Alterations of bone material properties in growing <em>Ifitm5</em>/BRIL p.s42 knock-in mice, a new model for atypical type vi osteogenesis imperfecta

Hedjazi, Ghazal; Guterman-Ram, Gali; Blouin, Stéphane; Schemenz, Victoria; Wagermaier, Wolfgang; Fratzl, Peter; Hartmann, Markus A.; Zwerina, Jochen; Fratzl-Zelman, Nadja; Marini, Joan C.

Affiliations

¹Ludwig Boltzmann Institute of Osteology at the Hanusch Hospital of OEGK and AUVA Trauma Centre Meidling, 1st Medical Department Hanusch Hospital, Heinrich Collin Strasse 30, 1140 Vienna, Austria

²Section on Heritable Disorders of Bone and Extracellular Matrix, NICHD, NIH, Bethesda, USA

³Vienna Bone and Growth Center, Vienna, Austria

⁴Max Planck Institute of Colloids and Interfaces, Department of Biomaterials, Am Mühlenberg 1, 14476 Potsdam, Germany

Abstract and keywords

Introduction: Osteogenesis imperfecta (OI) is a heterogenous group of heritable connective tissue disorders characterized by high bone fragility due to low bone mass and impaired bone material properties. Atypical type VI OI is an extremely rare and severe form of bone dysplasia resulting from a loss-of-function mutation (p.S40L) in IFITM5/BRIL,the causative gene of OI type V and decreased osteoblast secretion of pigment epithelium-derived factor (PEDF), as in OI type VI. It is not yet known which alterations at the material level might lead to such a severe phenotype. We therefore characterized bone tissue at the micrometer level in a novel heterozygous Ifitm5/BRIL p.S42L knock-in murine model at 4 and 8 weeks of age.

Methods: We evaluated in female mice, total body size, femoral and lumbar bone mineral density (BMD) by dual-energy X-ray absorptiometry. In the femoral bone we examined osteoid deposition by light microscopy, assessed bone histomorphometry and mineralization density distribution by quantitative backscattered electron imaging (qBEI). Osteocyte lacunae were examined by qBEI and the osteocyte lacuno-canalicular network by confocal laser scanning microscopy. Vasculature was examined indirectly by qBEI as 2D porosity in cortex, and as 3D porosity by micro-CT in third trochanter. Collagen orientation was examined by second harmonic generation microscopy. Two-way ANOVA was used to discriminate the effect of age and genotype.

Results: Ifitm5/BRIL p.S42L female mice are viable, do not differ in body size, fat and lean mass from wild type (WT) littermates but have lower whole-body, lumbar and femoral BMD and multiple fractures.

The average and most frequent calcium concentration, CaMean and CaPeak, increased with age in metaphyseal and cortical bone in both genotypes and were always higher in Ifitm5/BRIL p.S42L than in WT, except CaMean in metaphysis at 4 weeks of age. The fraction of highly mineralized bone area, CaHigh, was also increased in Ifitm5/BRIL p.S42L metaphyseal bone at 8 weeks of age and at both ages in cortical bone. The fraction of lowly mineralized bone area, CaLow, decreased with age and was not higher in Ifitm5/BRIL p.S42L, consistent with lack of hyperosteoidosis on histological sections by visual exam. Osteocyte lacunae density was higher in Ifitm5/BRIL p.S42L than WT, whereas canalicular density was decreased. Indirect measurements of vascularity revealed a higher pore density at 4 weeks in cortical bone of Ifitm5/BRIL p.S42L than in WT and at both ages in the third trochanter. Importantly, the proportion of bone area with disordered collagen fibrils was highly increased in Ifitm5/BRIL p.S42L at both ages.

Conclusions: Despite normal skeletal growth and the lack of a collagen gene mutation, the Ifitm5/BRIL p.S42L mouse shows major OI-related bone tissue alterations such as hypermineralization of the matrix and elevated osteocyte porosity. Together with the disordered lacuno-canalicular network and the disordered collagen fibril orientation, these abnormalities likely contribute to overall bone fragility.

Keywords: Osteogenesis imperfecta; Growing mice; Bone matrix mineralization; Osteocyte lacunae; Osteocyte canalicular network; Bone vascularity; Collagen orientation

Links

DOI: 10.1016/j.bone.2022.116451

PubMed: 35654352

WoS: 000819117500006

History

Received: 2021-12-29

Revised: 2022-05-17

Accepted: 2022-05-25

Online: 2022-05-30

Cited Works (28)

