Janey D. Whalen

Genetic enhancement of fracture repair: Healing of an experimental segmental defect by adenoviral transfer of the BMP-2 gene

This study evaluated the ability of gene transfer to enhance bone healing. Segmental defects were created surgically in the femora of New Zealand white rabbits. First generation adenoviruses were used as vectors to introduce into the defects genes encoding either human bone morphogenetic protein-2 (BMP-2) or, as a negative control, firefly luciferase. Representative specimens were evaluated histologically after 8 weeks. Healing of the defects was monitored radiographically for 12 weeks, after which time the repair tissue was evaluated biomechanically. By radiological criteria, animals receiving the BMP-2 gene had healed their osseous lesions after 7 weeks, whereas those receiving the luciferase gene had not. Histologic examination of representative rabbits at 8 weeks confirmed ossification across the entire defect in response to the BMP-2 gene, whereas the control defect was predominantly fibrotic and sparsely ossified. At the end of the 12-week experiment, the control femora still showed no radiological signs of stable healing. The difference in radiologically defined healing between the experimental and control groups was statistically significant (P < 0.002). biomechanical testing of the femora at 12 weeks demonstrated statistically significant increases in the mean bending strength (p < 0.005) and bending stiffness (p < 0.05) of the animals treated with the bmp-2 gene. direct, local adenoviral delivery of an osteogenic gene thus led to the healing of an osseous lesion that otherwise would not do so. these promising data encourage the further development of genetic approaches to enhancing bone healing.

Ex Vivo Gene Therapy to Produce Bone Using Different Cell Types

Gene therapy and tissue engineering promise to revolutionize orthopaedic surgery. This study comprehensively compares five different cell types in ex vivo gene therapy to produce bone. The cell types include a bone marrow stromal cell line, primary muscle derived cells, primary bone marrow stromal cells, primary articular chondrocytes, and primary fibroblasts. After transduction by an adenovirus encoding for bone morphogenetic protein-2, all of the cell types were capable of secreting bone morphogenetic protein-2. However, the bone marrow stromal cell line and muscle derived cells showed more responsiveness to recombinant human bone morphogenetic protein-2 than did the other cell types. In vivo injection of each of the cell populations transduced to secrete bone morphogenetic protein-2 resulted in bone formation. Radiographic and histologic analyses corroborated the in vitro data regarding bone morphogenetic protein-2 secretion and cellular osteocompetence. This study showed the feasibility of using primary bone marrow stromal cells, primary muscle derived cells, primary articular chondrocytes, primary fibroblasts, and an osteogenesis imperfecta stromal cell line in ex vivo gene therapy to produce bone. The study also showed the advantages and disadvantages inherent in using each cell type.

Human skeletal muscle cells in ex vivo gene therapy to deliver bone morphogenetic protein-2

We have examined whether primary human muscle-derived cells can be used in ex vivo gene therapy to deliver BMP-2 and to produce bone in vivo. Two in vitro experiments and one in vivo experiment were used to determine the osteocompetence and BMP-2 secretion capacity of cells isolated from human skeletal muscle. We isolated five different populations of primary muscle cells from human skeletal muscle in three patients. In the first in vitro experiment, production of alkaline phosphatase by the cells in response to stimulation by rhBMP-2 was measured and used as an indicator of cellular osteocompetence. In the second, secretion of BMP-2 was measured after the cell populations had been transduced by an adenovirus encoding for BMP-2. In the in vivo experiment, the cells were cotransduced with a retrovirus encoding for a nuclear localised beta-galactosidase gene and an adenovirus encoding for BMP-2. The cotransduced cells were then injected into the hind limbs of severe combined immune-deficient (SCID) mice and analysed radiographically and histologically. The nuclear localised beta-galactosidase gene allowed identification of the injected cells in histological specimens. In the first in vitro experiment, the five different cell populations all responded to in vitro stimulation of rhBMP-2 by producing higher levels of alkaline phosphatase when compared with non-stimulated cells. In the second, the five different cell populations were all successfully transduced by an adenovirus to express and secrete BMP-2. The cells secreted between 444 and 2551 ng of BMP-2 over three days. In the in vivo experiment, injection of the transduced cells into the hind-limb musculature of SCID mice resulted in the formation of ectopic bone at 1, 2, 3 and 4 weeks after injection. Retroviral labelling of the cell nuclei showed labelled human muscle-derived cells occupying locations of osteoblasts in the ectopic bone, further supporting their osteocompetence. Cells from human skeletal muscle, because of their availability to orthopaedic surgeons, their osteocompetence, and their ability to express BMP-2 after genetic engineering, are an attractive cell population for use in BMP-2 gene therapy approaches.

