Ex vivo gene therapy to produce bone using different cell types

Ex vivo gene therapy-induced endochondral bone formation: comparison of muscle-derived stem cells and different subpopulations of primary muscle-derived cells

Muscle-based gene therapy and tissue engineering hold great promise for improving bone healing. However, the relative advantage of muscle-derived stem cells (MDSCs) or primary muscle-derived cells (MDCs) remains to be defined. We compared the ability of MDSCs and different subpopulations of MDCs (PP1 and PP3) to induce bone formation via ex vivo gene therapy. We were able to efficiently transduce the MDSCs and all the other evaluated populations of MDCs (efficiency of transduction = approximately 80%) by using a retroviral vector expressing human bone morphogenetic protein 4 (BMP4). All the transduced cell populations secreted high levels of BMP4 (140-300 ng/10(6) cells/24 h), but the MDSCs differentiated toward the osteogenic lineage more effectively than did the other muscle cell populations, as indicated by the expression of alkaline phosphatase, an early osteogenic marker. von Kossa staining indicated that mineralized bone formed as early as 7 days after implantation of any of the BMP4-expressing cell populations into immunocompetent syngeneic mice; however, MDSCs expressing BMP4 produced significantly more bone than did the other MDC populations, as evidenced by both histomorphometry and biochemical analysis. Further investigation revealed that MDSCs expressing BMP4 persisted for a significantly longer period of time at the bone forming sites than did the other BMP4-expressing MDC populations. Additionally, MDSCs expressing BMP4 triggered a smaller infiltration of CD4 lymphocytes within the bone forming areas than did the other MDC populations expressing BMP4. Finally, we demonstrated that MDSCs expressing BMP4 can heal a critical-sized skull bone defect in immunocompetent mice. In summary, this study shows that MDSCs are better than primary MDCs for use as cellular vehicles in BMP4-based ex vivo gene therapy to improve bone healing. The advantage of MDSCs may be attributable, at least in part, to their lower immunogenicity and higher capacity for in vivo survival.

Transfer and Stable Transgene Expression of a Mammalian Artificial Chromosome into Bone Marrow-Derived Human Mesenchymal Stem Cells

Mammalian artificial chromosomes (ACEs) transferred to autologous adult stem cells (SCs) provide a novel strategy for the ex vivo gene therapy of a variety of clinical indications. Unlike retroviral vectors, ACEs are stably maintained, autonomous, and nonintegrating. In this report we assessed the delivery efficiency of ACEs and evaluated the subsequent differentiation potential of ACE-transfected bone marrow-derived human mesenchymal stem cells (hMSCs). For this, an ACE carrying multiple copies of the red fluorescent protein (RFP) reporter gene was transferred under optimized conditions into hMSCs using standard cationic transfection reagents. RFP expression was detectable in 11% of the cells 4-5 days post-transfection. The RFP-expressing hMSCs were enriched by high-speed flow cytometry and maintained their potential to differentiate along adipogenic or osteogenic lineages. Fluorescent in situ hybridization and fluorescent microscopy demonstrated that the ACEs were stably maintained as single chromosomes and expressed the RFP transgenes in both differentiated cultures. These findings demonstrate the potential utility of ACEs for human adult SC ex vivo gene therapy.

Converse relationship between in vitro osteogenic differentiation and in vivo bone healing elicited by different populations of muscle-derived cells genetically engineered to express BMP4

In this study, we compared the use of primary muscle-derived osteoprogenitor cells (PP6 cells) for the delivery of BMP4 to improve bone healing to that of muscle-derived non-osteoprogenitor cells (PP1 cells). Surprisingly, the use of PP1 cells resulted in an improved outcome because of the lack of adverse responses to BMP4 involving cell differentiation, proliferation, and apoptosis.

INTRODUCTION

Although researchers frequently opt to use osteogenic cells for osteogenic bone morphogenetic protein (BMP)-based ex vivo gene therapy to improve bone healing, it remains unclear whether the osteogenic potential of a cellular vehicle affects the outcome of bone healing applications. Here we compared the use of muscle-derived non-osteoprogenitor cells (PP1 cells) to that of primary muscle-derived osteoprogenitor cells (PP6 cells) for the delivery of BMP4 to improve the healing of bone defects.

MATERIALS AND METHODS

Two distinct populations of primary rat muscle-derived cells--PP1 and PP6--were selected, transduced with retroviral vectors to express BMP4 or a marker gene (LacZ), and implanted into critical-sized calvarial defects created in syngeneic rats. The bone healing was monitored radiographically and histologically at 7 and 14 weeks after implantation. Cellular responses to BMP4 were evaluated by alkaline phosphatase histochemical staining and RT-PCR of another osteogenic marker to indicate osteogenic differentiation, a cell proliferation assay and BrdU (bromodeoxyuridine) labeling to assess cell proliferation, and the TUNEL assay to determine apoptosis.

