Center of Experimental Orthopaedics, Saarland University Medical Center, Homburg, Germany.
Departments of Anesthesia and Surgery, Boston Children's Hospital, Harvard Medical School, Boston, Massachusetts, USA.
Am J Sports Med. 2021 Nov;49(13):3696-3707. doi: 10.1177/03635465211049414. Epub 2021 Oct 13.
Gene transfer of the transcription factor SOX9 with clinically adapted recombinant adeno-associated virus (rAAV) vectors offers a powerful tool to durably enhance the repair process at sites of osteochondral injuries and counteract the development of perifocal osteoarthritis (OA) in the adjacent articular cartilage.
To examine the ability of an rAAV construct to improve the repair of focal osteochondral defects and oppose perifocal OA development over time in a large translational model relative to control gene transfer.
Controlled laboratory study.
Standardized osteochondral defects created in the knee joints of adult sheep were treated with rAAV-FLAG-h relative to control (reporter) rAAV- gene transfer. Osteochondral repair and degenerative changes in the adjacent cartilage were monitored using macroscopic, histological, immunohistological, and biochemical evaluations after 6 months. The microarchitecture of the subchondral bone was assessed by micro-computed tomography.
Effective, prolonged overexpression via rAAV was significantly achieved in the defects after 6 months versus rAAV- treatment. The application of rAAV-FLAG-h improved the individual parameters of defect filling, matrix staining, cellular morphology, defect architecture, surface architecture, subchondral bone, and tidemark as well as the overall score of cartilage repair in the defects compared with rAAV-. The overexpression of led to higher levels of proteoglycan production, stronger type II collagen deposition, and reduced type I collagen immunoreactivity in the - versus -treated defects, together with decreased cell densities and DNA content. rAAV-FLAG-h enhanced semiquantitative histological subchondral bone repair, while the microstructure of the incompletely restored subchondral bone in the defects was not different from that in the defects. The articular cartilage adjacent to the -treated defects showed reduced histological signs of perifocal OA changes versus rAAV-.
rAAV-mediated gene transfer enhanced osteochondral repair in sheep after 6 months and reduced perifocal OA changes. These results underline the potential of rAAV-FLAG-h as a therapeutic tool to treat cartilage defects and afford protection against OA.
The delivery of therapeutic rAAV to sites of focal injuries may offer a novel, convenient tool to enhance the repair of osteochondral defects involving both the articular cartilage and the underlying subchondral bone and provide a protective role by reducing the extent of perifocal OA.
利用经过临床改良的重组腺相关病毒(rAAV)载体转导转录因子 SOX9,可以持久增强骨软骨损伤部位的修复过程,并抑制相邻关节软骨中骨关节炎(OA)的发展。
在大型转化模型中,与对照基因转移相比,检查 rAAV 构建体改善局灶性骨软骨缺损修复和随时间推移抑制周围 OA 发展的能力。
对照(报告)rAAV-基因转导的成人羊膝关节中建立标准化的骨软骨缺损,然后用 rAAV-FLAG-h 处理。在 6 个月后,通过大体观察、组织学、免疫组织化学和生化评估监测骨软骨修复和相邻软骨的退行性变化。通过微计算机断层扫描评估软骨下骨的微观结构。
与 rAAV-治疗相比,6 个月后 rAAV-FLAG-h 显著实现了有效的、持续的过表达。rAAV-FLAG-h 的应用改善了与 rAAV-相比,缺损内缺陷填充、基质染色、细胞形态、缺陷结构、表面结构、软骨下骨和潮线以及软骨修复整体评分的各个参数。rAAV-FLAG-h 导致的 SOX9 过表达导致在 rAAV-处理的缺陷中产生更高水平的蛋白聚糖、更强的 II 型胶原沉积和降低的 I 型胶原免疫反应,同时降低细胞密度和 DNA 含量。rAAV-FLAG-h 增强了半定量组织学软骨下骨修复,而在 rAAV-处理的缺陷中,不完全恢复的软骨下骨的微观结构与 rAAV-处理的缺陷无差异。与 rAAV-处理的缺陷相比,rAAV-FLAG-h 处理的缺陷相邻的关节软骨显示出减少的周围 OA 变化的组织学迹象。
rAAV 介导的 SOX9 基因转移增强了绵羊 6 个月后的骨软骨修复,并减少了周围 OA 变化。这些结果强调了 rAAV-FLAG-h 作为治疗软骨缺陷的治疗工具的潜力,并通过减少周围 OA 的程度提供了保护作用。
将治疗性 rAAV 递送至局灶性损伤部位可能提供一种新颖、方便的工具,以增强涉及关节软骨和下面的软骨下骨的骨软骨缺损的修复,并通过减少周围 OA 的程度提供保护作用。
