View Item 

Show simple item record

Differential Adaptive Response of Growing Bones From Two Female Inbred Mouse Strains to Voluntary Cage‐Wheel Running
dc.contributor.authorSchlecht, Stephen H.
dc.contributor.authorRamcharan, Melissa A.
dc.contributor.authorYang, Yueqin
dc.contributor.authorSmith, Lauren M
dc.contributor.authorBigelow, Erin MR
dc.contributor.authorNolan, Bonnie T
dc.contributor.authorMoss, Drew E
dc.contributor.authorDevlin, Maureen J
dc.contributor.authorJepsen, Karl J
dc.date.accessioned2018-06-11T17:59:32Z
dc.date.available2019-07-01T14:52:17Zen
dc.date.issued2018-05
dc.identifier.citationSchlecht, Stephen H.; Ramcharan, Melissa A.; Yang, Yueqin; Smith, Lauren M; Bigelow, Erin MR; Nolan, Bonnie T; Moss, Drew E; Devlin, Maureen J; Jepsen, Karl J (2018). "Differential Adaptive Response of Growing Bones From Two Female Inbred Mouse Strains to Voluntary Cage‐Wheel Running." JBMR Plus 2(3): 143-153.
dc.identifier.issn2473-4039
dc.identifier.issn2473-4039
dc.identifier.urihttps://hdl.handle.net/2027.42/144252
dc.description.abstractThe phenotypic response of bones differing in morphological, compositional, and mechanical traits to an increase in loading during growth is not well understood. We tested whether bones of two inbred mouse strains that assemble differing sets of traits to achieve mechanical homeostasis at adulthood would show divergent responses to voluntary cage‐wheel running. Female A/J and C57BL6/J (B6) 4‐week‐old mice were provided unrestricted access to a standard cage‐wheel for 4 weeks. A/J mice have narrow and highly mineralized femora and B6 mice have wide and less mineralized femora. Both strains averaged 2 to 9.5 km of running per day, with the average‐distance run between strains not significantly different (p = 0.133). Exercised A/J femora showed an anabolic response to exercise with the diaphyses showing a 2.8% greater total area (Tt.Ar, p = 0.06) and 4.7% greater cortical area (Ct.Ar, p = 0.012) compared to controls. In contrast, exercised B6 femora showed a 6.2% (p < 0.001) decrease in Tt.Ar (p < 0.001) and a 6.7% decrease in Ct.Ar (p = 0.133) compared to controls, with the femora showing significant marrow infilling (p = 0.002). These divergent morphological responses to exercise, which did not depend on the daily distance run, translated to a 7.9% (p = 0.001) higher maximum load (ML) for exercised A/J femora but no change in ML for exercised B6 femora compared to controls. A consistent response was observed for the humeri but not the vertebral bodies. This differential outcome to exercise has not been previously observed in isolated loading or forced treadmill running regimes. Our findings suggest there are critical factors involved in the metabolic response to exercise during growth that require further consideration to understand how genotype, exercise, bone morphology, and whole‐bone strength interact during growth. © 2018 The Authors. JBMR Plus is published by Wiley Periodicals, Inc. on behalf of the American Society for Bone and Mineral Research.
dc.publisherWiley Periodicals, Inc.
dc.subject.otherBONE PHENOTYPE
dc.subject.otherA/J AND C57BL6/J MICE
dc.subject.otherVOLUNTARY CAGE‐WHEEL RUNNING
dc.subject.otherMECHANICAL LOADING
dc.subject.otherBONE FUNCTION
dc.titleDifferential Adaptive Response of Growing Bones From Two Female Inbred Mouse Strains to Voluntary Cage‐Wheel Running
dc.typeArticleen_US
dc.rights.robotsIndexNoFollow
dc.subject.hlbsecondlevelEndocrinology
dc.subject.hlbsecondlevelGeriatric Medicine
dc.subject.hlbsecondlevelRheumatology
dc.subject.hlbtoplevelHealth Sciences
dc.description.peerreviewedPeer Reviewed
dc.description.bitstreamurlhttps://deepblue.lib.umich.edu/bitstream/2027.42/144252/1/jbm410032.pdf
dc.description.bitstreamurlhttps://deepblue.lib.umich.edu/bitstream/2027.42/144252/2/jbm410032_am.pdf
dc.identifier.doi10.1002/jbm4.10032
dc.identifier.sourceJBMR Plus
dc.identifier.citedreferenceKnothe Tate ML, Knothe U, Niederer P. Experimental elucidation of mechanical load‐induced fluid flow and its potential role in bone metabolism and functional adaptation. Am J Med Sci. 1998; 316: 189 – 95.
dc.identifier.citedreferenceOdgaard A. Three‐dimensional methods for quantification of cancellous bone architecture. Bone. 1997; 20: 315 – 28.