RESULTS AND CONCLUSIONS

In all animals (nine rats per group), transduced PP1 cells expressing BMP4 demonstrated significantly advanced healing compared with PP6 cells expressing BMP4 and control cells expressing LacZ. We found that constitutive BMP4 expression negatively impacted the in vitro proliferation and in vivo survival rates of PP6 cells, but not PP1 cells. BMP4 exposure also directly inhibited the proliferation and induced the apoptosis of PP6 cells, but not PP1 cells. The impairment in PP6 cell proliferation was directly associated with the osteogenic differentiation of these cells. These results indicate that PP1 cells are better suited than osteoprogenitor cells for use as cellular vehicles to deliver osteogenic BMP4 to improve bone healing and that cellular behavior in response to a particular gene can be used to predict the cells' performance as delivery vehicles in ex vivo gene therapy.

Transduction of Passaged Human Articular Chondrocytes with Adenoviral, Retroviral, and Lentiviral Vectors and the Effects of Enhanced Expression of SOX9

Chondrocytes form and maintain the extracellular matrix of cartilage. The cells can be isolated from cartilage for applications such as tissue engineering, but their expansion in monolayer culture causes a progressive loss of chondrogenic phenotype. In this work, we have investigated the isolation of human articular chondrocytes from osteoarthritic (OA) cartilage at joint replacement, their expansion in monolayer culture, and their transduction with adenoviral, retroviral, and lentiviral vectors, using the gene encoding green fluorescent protein as a marker gene. The addition of growth factors (transforming growth factor beta(1), fibroblast growth factor 2, and platelet-derived growth factor BB) during cell culture was found to greatly increase cell proliferation and thereby to selectively enhance the efficiency of transduction with retrovirus. With adenoviral and lentiviral vectors the transduction efficiency achieved was 95 and 85%, respectively. Using growth factor-supplemented medium with a retroviral vector, efficiency in excess of 80% was achieved. The expression was stable for several months with both retrovirus and lentivirus when analyzed by fluorescence-activated cell-sorting flow analysis and immunoblotting. Transduction with SOX9 was investigated as a method to reinitiate cartilage matrix gene expression in passaged human OA chondrocytes. Endogenous collagen II expression (both mRNA and protein) was increased in monolayer culture using both adenoviral and retroviral vectors. Furthermore, collagen II gene expression in chondrocytes retrovirally transduced with SOX9 was stimulated by alginate bead culture, whereas in control chondrocytes it was not. These results demonstrated methods for rapid expansion and highly efficient transduction of human OA chondrocytes and the potential for the recovery of key features of chondrocyte phenotype by transduction with SOX9.

Retroviral delivery of Noggin inhibits the formation of heterotopic ossification induced by BMP-4, demineralized bone matrix, and trauma in an animal model

BACKGROUND

The heterotopic ossification of muscles, tendons, and ligaments is a common problem faced by orthopaedic surgeons. We investigated the ability of Noggin (a BMP [bone morphogenetic protein] antagonist) to inhibit heterotopic ossification.

METHODS

Part 1: A retroviral vector carrying the gene encoding human Noggin was developed and used to transduce muscle-derived stem cells. Part 2: Cells transduced with BMP-4 were implanted into both hind limbs of mice along with either an equal number, twice the number, or three times the number of Noggin-expressing muscle-derived stem cells (treated limb) or with nontransduced muscle-derived stem cells (control limb). At four weeks, the mice were killed and radiographs were made to look for evidence of heterotopic ossification. Part 3: Eighty milligrams of human demineralized bone matrix was implanted into the hind limbs of SCID (severe combined immunodeficiency strain) mice along with 100,000, 500,000, or 1,000,000 Noggin-expressing muscle-derived stem cells (treated limbs) or nontransduced muscle-derived stem cells (control limbs). At eight weeks, the mice were killed and radiographs were made. Part 4: Immunocompetent mice underwent bilateral Achilles tenotomy along with the implantation of 1,000,000 Noggin-expressing muscle-derived stem cells (treated limbs) or nontransduced muscle-derived stem cells (control limbs). At ten weeks, the mice were killed and radiographs were made.

RESULTS

Part 1: An in vitro BMP inhibition assay demonstrated that Noggin was expressed by muscle-derived stem cells at a level of 280 ng per million cells per twenty-four hours. Part 2: Three varying doses of Noggin-expressing muscle-derived stem cells inhibited the heterotopic ossification elicited by BMP-4-expressing muscle-derived stem cells. Heterotopic ossification was reduced in a dose-dependent manner by 53%, 74%, and 99%, respectively (p < 0.05). Part 3: Each of three varying doses of Noggin-expressing muscle-derived stem cells significantly inhibited the heterotopic ossification elicited by demineralized bone matrix. Heterotopic ossification was reduced by 91%, 99%, and 99%, respectively (p < 0.05). Part 4: All eleven animals that underwent Achilles tenotomy developed heterotopic ossification at the site of the injury in the control limbs. In contrast, the limbs treated with the Noggin-expressing muscle-derived stem cells had a reduction in the formation of heterotopic ossification of 83% and eight of the eleven animals had no radiographic evidence of heterotopic ossification (p < 0.05).

CONCLUSIONS

The delivery of Noggin mediated by muscle-derived stem cells can inhibit heterotopic ossification caused by BMP-4, demineralized bone matrix, and trauma in an animal model.

CLINICAL RELEVANCE

Gene therapy to deliver Noggin may become a powerful method to inhibit heterotopic ossification in targeted areas of the body.

