Your search keyword '"Shirley Lieu"' showing total 14 results

1. Impaired remodeling phase of fracture repair in the absence of matrix metalloproteinase-2

Author

Shirley Lieu, Erik Hansen, Russell Dedini, Danielle Behonick, Zena Werb, Theodore Miclau, Ralph Marcucio, and Céline Colnot

Subjects

Medicine, Pathology, RB1-214

Abstract

SUMMARY The matrix metalloproteinase (MMP) family of extracellular proteases performs crucial roles in development and repair of the skeleton owing to their ability to remodel the extracellular matrix (ECM) and release bioactive molecules. Most MMP-null skeletal phenotypes that have been previously described are mild, thus permitting the assessment of their functions during bone repair in the adult. In humans and mice, MMP2 deficiency causes a musculoskeletal phenotype. In this study, we assessed the role of MMP2 during mouse fracture repair and compared it with the roles of MMP9 and MMP13. Mmp2 was expressed at low levels in the normal skeleton and was broadly expressed in the fracture callus. Treatment of wild-type mice with a general MMP inhibitor, GM6001, caused delayed cartilage remodeling and bone formation during fracture repair, which resembles the defect observed in Mmp9–/– mice. Unlike Mmp9- and Mmp13-null mutations, which affect both cartilage and bone in the callus, the Mmp2-null mutation delayed bone remodeling but not cartilage remodeling. This remodeling defect occurred without changes in either osteoclast recruitment or vascular invasion of the fracture callus compared with wild type. However, we did not detect changes in expression of Mmp9, Mmp13 or Mt1-Mmp (Mmp14) in the calluses of Mmp2-null mice compared with wild type by in situ hybridization, but we observed decreased expression of Timp2 in the calluses of Mmp2-, Mmp9- and Mmp13-null mice. In keeping with the skeletal phenotype of Mmp2-null mice, MMP2 plays a role in the remodeling of new bone within the fracture callus and impacts later stages of bone repair compared with MMP9 and MMP13. Taken together, our results indicate that MMPs play unique and distinct roles in regulating skeletal tissue deposition and remodeling during fracture repair.

Published

2011

2. Site specific effects of zoledronic acid during tibial and mandibular fracture repair.

Author

Yan Yiu Yu, Shirley Lieu, Diane Hu, Theodore Miclau, and Céline Colnot

Subjects

Medicine, Science

Abstract

Numerous factors can affect skeletal regeneration, including the extent of bone injury, mechanical loading, inflammation and exogenous molecules. Bisphosphonates are anticatabolic agents that have been widely used to treat a variety of metabolic bone diseases. Zoledronate (ZA), a nitrogen-containing bisphosphonate (N-BP), is the most potent bisphosphonate among the clinically approved bisphosphonates. Cases of bisphosphonate-induced osteonecrosis of the jaw have been reported in patients receiving long term N-BP treatment. Yet, osteonecrosis does not occur in long bones. The aim of this study was to compare the effects of zoledronate on long bone and cranial bone regeneration using a previously established model of non-stabilized tibial fractures and a new model of mandibular fracture repair. Contrary to tibial fractures, which heal mainly through endochondral ossification, mandibular fractures healed via endochondral and intramembranous ossification with a lesser degree of endochondral ossification compared to tibial fractures. In the tibia, ZA reduced callus and cartilage formation during the early stages of repair. In parallel, we found a delay in cartilage hypertrophy and a decrease in angiogenesis during the soft callus phase of repair. During later stages of repair, ZA delayed callus, cartilage and bone remodeling. In the mandible, ZA delayed callus, cartilage and bone remodeling in correlation with a decrease in osteoclast number during the soft and hard callus phases of repair. These results reveal a more profound impact of ZA on cartilage and bone remodeling in the mandible compared to the tibia. This may predispose mandible bone to adverse effects of ZA in disease conditions. These results also imply that therapeutic effects of ZA may need to be optimized using time and dose-specific treatments in cranial versus long bones.

Published

2012

3. Role of matrix metalloproteinase 13 in both endochondral and intramembranous ossification during skeletal regeneration.

