骨关节疾病的基因治疗方法。腺相关病毒载体在关节软骨疾病、假体周围骨溶解和骨愈合实验模型中的评价

Acta orthopaedica. Supplementum Pub Date : 2007-04-01
Michael Ulrich-Vinther
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引用次数: 0

摘要

背景:基因治疗是一种通过将新基因导入细胞,以恢复或增加基因表达来治疗疾病的技术。许多生长因子和其他蛋白质具有促进运动系统中组织再生的能力,但它们的临床应用往往受到递送问题的阻碍。原则上,这些问题可以通过传递相关基因来克服,因为治疗物质可以在疾病部位的局部细胞直接持续地产生。关节软骨的愈合:关节软骨细胞接受各种基因传递方法的转导。经过基因改造后,它们能够在生物学相关水平上持续表达转基因产物。我们的研究已经证明,AAV载体是一种有效的工具,基因传递到关节软骨细胞在体外和体内。为此,我们证明了AAV载体介导的tgfbeta1过表达刺激软骨合成代谢。磨损碎片诱导的骨溶解:RANKL系统可能是治疗无菌性假体周围松动的关键治疗靶点。我们研究了使用AAV载体进行OPG基因转移是否对骨科磨损碎片引起的骨质流失具有保护作用。在破骨细胞生成和骨吸收实验中,转基因OPG的生物活性被证明是通过破坏破骨细胞生成和减少骨吸收来证明的。使用碎片诱导骨吸收的体内模型,我们证明了在接受AAV-OPG基因治疗的动物中完全抑制骨溶解。骨折愈合与骨质疏松症的关系:未来OPG治疗骨质疏松症的成功高度依赖于其对骨折愈合和重建的影响。使用体内骨折愈合模型,我们的研究表明,与大剂量静脉注射OPG治疗相比,AAV-OPG基因治疗与正常骨愈合不冲突。然而,AAV-OPG治疗抑制了骨折线上真实皮质骨的重塑和整合。结构异体骨愈合:结构异体骨由于缺乏成骨和重塑的潜力而经常发生骨折。为了克服这些局限性,我们利用包被AAV-caALK2载体的同种异体移植物介导体内基因转移。我们发现AAV载体能够在骨折愈伤组织中传导邻近的炎症细胞和成骨细胞,并且通过AAV- caalk2包被传递的BMP信号直接在同种异体移植物的皮质表面诱导骨形成。结论:本研究可能被视为复杂骨科疾病基因治疗选择发展的第一步。因此,我们的研究代表了rAAV载体在体外促进有效的基因转移到与骨科相关的细胞光谱的原理证明,并且在手术时单次给药rAAV载体靶向体内体细胞组织可能足以长期表达治疗性蛋白。未来通过rAAV载体成功传递转基因的关键是对载体或基因产物没有免疫反应。此外,开发具有调控基因表达的rAAV载体还需要在未来的研究中进一步关注。
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Gene therapy methods in bone and joint disorders. Evaluation of the adeno-associated virus vector in experimental models of articular cartilage disorders, periprosthetic osteolysis and bone healing.

Background: Gene therapy is a technique that draws on the introduction of new genes into cells for the purpose of treating disease by restoring or adding gene expression. Numerous growth factors and other proteins with the ability to promote the regeneration of tissues in the locomotive system have been identified, but their clinical use is often hindered by delivery problems. In principle, these problems can be overcome by delivering the relevant genes, as the therapeutic substances thereby can be persistently produced directly by local cells at the site of diseases.

Healing of articular cartilage: Articular chondrocytes are receptive to transduction using various gene delivery methods. Following genetic modification, they are capable of sustained expression of transgene products at biologically relevant levels. Our research has proved the AAV vector to be an effective tool for gene delivery to articular chondrocytes in vitro as well as in vivo. To this end, we have demonstrated that the AAV vector mediated TGFbeta1-overexpression stimulates cartilage anabolism. WEAR DEBRIS-INDUCED OSTEOLYSIS: The RANKL system may be a key therapeutic target in treatment of aseptic periprosthetic loosening. We investigated whether gene transfer of OPG using an AAV vector has protective effects against orthopaedic wear debris-induced bone loss. In osteoclastogenesis and in bone wafer resorption assays, the bioactivity of the transgene OPG was proven by depletion of osteoclastogenesis and reduced bone resorption. Using an in vivo model of debris-induced bone resorption, we demonstrated complete inhibition of osteolysis in animals receiving AAV-OPG gene therapy.

Fracture healing in relation to osteoporosis: The success of future OPG treatment of osteoporosis is highly dependent on its effects on fracture healing and remodelling. Using an in vivo fracture healing model, our studies demonstrated that AAV-OPG gene therapy did not conflict with normal bone healing, in contrast to high-dosage intravenous treatment with OPG. However, AAV-OPG therapy depressed remodelling and integration of the genuine cortical bone at the fracture line.

Structural bone allograft healing: Structural bone allografts often fracture due to their lack of osteogenic and remodelling potiential. To overcome these limitations, we utilized allografts coated with AAV-caALK2 vector that mediated in vivo gene transfer. We showed that the AAV vector was capable of transducing adjacent inflammatory cells and osteoblasts in the fracture callus and that BMP signals delivered via AAV-caALK2 coating induced bone formation directly on the cortical surface of the allograft.

Conclusion: The presented research may be seen as initial steps towards development of gene therapeutic treatment options for complex orthopaedic diseases. As such, our studies represent proof-of-principle that the rAAV vector promotes efficient gene transfer in vitro to a spectrum of cells with orthopaedic relevance, and that in vivo targeting of somatic tissue with a single administration of a rAAV vector at the time of surgery could be sufficient for long-term expression of therapeutic proteins. Essential to the future success of transgene delivery by rAAV vectors is the absence of an immune response to either the vector or the gene product. Furthermore, development of rAAV vectors with regulatory gene expression needs further attention in future research.

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