Transgenic mouse model of the mild dominant form of osteogenesis imperfecta.

Bonadio, Jeffrey; Saunders, Thomas L.; Tsai, Eugene; Goldstein, Steven A.; Morris-Wiman, Joyce; Brinkley, Linda L.; Dolan, David F.; Altschuler, Richard A.; Hawkins, Joseph E.; Bateman, John F.; Mascara, Thomas; Jaenisch, Rudolf

doi:10.1073/pnas.87.18.7145

Cited by 146 publications

(93 citation statements)

References 32 publications

(27 reference statements)

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“…The Brtl model is a glycine to cysteine substitution in the α1(I) chain leading to an OI type IV-like phenotype [45]. The Mov-13 model is a transgenic model carrying a murine retrovirus in the first intron of the COL1A1 gene resulting in a null allele and an OI type I-like phenotype [46]. Femurs from Brtl mice had reduced maximum load compared to Wt at three months of age [25].…”

Section: Discussionmentioning

confidence: 99%

Role of genetic background in determining phenotypic severity throughout postnatal development and at peak bone mass in Col1a2 deficient mice (oim)

Carleton¹,

McBride²,

Carson³

et al. 2008

Bone

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Osteogenesis imperfecta (OI) is a genetically and clinically heterogeneous disease characterized by extreme bone fragility. Although fracture numbers tend to decrease post-puberty, OI patients can exhibit significant variation in clinical outcome, even among related individuals harboring the same mutation. OI most frequently results from mutations in type I collagen genes, yet how genetic background impacts phenotypic outcome remains unclear. Therefore, we analyzed the phenotypic severity of a known proα2(I) collagen gene defect (oim) on two genetic backgrounds (congenic C57BL/6J and outbred B6C3Fe) throughout postnatal development to discern the phenotypic contributions of the Col1a2 locus relative to the contribution of the genetic background.To this end, femora and tibiae were isolated from wildtype (Wt) and homozygous (oim/oim) mice of each strain at 1, 2 and 4 months of age. Femoral geometry was determined via µCT prior to torsional loading to failure to assess bone structural and material biomechanical properties. Changes in mineral composition, collagen content and bone turnover were determined using neutron activation analyses, hydroxyproline content and serum pyridinoline crosslinks.Corresponding Author: Charlotte L. Phillips, Ph.D., Associate Professor, Departments of Biochemistry and Child Health, University of Missouri-Columbia, 1 Hospital Dr., M743 Medical Sciences Bldg., Columbia, MO 65212, Phone: (573) 882-5122, Fax: (573) 884-4597, Email: PhillipsCL@missouri.edu. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. µCT analysis demonstrated genotype-, strain-and age-associated changes in femoral geometry as well as a marked decrease in the amount of bone in oim/oim mice of both strains. Oim/oim mice of both strains, as well as C57BL/6J (B6) mice of all genotypes, had reduced femoral biomechanical strength properties compared to Wt at all ages, although they improved with age. Mineral levels of fluoride, magnesium and sodium were associated with biomechanical strength properties in both strains and all genotypes at all ages. Oim/oim animals also had reduced collagen content as compared to Wt at all ages. Serum pyridinoline crosslinks were highest at two months of age, regardless of strain or genotype. NIH Public AccessStrain differences in bone parameters exist throughout development, implicating a role for genetic background in determining biomechanical strength. Age-associated improvements indicate that oim/ oim animals partially compensate for their weaker bone material, but never attain Wt levels. These studies indicate the importance of genetic back...

