Your search keyword '"Timur A. Yorgan"' showing total 64 results

51. Increased Col10a1 expression is not causative for the phenotype of Phex-deficient Hyp mice

Author

Carsten Rendenbach, Michael Amling, Thorsten Schinke, Kathryn S. E. Cheah, Anke Jeschke, and Timur A. Yorgan

Subjects

medicine.medical_specialty, Biophysics, Gene Expression, Biology, Biochemistry, Bone and Bones, Mice, Internal medicine, Gene expression, medicine, Animals, Muscle, Skeletal, Molecular Biology, Osteomalacia, Osteoblasts, Osteoid, PHEX, Cell Biology, medicine.disease, Phenotype, PHEX Phosphate Regulating Neutral Endopeptidase, Mice, Mutant Strains, Familial Hypophosphatemic Rickets, Mice, Inbred C57BL, Hypophosphatemic Rickets, Disease Models, Animal, Fibroblast Growth Factor-23, Endocrinology, Hormone, Collagen Type X

Abstract

X-linked hypophosphatemic rickets (XLHR) is a severe disorder of phosphate homeostasis and skeletal mineralization caused by mutations of PHEX, encoding a bone-specific endopeptidase. Phex-deficient Hyp mice have been extensively studied to understand the molecular bases of XLHR, and here it was found that Fgf23, encoding a major phosphaturic hormone, was transcriptionally activated in bone-forming osteoblasts. We and others could additionally show that Col10a1 expression is increased in Hyp osteoblasts and bones, thereby raising the possibility that ectopic production of type X collagen could contribute to the impaired mineralization of the Hyp bone matrix. Here we show that an additional deficiency of the Col10a1 gene does not overtly affect the skeletal phenotype of Hyp mice. More specifically, Col10a1-deficient Hyp mice displayed severe disturbances of skeletal growth, bone mass acquisition and bone matrix mineralization, and they were essentially indistinguishable from Hyp littermates. This was confirmed by non-decalcified histology and bone-specific histomorphometry quantifying all relevant parameters of growth plate maturation, trabecular bone architecture and osteoid accumulation. Taken together, our results show that increased Col10a1 expression in Phex-deficient osteoblasts is not a major cause of the XLHR phenotype, which was an important issue to address based on the previous findings.

Published

2013

52. Hepatic lipase is expressed by osteoblasts and modulates bone remodeling in obesity

Author

Brigitte Müller, Timur A. Yorgan, Thorsten Schinke, Wolfgang Rüther, F. Timo Beil, Tayfun Yilmaz, Alexander Bartelt, Till Koehne, Joerg Heeren, Markus Heine, and Andreas Niemeier

Subjects

musculoskeletal diseases, Male, medicine.medical_specialty, Histology, Physiology, Endocrinology, Diabetes and Metabolism, Diet, High-Fat, Bone resorption, Bone remodeling, Osteoprotegerin, Internal medicine, medicine, Animals, Femur, Obesity, Cells, Cultured, Lipoprotein lipase, Lumbar Vertebrae, Osteoblasts, biology, Chemistry, Osteoblast, Cell Differentiation, Feeding Behavior, Lipase, Organ Size, X-Ray Microtomography, Mice, Inbred C57BL, Endocrinology, medicine.anatomical_structure, RANKL, biology.protein, Osteocalcin, Hepatic lipase, Bone Remodeling, Biomarkers

Abstract

A number of unexpected molecules were recently identified as products of osteoblasts, linking bone homeostasis to systemic energy metabolism. Here we identify the lipolytic enzyme hepatic lipase (HL, encoded by Lipc) as a novel cell-autonomous regulator of osteoblast function. In an unbiased genome-wide expression analysis, we find Lipc to be highly induced upon osteoblast differentiation, verified by quantitative Taqman analyses of primary osteoblasts in vitro and of bone samples in vivo. Functionally, loss of HL in vitro leads to increased expression and secretion of osteoprotegerin (OPG), while expression of some osteoblast differentiation makers is impaired. When challenging energy metabolism in a diet-induced obesity (DIO) study, lack of HL leads to a significant increase in bone formation markers and a decrease in bone resorption markers. Accordingly, in the DIO setting, we observe in Lipc(-/-) animals but not in wild-type controls a significant increase in lumbar vertebral trabecular bone mass and formation rate as well as in femoral trabecular bone mass and cortical thickness. Taken together, we demonstrate that HL expressed by osteoblasts has an impact on osteoblast OPG expression and that lack of HL leads to increased bone mass in DIO. These data provide a novel and completely unexpected molecular link in the complex interplay of osteoblasts and systemic energy metabolism.

