Osteocyte mechanosensing following short-term and long-term treatment with sclerostin antibody

wbldb

Morrell, Andrea E.¹; Robinson, Samuel T.¹; Ke, Hua Zhu^2,3; Holdsworth, Gill²; Guo, X. Edward¹

Osteocyte mechanosensing following short-term and long-term treatment with sclerostin antibody

Bone. August 2021;149:115967

©2021 Elsevier Inc. All rights reserved.

Affiliations

¹Bone Bioengineering Lab, Department of Biomedical Engineering, 365 Engineering Terrace, 1210 Amsterdam Avenue, Columbia University, New York, NY 10027, United States of America

²UCB Pharma, 208 Bath Road, Slough SL1 3WE, UK

³Angitia Biopharmaceuticals, Guangzhou, Guangdong, China
Abstract and keywords

Sclerostin antibody romosozumab (EVENITY™, romosozumab-aqqg) has a dual mechanism of action on bone, increasing bone formation and decreasing bone resorption, leading to increases in bone mass and strength, and a decreased risk of fracture, and has been approved for osteoporosis treatment in patients with high risk of fragility fractures. The bone formation aspect of the response to sclerostin antibody treatment has thus far been best described as having two phases: an immediate and robust phase of anabolic bone formation, followed by a long-term response characterized by attenuated bone accrual. We herein test the hypothesis that following the immediate pharmacologic anabolic response, the changes in bone morphology result in altered (lesser) mechanical stimulation of the resident osteocytes, initiating a negative feedback signal quantifiable by a reduced osteocyte signaling response to load. This potential desensitization of the osteocytic network is probed via a novel ex vivo assessment of intracellular calcium (Ca²⁺+) oscillations in osteocytes below the anteromedial surface of murine tibiae subjected to load after short-term (2 weeks) or long-term (8 weeks) treatment with sclerostin antibody or vehicle control. We found that for both equivalent load levels and equivalent strain levels, osteocyte Ca²⁺+ dynamics are maintained between tibiae from the control mice and the mice that received long-term sclerostin antibody treatment. Furthermore, under matched strain environments, we found that short-term sclerostin antibody treatment results in a reduction of both the number of responsive cells and the speed of their responses, which we attribute largely to the probability that the observed cells in the short-term group are relatively immature osteocytes embedded during initial pharmacologic anabolism. Within this study, we demonstrate that osteocytes embedded following long-term sclerostin antibody treatment exhibit localized Ca²⁺+ signaling akin to those of mature osteocytes from the vehicle group, and thus, systemic attenuation of responses such as circulating P1NP and bone formation rates likely occur as a result of processes downstream of osteocyte Ca²⁺+ signaling.

Keywords: Osteocytes; Mechanobiology; Calcium signaling; Sclerostin antibody
Links

DOI: 10.1016/j.bone.2021.115967

PubMed: 33892178

WoS: 000670402800011
History

Received: 2021-01-25

Revised: 2021-04-13

Accepted: 2021-04-15

Online: 2021-04-21

Cited Works (22)

