Ciliary parathyroid hormone signaling activates transforming growth factor-β to maintain intervertebral disc homeostasis during aging

Liwei Zheng , Yong Cao , Shuangfei Ni , Huabin Qi , Zemin Ling , Xin Xu , Xuenong Zou , Tianding Wu , Ruoxian Deng , Bo Hu , Bo Gao , Hao Chen , Yusheng Li , Jianxi Zhu , Francis Tintani , Shadpour Demehri , Amit Jain , Khaled M. Kebaish , Shenghui Liao , Cheryle A. Séguin , Janet L. Crane , Mei Wan , Hongbin Lu , Paul D. Sponseller , Lee H. III Riley , Xuedong Zhou , Jianzhong Hu , Xu Cao

Bone Research ›› 2018, Vol. 6 ›› Issue (1) : 21

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Bone Research ›› 2018, Vol. 6 ›› Issue (1) : 21 DOI: 10.1038/s41413-018-0022-y
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Ciliary parathyroid hormone signaling activates transforming growth factor-β to maintain intervertebral disc homeostasis during aging

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Abstract

Degenerative disc disease (DDD) is associated with intervertebral disc degeneration of spinal instability. Here, we report that the cilia of nucleus pulposus (NP) cells mediate mechanotransduction to maintain anabolic activity in the discs. We found that mechanical stress promotes transport of parathyroid hormone 1 receptor (PTH1R) to the cilia and enhances parathyroid hormone (PTH) signaling in NP cells. PTH induces transcription of integrin αvβ6 to activate the transforming growth factor (TGF)-β-connective tissue growth factor (CCN2)-matrix proteins signaling cascade. Intermittent injection of PTH (iPTH) effectively attenuates disc degeneration of aged mice by direct signaling through NP cells, specifically improving intervertebral disc height and volume by increasing levels of TGF-β activity, CCN2, and aggrecan. PTH1R is expressed in both mouse and human NP cells. Importantly, knockout PTH1R or cilia in the NP cells results in significant disc degeneration and blunts the effect of PTH on attenuation of aged discs. Thus, mechanical stress-induced transport of PTH1R to the cilia enhances PTH signaling, which helps maintain intervertebral disc homeostasis, particularly during aging, indicating therapeutic potential of iPTH for DDD.

Degenerative disc disease: hormone signaling keeps intervertebral core in balance

Sensory structures found in the jelly-like space between spinal discs release a hormone that helps preserve back health in aging mice. Xu Cao from Johns Hopkins University in Baltimore, Maryland, USA, and colleagues observed that levels of a critical growth factor declined in the space between adjacent vertebrae as mice aged, and that injecting a naturally occurring hormone that activates this growth factor could attenuate disc degeneration in older animals. The researchers showed, in response to mechanical stresses, receptor proteins that respond to this hormone relocate themselves to particular sensory organelles known as cilia that found within cells of the intervertebral core. That results in elevated hormone signaling—and drugs designed to have the same effect could help treat degenerative disc disease, one of the most common causes of chronic back pain.

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Liwei Zheng, Yong Cao, Shuangfei Ni, Huabin Qi, Zemin Ling, Xin Xu, Xuenong Zou, Tianding Wu, Ruoxian Deng, Bo Hu, Bo Gao, Hao Chen, Yusheng Li, Jianxi Zhu, Francis Tintani, Shadpour Demehri, Amit Jain, Khaled M. Kebaish, Shenghui Liao, Cheryle A. Séguin, Janet L. Crane, Mei Wan, Hongbin Lu, Paul D. Sponseller, Lee H. III Riley, Xuedong Zhou, Jianzhong Hu, Xu Cao. Ciliary parathyroid hormone signaling activates transforming growth factor-β to maintain intervertebral disc homeostasis during aging. Bone Research, 2018, 6(1): 21 DOI:10.1038/s41413-018-0022-y

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Waddell G. Low back pain: a twentieth century health care enigma. Spine (Phila. Pa 1976), 1996, 21:2820-2825

[2]

Frymoyer JW. Back pain and sciatica. N. Engl. J. Med., 1988, 318:291-300

[3]