A gene therapy approach to accelerating bone healing Evaluation of gene expression in a New Zealand white rabbit model

It has been demonstrated that BMPs, IGFs, and TGFβs improve the process of bone healing in vivo. We have suggested the use of gene therapy as a possible way to deliver growth factors to fracture sites in order to improve repair. The aim of this study was to develop a minimally invasive gene therapy approach to treat bone injuries locally without damaging the local blood circulation. A segmental defect of 1.3 cm was created in the diaphysis of the femur in mature NZW rabbits. Internal fixation with 7-hole DCP plates and 2.7 mm screws was used to stabilize the bone. After building a chamber by tightly closing the muscles around the segmental defect, 0.5 ml of either saline solution or a collagen gel containing 1 × 1010 particles of adenovirus carrying cDNA encoding either the bacterial β-galactosidase gene (LacZ), or the firefly luciferase gene were injected into the gap. The control side received 0.5 ml of saline solution without virus particles. Bone marrow, cortical and trabecular bone and surrounding muscle were harvested from the injected femur and were analyzed for local gene expression through X-gal staining or measurement of local luciferase activity. To determine whether distant sites were transduced, tissue from the spleen, liver, and lung were harvested as well as bone, bone marrow and muscle from the contralateral diaphysis of the femur. The delivery of the adenoviral vector suspended in saline solution led to local transduction of the bone, bone marrow and the muscle surrounding the gap. No luciferase activity was found in the contralateral femur, lung, or spleen, and only transient luciferase activity was seen in the liver. While marker gene expression persisted within the surrounding soft tissues for at least 2 weeks, the expression in bone lasted up to 6 weeks. This study has shown that it is possible to use adenoviral vectors to transfer and express genes locally within a segmental defect. Gene expression persisted for several weeks, which may be already sufficient to accelerate repair.

Potential role for gene therapy in the enhancement of fracture healing

Various proteins have the potential to initiate and accelerate fracture healing. Although osteogenic growth factors are the most prominent of these, there also may be important roles for other agents including growth factor receptors, angiogenic factors, and cytokine antagonists. Gene based delivery systems offer the potential to achieve therapeutic levels of these proteins locally within the fracture site for sustained times. Moreover, these delivery systems may deliver their products in a more biologically active form than that achieved by the exogenous application of recombinant proteins. Genes may be transferred to fractures by direct in vivo delivery or by indirect ex vivo delivery, using viral or nonviral vectors. Two examples are described in this article. With an ex vivo procedure, it was possible to transfer lac Z and neo(r) marker genes to the bones of mice, using retroviral transduction of bone marrow stromal cells. Gene expression in vivo persisted for several weeks. This procedure has the advantage of providing not only gene products but also osteoprogenitor cells to sites of bone healing. In vivo, local transfer of the lucerifase and lac Z marker genes was accomplished in a segmental defect model in the rabbit using adenoviral vectors. Under these conditions, gene expression in most tissues in and around the defect lasted between 2 and 6 weeks. These data encourage additional development of gene therapy for fracture healing. Such developments should go hand in hand with studies in the basic biology of fracture healing.

Potential role of direct adenoviral gene transfer in enhancing fracture repair.