In Vivo Evaluation of Gene Therapy Vectors in Ex Vivo-Derived Marrow Stromal Cells for Bone Regeneration in a Rat Critical-Size Calvarial Defect Model

Cells genetically modified to produce osteoinductive factors have potential for use in enhancing bone regeneration for reconstructive applications. Genetic modification of cells can be accomplished by a variety of gene therapy vectors. In this study we evaluated the ex vivo genetic modification of rat marrow stromal cells (MSCs) by adenoviral, retroviral, and cationic lipid vectors containing the gene for human bone morphogenetic protein 2 (hBMP-2). We investigated both the in vitro and in vivo osteogeneic potential of MSCs modified by each vector. In vitro, we found that only MSCs modified with the adenoviral vector produced detectable hBMP-2 and demonstrated a statistically significant increase in endogenous alkaline phosphatase activity indicative of osteogeneic differentiation. We further investigated the ability of genetically modified MSCs seeded on a titanium mesh scaffold to facilitate bone formation in vivo. In an orthotopic critical-size defect created in the rat cranium, bone formation was observed in all conditions with MSCs modified by the adenoviral vector demonstrating a small but statistically significant increase in bone formation relative to the other vectors and control. Implants in an ectopic location demonstrated minimal bone formation relative to the orthotopic location, with MSCs modified with cationic lipids forming less bone than the other vectors and control. Our results show that MSCs genetically modified with adenovirus containing the hBMP-2 gene had enhanced osteogeneic capacity relative to unmodified MSCs or MSCs modified by the other vectors. This study was the first to compare three different gene therapy vectors for the genetic modification of cells to produce osteoinductive factors for the purpose to enhance bone regeneration.

The role of cell type in bone healing mediated by ex vivo gene therapy

BACKGROUND

The ideal cellular vehicle for use in cell-mediated gene therapy to enhance bone healing has not yet been identified. The purpose of this study was to compare the capacity of two types of cells transduced with retro-bone morphogenetic protein 4 (BMP4)-muscle-derived cells (MDCs) and unfractioned bone marrow stromal cells (BMSCs).

METHOD

Primary rat MDCs and unfractioned rat BMSCs were transduced with a retrovirus to express BMP4. A 7-mm, critical-sized femur defect was created in adult rats, and 5 x 10(6) transduced cells were implanted into the femoral defect. Bone healing was monitored radiographically and histologically at 4, 8, and 12 weeks post-implantation.

RESULTS

All specimens in the MDC-BMP4 group and BMSC-BMP4 group showed a bridging callus at 8 and 12 weeks. At 12 weeks post-implantation the calluses of the MDC-BMP4 femora displayed significantly higher bone photodensity than the BMSC-BMP4 femora (P<0.05). Histomorphometry revealed no difference between the two treatment groups. However, non-union between newly formed and original bone was observed in none of the MDC femora but in six femora from the BMSC-BMP4 group.

CONCLUSION

Both MDCs and unfractioned BMSCs can improve healing of a critical-sized bone defect following transduction of the cells with retroBMP4. However, MDCs appear to yield superior results when compared with BMSCs in terms of improved healing of segmental defects.

Bone regeneration through transplantation of genetically modified cells

To the author's knowledge, the rabbit is the largest animal model used to explore bone regeneration with genetically modified cells. This technology needs to be expanded to larger animal models that represent a more clinically relevant application in which cells are isolated from the animal, expanded ex vivo, genetically modified, and implanted in a critical-size bone defect in the donor animal. Furthermore, optimization of the vector type, vector dose, cell dose, and carrier material choice must be accomplished in animal models before clinical investigation is initiated. Most research has focused on a single osteoinductive protein; however, multiple proteins may synergize to further enhance bone formation. In conclusion, transplantation of genetically modified cells provides a new opportunity to improve bone tissue regeneration.

Osteoinduction by ex vivo adenovirus-mediated BMP2 delivery is independent of cell type

The objective of the study was to analyze and compare the abilities of various human cell types with inherently dissimilar osteogenic potentials to induce heterotopic bone formation following ex vivo transduction with two distinct adenoviral vectors encoding bone morphogenetic protein type 2 (BMP2). The cells comprised primary human bone marrow mesenchymal stem cells (BM-MSCs), primary human skin fibroblasts (SFs), and a human diploid fetal lung cell line (MRC-5). The vectors included adenovirus type 5 or a chimeric adenovirus type 5 with the fiber gene of adenovirus type 35 (Ad5F35-BMP2), both demonstrating significantly different expression of BMP2 in vitro. The experimental groups consisted of the three human cell types transduced with each of the two adenoviral vectors. Using nonobese diabetic severe combined immunodeficiency (NOD/SCID) mice, the transduced cells were injected intramuscularly following ex vivo adenoviral transduction. The nature and extent of heterotopic bone formation were analyzed radiographically and histologically. At 14 days postinjection, abundant, highly mineralized bone was formed in mice injected with Ad5F35-BMP2-transduced cells irrespective of the cell type. There was no statistically significant difference in the amount of bone formed between BM-MSCs, SFs, and MRC-5 cells transduced with Ad5F35-BMP2, as assessed from bone surface area on biplanar plain radiography. Substantially lesser amounts or no bone could be detected in mice injected with cells transduced with Ad5-BMP2. Immunohistochemical analysis confirmed the presence of human cells in muscle as early as 2 days postdelivery; however, at 6-7 days after injection, the transduced cells could not be detected in surrounding muscle, or in the heterotopic bone, indicating the host origin of the newly formed bone. The results of the study demonstrate no significant difference in osteoinductive properties between BM-MSCs, SFs, and MRC-5 cells transduced ex vivo with the same type of adenovirus encoding BMP2. The level of BMP2 expression appears to be a crucial factor determining the extent of heterotopic bone formation and was significantly affected by the type of adenovirus used. In the cell types studied, Ad5F35-BMP2 was more efficacious than Ad5-BMP2 in providing adequate levels of BMP2 for efficient osteoinduction.

