The role of gene therapy. Fact or fiction?

Genetically modified cell spheroids for tissue engineering and regenerative medicine

Cell spheroids offer cell-to-cell interactions and show advantages in survival rate and paracrine effect to solve clinical and biomedical inquiries ranging from tissue engineering and regenerative medicine to disease pathophysiology. Therefore, cell spheroids are ideal vehicles for gene delivery. Genetically modified spheroids can enhance specific gene expression to promote tissue regeneration. Gene deliveries to cell spheroids are via viral vectors or non-viral vectors. Some new technologies like CRISPR/Cas9 also have been used in genetically modified methods to deliver exogenous gene to the host chromosome. It has been shown that genetically modified cell spheroids had the potential to differentiate into bone, cartilage, vascular, nerve, cardiomyocytes, skin, and skeletal muscle as well as organs like the liver to replace the diseased organ in the animal and pre-clinical trials. This article reviews the recent articles about genetically modified spheroid cells and explains the fabrication, applications, development timeline, limitations, and future directions of genetically modified cell spheroid.

The future: rehabilitation, gene therapy, optimization of healing

Tendon disorders can be debilitating for patients and are difficult to manage. Current management strategies offer symptomatic relief, but may not result in definitive disease resolution. Despite remodeling, the biochemical and mechanical properties of healed tendon tissue never match those of intact tendon. This article outlines the stages of tendon healing, and reviews the possible strategies for optimizing tendon healing and repair, such as cytokine therapy, gene therapy, and tissue engineering.

Combination of porous hydroxyapatite and cationic liposomes as a vector for BMP-2 gene therapy

The clinical significance of hydroxyapatite (HAP) as a bone substitute has become apparent in recent years and bone morphogenetic protein (BMP) a substance which induces bone has attracted much attention. In this study, a 1.2 cm diameter bone defects created on rabbit cranium were treated with the BMP-2 gene (cDNA plasmid) introduced with porous HAP after completion of hemostasis and the resultant bone formation was analyzed histopathologically. The amounts of bone formation was compared BMP-2 cDNA plasmids were not combined with cationic liposomes as a vector. Four groups of rabbits were compared. In the HAP group the cranial bone defect was treated with HAP containing 40 microg of liposomes and a dummy gene (PU). The BMP gene HAP group was treated with HAP soaked in liposomes and 10 microg of the BMP-2 gene. In addition, a group was treated with the gene without implanting HAP. Bone formation on the cranial defects was evaluated 3, 6 and 9 weeks after the operation, by X-ray and histopathological examinations. Three weeks after the operation there was vigorous bone formation in the cranial defect in the group which received the BMP-2 gene without HAP, and complete ossification was observed at 9 weeks. In the group which received HAP containing the BMP-2 gene, although new bone formation was evident surrounding the scaffold 3 weeks post-operation, the induced bone tissue did not fill all the pores of the scaffold even at 9 weeks post-operation. These results confirm the clinical usefulness of gene therapy for bone formation, using the BMP-2 gene combined with cationic liposomes as a vector. It is possible that the effects of administering the BMP-2 gene will be improved by specializing the microstructure of scaffold for gene therapy.

Suppression of early experimental osteoarthritis by gene transfer of interleukin-1 receptor antagonist and interleukin-10

Gene therapy offers a radically different approach to the treatment of arthritis. We demonstrated that cDNA coding for human interleukin-1 receptor-antagonist protein (IL-1Ra) and cDNA coding for human interleukin-10 (IL-10) can be delivered, by ex vivo techniques, to the synovial lining of joints, intra-articular expression of gene significantly reduced cartilage matrix degradation and cartilage breakdown. To achieve this, lapine synoviocytes were first transduced in culture by retroviral infection. The genetically modified synoviocytes were then transplanted by intra-articular injection into the knee joints of OA rabbits, assay of joint lavages confirmed that the gene expression was not lost 14 days after transfer. Knees receiving the IL-1Ra gene had significantly reduced cartilage breakdown. Delivery of the IL-10 gene was less effective, having only a moderate effect on cartilage breakdown. When both genes were injected together, there was a greater inhibition of cartilage breakdown, suggesting that simultaneous gene delivery may be necessary to treat OA by targeting the activities of multiple inflammatory effectors.

Treatment of experimental equine osteoarthritis by in vivo delivery of the equine interleukin-1 receptor antagonist gene

Osteoarthritis in horses and in humans is a significant social and economic problem and continued research and improvements in therapy are needed. Because horses have naturally occurring osteoarthritis, which is similar to that of humans, the horse was chosen as a species with which to investigate gene transfer as a potential therapeutic modality for the clinical treatment of osteoarthritis. Using an established model of equine osteoarthritis that mimics clinical osteoarthritis, the therapeutic effects resulting from intra-articular overexpression of the equine interleukin-1 receptor antagonist gene through adenoviral-mediated gene transfer were investigated. In vivo delivery of the equine IL-IRa gene led to elevated intra-articular expression of interleukin-1 receptor antagonist for approximately 28 days, resulting in significant improvement in clinical parameters of pain and disease activity, preservation of articular cartilage, and beneficial effects on the histologic parameters of synovial membrane and articular cartilage. Based on these findings, gene transfer of interleukin-1 receptor antagonist is an attractive treatment modality for the equine patient and also offers future promise for human patients with osteoarthritis.

Optimisation of the biology of soft tissue repair

As identified in this review, over the past twenty years there have been a number of very exciting new developments in the quest to optimise soft tissue repair. Comparing fetal soft tissue injuries, which heal by regeneration, to the adult processes of healing by inflammation-induced scar formation has led to a number of insights into how the latter may be improved. Seeding wounds with embryonic stem cells, bridging gaps with cell-derived "engineered tissues", addition of exogenous hyaluronic acid and modification of wounds to either enhance the growth factors which have been implicated in regeneration (e.g. TGF-B3) or block those implicated in scar formation (eg. TGF-B1) have all shown promise. Our group has quantified numerous cellular, molecular, biomechanical and matrix abnormalities of scar in a rabbit model of ligament healing. Based on these studies which we review here, three matrix deficiencies have been identified which appear to have specific implications to scar weakness: organisational "flaws", abnormal hydroxypyridinoline collagen cross-link densities and abnormally small, slow-maturing collagen fibrils. In tests aimed at finding therapeutic solutions in this model, the addition of a 7ug bolus of TGF-B1 at day 21 or 2.5ng/day of TGF-B1 being pumped into a wound x 21 days increased the size of ligament scars but did not improve their material strength. It also did not alter any of the above-noted matrix deficiencies. A liposome-mediated anti-sense gene therapy approach aimed at decreasing the expression of the proteoglycan decorin in 21-day scars, however, has significantly increased the size of scar collagen fibrils as well as improved these scars mechanically. Based on these positive results from a single dose of only one targeted molecule, we believe that this gene therapy approach has great potential for further scar improvement. If combined with some of the other biological strategies reviewed above, a repair which is closer to true regenerative healing of ligaments, and all soft tissues, may eventually be achieved.