Author

Danielle J Behonick, Zhiqing Xing, Shirley Lieu, Jenni M Buckley, Jeffrey C Lotz, Ralph S Marcucio, Zena Werb, Theodore Miclau, and Céline Colnot

Subjects

Medicine, Science

Abstract

Extracellular matrix (ECM) remodeling is important during bone development and repair. Because matrix metalloproteinase 13 (MMP13, collagenase-3) plays a role in long bone development, we have examined its role during adult skeletal repair. In this study we find that MMP13 is expressed by hypertrophic chondrocytes and osteoblasts in the fracture callus. We demonstrate that MMP13 is required for proper resorption of hypertrophic cartilage and for normal bone remodeling during non-stabilized fracture healing, which occurs via endochondral ossification. However, no difference in callus strength was detected in the absence of MMP13. Transplant of wild-type bone marrow, which reconstitutes cells only of the hematopoietic lineage, did not rescue the endochondral repair defect, indicating that impaired healing in Mmp13-/- mice is intrinsic to cartilage and bone. Mmp13-/- mice also exhibited altered bone remodeling during healing of stabilized fractures and cortical defects via intramembranous ossification. This indicates that the bone phenotype occurs independently from the cartilage phenotype. Taken together, our findings demonstrate that MMP13 is involved in normal remodeling of bone and cartilage during adult skeletal repair, and that MMP13 may act directly in the initial stages of ECM degradation in these tissues prior to invasion of blood vessels and osteoclasts.

Published

2007

4. Loss of Gi G-Protein-Coupled Receptor Signaling in Osteoblasts Accelerates Bone Fracture Healing

Author

Liping Wang, Edward C. Hsiao, Bruce R. Conklin, Ashley Urrutia, Céline Colnot, Mark J. Scott, Dylan O'Carroll, Shirley Lieu, and Robert A. Nissenson

Subjects

medicine.medical_specialty, Chemistry, Endocrinology, Diabetes and Metabolism, Wnt signaling pathway, Bone healing, Pertussis toxin, G Protein-Coupled Receptor Signaling, Endocrinology, DKK1, Internal medicine, Second messenger system, medicine, Orthopedics and Sports Medicine, Signal transduction, G protein-coupled receptor

Abstract

G-protein-coupled receptors (GPCRs) are key regulators of skeletal homeostasis and are likely important in fracture healing. Because GPCRs can activate multiple signaling pathways simultaneously, we used targeted disruption of G(i) -GPCR or activation of G(s) -GPCR pathways to test how each pathway functions in the skeleton. We previously demonstrated that blockade of G(i) signaling by pertussis toxin (PTX) transgene expression in maturing osteoblastic cells enhanced cortical and trabecular bone formation and prevented age-related bone loss in female mice. In addition, activation of G(s) signaling by expressing the G(s) -coupled engineered receptor Rs1 in maturing osteoblastic cells induced massive trabecular bone formation but cortical bone loss. Here, we test our hypothesis that the G(i) and G(s) pathways also have distinct functions in fracture repair. We applied closed, nonstabilized tibial fractures to mice in which endogenous G(i) signaling was inhibited by PTX, or to mice with activated G(s) signaling mediated by Rs1. Blockade of endogenous G(i) resulted in a smaller callus but increased bone formation in both young and old mice. PTX treatment decreased expression of Dkk1 and increased Lef1 mRNAs during fracture healing, suggesting a role for endogenous G(i) signaling in maintaining Dkk1 expression and suppressing Wnt signaling. In contrast, adult mice with activated Gs signaling showed a slight increase in the initial callus size with increased callus bone formation. These results show that G(i) blockade and G(s) activation of the same osteoblastic lineage cell can induce different biological responses during fracture healing. Our findings also show that manipulating the GPCR/cAMP signaling pathway by selective timing of G(s) and G(i) -GPCR activation may be important for optimizing fracture repair.

Published

2015

5. Delayed Bone Regeneration Is Linked to Chronic Inflammation in Murine Muscular Dystrophy

Author

Shirley Lieu, Marie Mortreux, Frédéric Relaix, Yan Yiu Yu, Céline Colnot, Catia Pereira, Maud Wurmser, Frank Yang, Theodore Miclau, Rana Abou-Khalil, and Ralph S. Marcucio

Subjects

musculoskeletal diseases, Pathology, medicine.medical_specialty, business.industry, Endocrinology, Diabetes and Metabolism, Duchenne muscular dystrophy, Osteoporosis, Anatomy, Bone healing, medicine.disease, Bone remodeling, medicine.anatomical_structure, Osteoclast, medicine, Chronic inflammatory response, Orthopedics and Sports Medicine, Muscular dystrophy, Bone regeneration, business