Published

2013

53. Effects of extracellular phosphate on gene expression in murine osteoblasts

Author

Timo Heckt, Thorsten Schinke, Carsten Rendenbach, Thomas Streichert, Benjamin Otto, Anke Jeschke, Jean-Pierre David, Michael Amling, Christina Baldauf, and Timur A. Yorgan

Subjects

Endocrinology, Diabetes and Metabolism, Real-Time Polymerase Chain Reaction, Pyrophosphate, Phosphates, chemistry.chemical_compound, Hyperphosphatemia, Mice, Endocrinology, Calcification, Physiologic, Extracellular, medicine, Animals, Orthopedics and Sports Medicine, Oligonucleotide Array Sequence Analysis, Regulation of gene expression, Osteoblasts, Chemistry, PHEX, Osteoblast, Phosphate, medicine.disease, Cell biology, Mice, Inbred C57BL, Hypophosphatemic Rickets, Fibroblast Growth Factor-23, medicine.anatomical_structure, Biochemistry, Gene Expression Regulation

Abstract

That phosphate homeostasis is tightly linked to skeletal mineralization is probably best underscored by the fact that the phosphaturic hormone FGF23 is primarily expressed by terminally differentiated osteoblasts/osteocytes and that increased circulating FGF23 levels are causative for different types of hypophosphatemic rickets. In contrast, FGF23 inactivation results in hyperphosphatemia, and unexpectedly this phenotype is associated with severe osteomalacia in Fgf23-deficient mice. In this context it is interesting that different cell types have been shown to respond to extracellular phosphate, thereby raising the concept that phosphate can act as a signaling molecule. To identify phosphate-responsive genes in primary murine osteoblasts we performed genome wide expression analysis with cells maintained in medium containing either 1 or 4 mM sodium phosphate for 6 h. As confirmed by qRT-PCR, this analysis revealed that several known osteoblast differentiation markers (Bglap, Ibsp, and Phex) were unaffected by raising extracellular phosphate levels. In contrast, we found that the expression of Enpp1 and Ank, two genes encoding inhibitors of matrix mineralization, was induced by extracellular phosphate, while the expression of Sost and Dkk1, two genes encoding inhibitors of bone formation, was negatively regulated. The ability of osteoblasts to respond to extracellular phosphate was dependent on their differentiation state, and shRNA-dependent repression of the phosphate transporter Slc20a1 in MC3T3-E1 cells partially abolished their molecular response to phosphate. Taken together, our results provide further evidence for a role of extracellular phosphate as a signaling molecule and raise the possibility that severe hyperphosphatemia can negatively affect skeletal mineralization.

Published

2013

54. The Formation of Calcified Nanospherites during Micropetrosis Represents a Unique Mineralization Mechanism in Aged Human Bone

Author

Michaela Schweizer, Bjoern Busse, Annika vom Scheidt, Björn Hoffmann, Elizabeth A. Zimmermann, Petar Milovanovic, Michael Amling, George Sarau, Silke Christiansen, and Timur A. Yorgan

Subjects

0301 basic medicine, Aging, Materials science, Bone Matrix, Human bone, Bone canaliculus, Osteocytes, Mineralization (biology), Bone and Bones, Biomaterials, 03 medical and health sciences, Calcification, Physiologic, Bone material, Bone cell, medicine, Humans, General Materials Science, Aged, 80 and over, General Chemistry, Anatomy, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Osteopetrosis, Osteocyte, Female, Cortical bone, Nanospheres, Biotechnology, Biomineralization

Abstract

Osteocytes-the central regulators of bone remodeling-are enclosed in a network of microcavities (lacunae) and nanocanals (canaliculi) pervading the mineralized bone. In a hitherto obscure process related to aging and disease, local plugs in the lacuno-canalicular network disrupt cellular communication and impede bone homeostasis. By utilizing a suite of high-resolution imaging and physics-based techniques, it is shown here that the local plugs develop by accumulation and fusion of calcified nanospherites in lacunae and canaliculi (micropetrosis). Two distinctive nanospherites phenotypes are found to originate from different osteocytic elements. A substantial deviation in the spherites' composition in comparison to mineralized bone further suggests a mineralization process unlike regular bone mineralization. Clearly, mineralization of osteocyte lacunae qualifies as a strong marker for degrading bone material quality in skeletal aging. The understanding of micropetrosis may guide future therapeutics toward preserving osteocyte viability to maintain mechanical competence and fracture resistance of bone in elderly individuals.