Year	Entry
1993	Chipman SD, Sweet HO, McBride DJ Jr, Davisson MT, Marks SC Jr, Shuldiner AR, Wenstrup RJ, Rowe DW, Shapiro JR. Defective proα2(I) collagen synthesis in a recessive mutation in mice: a model of human osteogenesis imperfecta. Proc Natl Acad Sci USA. March 1993;90(5):1701-1705.
2000	Rauch F, Travers R, Parfitt AM, Glorieux FH. Static and dynamic bone histomorphometry in children with osteogenesis imperfecta. Bone. June 2000;26(6):581-589.
1979	Sillence DO, Senn A, Danks DM. Genetic heterogeneity in osteogenesis imperfecta. J Med Genet. 1979;12(2):101-116.
2010	Doube M, Kłosowski MM, Arganda-Carreras I, Cordelières FP, Dougherty RP, Jackson JS, Schmid B, Hutchinson JR, Shefelbine SJ. BoneJ: free and extensible bone image analysis in ImageJ. Bone. December 2010;47(6):1076-1079.
2004	Hernandez CJ, Majeska RJ, Schaffler MB. Osteocyte density in woven bone. Bone. November 2004;35(5):1095-1099.
2010	Bouxsein ML, Boyd SK, Christiansen BA, Guldberg RE, Jepsen KJ, Müller R. Guidelines for assessment of bone microstructure in rodents using micro-computed tomography. J Bone Miner Res. July 2010;25(7):1468-1486.
2016	Forlino A, Marini JC. Osteogenesis imperfecta. Lancet. April 16, 2016;387(10028):1657-1671.
2007	Glatt V, Canalis E, Stadmeyer L, Bouxsein ML. Age‐related changes in trabecular architecture differ in female and male C57BL/6J mice. J Bone Miner Res. August 2007;22(8):1197-1207.
2014	Carriero A, Doube M, Vogt M, Busse B, Zustin J, Levchuk A, Schneider P, Müller R, Shefelbine SJ. Altered lacunar and vascular porosity in osteogenesis imperfecta mouse bone as revealed by synchrotron tomography contributes to bone fragility. Bone. April 2014;61:116-124.
2008	Roschger P, Paschalis EP, Fratzl P, Klaushofer K. Bone mineralization density distribution in health and disease. Bone. March 2008;42(3):456-466.
2020	Razi H, Predan J, Fischer FD, Kolednik O, Fratzl P. Damage tolerance of lamellar bone. Bone. January 2020;130:115102.
2015	Wagermaier W, Klaushofer K, Fratzl P. Fragility of bone material controlled by internal interfaces. Calcif Tiss Int. September 2015;97(3):201-212.
1997	Jepsen KJ, Schaffler MB, Kuhn JL, Goulet RW, Bonadio J, Goldstein SA. Type I collagen mutation alters the strength and fatigue behavior of Mov13 cortical tissue. J Biomech. November–December 1997;30(11-12):1141-1147.
2021	Ayoubi M, van Tol AF, Weinkamer R, Roschger P, Brugger PC, Berzlanovich A, Bertinetti L, Roschger A, Fratzl P. 3D interrelationship between osteocyte network and forming mineral during human bone remodeling. Adv Healthc Mater. June 2021;10(12):2100113.
2013	Kerschnitzki M, Kollmannsberger P, Burghammer M, Duda GN, Weinkamer R, Wagermaier W, Fratzl P. Architecture of the osteocyte network correlates with bone material quality. J Bone Miner Res. December 2013;28(8):1837-1845.
2006	Peterlik H, Roschger P, Klaushofer K, Fratzl P. From brittle to ductile fracture of bone. Nat Mater. January 2006;5(1):52-55.
2007	Miller LM, Little W, Schirmer A, Sheik F, Busa B, Judex S. Accretion of bone quantity and quality in the developing mouse skeleton. J Bone Miner Res. July 2007;22(7):1037-1045.
1996	Fratzl P, Paris O, Klaushofer K, Landis WJ. Bone mineralization in an osteogenesis imperfecta mouse model studied by small-angle x-ray scattering. J Clin Invest. January 15, 1996;97(2):396-402.
2012	Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. July 2012;9(7):671-675.
2020	Jandl NM, von Kroge S, Stürznickel J, Baranowsky A, Stockhausen KE, Mushumba H, Beil FT, Püschel K, Amling M, Rolvien T. Large osteocyte lacunae in iliac crest infantile bone are not associated with impaired mineral distribution or signs of osteocytic osteolysis. Bone. June 2020;135:115324.
2013	Dallas SL, Prideaux M, Bonewald LF. The osteocyte: an endocrine cell … and more. Endocr Rev. October 2013;34(4):658-690.
1998	Müller R, Van Campenhout H, Van Damme B, Van der Perre G, Dequeker J, Hildebrand T, Rüegsegger P. Morphometric analysis of human bone biopsies: a quantitative structural comparison of histological sections and micro-computed tomography. Bone. July 1998;23(1):59-66.
2014	Carriero A, Zimmermann EA, Paluszny A, Tang SY, Bale H, Busse B, Alliston T, Kazakia G, Ritchie RO, Shefelbine SJ. How tough is brittle bone? investigating osteogenesis imperfecta in mouse bone. J Bone Miner Res. June 2014;29(6):1392-1401.
2004	Kozloff KM, Carden A, Bergwitz C, Forlino A, Uveges TE, Morris MD, Marini JC, Goldstein SA. Brittle IV mouse model for osteogenesis imperfecta IV demonstrates postpubertal adaptations to improve whole bone strength. J Bone Miner Res. April 2004;19(4):614-622.
2022	Kang H, Aryal AC S, Barnes AM, Martin A, David V, Crawford SE, Marini JC. Antagonism between PEDF and TGF-β contributes to type VI osteogenesis imperfecta bone and vascular pathogenesis. J Bone Miner Res. May 2022;37(5):925-937.
2000	Glorieux FH, Travers R, Taylor A, Bowen JR, Rauch F, Norman M, Parfitt AM. Normative data for iliac bone histomorphometry in growing children. Bone. February 2000;26(2):103-109.
2016	Granke M, Makowski AJ, Uppuganti S, Nyman JS. Prevalent role of porosity and osteonal area over mineralization heterogeneity in the fracture toughness of human cortical bone. J Biomech. September 6, 2016;49(13):2748-2755.
2013	Dempster DW, Compston JE, Drezner MK, Glorieux FH, Kanis JA, Malluche H, Meunier PJ, Ott SM, Recker RR, Parfitt AM. Standardized nomenclature, symbols, and units for bone histomorphometry: a 2012 update of the report of the ASBMR Histomorphometry Nomenclature Committee. J Bone Miner Res. January 2013;28(1):2-17.

Cited By (1)

Year	Entry
2023	Misof BM, Roschger P, Mähr M, Fratzl-Zelman N, Glorieux FH, Hartmann MA, Rauch F, Blouin S. Accelerated mineralization kinetics in children with osteogenesis imperfecta type 1. Bone. January 2023;166:116580.