Sclerostin antibody administration converts bone lining cells into active osteoblasts

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Kim, Sang Wan^1,*; Lu, Yanhui^2,*; Williams, Elizabeth A.²; Lai, Forest³; Lee, Ji Yeon¹; Enishi, Tetsuya²; Balani, Deepak H.²; Ominsky, Michael S.^4,5; Ke, Hua Zhu^4,6; Kronenberg, Henry M.^2,†; Wein, Marc N.^2,†

Sclerostin antibody administration converts bone lining cells into active osteoblasts

J Bone Miner Res. May 2017;32(5):892-901

©2016 American Society for Bone and Mineral Research

^*These authors contributed equally.

^†These authors contributed equally.

Affiliations

¹Department of Internal Medicine, Seoul National University College of Medicine and Boramae Medical Center, Seoul, Republic of Korea

²Endocrine Unit, Massachusetts General Hospital, Harvard Medical School, Boston, MA, USA

³Henry M. Goldman School of Dental Medicine, Boston University, Boston, MA, USA

⁴Department of Metabolic Disorders, Amgen Inc., Thousand Oaks, CA, USA

⁴Department of Metabolic Disorders, Amgen Inc., Thousand Oaks, CA, USA

⁵Present address: Radius Health Inc., Waltham, MA, USA

⁶Present address: New Medicines, UCB Pharma, Slough, UK
Abstract and keywords

Sclerostin antibody (Scl-Ab) increases osteoblast activity, in part through increasing modeling-based bone formation on previously quiescent surfaces. Histomorphometric studies have suggested that this might occur through conversion of bone lining cells into active osteoblasts. However, direct data demonstrating Scl-Ab-induced conversion of lining cells into active osteoblasts are lacking. Here, we used in vivo lineage tracing to determine if Scl-Ab promotes the conversion of lining cells into osteoblasts on periosteal and endocortical bone surfaces in mice. Two independent, tamoxifen-inducible lineage-tracing strategies were used to label mature osteoblasts and their progeny using the DMP1 and osteocalcin promoters. After a prolonged “chase” period, the majority of labeled cells on bone surfaces assumed a thin, quiescent morphology. Then, mice were treated with either vehicle or Scl-Ab (25 mg/kg) twice over the course of the subsequent week. After euthanization, marked cells were enumerated, their thickness quantified, and proliferation and apoptosis examined. Scl-Ab led to a significant increase in the average thickness of labeled cells on periosteal and endocortical bone surfaces, consistent with osteoblast activation. Scl-Ab did not induce proliferation of labeled cells, and Scl-Ab did not regulate apoptosis of labeled cells. Therefore, direct reactivation of quiescent bone lining cells contributes to the acute increase in osteoblast numbers after Scl-Ab treatment in mice.

Keywords: OSTEOBLASTS; MOLECULAR PATHWAYS–REMODELING; WNT/ß-CATENIN/LRPS; ANABOLICS; PRECLINICAL STUDIES
Links

DOI: 10.1002/jbmr.3038

PubMed: 27862326

WoS: 000400590900003
History

Received: 2016-09-07

Revised: 2016-10-31

Accepted: 2016-11-08

Online: 2016-11-14

Cited Works (20)