Published

2016

55. Impaired bone remodeling and its correction by combination therapy in a mouse model of mucopolysaccharidosis-I

Author

Christina Baldauf, Christoph Riedel, Michaela Schweizer, Matthias Krause, Ralf Stuecker, Boris Fehse, Bjoern Busse, Thorsten Schinke, Michael Amling, Thomas Braulke, Jan M. Pestka, Timur A. Yorgan, Kerstin Cornils, Nicole Muschol, Sonja C. Kuehn, Mona Neven, Sandra Breyer, Johannes Keller, Till Koehne, and Sandra Markmann

Subjects

Male, medicine.medical_specialty, Combination therapy, Mucopolysaccharidosis I, Osteoclasts, Biology, Bone remodeling, Iduronidase, Mice, Osteoclast, Internal medicine, Genetics, Lysosomal storage disease, medicine, Animals, Humans, Enzyme Replacement Therapy, Child, Molecular Biology, Cells, Cultured, Genetics (clinical), Bone Marrow Transplantation, Cell Proliferation, General Medicine, Enzyme replacement therapy, medicine.disease, Combined Modality Therapy, Phenotype, Mice, Inbred C57BL, Disease Models, Animal, Endocrinology, medicine.anatomical_structure, Immunology, Female, Bone Remodeling

Abstract

Mucopolysaccharidosis-I (MPS-I) is a lysosomal storage disease (LSD) caused by inactivating mutations of IDUA, encoding the glycosaminoglycan-degrading enzyme α-l-iduronidase. Although MPS-I is associated with skeletal abnormalities, the impact of IDUA deficiency on bone remodeling is poorly defined. Here we report that Idua-deficient mice progressively develop a high bone mass phenotype with pathological lysosomal storage in cells of the osteoblast lineage. Histomorphometric quantification identified shortening of bone-forming units and reduced osteoclast numbers per bone surface. This phenotype was not transferable into wild-type mice by bone marrow transplantation (BMT). In contrast, the high bone mass phenotype of Idua-deficient mice was prevented by BMT from wild-type donors. At the cellular level, BMT did not only normalize defects of Idua-deficient osteoblasts and osteocytes but additionally caused increased osteoclastogenesis. Based on clinical observations in an individual with MPS-I, previously subjected to BMT and enzyme replacement therapy (ERT), we treated Idua-deficient mice accordingly and found that combining both treatments normalized all histomorphometric parameters of bone remodeling. Our results demonstrate that BMT and ERT profoundly affect skeletal remodeling of Idua-deficient mice, thereby suggesting that individuals with MPS-I should be monitored for their bone remodeling status, before and after treatment, to avoid long-term skeletal complications.

Published

2015

56. Relevance of Wnt signaling for osteoanabolic therapy

Author

Timur A. Yorgan and Thorsten Schinke

Subjects

Cell type, Lrp5, β-Catenin, Osteoblast, Genetic disorder, Wnt signaling pathway, LRP6, LRP5, Review, Biology, Bone remodeling, medicine.disease, Bioinformatics, Cell biology, Wnt, medicine.anatomical_structure, medicine, Receptor, Sost

Abstract

The Wnt signaling pathway is long known to play fundamental roles in various aspects of embryonic development, but also in several homeostatic processes controlling tissue functions in adults. The complexity of this system is best underscored by the fact that the mammalian genome encodes for 19 different Wnt ligands, most but not all of them acting through an intracellular stabilization of β-catenin, representing the key molecule within the so-called canonical Wnt signaling pathway. Wnt ligands primarily bind to 10 different serpentine receptors of the Fzd family, and this binding can be positively or negatively regulated by additional molecules present at the surface of the respective target cells. One of these molecules is the transmembrane protein Lrp5, which has been shown to act as a Wnt co-receptor. In 2001, Lrp5, and thereby Wnt signaling, entered center stage in the research area of bone remodeling, a homeostatic process controlling bone mass, whose disturbance causes osteoporosis, one of the most prevalent disorders worldwide. More specifically, it was found that inactivating mutations of the human LRP5 gene cause osteoporosis-pseudoglioma syndrome, a rare genetic disorder characterized by impaired bone formation and persistence of hyaloid vessels in the eyeballs. In addition, activating LRP5 mutations were identified in individuals with osteosclerosis, a high bone mass condition characterized by excessive bone formation. Especially explained by the lack of cost-effective osteoanabolic treatment options, these findings had an immediate impact on the research regarding the bone-forming cell type, i.e. the osteoblast, whose differentiation and function is apparently controlled by Wnt signaling. This review summarizes the most important results obtained in a large number of studies, involving tissue culture experiments, mouse models and human patients. While there are still many open questions regarding the precise molecular interactions controlling Wnt signaling in osteoblasts, it is obvious that understanding this pathway is a key to optimize the therapeutic strategies for treating various skeletal disorders, including osteoporosis.

