Ronsyn Mark W, Daans Jasmijn, Spaepen Gie, Chatterjee Shyama, Vermeulen Katrien, D'Haese Patrick, Van Tendeloo Viggo Fi, Van Marck Eric, Ysebaert Dirk, Berneman Zwi N, Jorens Philippe G, Ponsaerts Peter
Division of Clinical Pharmacology, University of Antwerp, Antwerp, Belgium.
BMC Biotechnol. 2007 Dec 14;7:90. doi: 10.1186/1472-6750-7-90.
Bone marrow-derived stromal cells (MSC) are attractive targets for ex vivo cell and gene therapy. In this context, we investigated the feasibility of a plasmid-based strategy for genetic modification of human (h)MSC with enhanced green fluorescent protein (EGFP) and neurotrophin (NT)3. Three genetically modified hMSC lines (EGFP, NT3, NT3-EGFP) were established and used to study cell survival and transgene expression following transplantation in rat spinal cord.
First, we demonstrate long-term survival of transplanted hMSC-EGFP cells in rat spinal cord under, but not without, appropriate immune suppression. Next, we examined the stability of EGFP or NT3 transgene expression following transplantation of hMSC-EGFP, hMSC-NT3 and hMSC-NT3-EGFP in rat spinal cord. While in vivo EGFP mRNA and protein expression by transplanted hMSC-EGFP cells was readily detectable at different time points post-transplantation, in vivo NT3 mRNA expression by hMSC-NT3 cells and in vivo EGFP protein expression by hMSC-NT3-EGFP cells was, respectively, undetectable or declined rapidly between day 1 and 7 post-transplantation. Further investigation revealed that the observed in vivo decline of EGFP protein expression by hMSC-NT3-EGFP cells: (i) was associated with a decrease in transgenic NT3-EGFP mRNA expression as suggested following laser capture micro-dissection analysis of hMSC-NT3-EGFP cell transplants at day 1 and day 7 post-transplantation, (ii) did not occur when hMSC-NT3-EGFP cells were transplanted subcutaneously, and (iii) was reversed upon re-establishment of hMSC-NT3-EGFP cell cultures at 2 weeks post-transplantation. Finally, because we observed a slowly progressing tumour growth following transplantation of all our hMSC cell transplants, we here demonstrate that omitting immune suppressive therapy is sufficient to prevent further tumour growth and to eradicate malignant xenogeneic cell transplants.
In this study, we demonstrate that genetically modified hMSC lines can survive in healthy rat spinal cord over at least 3 weeks by using adequate immune suppression and can serve as vehicles for transgene expression. However, before genetically modified hMSC can potentially be used in a clinical setting to treat spinal cord injuries, more research on standardisation of hMSC culture and genetic modification needs to be done in order to prevent tumour formation and transgene silencing in vivo.
骨髓来源的基质细胞(MSC)是体外细胞和基因治疗的有吸引力的靶点。在此背景下,我们研究了一种基于质粒的策略对人(h)MSC进行增强型绿色荧光蛋白(EGFP)和神经营养因子(NT)3基因修饰的可行性。建立了三种基因修饰的hMSC系(EGFP、NT3、NT3 - EGFP),并用于研究其移植到大鼠脊髓后的细胞存活和转基因表达情况。
首先,我们证明了在适当的免疫抑制下,而不是没有免疫抑制时,移植的hMSC - EGFP细胞能在大鼠脊髓中长期存活。接下来,我们检测了hMSC - EGFP、hMSC - NT3和hMSC - NT3 - EGFP移植到大鼠脊髓后EGFP或NT3转基因表达的稳定性。虽然移植的hMSC - EGFP细胞在移植后不同时间点的体内EGFP mRNA和蛋白表达很容易检测到,但hMSC - NT3细胞的体内NT3 mRNA表达以及hMSC - NT3 - EGFP细胞的体内EGFP蛋白表达在移植后第1天到第7天分别检测不到或迅速下降。进一步研究表明,hMSC - NT3 - EGFP细胞体内EGFP蛋白表达的下降:(i)与转基因NT3 - EGFP mRNA表达的减少有关,如在移植后第1天和第7天对hMSC - NT3 - EGFP细胞移植进行激光捕获显微切割分析后所示;(ii)当hMSC - NT3 - EGFP细胞皮下移植时不会发生;(iii)在移植后2周重新建立hMSC - NT3 - EGFP细胞培养时可逆转。最后,因为我们观察到所有hMSC细胞移植后肿瘤生长缓慢,我们在此证明省略免疫抑制治疗足以防止肿瘤进一步生长并根除恶性异种细胞移植。
在本研究中,我们证明通过使用适当的免疫抑制,基因修饰的hMSC系可以在健康大鼠脊髓中存活至少3周,并可作为转基因表达的载体。然而,在基因修饰的hMSC有可能用于临床治疗脊髓损伤之前,需要对hMSC培养和基因修饰的标准化进行更多研究,以防止体内肿瘤形成和转基因沉默。
