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11. αSMA Osteoprogenitor Cells Contribute to the Increase in Osteoblast Numbers in Response to Mechanical Loading.

Author

Matthews, B. G., Wee, N. K. Y., Widjaja, V. N., Price, J. S., Kalajzic, I., and Windahl, S. H.

Subjects
PERIOSTEUM, OSTEOBLASTS, COMPACT bone, AXIAL loads, CELLS, BONE growth, TIBIA, OSTEOBLAST metabolism, MUSCLE protein metabolism, CELL differentiation, RESEARCH, ANIMAL experimentation, RESEARCH methodology, PHYSIOLOGIC strain, CELL physiology, MEDICAL cooperation, EVALUATION research, COMPARATIVE studies, STEM cells, WEIGHT-bearing (Orthopedics), MICE
Abstract

Bone is a dynamic tissue that site-specifically adapts to the load that it experiences. In response to increasing load, the cortical bone area is increased, mainly through enhanced periosteal bone formation. This increase in area is associated with an increase in the number of bone-forming osteoblasts; however, the origin of the cells involved remains unclear. Alpha-smooth muscle actin (αSMA) is a marker of early osteoprogenitor cells in the periosteum, and we hypothesized that the new osteoblasts that are activated by loading could originate from αSMA-expressing cells. Therefore, we used an in vivo fate-mapping approach in an established axial loading model to investigate the role of αSMA-expressing cells in the load-induced increase in osteoblasts. Histomorphometric analysis was applied to measure the number of cells of different origin on the periosteal surface in the most load-responsive region of the mouse tibia. A single loading session failed to increase the number of periosteal αSMA-expressing cells and osteoblasts. However, in response to multiple episodes of loading, the caudal, but not the cranial, periosteal surface was lined with an increased number of osteoblasts originating from αSMA-expressing cells 5 days after the initial loading session. The proportion of osteoblasts derived from αSMA-labeled progenitors increased by 70% (p < 0.05), and the proportion of αSMA-labeled cells that had differentiated into osteoblasts was doubled. We conclude that αSMA-expressing osteoprogenitors can differentiate and contribute to the increase in periosteal osteoblasts induced by mechanical loading in a site-specific manner. [ABSTRACT FROM AUTHOR]

Published
2020
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14. Roles of parathyroid hormone (PTH) receptor and reactive oxygen species in hyperlipidemia-induced PTH resistance in preosteoblasts

Author

Li, X, Garcia, J, Lu, J, Iriana, S, Kalajzic, I, Rowe, D, Demer, LL, and Tintut, Y

Subjects
Biochemistry & Molecular Biology, BIOACTIVE LIPIDS, Cells, Medical Physiology, Green Fluorescent Proteins, PREOSTEOBLASTS, Hyperlipidemias, Cardiovascular, Osteocytes, Transgenic, LDL, Mice, Receptors, 2.1 Biological and endogenous factors, Animals, REACTIVE OXYGEN SPECIES, Aetiology, Chromans, HYPERLIPIDEMIA, Inflammation, Cultured, Osteoblasts, PTH RECEPTOR, Atherosclerosis, Mutant Strains, Parathyroid Hormone, Osteoporosis, Female, Biochemistry and Cell Biology, Receptor, Type 1
Abstract

Bioactive lipids initiate inflammatory reactions leading to pathogenesis of atherosclerosis. Evidence shows that they also contribute to bone loss by inhibiting parathyroid hormone receptor (PTH1R) expression and differentiation of osteoblasts. We previously demonstrated that bone anabolic effects of PTH(1-34) are blunted in hyperlipidemic mice and that these PTH effects are restored by antioxidants. However, it is not clear which osteoblastic cell developmental stage is targeted by bioactive lipids. To investigate the effects of hyperlipidemia at the cellular level, hyperlipidemic Ldlr-/- mice were bred with Col3.6GFPtpz mice, in which preosteoblasts/osteoblasts carry a topaz fluorescent label, and with Col2.3GFPcyan mice, in which more mature osteoblasts/osteocytes carry a cyan fluorescent label. Histological analyses of trabecular bone surfaces in femoral as well as calvarial bones showed that intermittent PTH(1-34) increased fluorescence intensity in WT-Tpz mice, but not in Tpz-Ldlr-/- mice. In contrast, PTH(1-34) did not alter fluorescence intensity in femoral cortical envelopes of either WT-Cyan or Ldlr-/--Cyan mice. To test the mechanism of PTH1R downregulation, preosteoblastic MC3T3-E1 cells were treated with bioactive lipids and the antioxidant Trolox. Results showed that inhibitory effects of PTH1R levels by bioactive lipids were rescued by pretreatment with Trolox. The inhibitory effects on expression of PTH1R as well as on PTH-induced osteoblastic genes were mimicked by xanthine/xanthine oxidase, a known generator of reactive oxygen species. These findings suggest an important role of the preosteoblastic development stage as the target and downregulation of PTH receptor expression mediated by intracellular oxidant stress as a mechanism in hyperlipidemia- induced PTH resistance. © 2013 Wiley Periodicals, Inc. © 2013 Wiley Periodicals, Inc.

Published
2014

16. FGF2 Enhances Odontoblast Differentiation by αSMA+ Progenitors In Vivo.

Author

Vidovic-Zdrilic, I., Vining, K. H., Vijaykumar, A., Kalajzic, I., Mooney, D. J., and Mina, M.