Gene therapy has much to offer in the treatment of conditions in which it is necessary to increase the formation of bone. Nonunions, segmental defects, and aseptic loosening are examples of conditions where the local expression of genes that inhibit osteolysis and promote osteogenesis might be helpful. Studies in which one such possibility has been evaluated experimentally are described. These investigations used a surgically produced segmental defect in the femurs of New Zealand White rabbits as the model system. Adjacent muscle was fashioned around the defect to form a chamber into which adenoviral vectors were injected. High levels of transgene expression were found in the muscle surrounding the defect after injection of vectors carrying marker genes. Transgene expression also was seen in the cut ends of the bone and the scar tissue within the gap. No transgene expression was seen in the contralateral limb, spleen, or lung; transient, low levels of expression were found in the liver. Transgene expression declined with time, disappearing from all tissue but bone by Day 26; expression persisted in bone for at least 6 weeks. The control defects did not heal spontaneously. Injection of adenovirus carrying a human bone morphogenetic protein-2 complementary deoxyribonucleic acid led to healing of the segmental defect within 12 weeks, as judged by radiographic, histologic, and biomechanical criteria. Adenovirus carrying a human transforming growth factor-beta 1 complementary deoxyribonucleic acid showed signs of improved healing, but not to the extent seen with the bone morphogenetic protein-2 complementary deoxyribonucleic acid. This approach to therapy holds much promise as a novel means of promoting osteogenesis.

Gene therapy for osteoporosis: evaluation in a murine ovariectomy model

Various cytokines and cytokine antagonists hold promise as new therapeutic agents for osteoporosis, but their application is hindered by delivery problems. Gene transfer offers an attractive technology with which to obviate these restrictions. Its utility was evaluated in an animal model of osteoporosis. Disease was induced by surgical ovariectomy and monitored by measuring bone weight after 12 days, and by histomorphometry after 5 weeks. Genes were transferred to the mice by intramedullary injection of adenoviral vectors. LacZ and luciferase marker genes were used to identify the bone marrow cells transduced by this procedure, and to track the possible spread of transgenes to other organs. The effect on bone loss of transferring a cDNA encoding the human interleukin-1 receptor antagonist (IL-1Ra) was then evaluated. The intramedullary injection of adenoviral vectors transduced lining osteoblasts, osteocytes and cells within the bone marrow. Luciferase activity persisted within the injected femora and adjacent musculature for at least 3 weeks, and in the draining lymph nodes for 2 weeks. Transient, low level expression was present in the liver, but no luciferase was detected at any time in the lung or spleen. Intramedullary introduction of the IL-1Ra gene resulted in circulation of the corresponding protein at concentrations that peaked on day 3, and returned to baseline by day 12. Transfer of the IL-1Ra gene strongly reduced the early loss of bone mass occurring in response to ovariectomy. Furthermore, it completely inhibited the loss of matrix detected by histomorphometry at 5 weeks. The protective effect of this gene was not restricted to bones receiving intramedullary injection of the vector, but occurred in all bones that were evaluated. This proof of concept encourages further development of gene therapy approaches to the treatment of osteoporosis.

Proteins bound to polyethylene components in patients who have aseptic loosening after total joint arthroplasty. A preliminary report.