dc.identifier.citedreferenceJepsen KJ, Pennington DE, Lee Y‐L., Warman M, Nadeau J. Bone brittleness varies with genetic background in A/J and C57BL/6J inbred mice. J Bone Miner Res. 2001; 16: 1854 – 62.
dc.identifier.citedreferenceDe Bono J, Adlam D, Paterson D, Channon K. Novel quantitative phenotypes of exercise training in mouse models. Am J Physiol Regul Integr Comp Physiol. 2006; 290: R926 – 34.
dc.identifier.citedreferenceWu J, Wang XX, Takasaki M, Ohta A, Higuchi M, Ishimi Y. Cooperative effects of exercise training and genistein administration on bone mass in ovariectomized mice. J Bone Miner Res. 2001; 16: 1829 – 36.
dc.identifier.citedreferenceWu J, Wang XX, Higuchi M, Yamada K, Ishimi Y. High bone mass gained by exercise in growing male mice is increased by subsequent reduced exercise. J Appl Physiol. 2004; 97: 806 – 10.
dc.identifier.citedreferenceWallace JM, Rajachar RM, Allen MR, et al. Exercise‐induced changes in the cortical bone of growing mice are bone‐ and gender‐specific. Bone. 2007; 40: 1120 – 7.
dc.identifier.citedreferenceTurner CH, Robling AG. Exercise as an anabolic stimulus for bone. Curr Pharm Des. 2004; 10: 2629 – 41.
dc.identifier.citedreferencePlochocki JH, Rivera JP, Zhang C, Ebba SA. Bone modeling response to voluntary exercise in the hindlimb of mice. J Morphol. 2008; 269: 313 – 8.
dc.identifier.citedreferenceStyner M, Thompson WR, Galior K, et al. Bone marrow fat accumulation accelerated by high fat diet is suppressed by exercise. Bone. 2014; 64: 39 – 46.
dc.identifier.citedreferenceStyner M, Pagnotti GM, McGrath C, et al. Exercise decreases marrow adipose tissue through beta‐oxidation in obese running mice. J Bone Miner Res. 2017; 32: 1692 – 702.
dc.identifier.citedreferenceIsaksson H, Tolvanen V, Finnilä MA, et al. Physical exercise improves properties of bone and collagen network in growing and maturing mice. Calcif Tissue Int. 2009; 85: 247 – 56.
dc.identifier.citedreferenceKelly SA, Czech PP, Wight JT, Blank KM, Garland T Jr. Experimental evolution and phenotypic plasticity of hindlimb bones in high‐activity house mice. J Morphol. 2006; 267: 360 – 74.
dc.identifier.citedreferenceHamrick MW, Skedros JG, Pennington C, McNeil PL. Increased osteogenic response to exercise in metaphyseal versus diaphyseal cortical bone. J Musculoskelet Neuronal Interact. 2006; 6: 258 – 63.
dc.identifier.citedreferenceDe Souza RL, Matsuura M, Eckstein F, Rawlinson SCF, Lanyon LE, Pitsillides AA. 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 load element. Bone. 2005; 37: 810 – 8.
dc.identifier.citedreferenceFritton 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.
dc.identifier.citedreferenceUmemura Y, Baylink DJ, Wergedal JE, Mohan S, Srivastava AK. A time course of bone response to jump exercise in C57BL/6J mice. J Bone Miner Metab. 2002; 20: 209 – 15.
dc.identifier.citedreferencePearson OM, Lieberman DE. The aging of Wolff’s “law”: ontogeny and responses to mechanical loading in cortical bone. Yearb Phys Anthropol. 2004; 47: 63 – 99.
dc.identifier.citedreferenceFarr JN, Amin S, LeBrasseur NK, et al. Body composition during childhood and adolescence: relations to bone strength and microstructure. J Clin Endocrinol Metab. 2014; 99: 4641 – 8.
dc.identifier.citedreferenceRobling AG, Burr DB, Turner CH. Partitioning a daily mechanical stimulus into discrete loading bouts improves the osteogenic response to loading. J Bone Miner Res. 2000; 15: 1596 – 602.
dc.identifier.citedreferenceJepsen KJ, Bigelow EMR, Schlecht SH. Women build long bones with less cortical mass relative to body size and bone size compared to men. Clin Orthop Relat Res. 2015 Aug; 473 (8): 2530 – 9.
dc.identifier.citedreferenceJepsen KJ, Kozminski A, Bigelow EMR, et al. Femoral neck external size but not aBMD predicts structural and mass changes for women transitioning through menopause. J Bone Miner Res. 2017; 32: 1218 – 28.