Abstract

Duchenne muscular dystrophy (DMD) patients exhibit skeletal muscle weakness with continuous cycles of muscle fiber degeneration/regeneration, chronic inflammation, low bone mineral density, and increased risks of fracture. Fragility fractures and associated complications are considered as a consequence of the osteoporotic condition in these patients. Here, we aimed to establish the relationship between muscular dystrophy and fracture healing by assessing bone regeneration in mdx mice, a model of DMD with absence of osteoporosis. Our results illustrate that muscle defects in mdx mice impact the process of bone regeneration at various levels. In mdx fracture calluses, both cartilage and bone deposition were delayed followed by a delay in cartilage and bone remodeling. Vascularization of mdx fracture calluses was also decreased during the early stages of repair. Dystrophic muscles are known to contain elevated numbers of macrophages contributing to muscle degeneration. Accordingly, we observed increased macrophage recruitment in the mdx fracture calluses and abnormal macrophage accumulation throughout the process of bone regeneration. These changes in the inflammatory environment subsequently had an impact on the recruitment of osteoclasts and the remodeling phase of repair. Further damage to the mdx muscles, using a novel model of muscle trauma, amplified both the chronic inflammatory response and the delay in bone regeneration. In addition, PLX3397 treatment of mdx mice, a cFMS (colony stimulating factor receptor 1) inhibitor in monocytes, partially rescued the bone repair defect through increasing cartilage deposition and decreasing the number of macrophages. In conclusion, chronic inflammation in mdx mice contributes to the fracture healing delay and is associated with a decrease in angiogenesis and a transient delay in osteoclast recruitment. By revealing the role of dystrophic muscle in regulating the inflammatory response during bone repair, our results emphasize the implication of muscle in the normal bone repair process and may lead to improved treatment of fragility fractures in DMD patients.

Published

2014

6. Impaired remodeling phase of fracture repair in the absence of matrix metalloproteinase-2

Author

Russell Dedini, Danielle J. Behonick, Zena Werb, Erik N. Hansen, Theodore Miclau, Shirley Lieu, Céline Colnot, and Ralph S. Marcucio

Subjects

Neuroscience (miscellaneous), Medicine (miscellaneous), lcsh:Medicine, Bone healing, Matrix metalloproteinase, Biology, General Biochemistry, Genetics and Molecular Biology, Bone remodeling, Extracellular matrix, 03 medical and health sciences, Mice, 0302 clinical medicine, Immunology and Microbiology (miscellaneous), Osteoclast, Osteogenesis, Matrix Metalloproteinase 13, medicine, lcsh:Pathology, Animals, Humans, 030304 developmental biology, Fracture Healing, 0303 health sciences, Tissue Inhibitor of Metalloproteinase-2, Cartilage, lcsh:R, Wild type, Anatomy, Dipeptides, Cell biology, body regions, medicine.anatomical_structure, Matrix Metalloproteinase 9, 030220 oncology & carcinogenesis, MMP14, Matrix Metalloproteinase 2, Bone Remodeling, Biomarkers, Research Article, lcsh:RB1-214

Abstract

SUMMARY The matrix metalloproteinase (MMP) family of extracellular proteases performs crucial roles in development and repair of the skeleton owing to their ability to remodel the extracellular matrix (ECM) and release bioactive molecules. Most MMP-null skeletal phenotypes that have been previously described are mild, thus permitting the assessment of their functions during bone repair in the adult. In humans and mice, MMP2 deficiency causes a musculoskeletal phenotype. In this study, we assessed the role of MMP2 during mouse fracture repair and compared it with the roles of MMP9 and MMP13. Mmp2 was expressed at low levels in the normal skeleton and was broadly expressed in the fracture callus. Treatment of wild-type mice with a general MMP inhibitor, GM6001, caused delayed cartilage remodeling and bone formation during fracture repair, which resembles the defect observed in Mmp9–/– mice. Unlike Mmp9- and Mmp13-null mutations, which affect both cartilage and bone in the callus, the Mmp2-null mutation delayed bone remodeling but not cartilage remodeling. This remodeling defect occurred without changes in either osteoclast recruitment or vascular invasion of the fracture callus compared with wild type. However, we did not detect changes in expression of Mmp9, Mmp13 or Mt1-Mmp (Mmp14) in the calluses of Mmp2-null mice compared with wild type by in situ hybridization, but we observed decreased expression of Timp2 in the calluses of Mmp2-, Mmp9- and Mmp13-null mice. In keeping with the skeletal phenotype of Mmp2-null mice, MMP2 plays a role in the remodeling of new bone within the fracture callus and impacts later stages of bone repair compared with MMP9 and MMP13. Taken together, our results indicate that MMPs play unique and distinct roles in regulating skeletal tissue deposition and remodeling during fracture repair.