Ex vivo gene therapy for skeletal regeneration in cranial defects compromised by postoperative radiotherapy

Because radiation remains a common postoperative treatment for head and neck cancers, it is critical to determine whether new bone-regenerative approaches are effective for healing craniofacial defects challenged by therapeutic doses of radiation. The objective of this study was to determine whether the deleterious effects of radiotherapy could be overcome by ex vivo gene therapy to heal craniofacial defects. Rat calvarial critical-sized defects were treated with either an inlay calvarial bone graft or syngeneic dermal fibroblasts transduced ex vivo with an adenovirus engineered to express bone morphogenetic protein 7 (BMP-7), a morphogen known to stimulate bone formation. Two weeks postoperatively, either no radiation or a single 12-Gy radiation dose was delivered to the operated area and the tissue was harvested 4 weeks later. None of the inlay bone grafts healed at the wound margins of either the radiated or nonradiated sites. In contrast, bone was successfully regenerated when using an ex vivo gene therapy approach. More bone formed in the nonradiated group as determined by the percentage of defect surface covered (87 +/- 4.1 versus 65 +/- 4.7%; p = 0.003) and percentage of defect area filled by new bone (60 +/- 5.9 versus 32 +/- 2.7%; p = 0.002). Although the effects of radiation on the wound were not completely overcome by the gene therapy approach, bone regeneration was still successful despite the radiation sensitivity of the fibroblasts. These results indicate that BMP-7 ex vivo gene therapy is capable of successfully regenerating bone in rat calvarial defects even after a therapeutic dose of radiation. This approach may represent a new strategy for regenerating skeletal elements lost due to head and neck cancer.

Bone formation following transplantation of genetically modified primary bone marrow stromal cells

Bone marrow stromal cells contain mesenchymal stem cells that can differentiate into a variety of mesenchymal tissues; in the presence of BMP-2, for example, they differentiate into osteoblasts. We constructed replication-deficient adenoviral vectors encoding human BMP-2 (BMP-2/Ad) or BMP-4 (BMP-4/Ad) and used them to transduce primary bone marrow stromal cells from the femurs of four-week-old female C3H mice, which then expressed and processed functional BMP-2 or BMP-4 protein. Enzyme assays and histochemical staining showed both groups of cells to possess alkaline phosphatase activity, a marker of differentiation into osteoblasts, though the activity was higher in cells transduced with BMP-2/Ad. When BMP-2/Ad-transduced cells were injected into the thigh muscles of immunocompetent C3H mice, ossicle development was detected on radiographs within four weeks after injection. Moreover, histological analysis indicated that newly developed ossicles contain mature osseous components, including cortical bone and bone marrow, within eight weeks. Thus, syngeneic transplantation of genetically modified primary bone marrow stromal cells induced bone formation in immunocompetent mice, perhaps indicating its potential for use in the development of therapeutic protocols aimed at enhancing bone formation.

Transplantation of skin fibroblasts expressing BMP-2 promotes bone repair more effectively than those expressing Runx2

We investigated the osteogenic potential of skin fibroblasts that overexpressed BMP-2 or Runx2 by using adenoviral vectors. In in vitro experiments, skin fibroblasts infected with adenovirus vector encoding BMP-2 (AdBMP-2) released substantial levels of BMP-2 proteins into culture media, and those infected with adenovirus vector encoding Runx2 (AdRunx2) produced its protein. Transduction of BMP-2 or Runx2, respectively, increased alkaline phosphatase (ALP) activity and induced expression of mRNAs of ALP, osteocalcin, and osterix in skin fibroblasts. In in vivo experiments, we investigated the bone induction activity by transplantation of a complex composed of carrier [poly-D,L-lactic-co-glycolic acid/gelatin sponge (PGS)] and skin fibroblasts (PGS/SF complex). Transplantation of PGS/SF complexes composed of skin fibroblasts transduced with AdBMP-2-induced ectopic bone formation when transplanted into the subfascia of back muscle, unlike those infected with AdRunx2. Transplantation of PGS/SF complexes composed of skin fibroblasts transduced with AdBMP-2 into craniotomy defects induced bone formation from 2 weeks after transplantation, and almost all PGS was replaced by newly synthesized bone at 6 weeks. To investigate the fate of the transplanted cells, we transplanted skin fibroblasts isolated from green fluorescence protein transgenic mice into craniotomy defects. Transplantation of these skin fibroblasts transfected with AdBMP-2 generated green fluorescence protein-positive osteoblasts and osteocytes, indicating that the transplanted skin fibroblasts differentiated into osteoblastic lineage cells during bone repair. In contrast, transplantation of PGS/SF complexes composed of skin fibroblasts transduced with AdRunx2 induced a few ALP-positive cells at 1 week after transplantation, but their number decreased depending on time after transplantation. In addition, transplantation of these complexes was insufficient to induce bone repair. Taken together, our results suggest that skin fibroblasts expressing BMP-2 are more suitable for cell-mediated therapy of bone repair than those expressing Runx2.

