Zavala Gabriela, Ramos María-Paz, Figueroa-Valdés Aliosha I, Cisternas Pablo, Wyneken Ursula, Hernández Macarena, Toa Pauline, Salmons Brian, Dangerfield John, Gunzburg Walter H, Khoury Maroun
Consorcio REGENERO, Chilean Consortium for Regenerative Medicine, Santiago, Chile.
Laboratory of Nano-Regenerative Medicine, Faculty of Medicine, Universidad de los Andes, Santiago, Chile.
Front Pharmacol. 2020 May 21;11:679. doi: 10.3389/fphar.2020.00679. eCollection 2020.
The clinical benefit of therapies using Mesenchymal Stem Cells (MSCs) is attributable to their pleiotropic effect over cells and tissues, mainly through their secretome. This paracrine effect is mediated by secreted growth factors and extracellular vesicles (EV) including small EV (sEV). sEV are extra-cellular, membrane encompassed vesicles of 40 to 200 nm diameter that can trigger and signal many cellular responses depending on their cargo protein and nucleic acid repertoire. sEV are purified from cell culture conditioned media using several kits and protocols available that can be tedious and time-consuming, involving sequences of ultracentrifugations and density gradient separations, making their production a major challenge under Good Manufacturing Practices (GMP) conditions. We have developed a method to efficiently enrich cell culture media with high concentrations of sEV by encapsulating cells in semipermeable cellulose beads that allows selectively the release of small particles while offering a 3D culture condition. This method is based on the pore size of the capsules, allowing the release of particles of ≤ 200 nm including sEV. As a proof-of-principle, MSCs were encapsulated and their sEV release rate (sEV-Cap) was monitored throughout the culture and compared to sEV isolated from 2D seeded cells (sEV-2D) by repetitive ultracentrifugation cycles or a commercial kit. The isolated sEV expressed CD63, CD9, and CD81 as confirmed by flow cytometry analysis. Under transmission electron microscopy (TEM), they displayed the similar rounded morphology as sEV-2D. Their corresponding diameter size was validated by nanoparticle tracking analysis (NTA). Interestingly, sEV-Cap retained the expected biological activities of MSCs, including a pro-angiogenic effect over endothelial cells, neuritic outgrowth stimulation in hippocampal neurons and immunosuppression of T cells . Here, we successfully present a novel, cost, and time-saving method to generate sEV from encapsulated MSCs. Future applications include using encapsulated cells as a retrievable delivery device that can interact with the host niche by releasing active agents , including sEV, growth factors, hormones, and small molecules, while avoiding cell clearance, and the negative side-effect of releasing undesired components including apoptotic bodies. Finally, particles produced following the encapsulation protocol display beneficial features for their use as drug-loaded delivery vehicles.
使用间充质干细胞(MSCs)的疗法的临床益处归因于它们对细胞和组织的多效性作用,主要是通过其分泌组。这种旁分泌作用由分泌的生长因子和细胞外囊泡(EV)介导,包括小细胞外囊泡(sEV)。sEV是直径为40至200nm的细胞外膜包被囊泡,可根据其携带的蛋白质和核酸成分引发并信号传导许多细胞反应。sEV是使用几种可用的试剂盒和方案从细胞培养条件培养基中纯化的,这些方法可能繁琐且耗时,涉及超速离心和密度梯度分离序列,使其在良好生产规范(GMP)条件下的生产成为一项重大挑战。我们开发了一种方法,通过将细胞封装在半透性纤维素珠中,有效地富集含有高浓度sEV的细胞培养基,该方法允许选择性地释放小颗粒,同时提供三维培养条件。该方法基于胶囊的孔径,允许释放≤200nm的颗粒,包括sEV。作为原理验证,将MSCs封装起来,并在整个培养过程中监测其sEV释放率(sEV-Cap),并与通过重复超速离心循环或商业试剂盒从二维接种细胞中分离的sEV(sEV-2D)进行比较。通过流式细胞术分析证实,分离出的sEV表达CD63、CD9和CD81。在透射电子显微镜(TEM)下,它们呈现出与sEV-2D相似的圆形形态。通过纳米颗粒跟踪分析(NTA)验证了它们相应的直径大小。有趣的是,sEV-Cap保留了MSCs预期的生物学活性,包括对内皮细胞的促血管生成作用、对海马神经元神经突生长的刺激以及对T细胞的免疫抑制作用。在此,我们成功地提出了一种从封装的MSCs中生成sEV的新颖、经济且省时的方法。未来的应用包括将封装的细胞用作可回收的递送装置,该装置可以通过释放活性剂(包括sEV、生长因子、激素和小分子)与宿主微环境相互作用,同时避免细胞清除以及释放包括凋亡小体在内的不良成分的负面影响。最后,按照封装方案产生的颗粒作为载药递送载体具有有益的特性。