Subjects
FIBROBLAST growth factor 2, ODONTOBLASTS, CELL differentiation, ACTIN research, SMOOTH muscle proteins, PROGENITOR cells, IN vivo studies, FATE mapping (Genetics), WOUNDS & injuries, ANIMALS, CONNECTIVE tissue cells, FLOW cytometry, GENE expression, GROWTH factors, IN situ hybridization, MICE
Abstract

The goal of this study was to examine the effects of early and limited exposure of perivascular cells expressing α (αSMA) to fibroblast growth factor 2 (FGF2) in vivo. We performed in vivo fate mapping by inducible Cre-loxP and experimental pulp injury in molars to induce reparative dentinogenesis. Our results demonstrate that early delivery of exogenous FGF2 to exposed pulp led to proliferative expansion of αSMA-tdTomato+ cells and their accelerated differentiation into odontoblasts. In vivo lineage-tracing experiments showed that the calcified bridge/reparative dentin in FGF2-treated pulps were lined with an increased number of Dspp+ odontoblasts and devoid of BSP+ osteoblasts. The increased number of odontoblasts derived from αSMA-tdTomato+ cells and the formation of reparative dentin devoid of osteoblasts provide in vivo evidence for the stimulatory effects of FGF signaling on odontoblast differentiation from early progenitors in dental pulp. [ABSTRACT FROM AUTHOR]

Published
2018
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17. Bone-specific overexpression of NPY modulates osteogenesis

Author

Matic, I., Brya G. Matthews, Kizivat, T., Igwe, J. C., Marijanovic, I., Ruohonen, S. T., Savontaus, E., Adams, D. J., and Kalajzic, I.

Subjects
Mice, Osteoblasts, Osteogenesis, mental disorders, Animals, Mice, Transgenic, Neuropeptide Y, Osteoblast, Osteocyte, Col2.3 promoter, Osteocytes, humanities, Article, Bone and Bones
Abstract

Neuropeptide Y (NPY) is a peptide involved in the regulation of appetite and energy homeostasis. Genetic data indicates that NPY decreases bone formation via central and peripheral activities. NPY is produced by various cell types including osteocytes and osteoblasts and there is evidence suggesting that peripheral NPY is important for regulation of bone formation. We sought to investigate the role of bone-derived NPY in bone metabolism. We generated a mouse where NPY was over-expressed specifically in mature osteoblasts and osteocytes (Col2.3NPY) and characterized the bone phenotype of these mice in vivo and in vitro. Trabecular and cortical bone volume was reduced in 3-month-old animals, however bone formation rate and osteoclast activity were not significantly changed. Calvarial osteoblast cultures from Col2.3NPY mice also showed reduced mineralization and expression of osteogenic marker genes. Our data suggest that osteoblast/osteocyte-derived NPY is capable of altering osteogenesis in vivo and in vitro and may represent an important source of NPY for regulation of bone formation. However, it is possible that other peripheral sources of NPY such as the sympathetic nervous system and vasculature also contribute to peripheral regulation of bone turnover.

Published
2012

22. αSMA-Expressing Perivascular Cells Represent Dental Pulp Progenitors In Vivo.

Author

Vidovic, I., Banerjee, A., Fatahi, R., Matthews, B. G., Dyment, N. A., Kalajzic, I., and Mina, M.

Subjects
DENTAL pulp, PROGENITOR cells, ODONTOBLASTS, DENTIN, LABORATORY mice, FATE mapping (Genetics), DENTINOGENESIS, MOLARS, CONNECTIVE tissue cells, MUSCLE protein metabolism, OSTEOBLASTS, ANIMAL experimentation, ANIMALS, CELL differentiation, GENES, IMMUNOHISTOCHEMISTRY, MICE, RESEARCH funding, FETAL development, PHYSIOLOGY
Abstract

The goal of this study was to examine the contribution of perivascular cells to odontoblasts during the development, growth, and repair of dentin using mouse molars as a model. We used an inducible, Cre-loxP in vivo fate-mapping approach to examine the contributions of the descendants of cells expressing the αSMA-CreERT2 transgene to the odontoblast lineage. In vivo lineage-tracing experiments in molars showed the contribution of αSMA-tdTomato+ cells to a small number of newly formed odontoblasts during primary dentinogenesis. Using an experimental pulp exposure model in molars to induce reparative dentinogenesis, we demonstrate the contribution of αSMA-tdTomato+ cells to cells secreting reparative dentin. Our results demonstrate that αSMA-tdTomato+ cells differentiated into Col2.3-GFP+ cells composed of both Dspp+ odontoblasts and Bsp+ osteoblasts. Our findings identify a population of mesenchymal progenitor cells capable of giving rise to a second generation of odontoblasts during reparative dentinogenesis. This population also makes a small contribution to odontoblasts during primary dentinogenesis. [ABSTRACT FROM AUTHOR]

Published
2017
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23. Calcitonin impairs the anabolic effect of PTH in young rats and stimulates expression of sclerostin by osteocytes

Author

Gooi, JH, Pompolo, S, Karsdal, MA, Kulkarni, NH, Kalajzic, I, McAhren, SHM, Han, B, Onyia, JE, Ho, PWM, Gillespie, MT, Walsh, NC, Chia, LY, Quinn, JMW, Martin, TJ, Sims, NA, Gooi, JH, Pompolo, S, Karsdal, MA, Kulkarni, NH, Kalajzic, I, McAhren, SHM, Han, B, Onyia, JE, Ho, PWM, Gillespie, MT, Walsh, NC, Chia, LY, Quinn, JMW, Martin, TJ, and Sims, NA

