Osteocytes subjected to fluid flow inhibit osteoclast formation and bone resorption

Tan, S. Djien<sup>1,2</sup>; de Vries, Teun J.<sup>1,3</sup>; Kuijpers-Jagtman, Anne Marie<sup>2</sup>; Semeins, Cornelis M.<sup>1</sup>; Everts, Vincent<sup>1</sup>; Klein-Nulend, Jenneke<sup>1</sup>

Affiliations

¹Department of Oral Cell Biology, Academic Centre for Dentistry Amsterdam-Universiteit van Amsterdam and Vrije Universiteit, Research Institute MOVE, Amsterdam, The Netherlands

²Department of Orthodontics and Oral Biology, Radboud University Nijmegen Medical Centre, Nijmegen, The Netherland

³Department of Periodontology, Academic Centre for Dentistry Amsterdam-Universiteit van Amsterdam and Vrije Universiteit, Research Institute MOVE, Amsterdam, The Netherlands

Abstract and keywords

Bone has the capacity to alter its mass and structure to its mechanical environment. Osteocytes are the predominant bone cells and it is generally accepted that the osteocytes are the professional mechanosensors of bone. A strain-derived fluid flow through the lacuno-canalicular porosity seems to mechanically activate them, resulting in the production of signalling molecules such as nitric oxide (NO). We hypothesize that mechanically stimulated osteocytes modulate osteoclast formation and activity via soluble factors, thus affecting bone resorption.

Osteocytes, osteoblasts, and periosteal fibroblasts were isolated from fetal chicken calvariae via enzymatic digestion. The periosteal fibroblasts were obtained from the periostea. Osteocytes were separated from osteoblasts by immunomagnetic separation. Cells were mechanically stimulated for 1 h with pulsating fluid flow (PFF, 0.70 ± 0.30 Pa) at 5 Hz, or kept under static conditions. Conditioned medium was collected after 60 min. The effect of conditioned medium on osteoclastogenesis was tested on mouse bone marrow cells in the presence of macrophage colony stimulating factor and receptor activator of NF-κB ligand. After 6 days of culture, osteoclast formation and bone resorption was determined.

Osteocytes subjected to 1 h pulsating fluid flow produced conditioned medium that inhibited the formation of osteoclasts. For osteoblast PFF-conditioned medium, such effect was, to a lesser extent, also observed, but not for periosteal fibroblast PFF-conditioned medium. Furthermore, PFF-treated osteocytes, but not osteoblast or periosteal fibroblast, produced conditioned medium that resulted in a decreased bone resorption. The NO synthase inhibitor N^G-nitro-l-arginine methyl ester attenuated the inhibitory effects of osteocyte PFF-conditioned medium on osteoclast formation and resorption.

We conclude that osteocytes subjected to PFF inhibit osteoclast formation and resorption via soluble factors, and the release of these factors was at least partially dependent on activation of an NO pathway in osteocytes in response to PFF. Thus, the osteocyte appears to be more responsive to PFF than the osteoblast or periosteal fibroblast regarding to the production of soluble factors affecting osteoclast formation and bone resorption.

Keywords: Osteocyte; Osteoblast; Osteoclast; Osteoclast formation; Osteoclast activity; Bone resorption; Mechanical loading; Fluid flow; In vitro

Links

DOI: 10.1016/j.bone.2007.07.019

PubMed: 17855178

WoS: 000250528900001

History

Received: 2007-01-17

Revised: 2007-07-05

Accepted: 2007-07-27

Online: 2007-08-10

Cited Works (15)

