Top

Current Osteoporosis Reports

Published in:

01-12-2018 | Biomechanics (G Niebur and J Wallace, Section Editors)

In Vivo Osteocyte Mechanotransduction: Recent Developments and Future Directions

Authors: Paige V. Hinton, Susan M. Rackard, Oran D. Kennedy

Published in: Current Osteoporosis Reports | Issue 6/2018

Abstract

Purpose of Review

Mechanical loading is an essential stimulus for skeletal tissues. Osteocytes are primarily responsible for sensing mechanical stimuli in bone and for orchestrating subsequent responses. This is critical for maintaining homeostasis, and responding to injury/disease. The osteocyte mechanotransduction pathway, and the downstream effects it mediates, is highly complex. In vivo models have proved invaluable in understanding this process. This review summarizes the commonly used models, as well as more recently developed ones, and describes how they are used to address emerging questions in the field.

Recent Findings

Minimally invasive animal models can be used to determine mechanisms of osteocyte mechanotransduction, at the cell and molecular level, while simultaneously reducing potentially confounding responses such as inflammation/wound-healing.

Summary

The details of osteocyte mechanotransduction in bone are gradually becoming clearer. In vivo model systems are a key tool in pursing this question. Advances in this field are explored and discussed in this review.

Ehrlich PJ, Lanyon LE. Mechanical strain and bone cell function: a review. Osteoporos Int. 2002;13:688–700.CrossRef

• Schaffler MB, Cheung WY, Majeska R, Kennedy O. Osteocytes: master orchestrators of bone. Calcif Tissue Int. 2014;94:5–24 Provides a detailed review of experimental and theoretical approaches used in osteocyte mechanobiology. CrossRef

Dallas SL, Bonewald LF. Dynamics of the transition from osteoblast to osteocyte. Ann N Y Acad Sci. 2010;1192:437–43.CrossRef

Lerner UH. Osteoblasts, osteoclasts, and osteocytes: unveiling their intimate-associated responses to applied orthodontic forces. Remodeling and Modeling of Bone Tissue YSODO. 2012;18:237–48.

Franz-Odendaal TA, Hall BK, Witten PE. Buried alive: how osteoblasts become osteocytes. Dev Dyn. 2006;235:176–90.CrossRef

Schaffler MB, Kennedy OD. Osteocyte signaling in bone. Curr Osteoporos Rep. 2012;10:118–25.CrossRef

• Bonewald LF. The amazing osteocyte. J Bone Miner Res. 2011;26:229–38 Provides an excellent review of osteocyte biology and function. CrossRef

Budyn E, et al. How the morphology of osteocytes contributes to their mechanotransduction near microdamage. MRS Proc. 2015;1724:mrsf14–1724–h12–24.CrossRef

Kato Y, Windle JJ, Koop BA, Mundy GR, Bonewald LF. Establishment of an osteocyte-like cell line, MLO-Y4. J Bone Miner Res. 2010;12:2014–23.CrossRef

10.

• Bonewald LF. Establishment and characterization of an osteocyte-like cell line, MLO-Y4. J Bone Miner Metab. 1999;17:61–5 Describes the establishment of the first osteocyte cell line. CrossRef

11.

Goodship AE, Lanyon LE, McFie H. Functional adaptation of bone to increased stress. An experimental study. J Bone Jt Surgery. 1979;61:539–46.CrossRef

12.

Lee TC, Staines A, Taylor D. Bone adaptation to load: microdamage as a stimulus for bone remodelling. J Anat. 2002;201:437–46.CrossRef

13.

Temiyasathit S, Jacobs CR. Osteocyte primary cilium and its role in bone mechanotransduction. Ann N Y Acad Sci. 2010;1192:422–8.CrossRef

14.

Ducy P, Desbois C, Boyce B, Pinero G, Story B, Dunstan C, et al. Increased bone formation in osteocalcin-deficient mice. Nature. 1996;382:448–52. https://doi.org/10.1038/382448a0.CrossRefPubMed

15.

Wei J, Karsenty G. An overview of the metabolic functions of osteocalcin. Current Osteoporosis Reports. 2015;13:180–5.CrossRef

16.

