Nazari Ali Riza, Gresseau Loraine, Habelrih Tiffany, Zia Aliabbas, Lahaie Isabelle, Er-Reguyeg Yosra, Coté France, Annabi Borhane, Rivard Alain, Chemtob Sylvain, Desjarlais Michel
Department of Ophthalmology, Maisonneuve-Rosemont Hospital Research Center, University of Montréal, Montréal, QC H1T 2M4, Canada.
Department of Pediatrics, Ophthalmology and Pharmacology, Centre Hospitalier Universitaire Sainte-Justine Research Center, Montréal, QC H2X 0A9, Canada.
Biomedicines. 2024 Nov 22;12(12):2669. doi: 10.3390/biomedicines12122669.
Choroidal involution is a common feature of age-related ischemic retinopathies such as age-related macular degeneration (AMD). It is now well recognized that endothelial progenitor cells (EPCs) are essential to endothelial repair processes and in maintaining vascular integrity. However, the contribution of EPCs and the role of senescence in age-related choroidal vascular degeneration remain to be investigated. In this study, we compared the senescent phenotype of EPCs in the choroid and performed whole-genome profiling of EPCs derived from young versus old rats. We isolated and compared the retinas of young (6-weeks-old) and old (16-18-month-old) rats. The thickness of the choroid and outer nuclear layer (ONL), along with local quantification of CD34+ EPCs, was performed. Compared to young rats, older rats displayed a significant reduction in choroidal and ONL thickness associated with markedly fewer choroid-localized EPCs; this was attested by lower expression of several EPC markers (CXCR4, CD34, CD117, CD133, and KLF-2). Choroid and choroid-localized EPCs displayed abundant senescence as revealed by increased β-gal and P53 expression and decreased Lamin-B1 (immunostaining and RT-qPCR). Concordantly, choroidal cells and EPCs isolated from older rats were unable to form vascular networks ex vivo. To better understand the potential mechanisms associated with the dysfunctional EPCs linked to age-related choroidal involution, we performed whole-genome profiling (mRNA and miRNA) of EPCs derived from old and young rats using next-generation sequencing (NGS); 802 genes were significantly modulated in old vs. young EPCs, corresponding to ~2% of total genes expressed. Using a bioinformatic algorithm, the KEGG pathways suggested that these genes participate in the modulation of several key signaling processes including inflammation, G protein-coupled receptors, and hematopoietic cell lineages. Moreover, we identified 13 miRNAs involved in the regulation of immune system processes, cell cycle arrest and senescence, which are significantly modulated in EPCs from old rats compared to young ones. Our results suggest that age-related choroidal involution is associated with fewer EPCs, albeit displaying a senescence-like phenotype. One would be tempted to propose that biological modification of native EPCs (such as with senolytic agents) could potentially provide a new strategy to preserve the vascular integrity of the aged choroid, and evade progression to degenerative maculopathies.
脉络膜退化是年龄相关性缺血性视网膜病变(如年龄相关性黄斑变性,AMD)的常见特征。目前人们已经充分认识到,内皮祖细胞(EPC)对于内皮修复过程以及维持血管完整性至关重要。然而,EPC的作用以及衰老在年龄相关性脉络膜血管退化中的作用仍有待研究。在本研究中,我们比较了脉络膜中EPC的衰老表型,并对来自年轻和老年大鼠的EPC进行了全基因组分析。我们分离并比较了年轻(6周龄)和老年(16 - 18月龄)大鼠的视网膜。测量了脉络膜和外核层(ONL)的厚度,并对CD34 + EPC进行了局部定量分析。与年轻大鼠相比,老年大鼠的脉络膜和ONL厚度显著降低,脉络膜局部EPC数量明显减少;这通过几种EPC标志物(CXCR4、CD34、CD117、CD133和KLF - 2)的低表达得到证实。脉络膜和脉络膜局部EPC显示出丰富的衰老特征,表现为β - gal和P53表达增加以及Lamin - B1减少(免疫染色和RT - qPCR)。一致地,从老年大鼠分离的脉络膜细胞和EPC在体外无法形成血管网络。为了更好地理解与年龄相关性脉络膜退化相关的功能失调EPC的潜在机制,我们使用下一代测序(NGS)对来自老年和年轻大鼠的EPC进行了全基因组分析(mRNA和miRNA);在老年与年轻EPC中,802个基因受到显著调节,约占总表达基因的2%。使用生物信息学算法,KEGG通路表明这些基因参与了包括炎症、G蛋白偶联受体和造血细胞谱系在内的几个关键信号过程的调节。此外,我们鉴定出13种参与免疫系统过程、细胞周期停滞和衰老调节的miRNA,与年轻大鼠相比,老年大鼠的EPC中这些miRNA受到显著调节。我们的结果表明,年龄相关性脉络膜退化与较少的EPC相关,尽管其表现出衰老样表型。有人可能会提出,对天然EPC进行生物学修饰(如使用衰老溶解剂)可能潜在地提供一种新策略,以保持老年脉络膜的血管完整性,并避免进展为退行性黄斑病变。