Published

2011

7. Immunolocalization of BMPs, BMP antagonists, receptors, and effectors during fracture repair

Author

Yan Yiu Yu, Theodore Miclau, Chuanyong Lu, Ralph S. Marcucio, Shirley Lieu, and Céline Colnot

Subjects

animal structures, Histology, Physiology, Endocrinology, Diabetes and Metabolism, Osteoclasts, Bone healing, Bone morphogenetic protein, Bone morphogenetic protein 2, Chondrocyte, Fractures, Bone, Mice, Chondrocytes, medicine, Animals, BMP signaling pathway, Endochondral ossification, Fracture Healing, Inflammation, Osteoblasts, Tibia, Chemistry, Bone Morphogenetic Protein Receptors, Anatomy, Immunohistochemistry, BMPR2, Cell biology, Mice, Inbred C57BL, medicine.anatomical_structure, Bone Morphogenetic Proteins, embryonic structures, Intramembranous ossification, Signal Transduction

Abstract

Bone morphogenetic proteins (BMPs) are potent bone inducers used clinically to enhance fracture repair. BMPs have been shown to be produced in the fracture callus; however, the comparative expression of BMPs and BMP signaling components has only been partially examined at the cellular level. The aim of the present study was to establish a detailed spatiotemporal localization of BMPs and BMP signaling components in mouse models of stabilized and nonstabilized fractures. During healing of nonstabilized fractures, which occurs via endochondral ossification, BMP2, 3, 4, 5, and 8, noggin, BMPRIA, BMPRII, and pSmad 1/5/8 were immunolocalized in the activated periosteum as early as 3 days after fracture. BMP2, 4, 5, 6, 7, and 8 and noggin were also found in isolated inflammatory cells within granulation tissue during the early stages of repair, but not BMP receptors and effectors. During the soft callus phase of repair, all BMPs and BMP signaling components were detected in chondrocytes with various intensities of staining depending on the stage of chondrocyte differentiation and their location in the callus. The strongest staining was observed in hypertrophic chondrocytes with decreased intensity during the hard callus phase of repair. All BMPs and components of the BMP pathway were detected in osteoblasts and osteocytes within new bone, with strongest intensity of immunoreaction reported during the early soft callus phase followed by decreasing intensity during the hard callus phase of repair. Most components of the BMP pathway were also detected in endothelial cells associated with new bone. In stabilized fractures that heal strictly via intramembranous ossification, BMPs and BMP antagonists were detected in isolated inflammatory cells and BMP signaling components were not detectable in osteoblasts or osteocytes within new bone. In conclusion, the BMP signaling pathway is primarily activated during fracture healing via endochondral ossification, suggesting that this pathway may influence the mode of healing during the recruitment of skeletal progenitors.

Published

2010

8. Loss of Gi G-Protein-Coupled Receptor Signaling in Osteoblasts Accelerates Bone Fracture Healing

Author

Liping, Wang, Edward C, Hsiao, Shirley, Lieu, Mark, Scott, Dylan, O'Carroll, Ashley, Urrutia, Bruce R, Conklin, Celine, Colnot, and Robert A, Nissenson

Subjects

Fracture Healing, Fractures, Bone, Mice, Osteoblasts, Lymphoid Enhancer-Binding Factor 1, Cyclic AMP, Animals, Intercellular Signaling Peptides and Proteins, Female, Mice, Transgenic, GTP-Binding Protein alpha Subunits, Gi-Go, Second Messenger Systems, Receptors, G-Protein-Coupled