Abstract

The therapeutic goal of increasing bone mass by co-treatment of parathyroid hormone (PTH) and an osteoclast inhibitor has been complicated by the undefined contribution of osteoclasts to the anabolic activity of PTH. To determine whether active osteoclasts are required at the time of PTH administration, we administered a low dose of the transient osteoclast inhibitor salmon calcitonin (sCT) to young rats receiving an anabolic PTH regimen. Co-administration of sCT significantly blunted the anabolic effect of PTH as measured by peripheral quantitative computer tomography (pQCT) and histomorphometry in the femur and tibia, respectively. To determine gene targets of sCT, we carried out quantitative real time PCR and microarray analysis of metaphyseal samples 1.5, 4 and 6.5h after administration of a single injection of PTH, sCT or PTH+sCT. Known targets of PTH action, IL-6, ephrinB2 and RANKL, were not modified by co-administration with sCT. Surprisingly, at all time points, we noted a significant upregulation of sclerostin mRNA by sCT treatment, as well as down-regulation of two other osteocyte gene products, MEPE and DMP1. Immunohistochemistry confirmed that sCT administration increased the percentage of osteocytes expressing sclerostin, suggesting a mechanism by which sCT reduced the anabolic effect of PTH. Neither mRNA for CT receptor (Calcr) nor labeled CT binding could be detected in sclerostin-enriched cells differentiated from primary calvarial osteoblasts. In contrast, osteocytes freshly isolated from calvariae expressed a high level of Calcr mRNA. Furthermore immunohistochemistry revealed co-localization of CT receptor (CTR) and sclerostin in some osteocytes in calvarial sections. Taken together these data indicate that co-treatment with sCT can blunt the anabolic effect of PTH and this may involve direct stimulation of sclerostin production by osteocytes. These data directly implicate calcitonin as a negative regulator of bone formation through a previously u

Published
2010

25. Bmp2 gene in osteoblasts of periosteum and trabecular bone links bone formation to vascularization and mesenchymal stem cells

Author

Yang, W., primary, Guo, D., additional, Harris, M.A., additional, Cui, Y., additional, Gluhak-Heinrich, J., additional, Wu, J., additional, Chen, X.-D., additional, Skinner, C, additional, Nyman, J., additional, Edwards, J.R., additional, Mundy, G.R., additional, Lichtler, A., additional, Kream, B., additional, Rowe, D., additional, Kalajzic, I., additional, David, V., additional, Quarles, D., additional, Villareal, D., additional, Scott, Greg, additional, Ray, Manas, additional, Liu, S., additional, Martin, J.F., additional, Mishina, Y., additional, and Harris, S.E., additional

Published
2013
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34. αSMA-Expressing Perivascular Cells Represent Dental Pulp Progenitors In Vivo

Author

Vidovic Zdrilić, Ivana, Banerjee, A., Fatahi, R., Matthews, B.G., Dyment, N.A., Kalajzic, I., Mina, M. Vidović, Ivana, and Mina, M.

Subjects
0301 basic medicine, BIOMEDICINA I ZDRAVSTVO. Dentalna medicina, Population, Dentistry, Mice, Transgenic, Mice, 03 medical and health sciences, 0302 clinical medicine, Dentin sialophosphoprotein, stomatognathic system, stem cells, dentin sialophosphoprotein, odontoblasts, Dentin, medicine, Animals, BIOMEDICINE AND HEALTHCARE. Dental Medicine, Transgenes, education, General Dentistry, Dental Pulp, education.field_of_study, Osteoblasts, Chemistry, business.industry, Cell Differentiation, Mesenchymal Stem Cells, Research Reports, 030206 dentistry, Amelogenesis, odontoblasts, pulp biology, dentinogenesis, reparative dentin, stem cells, dentin sialophosphoprotein, Immunohistochemistry, Molar, Actins, reparative dentin, Cell biology, pulp biology, dentinogenesis, 030104 developmental biology, medicine.anatomical_structure, Odontoblast, Dentinogenesis, Pulp (tooth), Stem cell, business
Abstract

The goal of this study was to examine the contribution of perivascular cells to odontoblasts during the development, growth, and repair of dentin using mouse molars as a model. We used an inducible, Cre-loxP in vivo fate-mapping approach to examine the contributions of the descendants of cells expressing the αSMA-CreERT2 transgene to the odontoblast lineage. In vivo lineage-tracing experiments in molars showed the contribution of αSMA-tdTomato cells to a small number of newly formed odontoblasts during primary dentinogenesis. Using an experimental pulp exposure model in molars to induce reparative dentinogenesis, we demonstrate the contribution of αSMA-tdTomato cells to cells secreting reparative dentin. Our results demonstrate that αSMA-tdTomato cells differentiated into Col2.3-GFP cells composed of both Dspp odontoblasts and Bsp osteoblasts. Our findings identify a population of mesenchymal progenitor cells capable of giving rise to a second generation of odontoblasts during reparative dentinogenesis. This population also makes a small contribution to odontoblasts during primary dentinogenesis.

35. A systems biology approach to the identification and analysis of transcriptional regulatory networks in osteocytes

Author

Harris Stephen E, Dean Angela K, Kalajzic Ivo, and Ruan Jianhua

Subjects
Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5
Abstract

Abstract Background The osteocyte is a type of cell that appears to be one of the key endocrine regulators of bone metabolism and a key responder to initiate bone formation and remodeling. Identifying the regulatory networks in osteocytes may lead to new therapies for osteoporosis and loss of bone. Results Using microarray, we identified 269 genes over-expressed in osteocyte, many of which have known functions in bone and muscle differentiation and contractility. We determined the evolutionarily conserved and enriched TF binding sites in the 5 kb promoter regions of these genes. Using this data, a transcriptional regulatory network was constructed and subsequently partitioned to identify cis-regulatory modules. Conclusion Our results show that many osteocyte-specific genes, including two well-known osteocyte markers DMP1 and Sost, have highly conserved clustering of muscle-related cis-regulatory modules, thus supporting the concept that a muscle-related gene network is important in osteocyte biology and may play a role in contractility and dynamic movements of the osteocyte.

Published
2009
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36. Signaling pathways associated with Lgr6 to regulate osteogenesis.