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Section: Discussionmentioning

confidence: 99%

Role of genetic background in determining phenotypic severity throughout postnatal development and at peak bone mass in Col1a2 deficient mice (oim)

Carleton¹,

McBride²,

Carson³

et al. 2008

Bone

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“…During the past decade, transgenic animal models have been introduced into the research of bone biology (Pavlin et al, 1989(Pavlin et al, , 1992Bonadio et al, 1990;Kream et al, 1995;Ducy et al, 1996;Rossert et al, 1996), but their utilization for studying the regulation of periodontal cells and the alveolar bone homeostasis was limited. A recently developed tooth movement model in wild-type and transgenic mice (Pavlin et al, 2000a(Pavlin et al, ,b, 2001a allows for the study of genetic responses in individual cell populations within the periodontal ligament and the alveolar bone perturbed by mechanical stress in a non-invasive manner.…”

Section: (I) Introductionmentioning

confidence: 99%

“…Furthermore, these results, and those of others, emphasize the necessity for results obtained from bone cells in culture to be confirmed in an in vivo model, whenever possible. Several transgenic models have been used to study osteoblast biology (Bonadio et al, 1990;Ducy et al, 1996;Rossert et al, 1996), but this technique has not been applied in studies investigating either the effect of mechanical loading on bone cells or the mechanical response of the dentoalveolar complex to physiological forces or to orthodontic stress. To address this deficiency, and to utilize the advantages of a smaller animal model, we developed a biomechanically defined animal model for periodontal mechanical loading and a relative quantitative video image analysis for measuring the degree of expression of osteoblast marker genes in periodontal osteoblasts.…”

Section: (I) Introductionmentioning

confidence: 99%

Effect of Mechanical Loading On Periodontal Cells

Pavlin

Gluhak-Heinrich²

2001

Critical Reviews in Oral Biology & Medicine

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Mechanical loading is an important regulatory factor in alveolar bone homeostasis, and plays an essential role in maintaining the structure and mass of the alveolar processes throughout lifetime. A better understanding of the cellular and molecular responses of periodontal cells is a prerequisite for further improvements of therapeutic approaches in orthodontics, periodontal and alveolar bone repair and regeneration, implantology, and post-surgical wound healing. The purpose of this review is to provide an insight into some cell culture and animal models used for studying the effects of mechanical loading on periodontal cells, and into the recent developments and utilization of new in vivo animal models. There has been an increased awareness about the need for improvement and development of in vivo models to supplement the widely used cell culture models, and for biological validation of in vitro results, especially in the light of evidence that developmental models may not always reflect bone homeostasis in an adult organism. Due to the limitations of in vivo models, previous studies on mechanical regulation of alveolar bone osteoblasts and cementoblasts mostly focused on proliferative responses, rather than on the stimulation of cell differentiation. To address this problem, we have recently characterized and implemented a mouse osteoinductive tooth movement model for studying mechanically induced regulation of osteoblast-and cementoblast-associated genes. In this model, a defined and reproducible mechanical osteogenic loading is applied during a time course of up to two weeks. Regulation of gene expression in either wild-type or transgenic animals is assessed by a relative quantitative measurement of the level of target mRNAs directly within the subpopulations of periodontal cells. To date, results demonstrate a defined temporal pattern of cellspecific gene regulation in periodontal osteoblasts mechanically stimulated to differentiate and deposit bone matrix. The responses of osteoblast-associated genes to mechanical loading were 10-to 20-fold greater than the increase in the numbers of these cells, indicating that the induction of differentiation and an increase of cell function are the primary responses to osteogenic loading. The progression of the osteoblast phenotype in the intact mouse periodontium was several-fold faster compared with that in cultured cells, suggesting that the mechanical signal may be targeting osteoblast precursors in the state of readiness to respond to an environmental challenge, without the initial proliferative response. An early response of alkaline phosphatase and bone sialoprotein genes was detected after 24 hrs of treatment, followed by a concomitant stimulation of osteocalcin and collagen I between 24 and 48 hrs, and deposition of osteoid after 72 hrs. Although cementoblasts constitutively express biochemical markers similar to those of osteoblasts, distinct responses of osteocalcin, collagen I, and bone sialoprotein genes to mechanical loading were observed in the ...