Boos N et al. Classification of age-related changes in lumbar intervertebral discs: 2002 Volvo Award in basic science. Spine (Phila Pa 1976), 2002, 27:2631-2644

[4]

Miller JA, Schmatz C, Schultz AB. Lumbar disc degeneration: correlation with age, sex, and spine level in 600 autopsy specimens. Spine (Phila Pa 1976)., 1988, 13:173-178

[5]

Raj PP. Intervertebral disc: anatomy-physiology-pathophysiology-treatment. Pain Pract., 2008, 8:18-44

[6]

Vos T et al. Years lived with disability (YLDs) for 1160 sequelae of 289 diseases and injuries 1990-2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet, 2012, 380:2163-2196

[7]

Trout JJ, Buckwalter JA, Moore KC. Ultrastructure of the human intervertebral disc: II. Cells of the nucleus pulposus. Anat. Rec., 1982, 204:307-314

[8]

McCann MR, Tamplin OJ, Rossant J, Seguin CA. Tracing notochord-derived cells using a Noto-cre mouse: implications for intervertebral disc development. Dis. Models Mech., 2012, 5:73-82

[9]

Adams MA, Roughley PJ. What is intervertebral disc degeneration, and what causes it? Spine, 2006, 31:2151-2161

[10]

Nerurkar NL, Elliott DM, Mauck RL. Mechanical design criteria for intervertebral disc tissue engineering. J. Biomech., 2010, 43:1017-1030

[11]

Stokes IAF, Iatridis JC. Mechanical conditions that accelerate intervertebral disc degeneration: overload versus immobilization. Spine, 2004, 29:2724-2732

[12]

Wuertz K et al. In vivo remodeling of intervertebral discs in response to short- and long-term dynamic compression. J. Orthop. Res., 2009, 27:1235-1242

[13]

Hwang PY, Chen J, Jing L, Hoffman BD, Setton LA. The role of extracellular matrix elasticity and composition in regulating the nucleus pulposus cell phenotype in the intervertebral disc: a narrative review. J. Biomech. Eng.Trans. ASME, 2014, 136:021010

[14]

Neidlinger-Wilke C et al. Mechanical loading of the intervertebral disc: from the macroscopic to the cellular level. Eur. Spine J., 2014, 23:S333-S343

[15]

Le Maitre CL et al. Altered integrin mechanotransduction in human nucleus pulposus cells derived from degenerated discs. Arthritis Rheum., 2009, 60:460-469

[16]

Tran CM et al. Regulation of CCN2/connective tissue growth factor expression in the nucleus pulposus of the intervertebral disc: role of Smad and activator protein 1 signaling. Arthritis Rheum., 2010, 62:1983-1992
[17]

Bedore J et al. Impaired intervertebral disc development and premature disc degeneration in mice with notochord-specific deletion of CCN2. Arthritis Rheum., 2013, 65:2634-2644
[18]

Bian Q et al. Mechanosignaling activation of TGF beta maintains intervertebral disc homeostasis. Bone Res., 2017, 5:17008

[19]

Yuan X, Serra RA, Yang SY. Function and regulation of primary cilia and intraflagellar transport proteins in the skeleton. Marrow, 2015, 1335:78-99
[20]

Green JA et al. Recruitment of beta-arrestin into neuronal cilia modulates somatostatin receptor subtype 3 ciliary localization. Mol. Cell. Biol., 2016, 36:223-235
[21]

Leaf A, Von Zastrow M. Dopamine receptors reveal an essential role of IFT-B, KIF17, and Rab23 in delivering specific receptors to primary cilia. Elife, 2015, 4:e06996

[22]

Liem KF et al. The IFT-A complex regulates Shh signaling through cilia structure and membrane protein trafficking. J. Cell Biol., 2012, 197:789-800

[23]

Kopinke D, Roberson EC, Reiter JF. Ciliary hedgehog signaling restricts injury-induced adipogenesis. Cell, 2017, 170:340

[24]

McIntyre JC, Hege MM, Berbari NF. Trafficking of ciliary G protein-coupled receptors. G Protein-Couple. Recept. Signal. Traffick. Regul., 2016, 132:35-54

