Division of Cardiology, Emory University School of Medicine, Atlanta, GA 30322, USA.
Biomaterials. 2013 Jun;34(17):4235-41. doi: 10.1016/j.biomaterials.2013.02.005. Epub 2013 Mar 9.
Since the successful generation of induced pluripotent stem cells (iPSC) from adult somatic cells using integrating-viral methods, various methods have been tried for iPSC generation using non-viral and non-integrating technique for clinical applications. Recently, various non-viral approaches such as protein, mRNA, microRNA, and small molecule transduction were developed to avoid genomic integration and generate stem cell-like cells from mouse and human fibroblasts. Despite these successes, there has been no successful generation of iPSC from bone marrow (BM)-derived hematopoietic cells derived using non-viral methods to date. Previous reports demonstrate the ability of polymeric micro and nanoparticles made from polyketals to deliver various molecules to macrophages. MicroRNA-loaded nanoparticles were created using the polyketal polymer PK3 (PK3-miR) and delivered to somatic cells for 6 days, resulting in the formation of colonies. Isolated cells from these colonies were assayed and substantial induction of the pluripotency markers Oct4, Sox2, and Nanog were detected. Moreover, colonies transferred to feeder layers also stained positive for pluripotency markers including SSEA-1. Here, we demonstrate successful activation of pluripotency-associated genes in mouse BM-mononuclear cells using embryonic stem cell (ESC)-specific microRNAs encapsulated in the acid sensitive polyketal PK3. These reprogramming results demonstrate that a polyketal-microRNA delivery vehicle can be used to generate various reprogrammed cells without permanent genetic manipulation in an efficient manner.
自利用整合病毒方法从成体细胞成功生成诱导多能干细胞(iPSC)以来,已经尝试了各种使用非病毒和非整合技术的方法来进行 iPSC 的生成,以用于临床应用。最近,已经开发了各种非病毒方法,如蛋白质、mRNA、microRNA 和小分子转导,以避免基因组整合,并从小鼠和人成纤维细胞中生成类干细胞细胞。尽管取得了这些成功,但迄今为止,尚未成功地从骨髓(BM)来源的造血细胞中使用非病毒方法生成 iPSC。以前的报告证明了由聚酮制成的微纳米聚合物能够将各种分子递送至巨噬细胞。使用聚酮聚合物 PK3(PK3-miR)创建了负载 microRNA 的纳米颗粒,并将其递送至体细胞 6 天,导致集落的形成。从这些集落中分离的细胞进行了检测,并且检测到多能性标记物 Oct4、Sox2 和 Nanog 的大量诱导。此外,转移到饲养层的集落也对包括 SSEA-1 在内的多能性标记物呈阳性染色。在这里,我们证明了使用封装在酸敏感聚酮 PK3 中的胚胎干细胞(ESC)特异性 microRNA 成功激活了小鼠 BM-单核细胞中的多能性相关基因。这些重编程结果表明,聚酮-microRNA 递送载体可以有效地用于生成各种重编程细胞,而无需进行永久性遗传操作。