Published

2014

57. Fracture healing in a mouse model of Hajdu–Cheney-Syndrome with high turnover osteopenia results in decreased biomechanical stability

Author

Tobias Malte Ballhause, Shan Jiang, Weixin Xie, Jan Sevecke, Christine Dowling, Tobias Dust, Sabine Brandt, Peter R. Mertens, Timur Alexander Yorgan, Thorsten Schinke, Karl-Heinz Frosch, Anke Baranowsky, and Johannes Keller

Subjects

Medicine, Science

Abstract

Abstract Notch signaling regulates cell fate in multiple tissues including the skeleton. Hajdu–Cheney-Syndrome (HCS), caused by gain-of-function mutations in the Notch2 gene, is a rare inherited disease featuring early-onset osteoporosis and increased risk for fractures and non-union. As the impact of Notch2 overactivation on fracture healing is unknown, we studied bone regeneration in mice harboring a human HCS mutation. HCS mice, displaying high turnover osteopenia in the non-fractured skeleton, exhibited only minor morphologic alterations in the progression of bone regeneration, evidenced by static radiological and histological outcome measurements. Histomorphometry showed increased osteoclast parameters in the callus of HCS mice, which was accompanied by an increased expression of osteoclast and osteoblast markers. These observations were accompanied by inferior biomechanical stability of healed femora in HCS mice. Together, our data demonstrate that structural indices of bone regeneration are normal in HCS mice, which, however, exhibit signs of increased callus turnover and display impaired biomechanical stability of healed fractures.

Published

2023

58. The selective norepinephrine reuptake inhibitor reboxetine promotes late-stage fracture healing in mice

Author

Antonia Donat, Shan Jiang, Weixin Xie, Paul Richard Knapstein, Lilly-Charlotte Albertsen, Judith Luisa Kokot, Jan Sevecke, Ruben Augustin, Denise Jahn, Timur Alexander Yorgan, Karl-Heinz Frosch, Serafeim Tsitsilonis, Anke Baranowsky, and Johannes Keller

Subjects

Injury, Treatment, Cellular physiology, Science

Abstract

Summary: Impaired fracture healing is of high clinical relevance, as up to 15% of patients with long-bone fractures display non-unions. Fracture patients also include individuals treated with selective norepinephrine reuptake inhibitors (SNRI). As SNRI were previously shown to negatively affect bone homeostasis, it remained unclear whether patients with SNRI are at risk of impaired bone healing. Here, we show that daily treatment with the SNRI reboxetine reduces trabecular bone mass in the spine but increases cortical thickness and osteoblast numbers in the femoral midshaft. Most importantly, reboxetine does not impair bone regeneration in a standardized murine fracture model, and even improves callus bridging and biomechanical stability at late healing stages. In sum, reboxetine affects bone remodeling in a site-specific manner. Treatment does not interfere with the early and intermediate stages of bone regeneration and improves healing outcomes of the late-stage fracture callus in mice.

Published

2023

59. The WNT1 G177C mutation specifically affects skeletal integrity in a mouse model of osteogenesis imperfecta type XV

Author

Nele Vollersen, Wenbo Zhao, Tim Rolvien, Fabiola Lange, Felix Nikolai Schmidt, Stephan Sonntag, Doron Shmerling, Simon von Kroge, Kilian Elia Stockhausen, Ahmed Sharaf, Michaela Schweizer, Meliha Karsak, Björn Busse, Ernesto Bockamp, Oliver Semler, Michael Amling, Ralf Oheim, Thorsten Schinke, and Timur Alexander Yorgan