dc.identifier.citedreferenceKohn DH, Sahar ND, Wallace JM, Golcuck K, Morris MD. Exercise alters mineral and matrix composition in the absence of adding new bone. Cells Tissues Organs. 2009; 189: 33 – 7.
dc.identifier.citedreferencePoliachik SL, Threet D, Srinivasan S, Gross TS. 32 wk old C3H/HeJ mice actively respond to mechanical loading. Bone. 2008; 42: 653 – 9.
dc.identifier.citedreferencePandey N, Bhola S, Goldstone A, et al. Interindividual variation in functionally adapted trait sets is established during postnatal growth and predictable based on bone robustness. J Bone Miner Res. 2009; 24: 1969 – 80.
dc.identifier.citedreferenceBhola S, Chen J, Fusco J, et al. Variation in childhood skeletal robustness is an important determinant of cortical area in young adults. Bone. 2011; 49: 799 – 809.
dc.identifier.citedreferenceSchlecht SH, Bigelow EMR, Jepsen KJ. How does bone strength compare across sex, site, and ethnicity ? Clin Orthop Relat Res. 2015; 473: 2540 – 7.
dc.identifier.citedreferenceThifault S, Lalonde R, Sanon N, Hamet P. Comparisons between C57BL/6J and A/J mice in motor activity and coordination, hole‐poking, and spatial learning. Brain Res Bull. 2002; 58: 213 – 8.
dc.identifier.citedreferenceRubin CT, Lanyon LE. Dynamic strain similarity in vertebrates: an alternative to allometric limb bone scaling. J Theor Biol. 1984; 107: 321 – 7.
dc.identifier.citedreferenceJones H, Priest J, Hayes WC, Tichenor C, Nagel D. Humeral hypertrophy in response to exercise. J Bone Joint Surg. 1977; 59: 204 – 8.
dc.identifier.citedreferenceBradney M, Pearce G, Naughton G, et al. Moderate exercise during growth in prepubertal boys: changes in bone mass, size, volumetric density, and bone strength: a controlled prospective study. J Bone Miner Res. 1998; 13: 1814 – 21.
dc.identifier.citedreferenceBass SL, Saxon L, Daly RM, et al. The effect of mechanical loading on the size and shape of bone in pre‐, peri‐, and postpubertal girls: a study in tennis players. J Bone Miner Res. 2002; 17: 2274 – 80.
dc.identifier.citedreferenceKontulainen S, Sievanen H, Kannus P, Pasanen M, Vuori I. Effect of long‐term impact‐loading on mass, size, and estimated strength of humerus and radius of female racquet‐sports players: a peripheral quantitative computed tomography study between young and old starters and controls. J Bone Miner Res. 2003; 18: 352 – 9.
dc.identifier.citedreferenceAkhter 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.
dc.identifier.citedreferenceBeamer WG, Donahue LR, Rosen CJ, Baylink DJ. Genetic variability in adult bone density among inbred strains of mice. Bone. 1996; 18: 397 – 403.
dc.identifier.citedreferenceAkhter MP, Iwaniec UT, Covey DM, Cullen DM, Kimmel DB, Recker RR. Genetic variations in bone density, histomorphometry, and strength in mice. Calcif Tissue Int. 2000; 67: 337 – 44.
dc.identifier.citedreferenceTurner CH, Hsieh Y‐F., Muller R, et al. Genetic regulation of cortical and trabecular bone strength and microstructure in inbred strains of mice. J Bone Miner Res. 2000; 15: 1126 – 31.
dc.identifier.citedreferencePreston H. Effects of exercise and genetic strain on bone strength, musculoskeletal gene expression and activity levels in C57BL/6J and DBA/2J adult female mice [dissertation]. [University Park]: Kinesiology: Pennsylvania State University; 2009.
dc.identifier.citedreferenceKodama Y, Umemura Y, Nagasawa S, et al. Exercise and mechanical loading increase periosteal bone formation and whole bone strength in CB7BL/6J mice but not in C3H/Hej mice. Calcif Tissue Int. 2000; 66: 2000.
dc.identifier.citedreferenceKodama Y, Dimai HP, Wergedal J, et al. Cortical tibial bone volume in two strains of mice: effects of sciatic neurectomy and genetic regulation of bone response to mechanical loading. Bone. 1999; 25: 1999.
dc.identifier.citedreferenceSchlecht SH, Smith LM, Ramcharan MA, et al. Canalization leads to similar whole bone mechanical function at maturity in two inbred strains of mice. J Bone Miner Res. 2017; 32: 1002 – 13.
dc.identifier.citedreferencePrice C, Herman BC, Lufkin T, Goldman HM, Jepsen KJ. Genetic variation in bone growth patterns defines adult mouse bone fragility. J Bone Miner Res. 2005; 20: 1983 – 91.
dc.identifier.citedreferenceSmith L, