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Abstract

Some genetic disorders are associated with distinctive facial features, which can aid in diagnosis. While considerable advances have been made in identifying causal genes, relatively little progress has been made toward understanding how a particular genotype results in a characteristic craniofacial phenotype. An example is sclerosteosis/van Buchem disease, which is caused by mutations in the Wnt inhibitor sclerostin (SOST). Affected patients have a high bone mass coupled with a distinctive appearance where the mandible is enlarged and the maxilla is foreshortened. Here, mice carrying a null mutation in Sost were analyzed using quantitative micro–computed tomographic (µCT) imaging and histomorphometric analyses to determine the extent to which the size and shape of craniofacial skeleton were altered. Sost^−/− mice exhibited a significant increase in appositional bone growth, which increased the height and width of the mandible and reduced the diameters of foramina. In vivo fluorochrome labeling, histology, and immunohistochemical analyses indicated that excessive bone deposition in the premaxillary suture mesenchyme curtailed overall growth, leading to midfacial hypoplasia. The amount of bone extracellular matrix produced by Sost^−/− cells was significantly increased; as a consequence, osteoid seams were evident throughout the facial skeleton. Collectively, these analyses revealed a remarkable fidelity between human characteristics of sclerosteosis/van Buchem disease and the Sost^−/− phenotype and provide clues into the conserved role for sclerostin signaling in modulating craniofacial morphology.

Keywords

Wnt signaling pathway facial bones craniofacial abnormalities periosteum cranial sutures

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References

Balemans

Ebeling

Patel

Van Hul

Olson

Dioszegi

Lacza

Wuyts

Van Den Ende

Willems

, et al. 2001. Increased bone density in sclerosteosis is due to the deficiency of a novel secreted protein (SOST). Hum Mol Genet. 10(5):537–543.

Balemans

Patel

Ebeling

Van Hul

Wuyts

Lacza

Dioszegi

Dikkers

Hildering

Willems

, et al. 2002. Identification of a 52 kb deletion downstream of the SOST gene in patients with van Buchem disease. J Med Genet. 39(2):91–97.

Balemans

Van Den Ende

Freire Paes-Alves

Dikkers

Willems

Vanhoenacker

de Almeida-Melo

Alves

Stratakis

Hill

, et al. 1999. Localization of the gene for sclerosteosis to the van Buchem disease-gene region on chromosome 17q12-q21. Am J Hum Genet. 64(6):1661–1669.

Chalmers

Barclay

Davison

Macleod

Williams

. 1969. Quantitative measurements of osteoid in health and disease. Clin Orthop Relat Res. 63:196–209.

Chang

Kramer

Huber

Kinzel

Guth-Gundel

Leupin

Kneissel

. 2014. Disruption of Lrp4 function by genetic deletion or pharmacological blockade increases bone mass and serum sclerostin levels. Proc Natl Acad Sci USA. 111(48):E5187–E5195.

Chen

Yuan

Bahat

Helms

. 2020. Bioactivating a bone substitute accelerates graft incorporation in a murine model of vertical ridge augmentation. Dent Mater. 36(10):1303–1313.

Choi

Arron

Townsend

. 2009. Promising bone-related therapeutic targets for rheumatoid arthritis. Nat Rev Rheumatol. 5(10):543–548.

Costa

Bilezikian

. 2012. Sclerostin: therapeutic horizons based upon its actions. Curr Osteoporos Rep. 10(1):64–72.

Delgado-Calle

Anderson

Cregor

Condon

Kuhstoss

Plotkin

Bellido

Roodman

. 2017. Genetic deletion of Sost or pharmacological inhibition of sclerostin prevent multiple myeloma-induced bone disease without affecting tumor growth. Leukemia. 31(12):2686–2694.

10.

Delgado-Calle

Sato

Bellido

. 2017. Role and mechanism of action of sclerostin in bone. Bone. 96:29–37.

11.

Dempster

Compston

Drezner

Glorieux

Kanis

Malluche

Meunier

Ott

Recker

Parfitt

. 2013. Standardized nomenclature, symbols, and units for bone histomorphometry: a 2012 update of the report of the ASBMR Histomorphometry Nomenclature Committee.J Bone Miner Res. 28(1):2–17.

12.

Duan

Bonewald

. 2016. The role of the Wnt/β-catenin signaling pathway in formation and maintenance of bone and teeth. Int J Biochem Cell Biol. 77(pt A):23–29.

13.

Gorlin

Cohen

Levin

. 1990. Syndromes of the head and neck. New York: Oxford University Press.

14.

Hennessy

Stringer

. 2002. Geometric morphometric study of the regional variation of modern human craniofacial form. Am J Phys Anthropol. 117(1):37–48.

15.

Janssens

Van Hul

. 2002. Molecular genetics of too much bone. Hum Mol Genet. 11(20):2385–2393.

16.

Lewiecki

Dinavahi

Lazaretti-Castro

Ebeling

Adachi

Miyauchi

Gielen

Milmont

Libanati

Grauer

. 2019. One year of romosozumab followed by two years of denosumab maintains fracture risk reductions: results of the FRAME extension study. J Bone Miner Res. 34(3):419–428.

17.

Johnson

Smith

Salmon

Shi

Brunski

Helms

. 2015. Disrupting the intrinsic growth potential of a suture contributes to midfacial hypoplasia. Bone. 81:186–195.

18.

Ominsky

Niu

Sun

Daugherty

D’Agostin

Kurahara

Gao

Cao

Gong

, et al. 2008. Targeted deletion of the sclerostin gene in mice results in increased bone formation and bone strength. J Bone Miner Res. 23(6):860–869.

19.

Zhang

Kang

Liu

Zhang

Harris

. 2005. Sclerostin binds to LRP5/6 and antagonizes canonical Wnt signaling. J Biol Chem. 280(20):19883–19887.

20.

Lim

Liu

Hunter

Cheng

Mah

Helms

. 2014. Downregulation of Wnt causes root resorption. Am J Orthod Dentofacial Orthop. 146(3):337–345.

21.

Lustig

Jerchow

Sachs

Weiler

Pietsch

Karsten

van de Wetering

Clevers

Schlag

Birchmeier

, et al. 2002. Negative feedback loop of Wnt signaling through upregulation of conductin/axin2 in colorectal and liver tumors. Mol Cell Biol. 22(4):1184–1193.

22.

Parsons

. 1930. Alveolar and facial prognathism. J Anat. 65(pt 1):149–151.

23.

Sato

Cregor

Delgado-Calle

Condon

Allen

Peacock

Plotkin

Bellido

. 2016. Protection from glucocorticoid-induced osteoporosis by anti-catabolic signaling in the absence of Sost/sclerostin. J Bone Miner Res. 31(10):1791–1802.

24.

Scheiber

Barton

Khoury

Marini

Swiderski

Caird

Kozloff

. 2019. Sclerostin antibody-induced changes in bone mass are site specific in developing crania. J Bone Miner Res. 34(12):2301–2310.

25.

Schwarze

Dobsak

Gruber

Bookstein

. 2019. Anatomical similarity between the Sost-knockout mouse and sclerosteosis in humans. Anat Rec (Hoboken). 303(9):2295–2308.

26.

Sicher

. 1946. The growth of the mandible. J Dent Res. 25:158.

27.

Stein

Witkop

Hill

Fallon

Viernstein

Gucer

McKeever

Long

Altman

Miller

, et al. 1983. Sclerosteosis: neurogenetic and pathophysiologic analysis of an American kinship. Neurology. 33(3):267–277.

28.

Stephen

Hamersma

Gardner

Beighton

. 2001. Dental and oral manifestations of sclerosteosis. Int Dent J. 51(4):287–290.

29.

Delgado-Calle

Condon

Maycas

Zhang

Carlesso

Taketo

Burr

Plotkin

Bellido

. 2015. Osteocytes mediate the anabolic actions of canonical Wnt/β-catenin signaling in bone. Proc Natl Acad Sci USA. 112(5):E478–E486.

30.

van Bezooijen

Bronckers

Gortzak

Hogendoorn

van der Wee-Pals

Balemans

Oostenbroek

Van Hul

Hamersma

Dikkers

, et al. 2009. Sclerostin in mineralized matrices and van Buchem disease. J Dent Res. 88(6):569–574.

31.

van Buchem

Hadders

Hansen

Woldring

. 1962. Hyperostosis corticalis generalisata: report of seven cases. Am J Med. 33:387–397.

32.

Van Hul

Balemans

Van Hul

Dikkers

Obee

Stokroos

Hildering

Vanhoenacker

Van Camp

Willems

. 1998. van Buchem disease (hyperostosis corticalis generalisata) maps to chromosome 17q12-q21. Am J Hum Genet. 62(2):391–399.

33.

van Lierop

Hamdy

Hamersma

van Bezooijen

Power

Loveridge

Papapoulos

. 2011. Patients with sclerosteosis and disease carriers: human models of the effect of sclerostin on bone turnover. J Bone Miner Res. 26(12):2804–2811.

34.

Van Wesenbeeck

Cleiren

Gram

Beals

Benichou

Scopelliti

Key

Renton

Bartels

Gong

, et al. 2003. Six novel missense mutations in the LDL receptor-related protein 5 (LRP5) gene in different conditions with an increased bone density. Am J Hum Genet. 72(3):763–771.

35.

Weivoda

Youssef

Oursler

. 2017. Sclerostin expression and functions beyond the osteocyte. Bone. 96:45–50.

36.

Winkler

Sutherland

Geoghegan

Hayes

Skonier

Shpektor

Jonas

Kovacevich

Staehling-Hampton

, et al. 2003. Osteocyte control of bone formation via sclerostin, a novel BMP antagonist. Embo J. 22(23):6267–6276.

37.

Yuan

Perez

Hyman

Wang

Pellegrini

Salmon

Bellido

Helms

. 2019. Aberrantly elevated Wnt signaling is responsible for cementum overgrowth and dental ankylosis. Bone. 122:176–183.

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Molecular Basis for Craniofacial Phenotypes Caused by Sclerostin Deletion

Abstract

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