Chondrogenesis enhanced by overexpression of sox9 gene in mouse bone marrow-derived mesenchymal stem cells

We investigated chondrogenesis of cell-mediated sox9 gene therapy as a new treatment regimen for cartilage regeneration. pIRES2-EGFP vector containing a full-length mouse sox9 cDNA was transfected into bone marrow-derived mesenchymal stem cells (MSCs) by lipofection and chondrogenic differentiation of these cells was evaluated. In vitro high density micromass culture of these sox9 transfected MSCs demonstrated that a matrix-rich micromass aggregate with EGFP expressing MSCs was positively stained by Alcian blue and type II collagen. Next, sox9 transfected MSCs were loaded into the diffusion chamber and transplanted into athymic mice to analyze in vivo chondrogenesis. A massive tissue formation in about 2mm diameter was visible in the chamber after 4 weeks transplantation. Histological examinations demonstrated that both Alcian blue and type II collagen were positively stained in the extracellular matrix of the mass while type X collagen was not stained. These results indicated that cell-mediated sox9 gene therapy could be a novel strategy for hyaline cartilage damage.

Muscle-based gene therapy and tissue engineering to improve bone healing

Failed fracture healing is a significant problem in orthopaedics, often seen in patients with scaphoid fractures, high-energy injuries, and osteoporosis. Current treatments often result in poor outcomes and donor site morbidity. Gene therapy has been the focus of much recent research to improve bone healing. In the current review, the authors specifically evaluate the use of muscle-derived cells as a gene delivery vehicle and inducible osteoprogenitor cell that can enhance bone regeneration. Muscle-derived cells have been used to deliver bone morphogenetic protein-2 and produce ectopic bone. These cells express osteocalcin and have been found within newly generated bone in locations normally occupied by osteoblasts and osteocytes. Finally, it is shown that muscle-derived cells coupled with ex vivo gene therapy can heal critical-sized calvarial defects.

Bone morphogenetic protein gene therapy

STUDY DESIGN

A retrospective analysis of previous BMP gene therapy and general gene therapy publications.

OBJECTIVE

To present the potential role of BMP gene therapy for the induction of osteogenesis and spinal fusion.

SUMMARY OF BACKGROUND DATA

A variety of viral and non-viral techniques have been utilized to insert foreign transgenes into cells, both in vivo and in vitro. These techniques are now being used to transduce cells with a BMP gene to express significant amounts of BMP. This secreted BMP can subsequently stimulate osteogenesis in a variety of locations, including in the paraspinal regions.

METHODS

A retrospective analysis of the literature.

RESULTS

Direct and ex vivo BMP gene therapy has been shown to successfully promote bone healing and regeneration in a variety of animal models. Long-term and regulated transgene expression are clear advantages of BMP gene delivery, compared to direct BMP application. To date, BMP gene delivery with adenoviral vectors have been the most effective approach for stimulating bone induction in vivo.

CONCLUSIONS

Although BMP gene therapy techniques have significant potential for the treatment of spine pathology, further preclinical and clinical research and development are required before this technology will have direct clinical applications.

BMP4-expressing muscle-derived stem cells differentiate into osteogenic lineage and improve bone healing in immunocompetent mice

Recent advances in molecular biology have led the way for novel approaches to improve bone healing. The ideal growth factor, vector, and delivery systems for producing bone in an immune competent animal model, however, have yet to be identified. Using a retrovirus encoding BMP4 and recently isolated muscle-derived stem cells (MDSCs), we demonstrated the following: MDSCs undergo osteogenic differentiation in response to BMP4 in a dose-dependent manner; retrovirus encoding BMP4 can efficiently transduce MDSCs, both enhancing osteogenic differentiation and inhibiting myogenic differentiation; transduced MDSCs can produce high levels of functional BMP4 as they differentiate toward an osteogenic lineage; allogeneic transduced MDSCs can induce robust de novo bone formation in immunocompetent mice despite the presence of an immune reaction, demonstrating the ability of this retroviral-BMP4-muscle construct to provide sufficient stimuli for osteoinduction in vivo; MDSCs appear to deliver BMP4, respond to the human BMP4 in an autocrine manner, and actively participate in bone formation, thus serving both osteoinductive and osteoproductive roles; and the BMP4-expressing MDSCs can induce bone formation and improve bone healing in a critical-sized skull defect in immunocompetent mice. Therefore, we believe that technology based on the MDSCs and vector system has great potential for promoting bone healing in a variety of musculoskeletal conditions.