Year	Entry
2005	Li X, Zhang Y, Kang H, Liu W, Liu P, Zhang J, Harris SE, Wu D. Sclerostin binds to LRP5/6 and antagonizes canonical Wnt signaling. J Biol Chem. May 20, 2005;280(20):19883-19887.
2009	Li X, Ominsky MS, Warmington KS, Morony S, Gong J, Cao J, Gao Y, Shalhoub V, Tipton B, Haldankar R, Chen Q, Winters A, Boone T, Geng Z, Niu Q-T, Ke HZ, Kostenuik PJ, Simonet WS, Lacey DL, Paszty C. Sclerostin antibody treatment increases bone formation, bone mass, and bone strength in a rat model of postmenopausal osteoporosis. J Bone Miner Res. April 2009;24(4):578-588.
2011	Padhi D, Jang G, Stouch B, Fang L, Posvar E. Single‐dose, placebo‐controlled, randomized study of AMG 785, a sclerostin monoclonal antibody. J Bone Miner Res. January 2011;26(1):19-26.
2013	Tsai JN, Uihlein AV, Lee H, Kumbhani R, Siwila-Sackman E, McKay EA, Burnett-Bowie S-AM, Neer RM, Leder BZ. Teriparatide and denosumab, alone or combined, in women with postmenopausal osteoporosis: the DATA study randomised trial. Lancet. July 6, 2013;382(9886):50-56.
2001	Brunkow ME, Gardner JC, Van Ness J, Paeper BW, Kovacevich BR, Proll S, Skonier JE, Zhao L, Sabo P, Fu Y-H, Alisch RS, Gillett L, Colbert T, Tacconi P, Galas D, Hamersma H, Beighton P, Mulligan JT. Bone dysplasia sclerosteosis results from loss of the SOST gene product, a novel cystine knot–containing protein. Am J Hum Genet. March 2001;68(3):577-589.
1995	Dobnig H, Turner RT. Evidence that intermittent treatment with parathyroid hormone increases bone formation in adult rats by activation of bone lining cells. Endocrinology. August 1995;136(8):3632-3638.
2012	Estrada K, Styrkarsdottir U, Evangelou E, Hsu Y-H, Duncan EL, Ntzani EE, Oei L, Albagha OME, Amin N, Kemp JP, Koller DL, Li G, Liu C-T, Minster RL, Moayyeri A, Vandenput L, Willner D, Xiao S-M, Yerges-Armstrong LM, Zheng H-F, Alonso N, Eriksson J, Kammerer CM, Kaptoge SK, Leo PJ, Thorleifsson G, Wilson SG, Wilson JF, Aalto V, Alen M, Aragaki AK, Aspelund T, Center JR, Dailiana Z, Duggan DJ, Garcia M, Garcia-Giralt N, Giroux S, Hallmans G, Hocking LJ, Husted LB, Jameson KA, Khusainova R, Kim GS, Kooperberg C, Koromila T, Kruk M, Laaksonen M, Lacroix AZ, Lee SH, Leung PC, Lewis JR, Masi L, Mencej-Bedrac S, Nguyen TV, Nogues X, Patel MS, Prezelj J, Rose LM, Scollen S, Siggeirsdottir K, Smith AV, Svensson O, Trompet S, Trummer O, van Schoor NM, Woo J, Zhu K, Balcells S, Brandi ML, Buckley BM, Cheng S, Christiansen C, Cooper C, Dedoussis G, Ford I, Frost M, Goltzman D, González-Macías J, Kähönen M, Karlsson M, Khusnutdinova E, Koh J-M, Kollia P, Langdahl BL, Leslie WD, Lips P, Ljunggren Ö, Lorenc RS, Marc J, Mellström D, Obermayer-Pietsch B, Olmos JM, Pettersson-Kymmer U, Reid DM, Riancho JA, Ridker PM, Rousseau F, Slagboom PE, Tang NLS, Urreizti R, Van Hul W, Viikari J, Zarrabeitia MT, Aulchenko YS, Castano-Betancourt M, Grundberg E, Herrera L, Ingvarsson T, Johannsdottir H, Kwan T, Li R, Luben R, Medina-Gómez C, Palsson ST, Reppe S, Rotter JI, Sigurdsson G, van Meurs JBJ, Verlaan D, Williams FMK, Wood AR, Zhou Y, Gautvik KM, Pastinen T, Raychaudhuri S, Cauley JA, Chasman DI, Clark GR, Cummings SR, Danoy P, Dennison EM, Eastell R, Eisman JA, Gudnason V, Hofman A, Jackson RD, Jones G, Jukema JW, Khaw K-T, Lehtimäki T, Liu Y, Lorentzon M, McCloskey E, Mitchell BD, Nandakumar K, Nicholson GC, Oostra BA, Peacock M, Pols HAP, Prince RL, Raitakari O, Reid IR, Robbins J, Sambrook PN, Sham PC, Shuldiner AR, Tylavsky FA, van Duijn CM, Wareham NJ, Cupples LA, Econs MJ, Evans DM, Harris TB, Kung AWC, Psaty BM, Reeve J, Spector TD, Streeten EA, Zillikens MC, Thorsteinsdottir U, Ohlsson C, Karasik D, Richards JB, Brown MA, Stefansson K, Uitterlinden AG, Ralston SH, Ioannidis JPA, Kiel DP, Rivadeneira F. Genome-wide meta-analysis identifies 56 bone mineral density loci and reveals 14 loci associated with risk of fracture. Nat Genet. April 15, 2012;44(5):491-501.