Abstract

G-protein-coupled receptors (GPCRs) are key regulators of skeletal homeostasis and are likely important in fracture healing. Because GPCRs can activate multiple signaling pathways simultaneously, we used targeted disruption of G(i) -GPCR or activation of G(s) -GPCR pathways to test how each pathway functions in the skeleton. We previously demonstrated that blockade of G(i) signaling by pertussis toxin (PTX) transgene expression in maturing osteoblastic cells enhanced cortical and trabecular bone formation and prevented age-related bone loss in female mice. In addition, activation of G(s) signaling by expressing the G(s) -coupled engineered receptor Rs1 in maturing osteoblastic cells induced massive trabecular bone formation but cortical bone loss. Here, we test our hypothesis that the G(i) and G(s) pathways also have distinct functions in fracture repair. We applied closed, nonstabilized tibial fractures to mice in which endogenous G(i) signaling was inhibited by PTX, or to mice with activated G(s) signaling mediated by Rs1. Blockade of endogenous G(i) resulted in a smaller callus but increased bone formation in both young and old mice. PTX treatment decreased expression of Dkk1 and increased Lef1 mRNAs during fracture healing, suggesting a role for endogenous G(i) signaling in maintaining Dkk1 expression and suppressing Wnt signaling. In contrast, adult mice with activated Gs signaling showed a slight increase in the initial callus size with increased callus bone formation. These results show that G(i) blockade and G(s) activation of the same osteoblastic lineage cell can induce different biological responses during fracture healing. Our findings also show that manipulating the GPCR/cAMP signaling pathway by selective timing of G(s) and G(i) -GPCR activation may be important for optimizing fracture repair.

Published

2014

9. Role of muscle stem cells during skeletal regeneration

Author

Frédéric Relaix, Rana Abou-Khalil, Theodore Miclau, Jaselle Perry, Catia Pereira, Ralph S. Marcucio, Frank Yang, Shirley Lieu, Anaïs Julien, and Céline Colnot

Subjects

Satellite Cells, Skeletal Muscle, Callus formation, medicine.medical_treatment, Bone healing, Biology, Bone morphogenetic protein, Fibroblast growth factor, Bone and Bones, Myoblasts, Periosteum, medicine, Animals, Humans, Regeneration, Bony Callus, Bone regeneration, Muscle, Skeletal, Stem cell transplantation for articular cartilage repair, Growth factor, Stem Cells, Cell Biology, Anatomy, Cell biology, Mice, Inbred C57BL, Molecular Medicine, Stem cell, Developmental Biology

Abstract

Although the importance of muscle in skeletal regeneration is well recognized clinically, the mechanisms by which muscle supports bone repair have remained elusive. Muscle flaps are often used to cover the damaged bone after traumatic injury yet their contribution to bone healing is not known. Here, we show that direct bone-muscle interactions are required for periosteum activation and callus formation, and that muscle grafts provide a source of stem cells for skeletal regeneration. We investigated the role of satellite cells, the muscle stem cells. Satellite cells loss in Pax7−/− mice and satellite cell ablation in Pax7CreERT2/+;DTAf/f mice impaired bone regeneration. Although satellite cells did not contribute as a large source of cells endogenously, they exhibited a potential to contribute to bone repair after transplantation. The fracture healing phenotype in Pax7CreERT2/+;DTAf/f mice was associated with decreased bone morphogenetic proteins (BMPs), insulin-like growth factor 1, and fibroblast growth factor 2 expression that are normally upregulated in response to fracture in satellite cells. Exogenous rhBMP2 improved bone healing in Pax7CreERT2/+;DTAf/f mice further supporting the role of satellite cells as a source of growth factors. These results provide the first functional evidence for a direct contribution of muscle to bone regeneration with important clinical implications as it may impact the use of muscle flaps, muscle stem cells, and growth factors in orthopedic applications. Stem Cells 2015;33:1501–1511

Published

2014

10. Delayed bone regeneration is linked to chronic inflammation in murine muscular dystrophy

Author

Rana, Abou-Khalil, Frank, Yang, Marie, Mortreux, Shirley, Lieu, Yan-Yiu, Yu, Maud, Wurmser, Catia, Pereira, Frédéric, Relaix, Theodore, Miclau, Ralph S, Marcucio, and Céline, Colnot

Subjects

musculoskeletal diseases, Inflammation, Bone Regeneration, Osteoclasts, Muscular Dystrophy, Animal, Monocytes, Article, Muscular Dystrophy, Duchenne, Mice, Cartilage, Chronic Disease, Mice, Inbred mdx, Animals, Humans