Subjects

Biology (General), QH301-705.5, Physiology, QP1-981

Abstract

Abstract The recent identification of homozygous WNT1 mutations in individuals with osteogenesis imperfecta type XV (OI-XV) has suggested that WNT1 is a key ligand promoting the differentiation and function of bone-forming osteoblasts. Although such an influence was supported by subsequent studies, a mouse model of OI-XV remained to be established. Therefore, we introduced a previously identified disease-causing mutation (G177C) into the murine Wnt1 gene. Homozygous Wnt1 G177C/G177C mice were viable and did not display defects in brain development, but the majority of 24-week-old Wnt1 G177C/G177C mice had skeletal fractures. This increased bone fragility was not fully explained by reduced bone mass but also by impaired bone matrix quality. Importantly, the homozygous presence of the G177C mutation did not interfere with the osteoanabolic influence of either parathyroid hormone injection or activating mutation of LRP5, the latter mimicking the effect of sclerostin neutralization. Finally, transcriptomic analyses revealed that short-term administration of WNT1 to osteogenic cells induced not only the expression of canonical WNT signaling targets but also the expression of genes encoding extracellular matrix modifiers. Taken together, our data demonstrate that regulating bone matrix quality is a primary function of WNT1. They further suggest that individuals with WNT1 mutations should profit from existing osteoanabolic therapies.

Published

2021

60. Mice carrying a ubiquitous R235W mutation of Wnt1 display a bone-specific phenotype

Author

Timur Alexander Yorgan, Tim Rolvien, Julian Stürznickel, Nele Vollersen, Fabiola Lange, Anke Baranowsky, Irm Hermans-Borgmeyer, Jean-Pierre David, Ralf Oheim, Michael Amling, and Thorsten Schinke

Subjects

Diseases of the musculoskeletal system, RC925-935

Published

2020

61. Gnathodiaphyseal dysplasia is not recapitulated in a respective mouse model carrying a mutation of the Ano5 gene

Author

Tim Rolvien, Osman Avci, Simon von Kroge, Till Koehne, Stefan Selbert, Stephan Sonntag, Doron Shmerling, Uwe Kornak, Ralf Oheim, Michael Amling, Thorsten Schinke, and Timur Alexander Yorgan

Subjects

Ano5, Gnathodiaphyseal dysplasia, Mouse model, Skeletal disorder, Diseases of the musculoskeletal system, RC925-935

Abstract

Mutations in the gene ANO5, encoding for the transmembrane protein Anoctamin 5 (Ano5), have been identified to cause gnathodiaphyseal dysplasia (GDD) in humans, a skeletal disorder characterized by sclerosis of tubular bones, increased fracture risk and fibro-osseous lesions of the jawbones. To better understand the pathomechanism of GDD we have generated via Crispr/CAS9 gene editing a mouse model harboring the murine equivalent (Ano5 p.T491F) of a GDD-causing ANO5 mutation identified in a previously reported patient. Skeletal phenotyping by contact radiography, μCT and undecalcified histomorphometry was performed in male mice, heterozygous and homozygous for the mutation, at the ages of 12 and 24 weeks. These mice did not display alterations of skeletal microarchitecture or mandible morphology. The results were confirmed in female mice and animals derived from a second, independent clone. Finally, no skeletal phenotype was observed in mice lacking ~40% of their Ano5 gene due to a frameshift mutation. Therefore, our results indicate that Ano5 is dispensable for bone homeostasis in mice, at least under unchallenged conditions, and that these animals may not present the most adequate model to study the physiological role of Anoctamin 5.

Published

2020

62. Decreased Trabecular Bone Mass in Col22a1-Deficient Mice

Author

Wenbo Zhao, Philip Wiedemann, Eva Maria Wölfel, Mona Neven, Stephanie Peters, Thomas Imhof, Manuel Koch, Björn Busse, Michael Amling, Thorsten Schinke, and Timur Alexander Yorgan

Subjects

bone remodeling, Col22a1, osteoclasts, osteoblasts, Cytology, QH573-671

Abstract

The bone matrix is constantly remodeled by the coordinated activities of bone-forming osteoblasts and bone-resorbing osteoclasts. Whereas type I collagen is the most abundant bone matrix protein, there are several other proteins present, some of them specifically produced by osteoblasts. In a genome-wide expression screening for osteoblast differentiation markers we have previously identified two collagen-encoding genes with unknown function in bone remodeling. Here we show that one of them, Col22a1, is predominantly expressed in bone, cultured osteoblasts, but not in osteoclasts. Based on this specific expression pattern we generated a Col22a1-deficient mouse model, which was analyzed for skeletal defects by µCT, undecalcified histology and bone-specific histomorphometry. We observed that Col22a1-deficient mice display trabecular osteopenia, accompanied by significantly increased osteoclast numbers per bone surface. In contrast, cortical bone parameters, osteoblastogenesis or bone formation were unaffected by the absence of Col22a1. Likewise, primary osteoblasts from Col22a1-deficient mice did not display a cell-autonomous defect, and they did not show altered expression of Rankl or Opg, two key regulators of osteoclastogenesis. Taken together, we provide the first evidence for a physiological function of Col22a1 in bone remodeling, although the molecular mechanisms explaining the indirect influence of Col22a1 deficiency on osteoclasts remain to be identified.

