负载VEGF-A sirna - fam外泌体的抗血管生成作用。

IF 3.7 3区医学 Q2 ENGINEERING, BIOMEDICAL

Bioengineering Pub Date : 2025-08-26 DOI:10.3390/bioengineering12090919

Woojune Hur, Basanta Bhujel, Seheon Oh, Seorin Lee, Ho Seok Chung, Jin Hyoung Park, Jae Yong Kim

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引用次数: 0

摘要

新血管性眼病是由血管内皮生长因子A （VEGFA）过表达引起的。因此，VEGFA抑制被认为是治疗眼部新生血管的主要策略。然而，现有的抗vegf疗法在稳定性和递送效率方面存在一些局限性。为了克服这些局限性，基于外泌体的VEGF siRNA递送技术引起了人们的关注，因为外泌体具有体内稳定性高和细胞内递送效率优异的优点。此外，将VEGFA siRNA装载到外泌体中不仅可以靶向特定的细胞或组织，还可以提高治疗效果。我们的研究团队利用层析技术对外泌体进行纯化浓缩，将荧光素酰胺（FAM）标记的VEGFA siRNA加入外泌体中，并观察体外给药的新效果。本研究成功地将hVEGFA siRNA-FAM导入到靶细胞中，特别是在治疗后48 h具有很高的疗效。此外，在处理后48小时，证实了VEGFA表达的抑制增强。使用凋亡标志物Annexin V-FITC（绿色）和PI-PE（红色）进行FACS分析，以确认是否存在凋亡。hVEGFA siRNA-FAM-EXO(1)和hVEGFA siRNA-FAM-EXO(2)处理组与未处理组（0 h）相比，随着暴露时间的延长，细胞凋亡增加。hVEGFA siRNA-FAM-EXO处理有效诱导细胞凋亡。24 h后，hVEGFA siRNA-FAM-EXO组细胞早期凋亡率分别为12.9%和13.9%，晚期凋亡率分别为1.5%和3.7%(1)和(2)。48 h后，hVEGFA siRNA-FAM-EXO组的早期凋亡率为23.9%，晚期凋亡率为39.4%和17.8%(1)和(2)，表明细胞凋亡进程具有时间依赖性。此外，我们还诱导人血管内皮细胞（HUVECs）形成管状，以证实装载VEGFA sirna的外泌体对体外血管生成实验的影响。与对照组相比，hVEGFA siRNA-FAM- exo(1)-和hVEGFA siRNA-FAM- exo(2)处理组在处理后48 h血管生成明显减弱，72 h完全消失，可能是由于huvec细胞内细胞质和VEGFA siRNA-FAM分泌的条件培养基中的VEGFA、PIGF和VEGFC减少所致。总之，fam标记的VEGFA siRNA被打包到外泌体中，并在管形成后随着时间的推移而降解，由于VEGFA、PIGF和VEGFC水平的降低导致细胞死亡。这项研究有望在未来支持体内新生血管模型（角膜炎、结膜炎或糖尿病视网膜病变模型）的发展。

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The Antiangiogenic Effect of VEGF-A siRNA-FAM-Loaded Exosomes.

Neovascular ocular diseases are caused by vascular endothelial growth factor A (VEGFA) overexpression. Thus, VEGFA inhibition is considered the main strategy for treating ocular neovascularization. However, existing anti-VEGF therapies have several limitations in stability and delivery efficiency. To overcome the limitations, exosome-based VEGF siRNA delivery technology has attracted attention since exosomes have the advantages of high in vivo stability and excellent intracellular delivery efficiency. Additionally, loading VEGFA siRNA into exosomes not only allows for targeting specific cells or tissues but can also improve therapeutic efficacy. Our research team purified and concentrated exosomes using chromatography techniques, added fluorescein amidite (FAM)-labeled VEGFA siRNA into exosomes, and observed the novel effect of drug delivery in vitro. This study successfully introduced hVEGFA siRNA-FAM into target cells, with high efficacy particularly at 48 h after treatment. Furthermore, the enhanced inhibition of VEGFA expression at 48 h post-treatment was confirmed. FACS analysis was performed using the apoptosis markers Annexin V-FITC (green) and PI-PE (red) to confirm the presence or absence of apoptosis. Both groups treated with hVEGFA siRNA-FAM-EXO (1) and hVEGFA siRNA-FAM-EXO (2) showed increased apoptosis as the exposure time passed compared to the untreated group (0 h). hVEGFA siRNA-FAM-EXO treatment effectively induced apoptosis. After 24 h, early apoptosis was 12.9% and 13.9% and late apoptosis was 1.5% and 3.7% in hVEGFA siRNA-FAM-EXO groups (1) and (2), respectively. After 48 h, early apoptosis was 23.9% and late apoptosis was 39.4% and 17.8% in hVEGFA siRNA-FAM-EXO groups (1) and (2), respectively, indicating a time-dependent pattern of apoptosis progression. Additionally, tube formation of human vascular endothelial cells (HUVECs) was induced to confirm the effect of VEGFA siRNA-loaded exosomes on the angiogenesis assay in vitro. Compared with controls, angiogenesis became significantly weakened in hVEGFA siRNA-FAM-EXO (1)- and hVEGFA siRNA-FAM-EXO (2)-treated groups at 48 h post-treatment and completely disappeared at 72 h, probably occurring due to decreased VEGFA, PIGF, and VEGFC in the intracellular cytosol and conditioned media secreted by VEGFA siRNA-FAM in HUVECs. In conclusions, FAM-tagged VEGFA siRNA was packed into exosomes and degraded over time after tube formation, leading to cell death due to a decrease in VEGFA, PIGF, and VEGFC levels. This study is expected to support the development of in vivo neovascularization models (keratitis, conjunctivitis, or diabetic retinopathy models) in the future.

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来源期刊

Bioengineering Chemical Engineering-Bioengineering

CiteScore

4.00

自引率

8.70%

发文量

661

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