Abstract

Duchenne muscular dystrophy (DMD) patients exhibit skeletal muscle weakness with continuous cycles of muscle fiber degeneration/regeneration, chronic inflammation, low bone mineral density, and increased risks of fracture. Fragility fractures and associated complications are considered as a consequence of the osteoporotic condition in these patients. Here, we aimed to establish the relationship between muscular dystrophy and fracture healing by assessing bone regeneration in mdx mice, a model of DMD with absence of osteoporosis. Our results illustrate that muscle defects in mdx mice impact the process of bone regeneration at various levels. In mdx fracture calluses, both cartilage and bone deposition were delayed followed by a delay in cartilage and bone remodeling. Vascularization of mdx fracture calluses was also decreased during the early stages of repair. Dystrophic muscles are known to contain elevated numbers of macrophages contributing to muscle degeneration. Accordingly, we observed increased macrophage recruitment in the mdx fracture calluses and abnormal macrophage accumulation throughout the process of bone regeneration. These changes in the inflammatory environment subsequently had an impact on the recruitment of osteoclasts and the remodeling phase of repair. Further damage to the mdx muscles, using a novel model of muscle trauma, amplified both the chronic inflammatory response and the delay in bone regeneration. In addition, PLX3397 treatment of mdx mice, a cFMS (colony stimulating factor receptor 1) inhibitor in monocytes, partially rescued the bone repair defect through increasing cartilage deposition and decreasing the number of macrophages. In conclusion, chronic inflammation in mdx mice contributes to the fracture healing delay and is associated with a decrease in angiogenesis and a transient delay in osteoclast recruitment. By revealing the role of dystrophic muscle in regulating the inflammatory response during bone repair, our results emphasize the implication of muscle in the normal bone repair process and may lead to improved treatment of fragility fractures in DMD patients.

Published

2013

11. MMP9 regulates the cellular response to inflammation after skeletal injury

Author

Ralph S. Marcucio, Chuanyong Lu, Theodore Miclau, Jeffrey Lang, Xiaodong Wang, Frank Yang, Céline Colnot, Diane Hu, Yan Yiu Yu, Zena Werb, and Shirley Lieu

Subjects

Male, Macrophage, Physiology, Endocrinology, Diabetes and Metabolism, Cellular differentiation, Mechanical environment, Cell Separation, Regenerative Medicine, Mouse models, Medical and Health Sciences, Mice, Engineering, 2.1 Biological and endogenous factors, Aetiology, Bone Marrow Transplantation, Mice, Knockout, Biological Sciences, Cell biology, medicine.anatomical_structure, Matrix Metalloproteinase 9, Intramembranous ossification, Stem Cell Research - Nonembryonic - Non-Human, medicine.symptom, Physical Injury - Accidents and Adverse Effects, Histology, Knockout, 1.1 Normal biological development and functioning, Inflammation, Bone healing, Biology, Bone morphogenetic protein 2, Article, Bone and Bones, Endocrinology & Metabolism, Underpinning research, Periosteum, medicine, Animals, Endochondral ossification, Transplantation, Fracture repair, Inflammatory and immune system, Cartilage, Stem Cell Research, Matrix metalloproteinase, body regions, Musculoskeletal, Immunology, Bone marrow

Abstract

Like other tissue injuries, bone fracture triggers an inflammatory response, which plays an important role in skeletal repair. Inflammation is believed to have both positive and negative effects on bone repair, but the underlying cellular mechanisms are not well understood. To assess the role of inflammation on skeletal cell differentiation, we used mouse models of fracture repair that stimulate either intramembranous or endochondral ossification. In the first model, fractures are rigidly stabilized leading to direct bone formation, while in the second model, fracture instability causes cartilage and bone formation. We compared the inflammatory response in these two mechanical environments and found changes in the expression patterns of inflammatory genes and in the recruitment of inflammatory cells and osteoclasts. These results suggested that the inflammatory response could influence skeletal cell differentiation after fracture. We then exploited matrix metalloproteinase 9 (MMP9) that is expressed in inflammatory cells and osteoclasts, and which we previously showed is a potential regulator of cell fate decisions during fracture repair. Mmp9(-/-) mice heal stabilized fractures via endochondral ossification, while wild type mice heal via intramembranous ossification. In parallel, we observed increases in macrophages and T cells in the callus of Mmp9(-/-) compared to wild type mice. To assess the link between the profile of inflammatory cells and skeletal cell fate functionally, we transplanted Mmp9(-/-) mice with wild type bone marrow, to reconstitute a wild type hematopoietic lineage in interaction with the Mmp9(-/-) stroma and periosteum. Following transplantation, Mmp9(-/-) mice healed stabilized fractures via intramembranous ossification and exhibited a normal profile of inflammatory cells. Moreover, Mmp9(-/-) periosteal grafts healed via intramembranous ossification in wild type hosts, but healed via endochondral ossification in Mmp9(-/-) hosts. We observed that macrophages accumulated at the periosteal surface in Mmp9(-/-) mice, suggesting that cell differentiation in the periosteum is influenced by factors such as BMP2 that are produced locally by inflammatory cells. Taken together, these results show that MMP9 mediates indirect effects on skeletal cell differentiation by regulating the inflammatory response and the distribution of inflammatory cells, leading to the local regulation of periosteal cell differentiation.