Published

2021

63. Conditional mouse models support the role of SLC39A14 (ZIP14) in Hyperostosis Cranialis Interna and in bone homeostasis.

Author

Gretl Hendrickx, Vere M Borra, Ellen Steenackers, Timur A Yorgan, Christophe Hermans, Eveline Boudin, Jérôme J Waterval, Ineke D C Jansen, Tolunay Beker Aydemir, Niels Kamerling, Geert J Behets, Christine Plumeyer, Patrick C D'Haese, Björn Busse, Vincent Everts, Martin Lammens, Geert Mortier, Robert J Cousins, Thorsten Schinke, Robert J Stokroos, Johannes J Manni, and Wim Van Hul

Subjects

Genetics, QH426-470

Abstract

Hyperostosis Cranialis Interna (HCI) is a rare bone disorder characterized by progressive intracranial bone overgrowth at the skull. Here we identified by whole-exome sequencing a dominant mutation (L441R) in SLC39A14 (ZIP14). We show that L441R ZIP14 is no longer trafficked towards the plasma membrane and excessively accumulates intracellular zinc, resulting in hyper-activation of cAMP-CREB and NFAT signaling. Conditional knock-in mice overexpressing L438R Zip14 in osteoblasts have a severe skeletal phenotype marked by a drastic increase in cortical thickness due to an enhanced endosteal bone formation, resembling the underlying pathology in HCI patients. Remarkably, L438R Zip14 also generates an osteoporotic trabecular bone phenotype. The effects of osteoblastic overexpression of L438R Zip14 therefore mimic the disparate actions of estrogen on cortical and trabecular bone through osteoblasts. Collectively, we reveal ZIP14 as a novel regulator of bone homeostasis, and that manipulating ZIP14 might be a therapeutic strategy for bone diseases.

Published

2018

64. Post-weaning epiphysiolysis causes distal femur dysplasia and foreshortened hindlimbs in fetuin-A-deficient mice.

Author

Laura J Brylka, Sina Köppert, Anne Babler, Beate Kratz, Bernd Denecke, Timur A Yorgan, Julia Etich, Ivan G Costa, Bent Brachvogel, Peter Boor, Thorsten Schinke, and Willi Jahnen-Dechent

Subjects

Medicine, Science

Abstract

Fetuin-A / α2-Heremans-Schmid-glycoprotein (gene name Ahsg) is a systemic inhibitor of ectopic calcification. Due to its high affinity for calcium phosphate, fetuin-A is highly abundant in mineralized bone matrix. Foreshortened femora in fetuin-A-deficient Ahsg-/- mice indicated a role for fetuin-A in bone formation. We studied early postnatal bone development in fetuin-A-deficient mice and discovered that femora from Ahsg-/- mice exhibited severely displaced distal epiphyses and deformed growth plates, similar to the human disease slipped capital femoral epiphysis (SCFE). The growth plate slippage occurred in 70% of Ahsg-/- mice of both sexes around three weeks postnatal. At this time point, mice weaned and rapidly gained weight and mobility. Epiphysis slippage never occurred in wildtype and heterozygous Ahsg+/- mice. Homozygous fetuin-A-deficient Ahsg-/- mice and, to a lesser degree, heterozygous Ahsg+/- mice showed lesions separating the proliferative zone from the hypertrophic zone of the growth plate. The hypertrophic growth plate cartilage in long bones from Ahsg-/- mice was significantly elongated and V-shaped until three weeks of age and thus prior to the slippage. Genome-wide transcriptome analysis of laser-dissected distal femoral growth plates from 13-day-old Ahsg-/- mice revealed a JAK-STAT-mediated inflammatory response including a 550-fold induction of the chemokine Cxcl9. At this stage, vascularization of the elongated growth plates was impaired, which was visualized by immunofluorescence staining. Thus, fetuin-A-deficient mice may serve as a rodent model of growth plate pathologies including SCFE and inflammatory cartilage degradation.

Published

2017