Year	Entry
1995	Klein-Nulend J, van der Plas A, Semeins CM, Ajubi NE, Frangos JA, Nijweide PJ, Burger EH. Sensitivity of osteocytes to biomechanical stress in vitro. FASEB J. March 1995;9(5):441-445.
1994	Weinbaum S, Cowin SC, Zeng Y. A model for the excitation of osteocytes by mechanical loading-induced bone fluid shear stresses. J Biomech. March 1994;27(3):339-360.
1999	Zaman G, Pitsillides AA, Rawlinson SCF, Suswillo RFL, Mosley JR, Cheng MZ, Platts LAM, Hukkanen M, Polak JM, Lanyon LE. Mechanical strain stimulates nitric oxide production by rapid activation of endothelial nitric oxide synthase in osteocytes. J Bone Miner Res. July 1999;14(7):1123-1131.
2002	Zhao S, Kato Y, Zhang Y, Harris S, Ahuja SS, Bonewald LF. MLO‐Y4 osteocyte‐like cells support osteoclast formation and activation. J Bone Miner Res. November 2002;17(11):2068-2079.
1996	Fox SW, Chambers TJ, Chow JW. Nitric oxide is an early mediator of the increase in bone formation by mechanical stimulation. Am J Physiol Endocrinol Metab. June 1996;270(6):E955-E960.
2006	Vezeridis PS, Semeins CM, Chen Q, Klein-Nulend J. Osteocytes subjected to pulsating fluid flow regulate osteoblast proliferation and differentiation. Biochem Biophys Res Commun. September 29, 2006;348(3):1082-1088.
1995	Cowin SC, Weinbaum S, Zeng Y. A case for bone canaliculi as the anatomical site of strain generated potentials. J Biomech. November 1995;28(11):1281-1297.
1992	van der Plas A, Nijweide PJ. Isolation and purification of osteocytes. J Bone Miner Res. April 1992;7(4):389-396.
1995	Klein-Nulend J, Semeins CM, Ajubi NE, Nijweide P, Burger EH. Pulsating fluid flow increases nitric oxide (NO) synthesis by osteocytes but not periosteal fibroblasts - correlation with prostaglandin upregulation. Biochem Biophys Res Commun. December 14, 1995;217(2):640-648.
1999	Burger EH, Klein-Nulend J. Mechanotransduction in bone: role of the lacunocanalicular network. FASEB J. May 1999;12(9001):S101-S112.
2004	Wang L, Ciani C, Doty SB, Fritton SP. Delineating bone's interstitial fluid pathway in vivo. Bone. March 2004;34(3):499-509.
2004	Bakker A, Klein-Nulend J, Burger E. Shear stress inhibits while disuse promotes osteocyte apoptosis. Biochem Biophys Res Commun. August 6, 2004;320(4):1163-1168.
2003	Burger EH, Klein-Nulend J, Smit TH. Strain-derived canalicular fluid flow regulates osteoclast activity in a remodelling osteon: a proposal. J Biomech. October 2003;36(10):1453-1459.
2000	Smit TH, Burger EH. Is BMU-coupling a strain-regulated phenomenon? a finite element analysis. J Bone Miner Res. February 2000;12(2):301-307.
1996	Bronckers ALJJ, Goei W, Luo G, Karsenty G, D'Souza RN, Lyaruu DM, Burger EH. DNA fragmentation during bone formation in neonatal rodents assessed by transferase-mediated end labeling. J Bone Miner Res. September 1996;11(9):1281-1291.