Published

2012

12. Bone morphogenetic protein 2 stimulates endochondral ossification by regulating periosteal cell fate during bone repair

Author

Céline Colnot, Chuanyong Lu, Yan Yiu Yu, and Shirley Lieu

Subjects

Male, Pathology, medicine.medical_specialty, Histology, animal structures, Physiology, Endocrinology, Diabetes and Metabolism, Bone Morphogenetic Protein 2, Neovascularization, Physiologic, Osteoclasts, Bone healing, Biology, Bone morphogenetic protein, Article, Fractures, Bone, Mice, Osteogenesis, Periosteum, Bone cell, medicine, Animals, Humans, Cell Lineage, Bone regeneration, Endochondral ossification, Cell Proliferation, Endosteum, Fracture Healing, Bone Transplantation, Ossification, Recombinant Proteins, Cell biology, Mice, Inbred C57BL, Cartilage, Intramembranous ossification, embryonic structures, Bone Remodeling, medicine.symptom, Chondrogenesis

Abstract

Bone repair depends on the coordinated action of numerous growth factors and cytokines to stimulate new skeletal tissue formation. Among all the growth factors involved in bone repair, Bone Morphogenetic Proteins (BMPs) are the only molecules now used therapeutically to enhance healing. Although BMPs are known as strong bone inducers, their role in initiating skeletal repair is not entirely elucidated. The aim of this study was to define the role of BMP2 during the early stages of bone regeneration and more specifically in regulating the fate of skeletal progenitors. During healing of non-stabilized fractures via endochondral ossification, exogenous BMP2 increased the deposition and resorption of cartilage and bone, which was correlated with a stimulation of osteoclastogenesis but not angiogenesis in the early phase of repair. During healing of stabilized fractures, which normally occurs via intramembranous ossification, exogenous BMP2 induced cartilage formation suggesting a role in regulating cell fate decisions. Specifically, the periosteum was found to be a target of exogenous BMP2 as shown by activation of the BMP pathway in this tissue. Using cell lineage analyses, we further show that BMP2 can direct cell differentiation towards the chondrogenic lineage within the periosteum but not the endosteum, indicating that skeletal progenitors within periosteum and endosteum respond differently to BMP signals. In conclusion, BMP2 plays an important role in the early stages of repair by recruiting local sources of skeletal progenitors within periosteum and endosteum and by determining their differentiation towards the chondrogenic and osteogenic lineages.

Published

2010

13. Role of matrix metalloproteinase 13 in both endochondral and intramembranous ossification during skeletal regeneration

Author

Céline Colnot, Theodore Miclau, Jenni M. Buckley, Ralph S. Marcucio, Shirley Lieu, Zhiqing Xing, Jeffrey C. Lotz, Zena Werb, Danielle J. Behonick, and Steinhardt, Richard

Subjects

Bone remodeling period, Bone Regeneration, General Science & Technology, Physiology, Knockout, lcsh:Medicine, 030209 endocrinology & metabolism, Bone healing, Regenerative Medicine, Bone remodeling, 03 medical and health sciences, Mice, 0302 clinical medicine, Osteogenesis, Bone cell, Matrix Metalloproteinase 13, medicine, 2.1 Biological and endogenous factors, Animals, Aetiology, lcsh:Science, Bone regeneration, Endochondral ossification, 030304 developmental biology, Fracture Healing, Mice, Knockout, 0303 health sciences, Multidisciplinary, Ossification, lcsh:R, Anatomy, Cell Biology, Cell biology, Musculoskeletal, Intramembranous ossification, lcsh:Q, medicine.symptom, Surgery/Orthopedics and Sports Medicine, Research Article