Author

King JS, Wan M, Wagley Y, Stestiv M, Kalajzic I, Hankenson KD, and Sanjay A

Subjects
Animals, Humans, Mice, Wnt Signaling Pathway physiology, Bone Morphogenetic Proteins metabolism, Receptors, G-Protein-Coupled metabolism, Receptors, G-Protein-Coupled genetics, Osteogenesis physiology, Osteogenesis genetics, Signal Transduction
Abstract

Fracture management largely relies on the bone's inherent healing capabilities and, when necessary, surgical intervention. Currently, there are limited osteoinductive therapies to promote healing, making targeting skeletal stem/progenitor cells (SSPCs) a promising avenue for therapeutic development. A limiting factor for this approach is our incomplete understanding of the molecular mechanisms governing SSPCs' behavior. We have recently identified that the Leucine-rich repeat-containing G-protein coupled receptor 6 (Lgr6) is expressed in sub-populations of SSPCs, and is required for maintaining bone volume during adulthood and for proper fracture healing. Lgr family members (Lgr4-6) are markers of stem cell niches and play a role in tissue regeneration primarily by binding R-Spondin (Rspo1-4). This interaction promotes canonical Wnt (cWnt) signaling by stabilizing Frizzled receptors. Interestingly, our findings here indicate that Lgr6 may also influence cWnt-independent pathways. Remarkably, Lgr6 expression was enhanced during Bmp-mediated osteogenesis of both human and murine cells. Using biochemical approaches, RNA sequencing, and bioinformatic analysis of published single-cell data, we found that elements of BMP signaling, including its target gene, pSMAD, and gene ontology pathways, are downregulated in the absence of Lgr6. Our findings uncover a molecular interdependency between the Bmp pathway and Lgr6, offering new insights into osteogenesis and potential targets for enhancing fracture healing., Competing Interests: Declaration of competing interest The authors declare that the research was conducted without any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024. Published by Elsevier Inc.)

Published
2024
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37. Losartan alters osteoblast differentiation and increases bone mass through inhibition of TGF B signalling in vitro and in an OIM mouse model.

Author

Morita M, Arshad F, Quayle LA, George CN, Lefley DV, Kalajzic I, Balsubramanian M, Cebe T, Reilly G, Bishop NJ, and Ottewell PD

Abstract

Excessive production of Transforming Growth Factor β (TGFβ) is commonly associated with dominant and recessive forms of OI. Previous reports have indicated that administration of TGFβ-targeted antibodies maybe of potential therapeutic benefit to OI patients. However, direct targeting of TGFβ is likely to cause multiple adverse effects including simulation of autoimmunity. In the current study we use patient-derived normal and OI fibroblasts, osteoblasts and OIM mouse models to determine the effects of Losartan, an angiotensin II receptor type 1 (AT1) antagonist, on TGFβ signalling and bone morphology in OI. In OIM mice bred on a mixed background administration of 0.6 g/L losartan for 4 weeks was associated with a significant reduction in TGFβ from 79.2 g/L in the control to 60.0 ng/ml following losartan ( p  < 0.05), reduced osteoclast activity as measured by CTX from 275.9 ng/ml in the control to 157.2 ng/ml following 0.6 g/L of losartan (p < 0.05) and increased cortical bone thickness ( P  < 0.001). Furthermore in OIM mice bred on a C57BL/6 background 0.6 g/L losartan increased trabecular bone volume in the tibiae ( P  < 0.05) and the vertebrae ( P  < 0.01), increased cortical bone thickness ( P  < 0.001) reduced the trabecular pattern factor ( P  < 0.01 and P < 0.001 for the tibiae and vertebrae respectively), reduced osteoclast ( P  < 0.05) and osteoblast (P < 0.01) numbers as well as reducing the area of bone covered by these cell types. Interestingly, losartan did not affect immune cells infiltrating into bone, nor did this drug alter TGFβ signalling in normal or OI fibroblasts. Instead, losartan reduced SMAD2 phosphorylation in osteoblasts, inhibiting their ability to differentiate. Our data suggest that losartan may be an effective treatment for the bone-associated dysmorphia displayed in OI whilst minimising potential adverse immune cell-related effects., Competing Interests: NJB is global chief investigator of the Ultragenyx-funded studies (ORBIT, COSMIC) of setrusumab in children and young adults with OI and has consulted with Alexion, Mereo and Rampart and has been DMEC chair for a Pfizer study (recifercept in achondroplasia). No other authors have relevant conflicts of interest to declare., (© 2024 The Authors.)

Published
2024
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38. Hair follicle-resident progenitor cells are a major cellular contributor to heterotopic subcutaneous ossifications in a mouse model of Albright hereditary osteodystrophy.

Author

McMullan P, Maye P, Root SH, Yang Q, Edie S, Rowe D, Kalajzic I, and Germain-Lee EL

Abstract

Heterotopic ossifications (HOs) are the pathologic process by which bone inappropriately forms outside of the skeletal system. Despite HOs being a persistent clinical problem in the general population, there are no definitive strategies for their prevention and treatment due to a limited understanding of the cellular and molecular mechanisms contributing to lesion development. One disease in which the development of heterotopic subcutaneous ossifications (SCOs) leads to morbidity is Albright hereditary osteodystrophy (AHO). AHO is caused by heterozygous inactivation of GNAS , the gene that encodes the α-stimulatory subunit (Gα s ) of G proteins. Previously, we had shown using our laboratory's AHO mouse model that SCOs develop around hair follicles (HFs). Here we show that SCO formation occurs due to inappropriate expansion and differentiation of HF-resident stem cells into osteoblasts. We also show in AHO patients and mice that Secreted Frizzled Related Protein 2 ( SFRP2) expression is upregulated in regions of SCO formation and that elimination of Sfrp2 in male AHO mice exacerbates SCO development. These studies provide key insights into the cellular and molecular mechanisms contributing to SCO development and have implications for potential therapeutic modalities not only for AHO patients but also for patients suffering from HOs with other etiologies.