2014	Ominsky MS, Niu Q-T, Li C, Li X, Ke HZ. Tissue-level mechanisms responsible for the increase in bone formation and bone volume by sclerostin antibody. J Bone Miner Res. June 2014;29(6):1424-1430.
2012	Kim SW, Pajevic PD, Selig M, Barry KJ, Yang J-Y, Shin CS, Baek W-Y, Kim J-E, Kronenberg HM. Intermittent parathyroid hormone administration converts quiescent lining cells to active osteoblasts. J Bone Miner Res. October 2012;27(10):2075-2084.
2012	Tu X, Rhee Y, Condon KW, Bivi N, Allen MR, Dwyer D, Stolina M, Turner CH, Robling AG, Plotkin LI, Bellido T. Sost downregulation and local Wnt signaling are required for the osteogenic response to mechanical loading. Bone. January 2012;50(1):209-217.
2010	Ominsky MS, Vlasseros F, Jolette J, Smith SY, Stouch B, Doellgast G, Gong J, Gao Y, Cao J, Graham K, Tipton B, Cai J, Deshpande R, Zhou L, Hale MD, Lightwood DJ, Henry AJ, Popplewell AG, Moore AR, Robinson MK, Lacey DL, Simonet WS, Paszty C. Two doses of sclerostin antibody in cynomolgus monkeys increases bone formation, bone mineral density, and bone strength. J Bone Miner Res. May 2010;25(5):948-959.
2014	McClung MR, Grauer A, Boonen S, Bolognese MA, Brown JP, Diez-Perez A, Langdahl BL, Reginster J-Y, Zanchetta JR, Wasserman SM, Katz L, Maddox J, Yang Y-C, Libanati C, Bone HG. Romosozumab in postmenopausal women with low bone mineral density. NEJM. January 30, 2014;370(5):412-420.
2014	Zhou BO, Yue R, Murphy MM, Peyer JG, Morrison SJ. Leptin-receptor-expressing mesenchymal stromal cells represent the main source of bone formed by adult bone marrow. Cell Stem Cell. August 7, 2014;15(2):154-168.
2010	Madisen L, Zwingman TA, Sunkin SM, Oh SW, Zariwala HA, Gu H, Ng LL, Palmiter RD, Hawrylycz MJ, Jones AR, Lein ES, Zeng H. A robust and high-throughput Cre reporting and characterization system for the whole mouse brain. Nat Neurosci. January 2010;13(1):133-140.
2005	Keller H, Kneissel M. SOST is a target gene for PTH in bone. Bone. August 2005;37(2):148-158.
2010	Kramer I, Loots GG, Studer A, Keller H, Kneissel M. Parathyroid hormone (PTH)–induced bone gain is blunted in SOST overexpressing and deficient mice. J Bone Miner Res. February 2010;25(2):178-189.
1989	Miller SC, de Saint-Georges L, Bowman BM, Jee WSS. Bone lining cells: structure and function. Scanning Microsc. 1989;3(3):953-961.
2010	Maes C, Kobayashi T, Selig MK, Torrekens S, Roth SI, Mackem S, Carmeliet G, Kronenberg HM. Osteoblast precursors, but not mature osteoblasts, move into developing and fractured bones along with invading blood vessels. Dev Cell. August 17, 2010;19(2):329-344.
2008	Robling AG, Niziolek PJ, Baldridge LA, Condon KW, Allen MR, Alam I, Mantila SM, Gluhak-Heinrich J, Bellido TM, Harris SE, Turner CH. Mechanical stimulation of bone in vivo reduces osteocyte expression of Sost/sclerostin. J Biol Chem. February 29, 2008;283(9):5866-5875.
2013	Baron R, Kneissel M. WNT signaling in bone homeostasis and disease: from human mutations to treatments. Nat Med. February 2013;19(2):179-192.

