Ulrich-Vinther Michael, Carmody Emily E, Goater J Jeffrey, S balle Kjeld, O'Keefe Regis J, Schwarz Edward M
Department of Orthopedics, Center for Musculoskeletal Research, University of Rochester Medical Center, Rochester, NY 14642, USA.
J Bone Joint Surg Am. 2002 Aug;84(8):1405-12. doi: 10.2106/00004623-200208000-00016.
Aseptic loosening of orthopaedic implants secondary to wear debris-induced osteolysis is a serious problem. Osteoprotegerin (OPG) is a natural decoy protein that inhibits osteoclast activation and bone resorption. This study investigated whether gene therapy using a recombinant adeno-associated viral vector that expresses OPG can inhibit wear debris-induced osteolysis.
A recombinant adeno-associated virus (rAAV) vector co-expressing OPG (rAAV-OPG-IRES-EGFP) was generated. A control vector expressing b-galactosidase (rAAV-LacZ) was also prepared. In vitro validation experiments were performed to determine rAAV-OPG-IRES-EGFP transduction efficiency, OPG expression level and function in bone wafer, and osteoclastic activity. The effect of rAAV-OPG-IRES-EGFP in vivo gene therapy on wear debris-induced osteolysis was then evaluated in a mouse calvarial model in which a single intramuscular injection of the vector was administered prior to the introduction of the wear debris. The effects of the rAAV-OPG-IRES-EGFP gene therapy on wear debris-induced osteoclastogenesis and bone resorption were determined by histomorphometry on day 10.
In vitro experiments revealed that 100% of human embryonic kidney 293 cells were transduced at a multiplicity of infection of 1000 with both rAAV-OPG-IRES-EGFP and rAAV-LacZ. At a rAAV-OPG-IRES-EGFP multiplicity of infection of 1000, an OPG concentration of 135 ng/mL of culture media was achieved after four days. Using a bone-wafer assay for osteoclast activity, we found that treatment with rAAV-OPG-IRES-EGFP reduced resorption sevenfold compared with parathyroid hormone-stimulated controls and elevenfold compared with rAAV-LacZ controls. Furthermore, a seventeenfold decrease in RANKL and macrophage colony-stimulating factor-induced splenocyte osteoclastogenesis was observed in co-cultures containing rAAV-OPG-IRES-EGFP-infected fibroblasts. In vivo administration of rAAV-OPG-IRES-EGFP resulted in detectable transduction of myocytes at the injection site and a significant increase in expression of serum OPG levels by the second day (p < 0.05). Maximal concentrations were obtained on day 6 and then leveled off throughout the observation period. In contrast, serum OPG could not be detected in the sham-treated, uninfected titanium-stimulated, or rAAV-LacZ-infected mice. In the control mice, titanium implantation resulted in a threefold increase in the mean number of osteoclasts adjacent to the sagittal suture as well as a twofold increase in the mean area of soft tissue in the sagittal suture compared with the sham-treated mice. In contrast, osteoclast numbers remained at basal levels, and the area of soft tissue in the sagittal suture was markedly reduced in titanium-implanted animals that received rAAV-OPG-IRES-EGFP treatment, demonstrating a complete inhibition of osteolysis in response to titanium particles.
A single intramuscular injection of the rAAV-OPG-IRES-EGFP vector can efficiently transduce myocytes to produce high levels of OPG. The OPG effectively inhibits wear debris-induced osteoclastogenesis and osteolysis.
Currently, there is no approved drug therapy to prevent or inhibit periprosthetic osteolysis. Although preclinical studies have identified potential drug therapies (i.e., bisphosphonates), there is no evidence that these drugs can effectively treat aseptic loosening in patients. This is the first evidence that in vivo OPG gene therapy can be used to prevent wear debris-induced osteolysis.
磨损颗粒诱导骨溶解继发的骨科植入物无菌性松动是一个严重问题。骨保护素(OPG)是一种天然的诱饵蛋白,可抑制破骨细胞活化和骨吸收。本研究调查了使用表达OPG的重组腺相关病毒载体进行基因治疗是否能抑制磨损颗粒诱导的骨溶解。
构建了共表达OPG的重组腺相关病毒(rAAV)载体(rAAV-OPG-IRES-EGFP)。还制备了表达β-半乳糖苷酶的对照载体(rAAV-LacZ)。进行体外验证实验,以确定rAAV-OPG-IRES-EGFP的转导效率、OPG在骨片上的表达水平和功能以及破骨细胞活性。然后在小鼠颅骨模型中评估rAAV-OPG-IRES-EGFP体内基因治疗对磨损颗粒诱导的骨溶解的影响,在引入磨损颗粒之前单次肌肉注射该载体。在第10天通过组织形态计量学确定rAAV-OPG-IRES-EGFP基因治疗对磨损颗粒诱导的破骨细胞生成和骨吸收的影响。
体外实验显示,在感染复数为1000时,rAAV-OPG-IRES-EGFP和rAAV-LacZ对100%的人胚肾293细胞进行了转导。在感染复数为rAAV-OPG-IRES-EGFP 1000时,四天后培养基中OPG浓度达到135 ng/mL。使用骨片检测破骨细胞活性,我们发现与甲状旁腺激素刺激的对照相比,rAAV-OPG-IRES-EGFP处理使吸收减少了7倍,与rAAV-LacZ对照相比减少了11倍。此外,在含有rAAV-OPG-IRES-EGFP感染的成纤维细胞的共培养物中,观察到RANKL和巨噬细胞集落刺激因子诱导的脾细胞破骨细胞生成减少了17倍。体内给予rAAV-OPG-IRES-EGFP导致注射部位的肌细胞可检测到转导,到第二天血清OPG水平的表达显著增加(p<0.05)。在第6天获得最大浓度,然后在整个观察期内趋于平稳。相比之下,在假手术处理、未感染钛刺激或rAAV-LacZ感染的小鼠中未检测到血清OPG。在对照小鼠中,与假手术处理的小鼠相比,钛植入导致矢状缝附近破骨细胞平均数量增加了3倍,矢状缝软组织平均面积增加了2倍。相比之下,在接受rAAV-OPG-IRES-EGFP治疗的钛植入动物中,破骨细胞数量保持在基础水平,矢状缝软组织面积明显减少,表明对钛颗粒引起的骨溶解有完全抑制作用。
单次肌肉注射rAAV-OPG-IRES-EGFP载体可有效转导肌细胞以产生高水平的OPG。OPG有效抑制磨损颗粒诱导的破骨细胞生成和骨溶解。
目前,尚无批准的药物疗法来预防或抑制假体周围骨溶解。尽管临床前研究已确定了潜在的药物疗法(即双膦酸盐),但没有证据表明这些药物能有效治疗患者的无菌性松动。这是体内OPG基因治疗可用于预防磨损颗粒诱导的骨溶解的首个证据。