Ectopic bone formation by electroporatic transfer of bone morphogenetic protein-4 gene

Orthopedic surgeons have long awaited the clinical application of bone morphogenetic proteins (BMPs) for bone regeneration. However, such possible applications involving proteins or genes transferred with virus vectors have encountered many problems, including high cost, immunological reactions, viral infection, etc. We adopted a new gene transfer system of in vivo electroporation with a plasmid expression vector. A solution of plasmid DNA containing mouse BMP-4 (pMiw-BMP4) was injected into the gastrocnemius of BALB/cA mice, and electric pulses were applied through paired-needle electrodes inserted percutaneously. As a control plasmid, LacZ-containing plasmid (pMiwZ) was transferred by electroporation. A control group in which pMiw-BMP4 was injected and not electroporated was also introduced. In these groups, the gastrocnemius was harvested at 7, 14, 21, and 28 days after electroporation (n = 6 in each). As nonplasmid controls, electroporation with saline injection (n = 6), electroporation without injection (n = 6), and saline injection only (n = 3) were prepared. In these groups, the mice were killed 7 days after experimentation. Ectopic calcification or ossification was examined by histology as well as soft X-ray. In all electroporated groups (pMiwZ, pMiw-BMP4, saline injection, and without injection), dystrophic calcification of muscle bundles and infiltration of mesenchymal cells were observed histologically. Ectopic bone formation was observed only in the pMiw-BMP4 electroporation group. At 7 days after pMiw-BMP4 electroporation, extracellular eosinophilic matrix in a collection of mesenchymal cells was observed. Between 14 and 28 days after electroporation, ectopic bone was observed in 44% of mice, and bone marrow-like cells observed in 22%. The newly formed bone was woven. Injection of pMiw-BMP4 or saline induced neither calcification nor ossification. Our findings indicate that BMP-4 transferred by electroporation can induce in vivo and in situ ectopic bone formation in skeletal muscle.

Use of a chimeric adenovirus vector enhances BMP2 production and bone formation

Recombinant adenoviral vectors have potential for the treatment of a variety of musculoskeletal defects and such gene therapy systems have been a recent research focus in orthopedic surgery. In studies reported here, two different adenovirus vectors have been compared for their ability to transduce human bone marrow mesenchymal stem cells (hBM-MSCs) and elicit bone formation in vivo. Vectors consisted either of standard adenovirus type 5 (Ad5) vector or a chimeric adenovirus type 5 vector that contains an adenovirus type 35 fiber (Ad5F35), which has been recently demonstrated to bestow a different cellular tropism, and a complete cDNA encoding human bone morphogenetic 2 (BMP2). Studies were also conducted to compare the transduction efficiency of these vectors using enhanced green fluorescent protein (GFP). hBM-MSCs transduced with Ad5F35 vectors had higher levels of transgene expression than those transduced with Ad5 vectors. The results also demonstrate that hBM-MSCs lack the coxsackie-adenovirus receptor (CAR), which is responsible for cellular adsorption of Ad5. Therefore, the data suggest that Ad5 virus adsorption to hBM-MSCs is inefficient. Ad5BMP2- or Ad5F35BMP2-transduced hBM-MSCs were also compared in an in vivo heterotopic bone formation assay. Mineralized bone was radiologically identified only in muscle that received the Ad5F35BMP2 transduced hBM-MSCs. In summary, Ad5F35BMP2 can efficiently transduce hBM-MSCs leading to enhanced bone formation in vivo.

Bone morphogenetic protein-transduced human fibroblasts convert to osteoblasts and form bone in vivo

Experimental cell or ex vivo gene therapy for localized bone formation typically uses osteoprogenitor cells propagated from periosteum or bone marrow. Both require bone or marrow biopsies to obtain cells. We have demonstrated that implantation of gingival or dermal fibroblasts transduced with BMP ex vivo, using a recombinant adenovirus (AdCMVBMP) attached to porous biodegradable scaffolds, form bone in vivo. Here we show that BMP-7-transduced fibroblasts suspended in injectable thermoset hydrogels form complete ossicles on subcutaneous injection and repair segmental defects in rat femurs. Bone formation was preceded by an intermediate cartilage stage. To determine the fate of the implanted transduced cells, thermoset hydrogel suspensions of ex vivo BMP-7-transduced or nontransduced fibroblasts were placed in diffusion chambers and implanted to allow development in vivo without direct contact with host cells. Only the BMP-transduced fibroblasts formed bone within the diffusion chambers in vivo, revealing that BMP transduction induces osteoblastic conversion of these cells.

Enhancement of bone healing based on ex vivo gene therapy using human muscle-derived cells expressing bone morphogenetic protein 2

Molecular biological advances have allowed the use of gene therapy in a clinical setting. In addition, numerous reports have indicated the existence of inducible osteoprogenitor cells in skeletal muscle. Because of this, we hypothesized that skeletal muscle cells might be ideal vehicles for delivery of bone-inductive factors. Using ex vivo gene transfer methods, we genetically engineered freshly isolated human skeletal muscle cells with adenovirus and retrovirus to express human bone morphogenetic protein 2 (BMP-2). These cells were then implanted into nonhealing bone defects (skull defects) in severe combined immune deficiency (SCID) mice. The closure of the defect was monitored grossly and histologically. Mice that received BMP-2-producing human muscle-derived cells experienced a full closure of the defect by 4 to 8 weeks posttransplantation. Remodeling of the newly formed bone was evident histologically during the 4- to 8-week period. When analyzed by fluorescence in situ hybridization, a small fraction of the transplanted human muscle-derived cells was found within the newly formed bone, where osteocytes normally reside. These results indicate that genetically engineered human muscle-derived cells enhance bone healing primarily by delivering BMP-2, while a small fraction of the cells seems to differentiate into osteogenic cells.