Cited By (18)

Year	Entry
2020	Delaisse J-M, Andersen TL, Kristensen HB, Jensen PR, Andreasen CM, Søe K. Re-thinking the bone remodeling cycle mechanism and the origin of bone loss. Bone. December 2020;141:115628.
2021	Lim K-E, Bullock WA, Horan DJ, Williams BO, Warman ML, Robling AG. Co-deletion of Lrp5 and Lrp6 in the skeleton severely diminishes bone gain from sclerostin antibody administration. Bone. February 2021;143:115708.
2021	Costa S, Fairfield H, Farrell M, Murphy CS, Soucy A, Vary C, Holdsworth G, Reagan MR. Sclerostin antibody increases trabecular bone and bone mechanical properties by increasing osteoblast activity damaged by whole-body irradiation in mice. Bone. June 2021;147:115918.
2021	Morrell AE, Robinson ST, Ke HZ, Holdsworth G, Guo XE. Osteocyte mechanosensing following short-term and long-term treatment with sclerostin antibody. Bone. August 2021;149:115967.
2022	Carpenter KA, Davison R, Shakthivel S, Anderson KD, Ko FC, Ross RD. Sclerostin antibody improves phosphate metabolism hormones, bone formation rates, and bone mass in adult Hyp mice. Bone. January 2022;154:116201.
2022	Koide M, Yamashita T, Nakamura K, Yasuda H, Udagawa N, Kobayashi Y. Evidence for the major contribution of remodeling-based bone formation in sclerostin-deficient mice. Bone. July 2022;160:116401.
2023	van Dijk Christiansen P, Andreasen CM, El-Masri BM, Laursen KS, Delaisse J-M, Andersen TL. Osteoprogenitor recruitment and differentiation during intracortical bone remodeling of adolescent humans. Bone. December 2023;177:116896.
2020	Matthews BG, Wee NKY, Widjaja VN, Price JS, Kalajzic I, Windahl SH. ΑSMA osteoprogenitor cells contribute to the increase in osteoblast numbers in response to mechanical loading. Calcif Tiss Int. February 2020;106(2):208-217.
2020	Carpenter KA, Ross RD. Sclerostin antibody treatment increases bone mass and normalizes circulating phosphate levels in growing Hyp mice. J Bone Miner Res. March 2020;35(3):596-607.
2020	Ayturk UM, Scollan JP, Ayturk DG, Suh ES, Vesprey A, Jacobsen CM, Pajevic PD, Warman ML. Single‐cell RNA sequencing of calvarial and long‐bone endocortical cells. J Bone Miner Res. October 2020;35(10):1981-1991.
2021	Gerbaix M, Ammann P, Ferrari S. Mechanically driven counter‐regulation of cortical bone formation in response to sclerostin‐neutralizing antibodies. J Bone Miner Res. February 2021;36(2):385-399.
2021	Balani DH, Trinh S, Xu M, Kronenberg HM. Sclerostin antibody administration increases the numbers of Sox9creER+ skeletal precursors and their progeny. J Bone Miner Res. April 2021;36(4):757-767.
2022	Eriksen EF, Chapurlat R, Boyce RW, Shi Y, Brown JP, Horlait S, Betah D, Libanati C, Chavassieux P. Modeling-based bone formation after 2 months of romosozumab treatment: results from the FRAME clinical trial. J Bone Miner Res. January 2022;37(1):36-40.
2023	Atkinson EG, Adaway M, Horan DJ, Korff C, Klunk A, Orr AL, Ratz K, Bellido T, Plotkin LI, Robling AG, Bidwell JP. Conditional loss of Nmp4 in mesenchymal stem progenitor cells enhances PTH-induced bone formation. J Bone Miner Res. January 2023;38(1):70-85.
2023	Sano H, Whitmarsh T, Skingle L, Shimakura T, Yamamoto N, Compston JE, Takahashi HE, Poole KES. Buds of new bone formation within the femoral head of hip fracture patients coincide with zones of low osteocyte sclerostin. J Bone Miner Res. November 2023;38(11):1603-1611.
2019	Ilas DC. The Role of Mesenchymal Stem Cells and Osteocytes in Subchondral Bone Changes in Hip Osteoarthritis [PhD thesis]. University of Leeds; May 2019.
2019	Surowiec R. Novel Models to Image and Quantify Bone Drug Efficacy and Disease Progression in Vivo: Addressing the Fragility Phenotype [PhD thesis]. University of Michigan; 2019.
2021	Harris TL. Mechanisms for Osteoblast and Osteocyte Initiation and Sustainment of Bone Formation in Young-Adult and Aged Mice [PhD thesis]. St. Louis, MO: Washington University in St. Louis; August 2021.