Abstract

Extracellular matrix (ECM) remodeling is important during bone development and repair. Because matrix metalloproteinase 13 (MMP13, collagenase-3) plays a role in long bone development, we have examined its role during adult skeletal repair. In this study we find that MMP13 is expressed by hypertrophic chondrocytes and osteoblasts in the fracture callus. We demonstrate that MMP13 is required for proper resorption of hypertrophic cartilage and for normal bone remodeling during non-stabilized fracture healing, which occurs via endochondral ossification. However, no difference in callus strength was detected in the absence of MMP13. Transplant of wild-type bone marrow, which reconstitutes cells only of the hematopoietic lineage, did not rescue the endochondral repair defect, indicating that impaired healing in Mmp13-/- mice is intrinsic to cartilage and bone. Mmp13-/- mice also exhibited altered bone remodeling during healing of stabilized fractures and cortical defects via intramembranous ossification. This indicates that the bone phenotype occurs independently from the cartilage phenotype. Taken together, our findings demonstrate that MMP13 is involved in normal remodeling of bone and cartilage during adult skeletal repair, and that MMP13 may act directly in the initial stages of ECM degradation in these tissues prior to invasion of blood vessels and osteoclasts.

Published

2007

14. Site Specific Effects of Zoledronic Acid during Tibial and Mandibular Fracture Repair

Author

Theodore Miclau, Diane Hu, Shirley Lieu, Yan Yiu Yu, and Céline Colnot

Subjects

Male, medicine.medical_specialty, Anatomy and Physiology, Long bone, lcsh:Medicine, Dentistry, 030209 endocrinology & metabolism, Zoledronic Acid, Bone remodeling, Mice, 03 medical and health sciences, Model Organisms, 0302 clinical medicine, Mandibular Fractures, medicine, Animals, Regeneration, lcsh:Science, Biology, Musculoskeletal System, Endochondral ossification, 030304 developmental biology, Fracture Healing, 0303 health sciences, Multidisciplinary, Bone Density Conservation Agents, Diphosphonates, business.industry, Ossification, Bone Injury, lcsh:R, Imidazoles, Osteonecrosis, Bone fracture, medicine.disease, Surgery, Mice, Inbred C57BL, Tibial Fractures, Cartilage, medicine.anatomical_structure, Intramembranous ossification, lcsh:Q, Bone Remodeling, medicine.symptom, Osteonecrosis of the jaw, business, Research Article

Abstract

Numerous factors can affect skeletal regeneration, including the extent of bone injury, mechanical loading, inflammation and exogenous molecules. Bisphosphonates are anticatabolic agents that have been widely used to treat a variety of metabolic bone diseases. Zoledronate (ZA), a nitrogen-containing bisphosphonate (N-BP), is the most potent bisphosphonate among the clinically approved bisphosphonates. Cases of bisphosphonate-induced osteonecrosis of the jaw have been reported in patients receiving long term N-BP treatment. Yet, osteonecrosis does not occur in long bones. The aim of this study was to compare the effects of zoledronate on long bone and cranial bone regeneration using a previously established model of non-stabilized tibial fractures and a new model of mandibular fracture repair. Contrary to tibial fractures, which heal mainly through endochondral ossification, mandibular fractures healed via endochondral and intramembranous ossification with a lesser degree of endochondral ossification compared to tibial fractures. In the tibia, ZA reduced callus and cartilage formation during the early stages of repair. In parallel, we found a delay in cartilage hypertrophy and a decrease in angiogenesis during the soft callus phase of repair. During later stages of repair, ZA delayed callus, cartilage and bone remodeling. In the mandible, ZA delayed callus, cartilage and bone remodeling in correlation with a decrease in osteoclast number during the soft and hard callus phases of repair. These results reveal a more profound impact of ZA on cartilage and bone remodeling in the mandible compared to the tibia. This may predispose mandible bone to adverse effects of ZA in disease conditions. These results also imply that therapeutic effects of ZA may need to be optimized using time and dose-specific treatments in cranial versus long bones.

Published

2012