Sedillot, C. Des moyens d’assurer la réussite des amputations des membres Résultats statistiques des amputations pratiquées par moi pendant la dernière année scolaire. C R Acad Sci. 1852;34

17.

Hert J, Lisková M, Landa J. Reaction of bone to mechanical stimuli. 1. Continuous and intermittent loading of tibia in rabbit. Praha. 1971;19:290–300.

18.

Hert J, Sklenská A, Lisková M. Reaction of bone to mechanical stimuli. 5. Effect of intermittent stress on the rabbit tibia after resection of the peripheral nerves. Praha. 1971;19:378–87.

19.

Meakin LB, Price JS, Lanyon LE. The contribution of experimental in vivo models to understanding the mechanisms of adaptation to mechanical loading in bone. Front Endocrinol. 2014;5.

20.

Lanyon LE, Rubin CT. Static vs dynamic loads as an influence on bone remodelling. J Biomech. 1984;17:897–905.CrossRef

21.

• Lanyon LE. Analysis of surface bone strain in the calcaneus of sheep during normal locomotion Strain analysis of the calcaneus. J Biomech. 1973;6:41–9 Describes one of the earliest methods of measuring surface strain of bone in vivo. CrossRef

22.

Stokes IA, Mente PL, Iatridis JC, Farnum CE, Aronsson DD. Enlargement of growth plate chondrocytes modulated by sustained mechanical loading. J Bone Jt Surg - Ser A. 2002;84:1842–8.CrossRef

23.

Lambers FM, Koch K, Kuhn G, Ruffoni D, Weigt C, Schulte FA, et al. Trabecular bone adapts to long-term cyclic loading by increasing stiffness and normalization of dynamic morphometric rates. Bone. 2013;55:325–34.CrossRef

24.

Seref-Ferlengez Z, Basta-Pljakic J, Kennedy OD, Philemon CJ, Schaffler MB. Structural and mechanical repair of diffuse damage in cortical bone in vivo. J Bone Miner Res. 2014;29:2537–44.CrossRef

25.

Skerry TM, Lanyon LE, Bitensky L, Chayen J. Early strain-related changes in enzyme activity in osteocytes following bone loading in vivo. J Bone Miner Res. 1989;4:783–8.CrossRef

26.

• Turner CH, Akhter MP, Raab DM, Kimmel DB, Recker RR. A noninvasive, in vivo model for studying strain adaptive bone modeling. Bone. 1991;12:73–9 Describes of the early noninvasive bone adaptation models. CrossRef

27.

Akhter MP, Cullen DM, Pedersen EA, Kimmel DB, Recker RR. Bone response to in vivo mechanical loading in two breeds of mice. Calcif Tissue Int. 1998;63:442–9.CrossRef

28.

Gross TS, Srinivasan S, Liu CC, Clemens TL, Bain SD. Noninvasive loading of the murine tibia: an in vivo model for the study of mechanotransduction. J Bone Miner Res. 2002;17:493–501.CrossRef

29.

Connelly JT, Fritton JC & Van Der Meulen MC Simulation of in vivo loading in the tibia of the C57BL/6 mouse. 49th Annu Meet Orthop Res Soc (2003).

30.

Christiansen BA, Anderson MJ, Lee CA, Williams JC, Yik JHN, Haudenschild DR. Musculoskeletal changes following non-invasive knee injury using a novel mouse model of post-traumatic osteoarthritis. Osteoarthr Cartil. 2012;20:773–82.CrossRef

31.

Torrance AG, Mosley JR, Suswillo RFL, Lanyon LE. Noninvasive loading of the rat ulna in vivo induces a strain-related modeling response uncomplicated by trauma or periostal pressure. Calcif Tissue Int. 1994;54:241–7.CrossRef

32.

Lee KCL, Maxwell A, Lanyon LE. Validation of a technique for studying functional adaptation of the mouse ulna in response to mechanical loading. Bone. 2002;31:407–12.CrossRef

33.

Robling AG, Duijvelaar KM, Geevers JV, Ohashi N, Turner CH. Modulation of appositional and longitudinal bone growth in the rat ulna by applied static and dynamic force. Bone. 2001;29:105–13.CrossRef

34.

Robling AG, Niziolek PJ, Baldridge LA, Condon KW, Allen MR, Alam I, et al. Mechanical stimulation of bone in vivo reduces osteocyte expression of Sost/sclerostin. J Biol Chem. 2008;283:5866–75.CrossRef

35.

Lara-Castillo N, et al. In vivo mechanical loading rapidly activates β–catenin signaling in osteocytes through a prostaglandin mediated mechanism HHS public access. Bone. 2015;76:58–66.CrossRef

36.

Guo D, Bonewald LF. Advancing our understanding of osteocyte cell biology. Therapeutic Advances in Musculoskeletal Disease. 2009;1:87–96.CrossRef

37.

Spatz JM, Ellman R, Cloutier AM, Louis L, van Vliet M, Suva LJ, et al. Sclerostin antibody inhibits skeletal deterioration due to reduced mechanical loading. J Bone Miner Res. 2013;28:865–74.CrossRef

38.

Kennedy OD, Laudier DM, Majeska RJ, Sun HB, Schaffler MB. Osteocyte apoptosis is required for production of osteoclastogenic signals following bone fatigue in vivo. Bone. 2014;64:132–7.CrossRef

39.

Vashishth D. Hierarchy of bone microdamage at multiple length scales. Int J Fatigue. 2007;29:1024–33.CrossRef

40.

Bellido T, Saini V, Pajevic PD. Effects of PTH on osteocyte function. Bone. 2013;54:250–7.CrossRef

41.

Verborgt O, Gibson GJ, Schaffler MB. Loss of osteocyte integrity in association with microdamage and bone remodeling after fatigue in vivo. J Bone Miner Res. 2000;15:60–7.CrossRef

42.

Emerton KB, Hu B, Woo AA, Sinofsky A, Hernandez C, Majeska RJ, et al. Osteocyte apoptosis and control of bone resorption following ovariectomy in mice. Bone. 2010;46:577–83.CrossRef

43.

Cardoso L, et al. Osteocyte apoptosis controls activation of intracortical resorption in response to bone fatigue. J BONE Miner Res J Bone Min Res. 2009;2424:597–605.CrossRef

44.

• Fritton JC, Myers ER, Wright TM, Van Der Meulen MCH. Loading induces site-specific increases in mineral content assessed by microcomputed tomography of the mouse tibia. Bone. 2005;36:1030–8 Describes the first tibial loading model to study osteocyte mechanotransduction in trabecular bone. CrossRef

45.

Morse A, McDonald MM, Kelly NH, Melville KM, Schindeler A, Kramer I, et al. Mechanical load increases in bone formation via a Sclerostin-independent pathway. J Bone Miner Res. 2014;29:2456–67. https://doi.org/10.1002/jbmr.2278.CrossRefPubMedPubMedCentral

46.

De Souza RL, et al. Non-invasive axial loading of mouse tibiae increases cortical bone formation and modifies trabecular organization: a new model to study cortical and cancellous compartments in a single loaded element. Bone. 2005;37:810–8.CrossRef

47.

Brodt MD, Silva MJ. Aged mice have enhanced endocortical response and normal periosteal response compared with young-adult mice following 1 week of axial tibial compression. J Bone Miner Res. 2010;25:2006–15.CrossRef

48.

Lynch ME, Main RP, Xu Q, Walsh DJ, Schaffler MB, Wright TM, et al. Cancellous bone adaptation to tibial compression is not sex dependent in growing mice. J Appl Physiol. 2010;109:685–91.CrossRef

49.

Zaman G, Jessop HL, Muzylak M, de Souza RL, Pitsillides AA, Price JS, et al. Osteocytes use estrogen receptor α to respond to strain but their ERα content is regulated by estrogen. J Bone Miner Res. 2006;21:1297–306.CrossRef

50.

Vashishth D, Koontz J, Qiu SJ, Lundin-Cannon D, Yeni YN, Schaffler MB, et al. In vivo diffuse damage in human vertebral trabecular bone. Bone. 2000;26:147–52.CrossRef

51.

Furman BD, Strand J, Hembree WC, Ward BD, Guilak F, Olson SA. Joint degeneration following closed intraarticular fracture in the mouse knee: a model of posttraumatic arthritis. J Orthop Res. 2007;25:578–92.CrossRef

52.

Christiansen BA, Guilak F, Lockwood KA, Olson SA, Pitsillides AA, Sandell LJ, et al. Non-invasive mouse models of post-traumatic osteoarthritis. Osteoarthr Cartil. 2015;23:1627–38.CrossRef

53.

Lockwood KA, Chu BT, Anderson MJ, Haudenschild DR, Christiansen BA. Comparison of loading rate-dependent injury modes in a murine model of post-traumatic osteoarthritis. J Orthop Res. 2014;32:79–88.CrossRef

54.

Ramme AJ, Lendhey M, Raya JG, Kirsch T, Kennedy OD. A novel rat model for subchondral microdamage in acute knee injury: a potential mechanism in post-traumatic osteoarthritis. Osteoarthr Cartil. 2016;24:1776–85.CrossRef

55.

Poulet B, Hamilton RW, Shefelbine S, Pitsillides AA. Characterizing a novel and adjustable noninvasive murine joint loading model. Arthritis Rheum. 2011;63:137–47.CrossRef

56.

Wu P, Holguin N, Silva MJ, Fu M, Liao W, Sandell LJ. Early response of mouse joint tissue to noninvasive knee injury suggests treatment targets. Arthritis Rheum. 2014;66:1256–65.CrossRef

57.

Yan H, et al. Suppression of NF-κB activity via nanoparticle-based siRNA delivery alters early cartilage responses to injury. Proc Natl Acad Sci. 2017;114:–E3871.

58.

Rai, M. F. et al. Post-traumatic osteoarthritis in mice following mechanical injury to the synovial joint. Sci Rep 2017;7.

59.

Matheny JB, Goff MG, Pownder SL, Koff MF, Hayashi K, Yang X, et al. An in vivo model of a mechanically-induced bone marrow lesion. J Biomech. 2017;64:258–61.CrossRef

60.

•• Lewis KJ, et al. Osteocyte calcium signals encode strain magnitude and loading frequency in vivo. Proc Natl Acad Sci. 2017;114:11775–80 Describes a new method of noninvasive mechanical loading to study osteocyte response. CrossRef

61.

Gu X, Spitzer NC. Distinct aspects of neuronal differentiation encoded by frequency of spontaneous Ca2+ transients. Nature. 1995;375:784–7.CrossRef

62.

Pereira AF, Javaheri B, Pitsillides AA, Shefelbine SJ. Predicting cortical bone adaptation to axial loading in the mouse tibia. J R Soc Interface. 2015;12:20150590.CrossRef

63.

Frost H. A determinant of bone architecture. The minimum effective strain. Send to Clin Orthop Relat Res. 1983;175:286–92.

64.

Morey ER, Sabelman EE, Turner RT, Baylink DJ. A new rat model simulating some aspects of space flight. Physiologist. 1979;22:S23–4.PubMed

65.

Judex S, Donahue LR, Rubin C. Genetic predisposition to low bone mass is paralleled by an enhanced sensitivity to signals anabolic to the skeleton. FASEB J. 2002;16:1280–2.CrossRef

66.

Cabahug-Zuckerman P, Frikha-Benayed D, Majeska RJ, Tuthill A, Yakar S, Judex S, et al. Osteocyte apoptosis caused by hind limb unloading is required to trigger osteocyte RANKL production and subsequent resorption of cortical and trabecular bone in mice femurs. J Bone Miner Res. 2016;31:1356–65.CrossRef

67.

Genetos DC, Geist DJ, Liu D, Donahue HJ, Duncan RL. Fluid shear-induced ATP secretion mediates prostaglandin release in MC3T3-E1 osteoblasts. J Bone Miner Res. 2005;20:41–9.CrossRef

68.

Forwood MR, Kelly WL, Worth NF. Localization of prostaglandin endoperoxide H synthase (PGHS)-1 and PGHS- 2 in bone following mechanical loading in vivo. Anat Rec. 1998;252:580–6.CrossRef

69.

Rawlinson SCF, et al. Loading-related increases in prostaglandin production in cores of adult canine cancellous bone in vitro: a role for prostacyclin in adaptive bone remodeling? JBMR. 1991;6:1345–51.CrossRef

70.

•• Robling, A. G. The interaction of biological factors with mechanical signals in bone adaptation: recent. Reviews recent developments in osteocyte mechanotransduction.

71.

Nguyen AM, Young Y-N, Jacobs CR. The primary cilium is a self-adaptable, integrating nexus for mechanical stimuli and cellular signaling. Biol Open. 2015;4:1733–8.CrossRef

72.

Hoey DA, Kelly DJ, Jacobs CR. A role for the primary cilium in paracrime signaling between mechanically stimulated osteocytes and mesenchymal stem cells. Biochem Biophys Res Commun Biochem Biophys Res Commun August. 2011;19:182–7.CrossRef

73.

Jacobs CR, Temiyasathit S, Castillo AB. Osteocyte mechanobiology and pericellular mechanics. Annu Rev Biomed Eng. 2010;12:369–400.CrossRef

74.

Plotkin LI, Speacht TL, Donahue HJ. Cx43 and mechanotransduction in bone. Current Osteoporosis Reports. 2015;13:67–72.CrossRef

75.

Cabahug-Zuckerman P, Stout RF Jr, Majeska RJ, Thi MM, Spray DC, Weinbaum S, et al. Potential role for a specialized β3 integrin-based structure on osteocyte processes in bone mechanosensation. J Orthop Res. 2018;36:642–52.PubMed

76.

Gudi S, Nolan JP, Frangos JA. Modulation of GTPase activity of G proteins by fluid shear stress and phospholipid composition. Proc Natl Acad Sci U S A. 1998;95:2515–9.CrossRef

77.

Zhang Y-L, Frangos JA, Chachisvilis M. Mechanical stimulus alters conformation of type 1 parathyroid hormone receptor in bone cells. Am J Phys Cell Phys. 2009;296:C1391–9.CrossRef

78.

Chachisvilis M, Zhang Y-L, Frangos JA. G protein-coupled receptors sense fluid shear stress in endothelial cells. Proc Natl Acad Sci U S A. 2006;103:15463–8.CrossRef

79.

Javaheri B, Stern AR, Lara N, Dallas M, Zhao H, Liu Y, et al. Deletion of a single β-catenin allele in osteocytes abolishes the bone anabolic response to loading. J Bone Miner Res. 2014;29:705–15.CrossRef

80.

Kang KS, Robling AG. New insights into Wnt-Lrp5/6-β-catenin signaling in mechanotransduction. Front Endocrinol. 2015;6:246.

81.

•• Bonewald LF. The role of the osteocyte in bone and nonbone disease. Endocrinol Metab Clin N Am. 2017;46:1–18 Describes an updated review of role of osteocytes in multiple pathological states. CrossRef

82.

Robling AG, Burr DB, Turner CH. Skeletal loading in animals. J Musculoskelet Neuronal Interact. 2001;1:249–62.PubMed

Title: In Vivo Osteocyte Mechanotransduction: Recent Developments and Future Directions
Authors: Paige V. Hinton
Susan M. Rackard
Oran D. Kennedy
Publication date: 01-12-2018
Publisher: Springer US
Published in: Current Osteoporosis Reports / Issue 6/2018
Print ISSN: 1544-1873
Electronic ISSN: 1544-2241
DOI: https://doi.org/10.1007/s11914-018-0485-1

Keynote webinar | Spotlight on medication adherence

Springer Medicine

In Vivo Osteocyte Mechanotransduction: Recent Developments and Future Directions

Abstract

Purpose of Review

Recent Findings

Summary

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Purpose of Review

Recent Findings

Summary

Please log in to get access to this content

Other articles of this Issue 6/2018

Micro-Finite Element Analysis of the Proximal Femur on the Basis of High-Resolution Magnetic Resonance Images

Recent Progress in Sarcopenia Research: a Focus on Operationalizing a Definition of Sarcopenia

Mineral and Bone Disease in Kidney Transplant Recipients

Updates in CKD-Associated Osteoporosis

Osteoblastic Factors in Prostate Cancer Bone Metastasis

Celiac Disease—Musculoskeletal Manifestations and Mechanisms in Children to Adults