Published
2024
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39. Endothelial to mesenchymal Notch signaling regulates skeletal repair.

Author

Novak S, Tanigawa H, Singh V, Root SH, Schmidt TA, Hankenson KD, and Kalajzic I

Subjects
Animals, Mice, Calcium-Binding Proteins metabolism, Calcium-Binding Proteins genetics, Adaptor Proteins, Signal Transducing metabolism, Adaptor Proteins, Signal Transducing genetics, Mesenchymal Stem Cells metabolism, Bone Morphogenetic Protein 2 metabolism, Bone Morphogenetic Protein 2 genetics, Osteogenesis genetics, Receptor, Notch1 metabolism, Receptor, Notch1 genetics, Male, Female, Intracellular Signaling Peptides and Proteins metabolism, Intracellular Signaling Peptides and Proteins genetics, Signal Transduction, Jagged-1 Protein metabolism, Jagged-1 Protein genetics, Fracture Healing, Endothelial Cells metabolism, Periosteum metabolism, Periosteum cytology
Abstract

We present a transcriptomic analysis that provides a better understanding of regulatory mechanisms within the healthy and injured periosteum. The focus of this work is on characterizing early events controlling bone healing during formation of periosteal callus on day 3 after fracture. Building on our previous findings showing that induced Notch1 signaling in osteoprogenitors leads to better healing, we compared samples in which the Notch 1 intracellular domain is overexpressed by periosteal stem/progenitor cells, with control intact and fractured periosteum. Molecular mechanisms and changes in skeletal stem/progenitor cells (SSPCs) and other cell populations within the callus, including hematopoietic lineages, were determined. Notably, Notch ligands were differentially expressed in endothelial and mesenchymal populations, with Dll4 restricted to endothelial cells, whereas Jag1 was expressed by mesenchymal populations. Targeted deletion of Dll4 in endothelial cells using Cdh5CreER resulted in negative effects on early fracture healing, while deletion in SSPCs using α-smooth muscle actin-CreER did not impact bone healing. Translating these observations into a clinically relevant model of bone healing revealed the beneficial effects of delivering Notch ligands alongside the osteogenic inducer, BMP2. These findings provide insights into the regulatory mechanisms within the healthy and injured periosteum, paving the way for novel translational approaches to bone healing.

Published
2024
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40. Hematopoietic and stromal DMP1-Cre labeled cells form a unique niche in the bone marrow.

Author

Root SH, Matthews BG, Torreggiani E, Aguila HL, and Kalajzic I

Subjects
Mice, Animals, Osteocytes metabolism, Stromal Cells, Bone Marrow Cells, Bone Marrow, Osteoblasts metabolism
Abstract

Skeletogenesis and hematopoiesis are interdependent. Niches form between cells of both lineages where microenvironmental cues support specific lineage commitment. Because of the complex topography of bone marrow (BM), the identity and function of cells within specialized niches has not been fully elucidated. Dentin Matrix Protein 1 (DMP1)-Cre mice have been utilized in bone studies as mature osteoblasts and osteocytes express DMP1. DMP1 has been identified in CXCL12 + cells and an undefined CD45 + population. We crossed DMP1-Cre with Ai9 reporter mice and analyzed the tdTomato + (tdT + ) population in BM and secondary hematopoietic organs. CD45 + tdT + express myeloid markers including CD11b and are established early in ontogeny. CD45 + tdT + cells phagocytose, respond to LPS and are radioresistant. Depletion of macrophages caused a significant decrease in tdT + CD11b + myeloid populations. A subset of CD45 + tdT + cells may be erythroid island macrophages (EIM) which are depleted after G-CSF treatment. tdT + CXCL12 + cells are in direct contact with F4/80 macrophages, express RANKL and form a niche with B220 + B cells. A population of resident cells within the thymus are tdT + and express myeloid markers and RANKL. In conclusion, in addition to targeting osteoblast/osteocytes, DMP1-Cre labels unique cell populations of macrophage and stromal cells within BM and thymus niches and expresses key microenvironmental factors., (© 2023. The Author(s).)

Published
2023
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41. CD51 labels periosteal injury-responsive osteoprogenitors.

Author

Cao Y, Kalajzic I, and Matthews BG

Abstract

The periosteum is a critical source of skeletal stem and progenitor cells (SSPCs) that form callus tissue in response to injury. There is yet to be a consensus on how to identify SSPCs in the adult periosteum. The aim of this study was to understand how potential murine periosteal SSPC populations behave in vivo and in response to injury. We evaluated the in vivo differentiation potential of Sca1 - CD51 + and Sca1 + CD51 + cells following transplantation. In vitro , the Sca1 + CD51 + population appears to be more primitive multipotent cells, but after transplantation, Sca1 - CD51 + cells showed superior engraftment, expansion, and differentiation into chondrocytes and osteoblasts. Despite representing a clear population with flow cytometry, we identified very few Sca1 + CD51 + cells histologically. Using a periosteal scratch injury model, we successfully mimicked the endochondral-like healing process seen in unstable fractures, including the expansion and osteochondral differentiation of αSMA + cells following injury. CD51 + cells were present in the cambium layer of resting periosteum and expanded following injury. Sca1 + CD51 - cells were mainly localized in the outer periosteal layer. We found that injury increased colony-forming unit fibroblast (CFU-F) formation in the periosteum and led to rapid expansion of CD90 + cells. Several other populations, including Sca1 - CD51 + and CD34 + cells, were expanded by day 7. Mice with enhanced fracture healing due to elevated Notch signaling mediated by NICD1 overexpression showed significant expansion of CD51 + and CD34 hi cells in the early stages of healing, suggesting these populations contribute to more rapid healing. In conclusion, we demonstrate that periosteal injury leads to the expansion of various SSPC populations, but further studies are required to confirm their lineage hierarchy in the adult skeletal system. Our data indicate that CD51 + skeletal progenitor cells are injury-responsive and show good engraftment and differentiation potential upon transplantation., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Cao, Kalajzic and Matthews.)