[25]

Schou KB, Pedersen LB, Christensen ST. Ins and outs of GPCR signaling in primary cilia. Embo Rep., 2015, 16:1099-1113

[26]

Oliazadeh N, Gorman KF, Eveleigh R, Bourque G, Moreau A. Identification of elongated primary cilia with impaired mechanotransduction in idiopathic scoliosis patients. Sci. Rep.-UK, 2017, 7:44260

[27]

Grimes DT et al. Zebrafish models of idiopathic scoliosis link cerebrospinal fluid flow defects to spine curvature. Science, 2016, 352:1341-1344

[28]

Kawane T, Mimura J, Yanagawa T, Fujii-Kuriyama Y, Horiuchi N. Parathyroid hormone (PTH) down-regulates PTH/PTH-related protein receptor gene expression in UMR-106 osteoblast-like cells via a 3 ‘,5 ‘-cyclic adenosine monophosphate-dependent, protein kinase A-independent pathway. J. Endocrinol., 2003, 178:247-256

[29]

Swarthout JT, D’Alonzo RC, Selvamurugan N, Partridge NC. Parathyroid hormone-dependent signaling pathways regulating genes in bone cells. Gene, 2002, 282:1-17

[30]

Qiu T et al. TGF-beta type II receptor phosphorylates PTH receptor to integrate bone remodelling signalling. Nat. Cell Biol., 2010, 12:224-U29

[31]

Wan M et al. Parathyroid hormone signaling through low-density lipoprotein-related protein 6. Genes Dev., 2008, 22:2968-2979

[32]

Yu B et al. Parathyroid hormone induces differentiation of mesenchymal stromal/stem cells by enhancing bone morphogenetic protein signaling. J. Bone Miner. Res., 2012, 27:2001-2014

[33]

Qiu T et al. IGF-I induced phosphorylation of PTH receptor enhances osteoblast to osteocyte transition. Bone Res., 2018, 6:5

[34]

Crane JL, Cao X. Bone marrow mesenchymal stem cells and TGF-beta signaling in bone remodeling. J. Clin. Invest., 2014, 124:466-472

[35]

Prisby R et al. Intermittent PTH(1-84) is osteoanabolic but not osteoangiogenic and relocates bone marrow blood vessels closer to bone-forming sites. J. Bone Miner. Res., 2011, 26:2583-2596

[36]

Qiu T et al. PTH receptor signaling in osteoblasts regulates endochondral vascularization in maintenance of postnatal growth plate. J. Bone Miner. Res., 2015, 30:309-317

[37]

Munger JS, Sheppard D. Cross talk among TGF-beta signaling pathways, integrins, and the extracellular matrix. Cold Spring Harb. Perspect. Biol., 2011, 3:a005017

[38]

Nishimura SL. Integrin-mediated transforming growth factor-beta activation, a potential therapeutic target in fibrogenic disorders. Am. J. Pathol., 2009, 175:1362-1370

[39]

Mamuya FA, Duncan MK. aV integrins and TGF-beta-induced EMT: a circle of regulation. J. Cell. Mol. Med., 2012, 16:445-455

[40]

Okabe M, Graham A. The origin of the parathyroid gland. Proc. Natl Acad. Sci. USA, 2004, 101:17716-17719

[41]

Weiss RE, Watabe N. Studies on the biology of fish bone. III. Ultrastructure of osteogenesis and resorption in osteocytic (cellular) and anosteocytic (acellular) bones. Calcif. Tissue Int., 1979, 28:43-56

[42]

Glowacki J, Cox KA, O’Sullivan J, Wilkie D, Deftos LJ. Osteoclasts can be induced in fish having an acellular bony skeleton. Proc. Natl Acad. Sci. USA, 1986, 83:4104-4107

[43]

Witten PE, Huysseune A. A comparative view on mechanisms and functions of skeletal remodelling in teleost fish, with special emphasis on osteoclasts and their function. Biol. Rev. Camb. Philos. Soc., 2009, 84:315-346

[44]