Human adenovirus serotypes 4p and 11p are efficiently expressed in cell lines of neural tumour origin

Most currently used adenovirus vectors are based upon adenovirus serotypes 2 and 5 (Ad2 and Ad5), which have limited efficiencies for gene transfer to human neural cells. Both serotypes bind to the known adenovirus receptor, CAR (coxsackievirus and adenovirus receptor), and have restricted cell tropism. The purpose of this study was to find vector candidates that are superior to Ad5 in infecting human neural tumours. Using flow cytometry, the vector candidates Ad4p, Ad11p and Ad17p were compared to the commonly used adenovirus vector Ad5v for their binding capacity to neural cell lines derived from glioblastoma, medulloblastoma and neuroblastoma cell lines. The production of viral structural proteins and the CAR-binding properties of the different serotypes were also assessed in these cells. Computer-based models of the fibre knobs of Ad4p and Ad17 were created based upon the crystallized fibre knob structure of adenoviruses and analysed for putative receptor-interacting regions that differed from the fibre knob of Ad5. The non CAR-binding vector candidate Ad11p showed clearly the best binding capacity to all of the neural cell lines, binding more than 90% of cells of all of the neural cell lines tested, in contrast to 20% or less for the commonly used vector Ad5v. Ad4p and Ad11p were also internalized and produced viral proteins more successfully than Ad5. Ad4p showed a low binding ability but a very efficient capacity for infection in cell culture. Ad17p virions neither bound or efficiently infected any of the neural cell lines studied.

Muscle-derived stem cells

The existence of cells with stem cell-like abilities derived from various tissues can now be extended to include the skeletal muscle compartment. Although researchers have focused on the utilization of these cells with regard to their myogenic capacity, initially exploring more efficient cellular therapy treatments for muscular dystrophy, it is becoming increasingly apparent that such cells may one day be used in the treatment of non-myogenic disorders. Evidence regarding the existence and differentiation capacity of muscle-derived stem cells is discussed, along with current theories regarding their proposed position within the myogenic hierarchy.

Gene therapy and tissue engineering in orthopaedic surgery

A new biologic era of orthopaedic surgery has been initiated by basic scientific advances that have resulted in the development of gene therapy and tissue engineering approaches for treating musculoskeletal disorders. The terminology, fundamental concepts, and current research in this burgeoning field must be understood by practicing orthopaedic surgeons. Different gene therapy approaches, multiple gene vectors, a multitude of cytokines, a growing list of potential scaffolds, and putative stem cells are being studied. Gene therapy and tissue engineering applications for bone healing, articular disorders, intervertebral disk pathology, and skeletal muscle injuries are being explored. Innovative methodologies that ensure patient safety can potentially lead to many new treatment strategies for musculoskeletal conditions.

Muscle-derived stem cells: characterization and potential for cell-mediated therapy

Skeletal muscle may represent a convenient source of stem cells for cell-mediated gene therapy and tissue-engineering applications. A population of cells isolated from skeletal muscle exhibits both multipotentiality and self-renewal capabilities. Satellite cells, referred to by many as muscle stem cells, are myogenic precursors that are capable of regenerating muscle and demonstrating self-renewal properties; however, they are considered to be committed to the myogenic lineage. Muscle-derived stem cells, which may represent a predecessor of the satellite cell, are considered to be distinct. This article considers the evidence for the existence of muscle-derived stem cells as well as their potential embryonic origin. Comparison of muscle-derived stem cells to bone marrow and hematopoietic-derived stem cells illustrates similarities and distinctions among these various stem cells. Hematopoietic stem cell research provides lessons for the isolation of a defined phenotype as well as for the expansion of the stem cells in vitro. Recent investigations highlighting the potential of stem cell transplantation for the treatment of muscular dystrophies are discussed.

Muscle-based gene therapy and tissue engineering for the musculoskeletal system

The recent expansion of molecular biology techniques has opened the gates for a rapid advancement in our knowledge of disease mechanisms. These techniques, in addition to advances in cell biology and polymer chemistry, are resulting in novel approaches to treating musculoskeletal disorders. Surgeons, who have traditionally used the tools of excision and reconstruction to treat patients, might now serve as surgical 'gardeners', who create microenvironments that are conducive for tissue regeneration. This review will update readers on the principles and current advances in muscle-based gene therapy and tissue engineering for the musculoskeletal system.

Effect of bone morphogenetic protein-2-expressing muscle-derived cells on healing of critical-sized bone defects in mice

BACKGROUND

Cells that express bone morphogenetic protein-2 (BMP-2) can now be prepared by transduction with adenovirus containing BMP-2 cDNA. Skeletal muscle tissue contains cells that differentiate into osteoblasts on stimulation with BMP-2. The objectives of this study were to prepare BMP-2-expressing muscle-derived cells by transduction of these cells with an adenovirus containing BMP-2 cDNA and to determine whether the BMP-2-expressing muscle-derived cells would elicit the healing of critical-sized bone defects in mice.

