Direct in vivo gene transfer to healing rat patellar ligament by intra-arterial delivery of haemagglutinating virus of Japan liposomes.

BACKGROUND: Manipulation of ligament healing has been a major focus of orthopaedic research. In recent years, gene transfer to healing ligament appears to be a feasible method for manipulating the healing process. In this study, we investigated the feasibility of gene transfer to healing rat patellar ligament by intra-arterial delivery. METHODS: An attempt was made to transfer a reporter gene (Escherichia coli, beta-galactosidase gene) to healing rat patellar ligament using the haemagglutinating virus of Japan (HVJ) liposome-mediated gene transfer method. Three days after cutting the patellar tendons of 25 14-week-old male Wistar rats, HVJ-liposome complexes containing beta-galactosidase (beta-gal) cDNA were injected into the femoral artery of 15 Wistar rats as the experimental group. HVJ liposomes without DNA were injected into the femoral artery of 10 Wistar rats as the control group. Three rats from the experimental group and two control rats were killed 3, 7, 14, 28 and 56 days after the injection. RESULTS: After X-gal staining, the rate of transfection in the experimental group (mean +/- SEM) was found to be 12.1% +/- 0.590%, 8.7% +/- 0.217%, 10.2% +/- 0.227%, 3.2% +/- 0.247% and 0.7% +/- 0.060% at post-injection days 3, 7, 14, 28 and 56 respectively. In control sections the number of blue-stained cells were very few at any point. CONCLUSION: We succeeded in introducing a reporter gene into healing rat patellar ligament by infra-arterial delivery of HVJ-liposome complexes. This method appears to have the potential to be applicable for soft-tissue healing studies and also healing studies of other tissues and organs.

Early biological effect of in vivo gene transfer of platelet-derived growth factor (PDGF)-B into healing patellar ligament.

To define the early biological effect of in vivo introduction of the PDGF-B gene on the healing of ligaments, a HVJ-liposome suspension containing platelet-derived growth factor (PDGF)-B cDNA was injected directly into the injured patellar ligament of 14-week-old male Wistar rats. Rats were killed at 1, 4 and 8 weeks for the morphological analysis of angiogenesis by laminin immunohistochemistry and of collagen deposition by Masson's Trichrome staining and collagen I immunohistochemistry. PDGF-B gene transfer caused the enhanced expression of PDGF in healing ligament up to 4 weeks after transfection, leading to an initial promotion of angiogenesis and subsequent enhanced collagen deposition in the wound. Enhanced and accelerated matrix synthesis in the PDGF-B gene introduced healing ligament suggests that this gene transfer technique may be a potentially useful tool for improving soft tissue repair.

Transient introduction of a foreign gene into healing rat patellar ligament.

We investigated the in vivo introduction of a reporter gene into healing rat patellar ligaments using the hemagglutinating virus of Japan (HVJ)-liposome-mediated gene transfer method. The mid-portion of the medial half of the patellar ligament was cut transversely with a scalpel in 14-wk-old male Wistar rats. A HVJ-liposome suspension containing beta-galactosidase (beta-gal) cDNA was injected directly into the injured site and pooled in the fascial pocket covering the injured site 3 d postoperatively. Thereafter, beta-gal-labeled cells were observed in the wound site accounting for 3% of the wound cells on the first day, 2% on the third, 7% on the seventh, 6% on the 14th, 2% on the 28th, and 0.2% on the 56th day after injection. The beta-gal-labeled cells were initially localized in and adjacent to the wound site, but they were observed spreading into the ligament substance away from the wound on the seventh day after injection. On day 28, beta-gal-labeled cells were observed throughout the length of the ligament substance. With double-labeling for marker antigens for monocyte/macrophage (ED-1) and for collagen I aminopropeptide (pN collagen I), it was revealed that fibroblastic (pN collagen I-positive) cells accounted for 63% and monocyte/macrophage lineage cells for 32% of the beta-gal-labeled cells in the day 7 wound. On day 28, they formed 58 and 35% of the beta-gal-labeled cells in the wound, respectively. Thus, we succeeded in introducing the beta-gal gene into healing rat patellar ligament. Moreover, labeling of the transfected cells made it possible to identify a biological event, namely that the cells in and around the wound site infiltrate into the uninjured ligament substance and come to populate the whole length of the ligament substance as repair progresses. These results suggest that ligament healing may involve not only the repair of the wound site itself but also extensive cellular infiltration of ligament substance adjacent to the wound.