Moss ML. Studies of the acellular bone of teleost fish. V. Histology and mineral homeostasis of fresh-water species. Acta Anat. (Basel), 1965, 60:262-276

[45]

Sapp G. Evolution: the first four billion years. Libr. J., 2008, 133:156
[46]

Madiraju P, Gawri R, Wang H, Antoniou J, Mwale F. Mechanism of parathyroid hormone-mediated suppression of calcification markers in human intervertebral disc cells. Eur. Cell Mater., 2013, 25:268-283

[47]

Zhou Z et al. Enhancement of lumbar fusion and alleviation of adjacent segment disc degeneration by intermittent PTH(1-34) in ovariectomized rats. J. Bone Miner. Res., 2016, 31:828-838

[48]

Jia H et al. Oestrogen and parathyroid hormone alleviate lumbar intervertebral disc degeneration in ovariectomized rats and enhance Wnt/beta-catenin pathway activity. Sci. Rep., 2016, 6

[49]

Risbud MV, Schaer TP, Shapiro IM. Toward an understanding of the role of notochordal cells in the adult intervertebral disc: from discord to accord. Dev. Dyn., 2010, 239:2141-2148

[50]

Sivakamasundari, V. & Lufkin, T. Bridging the gap: understanding embryonic intervertebral disc development. Cell Dev. Biol. 1, 103(2012).
[51]

Gower WE, Pedrini V. Age-related variations in proteinpolysaccharides from human nucleus pulposus, annulus fibrosus, and costal cartilage. J. Bone Jt. Surg. Am., 1969, 51:1154-1162

[52]

Antoniou J et al. The human lumbar intervertebral disc: evidence for changes in the biosynthesis and denaturation of the extracellular matrix with growth, maturation, ageing, and degeneration. J. Clin. Invest., 1996, 98:996-1003

[53]

Tran CM, Shapiro IM, Risbud MV. Molecular regulation of CCN2 in the intervertebral disc: lessons learned from other connective tissues. Matrix Biol., 2013, 32:298-306

[54]

Serra R et al. Expression of a truncated, kinase-defective TGF-beta type II receptor in mouse skeletal tissue promotes terminal chondrocyte differentiation and osteoarthritis. J. Cell Biol., 1997, 139:541-552

[55]

Yang X et al. TGF-beta/Smad3 signals repress chondrocyte hypertrophic differentiation and are required for maintaining articular cartilage. J. Cell Biol., 2001, 153:35-46

[56]

Bian Q et al. Excessive activation of TGFbeta by spinal instability causes vertebral endplate sclerosis. Sci. Rep., 2016, 6

[57]

Moore RJ. The vertebral end-plate: what do we know? Eur. Spine J., 2000, 9:92-96

[58]

Kobayashi T et al. PTHrP and Indian hedgehog control differentiation of growth plate chondrocytes at multiple steps. Development, 2002, 129:2977-2986
[59]

Ben Abdelkhalek H et al. The mouse homeobox gene Not is required for caudal notochord development and affected 1725 by the truncate mutation. Genes Dev., 2004, 18:1725-1736

[60]

Sakai D et al. Exhaustion of nucleus pulposus progenitor cells with ageing and degeneration of the intervertebral disc. Nat. Commun., 2012, 3

[61]

Masuda K et al. A novel rabbit model of mild, reproducible disc degeneration by an anulus needle puncture: correlation between the degree of disc injury and radiological and histological appearances of disc degeneration. Spine, 2005, 30:5-14

[62]

Kim HJ et al. The influence of facet joint orientation and tropism on the stress at the adjacent segment after lumbar fusion surgery: a biomechanical analysis. Spine J., 2015, 15:1841-1847

[63]

Malandrino A et al. The role of endplate poromechanical properties on the nutrient availability in the intervertebral disc. Osteoarthr. Cartil., 2014, 22:1053-1060

[64]

Nyman JS et al. Predicting mouse vertebra strength with micro-computed tomography-derived finite element analysis. Bone Rep., 2015, 4:664

Funding

Foundation for the National Institutes of Health (Foundation for the National Institutes of Health, Inc.)(AR071432)

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