METHODS

Primary cultures of muscle-derived cells from a normal male mouse were transduced with adenovirus encoding the recombinant human BMP-2 gene (adBMP-2). These cells (5 yen 10(5)) were implanted into a 5-mm-diameter critical-sized skull defect in female SCID (severe combined immunodeficiency strain) mice with use of a collagen sponge as a scaffold. Healing in the treatment and control groups was examined grossly and histologically at two and four weeks. Implanted cells were identified in vivo with use of the Y-chromosome-specific fluorescent in situ hybridization (FISH) technique, and their differentiation into osteogenic cells was demonstrated by osteocalcin immunohistochemistry.

RESULTS

Skull defects treated with muscle cells that had been genetically engineered to express BMP-2 had >85% closure within two weeks and 95% to 100% closure within four weeks. Control groups in which the defect was not treated (group 1), treated with collagen only (group 2), or treated with collagen and muscle cells without adBMP-2 (group 3) showed at most 30% to 40% closure of the defect by four weeks, and the majority of the skull defects in those groups showed no healing. Analysis of injected cells in group 4, with the Y-chromosome-specific FISH technique showed that the majority of the transplanted cells were located on the surfaces of the newly formed bone, but a small fraction (approximately 5%) was identified within the osteocyte lacunae of the new bone. Implanted cells found in the new bone stained immunohistochemically for osteocalcin, indicating that they had differentiated in vivo into osteogenic cells.

CONCLUSIONS

This study demonstrates that cells derived from muscle tissue that have been genetically engineered to express BMP-2 elicit the healing of critical-sized skull defects in mice. The cells derived from muscle tissue appear to enhance bone-healing by differentiating into osteoblasts in vivo.

CLINICAL RELEVANCE

Ex vivo gene therapy with muscle-derived cells that have been genetically engineered to express BMP-2 may be used to treat nonhealing bone defects. In addition, muscle-derived cells appear to include stem cells, which are easily obtained with muscle biopsy and could be used in gene therapy to deliver BMP-2.

The effect of bone morphogenetic protein-2 expression on the early fate of skeletal muscle-derived cells

The identification of bone morphogenetic proteins (BMPs) has stimulated intense interest in BMP delivery approaches. Ex vivo BMP-2 gene delivery has recently been described using skeletal muscle-derived cells. Skeletal muscle-derived cells, because of proven efficient transgene delivery and osteocompetence, represent an attractive cell population on which to base ex vivo BMP-2 gene delivery. However, the early in vivo fate of BMP-2-expressing muscle-derived cells is unknown. This study investigates the in vivo effects of BMP-2 secretion on skeletal muscle-derived cells in terms of cell survival and cell differentiation. The first experiment compared survival of BMP-2-expressing cells with control cells during the first 48 h after in vivo implantation. The results demonstrate that BMP-2 secretion did not adversely affect cell survival 8, 24, or 48 h after intramuscular implantation. The second experiment histologically compared the fate of BMP-2-expressing muscle-derived cells to the same cells not expressing BMP-2. The results show that BMP-2 expression prevented in vivo myogenic differentiation and promoted osteogenic differentiation of the transduced cells. This study further supports the existence of osteoprogenitor cells residing within skeletal muscle. Moreover, it is demonstrated that BMP-2 secretion does not adversely affect early cell survival of muscle-derived cells. These data are important for future investigations into BMP-2 gene delivery approaches to the musculoskeletal system.

Clonal isolation of muscle-derived cells capable of enhancing muscle regeneration and bone healing

Several recent studies suggest the isolation of stem cells in skeletal muscle, but the functional properties of these muscle-derived stem cells is still unclear. In the present study, we report the purification of muscle-derived stem cells from the mdx mouse, an animal model for Duchenne muscular dystrophy. We show that enrichment of desmin(+) cells using the preplate technique from mouse primary muscle cell culture also enriches a cell population expressing CD34 and Bcl-2. The CD34(+) cells and Bcl-2(+) cells were found to reside within the basal lamina, where satellite cells are normally found. Clonal isolation and characterization from this CD34(+)Bcl-2(+) enriched population yielded a putative muscle-derived stem cell, mc13, that is capable of differentiating into both myogenic and osteogenic lineage in vitro and in vivo. The mc13 cells are c-kit and CD45 negative and express: desmin, c-met and MNF, three markers expressed in early myogenic progenitors; Flk-1, a mouse homologue of KDR recently identified in humans as a key marker in hematopoietic cells with stem cell-like characteristics; and Sca-1, a marker for both skeletal muscle and hematopoietic stem cells. Intramuscular, and more importantly, intravenous injection of mc13 cells result in muscle regeneration and partial restoration of dystrophin in mdx mice. Transplantation of mc13 cells engineered to secrete osteogenic protein differentiate in osteogenic lineage and accelerate healing of a skull defect in SCID mice. Taken together, these results suggest the isolation of a population of muscle-derived stem cells capable of improving both muscle regeneration and bone healing.