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2009	Fritton SP, Weinbaum S. Fluid and solute transport in bone: flow-induced mechanotransduction. Annu Rev Fluid Mech. 2009;41:347-374.
2011	Hoey DA, Kelly DJ, Jacobs CR. A role for the primary cilium in paracrine signaling between mechanically stimulated osteocytes and mesenchymal stem cells. Biochem Biophys Res Commun. August 19, 2011;412(1):182-187.
2009	van Hove RP, Nolte PA, Vatsa A, Semeins CM, Salmon PL, Smit TH, Klein-Nulend J. Osteocyte morphology in human tibiae of different bone pathologies with different bone mineral density: is there a role for mechanosensing? Bone. August 2009;45(2):321-329.
2010	Lau E, Al-Dujaili S, Guenther A, Liu D, Wang L, You L. Effect of low-magnitude, high-frequency vibration on osteocytes in the regulation of osteoclasts. Bone. June 2010;46(6):1508-1515.
2010	Kamel MA, Picconi JL, Lara-Castillo N, Johnson ML. Activation of β-catenin signaling in MLO-Y4 osteocytic cells versus 2T3 osteoblastic cells by fluid flow shear stress and PGE2: implications for the study of mechanosensation in bone. Bone. November 2010;47(5):872-881.
2013	Klein-Nulend J, Bakker AD, Bacabac RG, Vatsa A, Weinbaum S. Mechanosensation and transduction in osteocytes. Bone. June 2013;54(2):182-190.
2020	Milovanovic P, Busse B. Phenomenon of osteocyte lacunar mineralization: indicator of former osteocyte death and a novel marker of impaired bone quality? Endocr Connect. April 2020;9(4):R70-R80.
2013	Dallas SL, Prideaux M, Bonewald LF. The osteocyte: an endocrine cell … and more. Endocr Rev. October 2013;34(4):658-690.
2010	Chen J-H, Liu C, You L, Simmons CA. Boning up on Wolff's Law: mechanical regulation of the cells that make and maintain bone. J Biomech. January 5, 2010;43(1):108-118.
2023	Bergen DJM, Maurizi A, Formosa MM, McDonald GLK, El-Gazzar A, Hassan N, Brandi M-L, Riancho JA, Rivadeneira F, Ntzani E, Duncan EL, Gregson CL, Kiel DP, Zillikens MC, Sangiorgi L, Högler W, Duran I, Mäkitie O, Van Hul W, Hendrickx G. High bone mass disorders: new insights from connecting the clinic and the bench. J Bone Miner Res. February 2023;38(2):229-247.
2020	Rabelo GD, vom Scheidt A, Klebig F, Hemmatian H, Citak M, Amling M, Busse B, Jähn K. Multiscale bone quality analysis in osteoarthritic knee joints reveal a role of the mechanosensory osteocyte network in osteophytes. Sci Rep. 2020;10:673.
2015	Cabahug-Zuckerman P. A Β₃ Integrin Based Mechanosome in Bone Tissue Osteocytes: Plasticity to Changes in Mechanical Loading [PhD thesis]. New York, NY: The City College of New York; 2015.
2016	Brown GN. The Sustainment and Consequences of Cytosolic Calcium Signals in Osteocytes [PhD thesis]. Columbia University; 2016.
2015	Brock GR Jr. Changes in Bone Tissue Properties With Osteoporosis Treatment [PhD thesis]. Ithaca, NY: Cornell University; January 2015.
2017	Shah AD. Elucidating the Effects of Interstitial Fluid Flow on Hepatocellular Carcinoma Invasion [PhD thesis]. Drexel University; June 2017.
2019	Piet J. Restoring Mechano-Adaptation in Aged Murine Bone [PhD thesis]. Northeastern University; March 2019.
2017	Kreipke TC. Structural, Mechanical, and Biological Relationships of Trabecular Bone in Osteoporosis [PhD thesis]. Notre Dame, IN: University of Notre Dame; April 2017.
2020	Simfia I. Estrogen Deficiency Alters the Mechanobiological Responses of Osteoblasts and Osteocytes [PhD thesis]. National University of Ireland Galway; April 2020.
2012	Sun X. Mechanically Induced Calcium Efflux from Bone Matrix Stimulates Osteoblasts [PhD thesis]. Purdue University; May 2012.
2008	Arnsdorf EJ. Guiding Osteogenic Lineage Commitment: The Role of Mesenchymal Stem Cell Biology and the Mechanical Microenvironment [PhD thesis]. Stanford University; September 2008.
2008	Kwon RY. Mechanical Behavior and Early Molecular Signaling During Mechanotransduction of Fluid Flow in Bone Cells [PhD thesis]. Stanford University; August 2008.
2009	Litzenberger JB. The Role of Integrin Signaling in Bone Mechanotransduction [PhD thesis]. Stanford University; 2009.
2009	Temiyasathit S. Investigating the Role of Primary Cilia in Mechanotransduction in Bone [PhD thesis]. Stanford University; September 2009.
2011	Boggs ME. Osteocyte-Neuron Communication in Bone: A Mechanism for Transmission of Pain Sensation Potentially Associated With Bone Cancer [PhD thesis]. University of Delaware; 2011.
2008	Waldorff EI. Effects of Aging and Disuse on Bone Remodeling in Response to Microdamage [PhD thesis]. University of Michigan; 2008.
2023	Madsen E. Cell and Material Specific Dual-Functional Peptides for Enhancing Mesenchymal Stem Cell Migration for Bone Tissue Engineering [PhD thesis]. University of Michigan; 2023.
2014	Carter Y. Quantitative Imaging of Sex and Age Differences in Human Cortical Bone Osteocyte Lacunae [PhD thesis]. University of Saskatchewan; July 2014.
2009	Rath AL. The Effects of Strain and Perilacunar Environment on the Mechanotransduction of Osteocytes [PhD thesis]. Winston-Salem, NC: Wake Forest University; May 2009.
2019	Khurelbaatar T. Quantitative Imaging and Computational Modelling to Estimate the Relationship Between Mechanical Strain and Changes Within the Distal Tibia in First-Time Marathon Trainees [Master's thesis]. Worcester, MA: Worcester Polytechnic Institute; June 2019.