Published
2023
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43. Inhibition of CGRP signaling impairs fracture healing in mice.

Author

Wee NKY, Novak S, Ghosh D, Root SH, Dickerson IM, and Kalajzic I

Subjects
Male, Mice, Female, Animals, Fracture Healing, X-Ray Microtomography, Mice, Inbred C57BL, Pain, Receptors, Calcitonin Gene-Related Peptide genetics, Receptors, Calcitonin Gene-Related Peptide metabolism, Calcitonin Gene-Related Peptide metabolism, Calcitonin
Abstract

Calcitonin gene-related peptide (CGRP) is a neuropeptide produced by sensory nerves and functions as a pain sensor. It acts by binding to the calcitonin-like receptor (CLR, protein; Calcrl, gene). CGRP inhibition has been recently introduced as therapeutic treatment of migraine-associated pain. Previous studies have shown that CGRP stimulates bone formation. The aim of our study is to determine whether the inhibition of CGRP signaling negatively impacted fracture healing. Using α-smooth muscle actin (αSMA) Cre animals crossed with Ai9 reporter mice, we showed that CGRP-expressing nerves are near αSMA + cells in the periosteum. In vitro experiments revealed that periosteal cells express Calcrl and receptor activity modifying protein 1; and CGRP stimulation increased periosteal cell proliferation. Using a tamoxifen-inducible model αSMACre/CLR fl/fl , we targeted the deletion of CLR to periosteal progenitor cells and examined fracture healing. Microcomputed tomography of fractured femurs showed a reduction in bone mass in αSMACre+/CLR fl/fl female mice relative to controls and callus volume in males. Pharmacological CGRP-CLR inhibition was achieved by subcutaneous delivery of customized pellets with small molecule inhibitor olcegepant (BIBN-4096) at a dose of 10 μg/day. BIBN-4096-treated C57BL/6J mice had a higher latency toward thermal nociception than placebo-treated mice, indicating impaired sensory function through CGRP inhibition. CGRP inhibition also resulted in reduced callus volume, bone mass, and bone strength compared to placebo controls. These results indicate that inhibiting CGRP by deleting CLR or by using BIBN-4096, contributes to delayed bone healing., (© 2022 Orthopaedic Research Society. Published by Wiley Periodicals LLC.)

Published
2023
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44. Lineage Tracing of RGS5-CreER-Labeled Cells in Long Bones During Homeostasis and Injury.

Author

Root SH, Vrhovac Madunic I, Kronenberg MS, Cao Y, Novak S, and Kalajzic I

Subjects
Mice, Animals, Osteocalcin metabolism, Osteogenesis, Fracture Healing physiology, Chondrocytes metabolism, Mice, Transgenic, Osteoblasts metabolism, Bony Callus metabolism, Bony Callus pathology, RGS Proteins genetics, RGS Proteins metabolism
Abstract

Regulator of G protein signaling 5 (RGS5) is a GTPase activator for heterotrimeric G-protein α-subunits, shown to be a marker of pericytes. Bone marrow stromal cell population (BMSCs) is heterogeneous. Populations of mesenchymal progenitors, cells supportive of hematopoiesis, and stromal cells regulating bone remodeling have been recently identified. Periosteal and bone marrow mesenchymal stem cells (MSCs) are participating in fracture healing, but it is difficult to distinguish the source of cells within the callus. Considering that perivascular cells exert osteoprogenitor potential, we generated an RGS5 transgenic mouse model (Rgs5-CreER) which when crossed with Ai9 reporter animals (Rgs5/Tomato), is suitable for lineage tracing during growth and post-injury. Flow cytometry analysis and histology confirmed the presence of Rgs5/Tomato+ cells within CD31+ endothelial, CD45+ hematopoietic, and CD31-CD45- mesenchymal/perivascular cells. A tamoxifen chase showed expansion of Rgs5/Tomato+ cells expressing osterix within the trabeculae positioned between mineralized matrix and vasculature. Long-term chase showed proportion of Rgs5/Tomato+ cells contributes to mature osteoblasts expressing osteocalcin. Following femoral fracture, Rgs5/Tomato+ cells are observed around newly formed bone within the BM cavity and expressed osterix and osteocalcin, while contribution within periosteum was low and limited to fibroblastic callus with very few positive chondrocytes. In addition, BM injury model confirmed that RGS5-Cre labels population of BMSCs expands during injury and participates in osteogenesis. Under homeostatic conditions, lineage-traced RGS5 cells within the trabecular area demonstrate osteoprogenitor capacity that in an injury model contributes to new bone formation primarily within the BM niche., (© The Author(s) 2023. Published by Oxford University Press. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published
2023
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45. Wnt-associated adult stem cell marker Lgr6 is required for osteogenesis and fracture healing.