BACKGROUND Immunological responses to proteins that adhere to ultra-high molecular weight polyethylene have not, to our knowledge, been examined previously in patients who have aseptic loosening. In the current study, polyethylene components from forty-nine failed prostheses recovered during revision procedures were examined for the presence of antibodies that were bound to the polyethylene surface or that were reactive with other proteins that were bound to the polyethylene surface. METHODS The polyethylene components consisted of thirty acetabular cups recovered during revision total hip arthroplasties and nineteen tibial components recovered during revision total knee arthroplasties. After extensive washing, bound proteins were extracted from the polyethylene components with use of 0.1-molar glycine-hydrogen chloride solution followed by four-molar guanidine hydrochloride solution. RESULTS Sufficient protein for analysis was recovered from forty-two polyethylene components. Polyacrylamide gel electrophoresis demonstrated a minimum of one and a maximum of twelve protein bands, with molecular weights ranging from thirteen to 231 kilodaltons. Immunoblotting revealed the presence of type-I collagen in most (thirty-four) of the forty-two explants, whereas aggrecan proteoglycans were detected in eight samples. Immunoglobulin also was detected in most (thirty-three) extracts, whereas type-II collagen was consistently absent. The presence of autologous antibodies directed against polyethylene-bound proteins in sera drawn at the time of the revision was investigated. Antibodies that were reactive against the ultra-high molecular weight polyethylene-bound proteins were detected in twenty-six of the forty-two patients with use of the Western blot technique. The number of reactive bands ranged from one to six, and the strongest binding was directed against a 103-kilodalton protein. Assays for specificity revealed that these sera autologous antibodies were reactive against the type-I collagen that was present in the explant solutions. CONCLUSIONS We hypothesize that immunoglobulin complexed with polyethylene may fix complement and that the complement cascade may in turn attract inflammatory cells to the polyethylene surface. Our data support the hypothesis that an immunological response to antigens bound to the polyethylene surface may contribute to aseptic loosening. CLINICAL RELEVANCE Despite improvements in materials and designs of prostheses, aseptic loosening is the most common complication of total joint replacement, frequently leading to revision operations. We examined the immunological response to proteins that bind to ultra-high molecular weight polyethylene in patients who had aseptic loosening and discovered a high prevalence of antibodies to polyethylene-bound proteins. This immunological response may contribute to an inflammatory reaction in the periprosthetic tissue, ultimately leading to increased bone resorption around the prosthesis.

Gene therapy in autoimmune diseases

Collectively, autoimmune diseases constitute a major, unmet, clinical challenge. Although no single autoimmune disorder is highly prevalent, there are over 80 of them, and 20% of the population is affected; approximately 75% of patients are women. Because these diseases are generally incurable and difficult to manage, there is a pressing need for novel approaches to their treatment. For reasons detailed below, we have proposed that gene therapy merits investigation in this regard.1 Traditional pharmacological approaches to treatment entail the synthesis of small, diffusable compounds given orally or by injection. These approaches have yet to provide ideal agents for use in autoimmune diseases. Recent research, however, has identified a number of proteins with the potential to improve treatment, but these are difficult to administer long term. Gene transfer provides the opportunity to deliver protein products, as well as therapeutic species of nucleic acids, such as antisense RNA, much more efficiently than traditional methods of drug therapy. Furthermore sustained, in situ production of the gene products would eliminate the need for frequent re-administration. In addition, gene delivery and subsequent expression has the potential to be highly localised, if needed. Indeed, gene therapy’s greatest strength may be its ability to produce high, sustained concentrations of therapeutic macromolecules within a defined anatomical location. In the case of RA, for example, anti-arthritic proteins are already being delivered systemically to patients by subcutaneous or intravenous injection. There is, however, no practical method for transferring these molecules selectively to joints in a sustained fashion. In its broadest sense, gene therapy is the transfer to patients of a gene, or genes, for therapeutic purposes. With some exceptions, such as skeletal muscle and skin, naked DNA is not efficiently taken up and expressed by mammalian cells. For this reason it is necessary to use vectors as agents of …

Feasibility of percutaneous gene transfer to an atrophic nonunion in a rabbit

Treatment of atrophic nonunions is a challenge to orthopaedic surgeons. Growth factors potentially are valuable factors for improvement of tissue healing. The use of growth factors, however, is limited by their short half-lives. Gene therapy has the potential to improve the treatment. This study aimed to establish and validate an atrophic nonunion model in a rabbit for the use of a percutaneous in vivo gene therapy protocol. An atrophic tibial nonunion was established in 24 New Zealand White rabbits. Radiologic and histologic followup was for 64 weeks. The rabbit tibias showed no radiologic or histologic signs of healing. In addition, an adenoviral vector carrying a marker gene was injected percutaneously into the nonunion site in 12 rabbits. Expression of the marker gene was assessed for as many as 4 weeks. The percutaneous gene delivery resulted in transgene expression in the nonunion site for as many as 4 weeks. The described model reliably leads to an atrophic tibial nonunion in rabbits. Adenoviral percutaneous gene delivery into the nonunion site is feasible and leads to transgene expression locally for at least 1 month. This study provides investigators with a reliable and reproducible model of an atrophic nonunion.