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“…For mutations that affect the folding or secretion of collagen I and II, the relative contribution of ER stress to the disease outcome is difficult to assess because of the developmental requirement for these proteins and their roles as structural components of the ECM. For example, mice heterozygous for either a Col1a1-or Col2a1-null allele develop skeletal defects (Lohler et al, 1984;Harbers et al, 1984;Bonadio et al, 1990; Li et al, 1995;Sahlman et al, 2001) and, therefore, loss of collagen function is an integral part of the pathogenesis observed. By contrast, the effects of null mutations of Comp, Col10a1 and Matn3 in mice are subtle (Rosati et al, 1994; Kwan et al, 1997;Svensson et al, 2002;Ko et al, 2004;van der Weyden et al, 2006), facilitating evaluation of the impact of ER stress in skeletal dysplasia.…”

Section: Journal Of Cell Sciencementioning

confidence: 99%

In vivo cellular adaptation to ER stress: survival strategies with double-edged consequences

Tsang

Chan

Bateman

et al. 2010

Journal of Cell Science

115

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SummaryDisturbances to the balance of protein synthesis, folding and secretion in the endoplasmic reticulum (ER) induce stress and thereby the ER stress signaling (ERSS) response, which alleviates this stress. In this Commentary, we review the emerging idea that ER stress caused by abnormal physiological conditions and/or mutations in genes that encode client proteins of the ER is a key factor underlying different developmental processes and the pathology of diverse diseases, including diabetes, neurodegeneration and skeletal dysplasias. Recent studies in mouse models indicate that the effect of ERSS in vivo and the nature of the cellular strategies induced to ameliorate pathological ER stress are crucial factors in determining cell fate and clinical disease features. Importantly, ERSS can affect cellular proliferation and the differentiation program; cells that survive the stress can become 'reprogrammed' or dysfunctional. These cellautonomous adaptation strategies can generate a spectrum of context-dependent cellular consequences, ranging from recovery to death. Secondary effects can include altered cell-extracellular-matrix interactions and non-cell-autonomous alteration of paracrine signaling, which contribute to the final phenotypic outcome. Recent reports showing that ER stress can be alleviated by chemical compounds suggest the potential for novel therapeutic approaches. (1) Physiological ER stress during development is mild and controllable. The cell can recover from and/or adapt to the protein-folding stress; it can also differentiate into a specialized cell type in a manner that depends on components of ERSS and appropriate developmental signals. (2) In severe pathological ER stress, ERSS is initially an adaptive response, but, if stress remains unresolved, perhaps because of continuous and/or cyclical expression of mutant protein, it can lead to interference with developmental signals and disruption of cellular gene expression patterns. The cell can then display altered proliferation and differentiation status, and become dysfunctional. (3) Under conditions of extreme stress, an apoptotic signal is triggered and becomes dominant, leading to cell death. This can occur through excessive production of reactive oxygen species (ROS) caused by enhanced protein-folding activity, which relates to levels of CHOP, GADD34 and ERO1 expression. Journal of Cell Science Attenuation of translationOne of the early responses to ER stress is the modulation of translation, a highly conserved adaptation mechanism (Yamasaki and Anderson, 2008). Phosphorylation of eukaryotic initiation factor 2 (eIF2) by PERK reduces protein translation and shifts the translation machinery to favor alternative modes of initiation, including selective translation of activating transcription factor 4 (ATF4) . Phosphorylated eIF2 also activates the conversion of microtubule-associated protein 1 light chain 3 (LC3-I), an essential protein for autophagy, to LC3-II and hence promotes autophagosome formation Kouroku et al., 2007), as well as t...

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Transgenic mouse model of the mild dominant form of osteogenesis imperfecta.

Cited by 146 publications

References 32 publications

Role of genetic background in determining phenotypic severity throughout postnatal development and at peak bone mass in Col1a2 deficient mice (oim)

Role of genetic background in determining phenotypic severity throughout postnatal development and at peak bone mass in Col1a2 deficient mice (oim)

Effect of Mechanical Loading On Periodontal Cells

In vivo cellular adaptation to ER stress: survival strategies with double-edged consequences

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