminates cellular mechanisms that precede development of cardiac hypertrophy, providing novel potential targets to remediate age-related cardiac diseases.
年龄是心脏代谢疾病的一个突出风险因素,常常导致心脏结构和功能的改变。然而,由生理性衰老本身导致的心脏重塑和功能障碍背后的确切分子机制仍然不清楚。理解这些机制需要能够很好地转化为人类情况的生物学模型。先前的研究表明,狒狒会出现与年龄相关的射血分数降低和心脏球形度增加,这与在人类中观察到的变化相似。本研究的目的是识别在功能适应之前的早期心脏分子改变,从而阐明与年龄相关变化的调节机制。我们对7.5 - 22.1岁雌性狒狒(相当于人类30 - 88岁)的左心室(LV)样本进行了无偏转录组学分析。进行了加权基因共表达网络和通路富集分析,以确定左心室中潜在的与年龄相关的机制,并进行了组织学验证。与年龄呈负相关的心肌转录本模块主要富集于心脏代谢,包括氧化磷酸化、三羧酸循环、糖酵解和脂肪酸β -氧化。与年龄呈正相关的转录本表明葡萄糖摄取、磷酸戊糖途径和己糖胺生物合成途径(HBP)上调,表明代谢向依赖葡萄糖的合成代谢途径转变。HBP的上调通常会导致糖胺聚糖前体合成增加。参与糖胺聚糖合成、修饰和中间代谢的转录本在老年动物中也上调,而糖胺聚糖降解转录本随年龄下调。这些改变会促进糖胺聚糖的积累,这在组织学上得到了验证。细胞外基质(ECM)诱导的信号通路上调与糖胺聚糖积累在时间上一致。我们发现随后心脏肥大相关通路上调,心肌细胞宽度增加。总体而言,我们的研究结果揭示了代谢从分解代谢途径向合成代谢途径的转录转变,这种转变通过HBP导致ECM糖胺聚糖积累,然后才出现心脏肥大相关通路转录本的上调。这项研究阐明了心脏肥大发展之前的细胞机制,为治疗与年龄相关的心脏病提供了新的潜在靶点。