Year	Entry
2013	Weatherholt AM, Fuchs RK, Warden SJ. Cortical and trabecular bone adaptation to incremental load magnitudes using the mouse tibial axial compression loading model. Bone. January 2013;52(1):372-379.
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.
2005	Glass DA II, Bialek P, Ahn JD, Starbuck M, Patel MS, Clevers H, Taketo MM, Long F, McMahon AP, Lang RA, Karsenty G. Canonical Wnt signaling in differentiated osteoblasts controls osteoclast differentiation. Dev Cell. May 2005;8(5):751-764.
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.
2008	Li X, Ominsky MS, Niu Q, Sun N, Daugherty B, D'Agostin D, Kurahara C, Gao Y, Cao J, Gong J, Asuncion F, Barrero M, Warmington K, Dwyer D, Stolina M, Morony S, Sarosi I, Kostenuik PJ, Lacey DL, Simonet WS, Ke HZ, Paszty C. Targeted deletion of the sclerostin gene in mice results in increased bone formation and bone strength. J Bone Miner Res. June 2008;23(6):860-869.
2004	van Bezooijen RL, Roelen BAJ, Visser A, van der Wee-Pals L, de Wilt E, Karperien M, Hamersma H, Papapoulos SE, ten Dijke P, Löwik CWGM. Sclerostin is an osteocyte-expressed negative regulator of bone formation, but not a classical BMP antagonist. J Exp Med. March 15, 2004;199(6):805-814.
2005	Semënov M, Tamai K, He X. SOST is a ligand for LRP5/LRP6 and a Wnt signaling inhibitor. J Biol Chem. July 22, 2005;280(29):26770-26775.
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.
2012	Lu XL, Huo B, Chiang V, Guo XE. Osteocytic network is more responsive in calcium signaling than osteoblastic network under fluid flow. J Bone Miner Res. March 2012;27(3):563-574.
2001	Gong Y, Slee RB, Fukai N, Rawadi G, Roman-Roman S, Reginato AM, Wang H, Cundy T, Glorieux FH, Lev D, Zacharin M, Oexle K, Marcelino J, Suwairi W, Heeger S, Sabatakos G, Apte S, Adkins WN, Allgrove J, Arslan-Kirchner M, Batch JA, Beighton P, Black GCM, Boles RG, Boon LM, Borrone C, Brunner HG, Carle GF, Dallapiccola B, De Paepe A, Floege B, Halfhide ML, Hall B, Hennekam RC, Hirose T, Jans A, Jüppner H, Kim CA, Keppler-Noreuil K, Kohlschuetter A, LaCombe D, Lambert M, Lemyre E, Letteboer T, Peltonen L, Ramesar RS, Romanengo M, Somer H, Steichen-Gersdorf E, Steinmann B, Sullivan B, Superti-Furga A, Swoboda W, van den Boogaard M-J, Van Hul W, Vikkula M, Votruba M, Zabel B, Garcia T, Baron R, Olsen BR, Warman ML. LDL receptor-related protein 5 (LRP5) affects bone accrual and eye development. Cell. November 16, 2001;107(4):513-523.
2012	Lu XL, Huo B, Park M, Guo XE. Calcium response in osteocytic networks under steady and oscillatory fluid flow. Bone. September 2012;51(3):466-473.
2005	Poole KES, Van Bezooijen RL, Loveridge N, Hamersma H, Papapoulos SE, Löwik CW, Reeve J. Sclerostin is a delayed secreted product of osteocytes that inhibits bone formation. FASEB J. August 2005;19(10):1842-1844.
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	Schaffler MB, Cheung W-Y, Majeska R, Kennedy O. Osteocytes: master orchestrators of bone. Calcif Tiss Int. January 2014;94(1):5-24.
2002	Judex S, Donahue L, Rubin C. Genetic predisposition to low bone mass is paralleled by an enhanced sensitivity to signals anabolic to the skeleton. FASEB J. August 2002;16(10):1280-1282.
2016	Cosman F, Crittenden DB, Adachi JD, Binkley N, Czerwinski E, Ferrari S, Hofbauer LC, Lau E, Lewiecki EM, Miyauchi A, Zerbini CAF, Milmont CE, Chen L, Maddox J, Meisner PD, Libanati C, Grauer A. Romosozumab treatment in postmenopausal women with osteoporosis. NEJM. October 20, 2016;375(16):1532-1543.
2014	Jing D, Baik AD, Lu XL, Zhou B, Lai X, Wang L, Luo E, Guo XE. In situ intracellular calcium oscillations in osteocytes in intact mouse long bones under dynamic mechanical loading. FASEB J. April 2014;28(4):1582-1592.
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.
2017	Kim SW, Lu Y, Williams EA, Lai F, Lee JY, Enishi T, Balani DH, Ominsky MS, Ke HZ, Kronenberg HM, Wein MN. Sclerostin antibody administration converts bone lining cells into active osteoblasts. J Bone Miner Res. May 2017;32(5):892-901.
2001	Balemans W, Ebeling M, Patel N, Van Hul E, Olson P, Dioszegi M, Lacza C, Wuyts W, Van Den J Ende, Willems P, Paes-Alves AF, Hill S, Bueno M, Ramos FJ, Tacconi P, Dikkers FG, Stratakis C, Lindpaintner K, Vickery B, Foernzler D, Van Hul W. Increased bone density in sclerosteosis is due to the deficiency of a novel secreted protein (SOST). Hum Mol Genet. March 1, 2001;10(5):537-543.
2007	Burge R, Dawson‐Hughes B, Solomon DH, Wong JB, King A, Tosteson A. Incidence and economic burden of osteoporosis‐related fractures in the United States, 2005–2025. J Bone Miner Res. March 2007;22(3):465-475.
2003	Winkler DG, Sutherland MK, Geoghegan JC, Yu C, Hayes T, Skonier JE, Shpektor D, Jonas M, Kovacevich BR, Staehling-Hampton K, Appleby M, Brunkow ME, Latham JA. Osteocyte control of bone formation via sclerostin, a novel BMP antagonist. EMBO J. January 2003;22(23):6267-6276.