Author

Doherty L, Wan M, Peterson A, Youngstrom DW, King JS, Kalajzic I, Hankenson KD, and Sanjay A

Subjects
Animals, Mice, Bone and Bones metabolism, Bone Regeneration, Cell Differentiation, Fracture Healing, Osteogenesis, Periosteum, Receptors, G-Protein-Coupled metabolism, Wnt Proteins metabolism, Adult Stem Cells metabolism, Fractures, Bone
Abstract

Despite the remarkable regenerative capacity of skeletal tissues, nonunion of bone and failure of fractures to heal properly presents a significant clinical concern. Stem and progenitor cells are present in bone and become activated following injury; thus, elucidating mechanisms that promote adult stem cell-mediated healing is important. Wnt-associated adult stem marker Lgr6 is implicated in the regeneration of tissues with well-defined stem cell niches in stem cell-reliant organs. Here, we demonstrate that Lgr6 is dynamically expressed in osteoprogenitors in response to fracture injury. We used an Lgr6-null mouse model and found that Lgr6 expression is necessary for maintaining bone volume and efficient postnatal bone regeneration in adult mice. Skeletal progenitors isolated from Lgr6-null mice have reduced colony-forming potential and reduced osteogenic differentiation capacity due to attenuated cWnt signaling. Lgr6-null mice consist of a lower proportion of self-renewing stem cells. In response to fracture injury, Lgr6-null mice have a deficiency in the proliferation of periosteal progenitors and reduced ALP activity. Further, analysis of the bone regeneration phase and remodeling phase of fracture healing in Lgr6-null mice showed impaired endochondral ossification and decreased mineralization. We propose that in contrast to not being required for successful skeletal development, Lgr6-positive cells have a direct role in endochondral bone repair., Competing Interests: Conflict of interest The authors report no conflict of interest., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published
2023
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46. Nanofiber matrix formulations for the delivery of Exendin-4 for tendon regeneration: In vitro and in vivo assessment.

Author

Abdulmalik S, Gallo J, Nip J, Katebifar S, Arul M, Lebaschi A, Munch LN, Bartly JM, Choudhary S, Kalajzic I, Banasavadi-Siddegowdae YK, Nukavarapu SP, and Kumbar SG

Abstract

Tendon and ligament injuries are the most common musculoskeletal injuries, which not only impact the quality of life but result in a massive economic burden. Surgical interventions for tendon/ligament injuries utilize biological and/or engineered grafts to reconstruct damaged tissue, but these have limitations. Engineered matrices confer superior physicochemical properties over biological grafts but lack desirable bioactivity to promote tissue healing. While incorporating drugs can enhance bioactivity, large matrix surface areas and hydrophobicity can lead to uncontrolled burst release and/or incomplete release due to binding. To overcome these limitations, we evaluated the delivery of a peptide growth factor (exendin-4; Ex-4) using an enhanced nanofiber matrix in a tendon injury model. To overcome drug surface binding due to matrix hydrophobicity of poly(caprolactone) (PCL)-which would be expected to enhance cell-material interactions-we blended PCL and cellulose acetate (CA) and electrospun nanofiber matrices with fiber diameters ranging from 600 to 1000 nm. To avoid burst release and protect the drug, we encapsulated Ex-4 in the open lumen of halloysite nanotubes (HNTs), sealed the HNT tube endings with a polymer blend, and mixed Ex-4-loaded HNTs into the polymer mixture before electrospinning. This reduced burst release from ∼75% to ∼40%, but did not alter matrix morphology, fiber diameter, or tensile properties. We evaluated the bioactivity of the Ex-4 nanofiber formulation by culturing human mesenchymal stem cells (hMSCs) on matrix surfaces for 21 days and measuring tenogenic differentiation, compared with nanofiber matrices in basal media alone. Strikingly, we observed that Ex-4 nanofiber matrices accelerated the hMSC proliferation rate and elevated levels of sulfated glycosaminoglycan, tendon-related genes (Scx, Mkx, and Tnmd), and ECM-related genes (Col-I, Col-III, and Dcn), compared to control. We then assessed the safety and efficacy of Ex-4 nanofiber matrices in a full-thickness rat Achilles tendon defect with histology, marker expression, functional walking track analysis, and mechanical testing. Our analysis confirmed that Ex-4 nanofiber matrices enhanced tendon healing and reduced fibrocartilage formation versus nanofiber matrices alone. These findings implicate Ex-4 as a potentially valuable tool for tendon tissue engineering., Competing Interests: All authors have been involved in writing of the review article and each of the authors has read and concurs with the content in the review article. All authors and co-authors accept the submission of the review article without any conflict of interest., (© 2023 The Authors.)

Published
2023
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47. PDGF inhibits BMP2-induced bone healing.

Author

Novak S, Madunic J, Shum L, Vucetic M, Wang X, Tanigawa H, Ghosh M, Sanjay A, and Kalajzic I

Abstract

Bone regeneration depends on a pool of bone/cartilage stem/progenitor cells and signaling mechanisms regulating their differentiation. Using in vitro approach, we have shown that PDGF signaling through PDGFRβ inhibits BMP2-induced osteogenesis, and significantly attenuates expression of BMP2 target genes. We evaluated outcomes of treatment with two anabolic agents, PDGF and BMP2 using different bone healing models. Targeted deletion of PDGFRβ in αSMA osteoprogenitors, led to increased callus bone mass, resulting in improved biomechanical properties of fractures. In critical size bone defects BMP2 treatment increased proportion of osteoprogenitors, while the combined treatment of PDGF BB with BMP2 decreased progenitor number at the injury site. BMP2 treatment induced significant bone formation and increased number of osteoblasts, while in contrast combined treatment with PDGF BB decreased osteoblast numbers. This is in vivo study showing that PDGF inhibits BMP2-induced osteogenesis, but inhibiting PDGF signaling early in healing process does not improve BMP2-induced bone healing., (© 2023. The Author(s).)

Published
2023
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48. AcanCreER lacks specificity to chondrocytes and targets periosteal progenitors in the fractured callus.

Author

Novak S and Kalajzic I

Subjects
Mice, Animals, Mice, Transgenic, Bony Callus, Tamoxifen pharmacology, Chondrocytes metabolism, Fractures, Bone metabolism
Abstract

Aggrecan (Acan) is a large proteoglycan molecule constituting the extracellular matrix of cartilage, secreted by chondrocytes. To specifically target the chondrocyte lineage, researchers have widely used the AcanCreER mouse model. Evaluation of specificity and efficiency of recombination, requires Cre animals to be crossed with reporter mice. In order to accurately interpret data from Cre models, it is imperative to consider A) the amount of recombination occurring in cells/tissues that are not intended for targeting (i.e., non-specific expression), B) the efficiency of Cre recombination, which can depend on dose and duration of tamoxifen treatment, and C) the activation of CreER without tamoxifen induction, known as "Cre leakage." Using a highly sensitive reporter mouse (Ai9, tdTomato), we performed a comprehensive analysis of the AcanCreER system. Surprisingly, we observed expression in cells within the periosteum. These cells expand at a stage when chondrocytes are not yet present within the forming callus tissue (Acan/Ai9 + cells). In pulse-chase experiments, we confirmed that fibroblastic Acan/Ai9 + cells within the periosteum can directly give rise to osteoblasts. Our results show that Acan/Ai9 + is not specific for the chondrocyte lineage in the fracture callus or with the tibial holes. The expression of AcanCreER in periosteal progenitor cells complicates the interpretation of studies evaluating the transition of chondrocytes to osteoblasts (termed transdifferentiation). Awareness of these issues and the limitations of the system will lead to better data interpretation., Competing Interests: Declaration of competing interest None., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published
2023
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49. Vitamin C epigenetically controls osteogenesis and bone mineralization.

Author

Thaler R, Khani F, Sturmlechner I, Dehghani SS, Denbeigh JM, Zhou X, Pichurin O, Dudakovic A, Jerez SS, Zhong J, Lee JH, Natarajan R, Kalajzic I, Jiang YH, Deyle DR, Paschalis EP, Misof BM, Ordog T, and van Wijnen AJ

Subjects
Animals, Ascorbic Acid pharmacology, Calcification, Physiologic genetics, Cell Differentiation genetics, Chromatin, DNA metabolism, DNA Methylation, Histones metabolism, Mice, Ascorbic Acid Deficiency genetics, Osteogenesis genetics
Abstract

Vitamin C deficiency disrupts the integrity of connective tissues including bone. For decades this function has been primarily attributed to Vitamin C as a cofactor for collagen maturation. Here, we demonstrate that Vitamin C epigenetically orchestrates osteogenic differentiation and function by modulating chromatin accessibility and priming transcriptional activity. Vitamin C regulates histone demethylation (H3K9me3 and H3K27me3) and promotes TET-mediated 5hmC DNA hydroxymethylation at promoters, enhancers and super-enhancers near bone-specific genes. This epigenetic circuit licenses osteoblastogenesis by permitting the expression of all major pro-osteogenic genes. Osteogenic cell differentiation is strictly and continuously dependent on Vitamin C, whereas Vitamin C is dispensable for adipogenesis. Importantly, deletion of 5hmC-writers, Tet1 and Tet2, in Vitamin C-sufficient murine bone causes severe skeletal defects which mimic bone phenotypes of Vitamin C-insufficient Gulo knockout mice, a model of Vitamin C deficiency and scurvy. Thus, Vitamin C's epigenetic functions are central to osteoblastogenesis and bone formation and may be leveraged to prevent common bone-degenerating conditions., (© 2022. The Author(s).)

Published
2022
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50. Natural Polymer-Based Micronanostructured Scaffolds for Bone Tissue Engineering.

Author

Katebifar S, Jaiswal D, Arul MR, Novak S, Nip J, Kalajzic I, Rudraiah S, and Kumbar SG

Subjects
Animals, Bone Regeneration, Bone and Bones, Polymers chemistry, Tissue Scaffolds chemistry, Nanofibers chemistry, Tissue Engineering
Abstract

Although bone tissue allografts and autografts aremoften used as a regenerative tissue during the bone healing, their availability, donor site morbidity, and immune response to grafted tissue are limiting factors their more common usage. Tissue engineered implants, such as acellular or cellular polymeric structures, can be an alternative solution. A variety of scaffold fabrication techniques including electrospinning, particulate leaching, particle sintering, and more recently 3D printing have been used to create scaffolds with interconnected pores and mechanical properties for tissue regeneration. Simply combining particle sintering and molecular self-assembly to create porous microstructures with imbued nanofibers to produce micronanostructures for tissue regeneration applications. Natural polymers like polysaccharides, proteins and peptides of plant or animal origin have gained significant attention due to their assured biocompatibility in tissue regeneration. However, majority of these polymers are water soluble and structures derived from them are in the form of hydrogels and require additional stabilization via cross-linking. For bone healing applications scaffolds are required to be strong, and support attachment, proliferation and differentiation of osteoprogenitors into osteoblasts. Our ongoing work utilizes plant polysaccharide cellulose derivatives and collagen to create mechanically stable and bioactive micronanostructured scaffold for bone tissue engineering. Scaffold microstructure is essentially solvent sintered cellulose acetate (CA) microspheres in the form of a negative template for trabecular bone with defined pore and mechanical properties. Collagen nanostructures are imbued into the 3D environment of CA scaffolds using collagen molecular self-assembly principles. The resultant CA-collagen micronanostructures provide the benefits of combined polymers and serve as an alternative material platform to many FDA approved polyesters. Our ongoing studies and published work confirm improved osteoprogenitor adhesion, proliferation, migration, differentiation, extracellular matrix (ECM) secretion in promoting bone healing. In this chapter we will provide a detailed protocol on the creation of micronanostructured CA-collagen scaffolds and their characterization for bone tissue engineering using human mesenchymal stem cells., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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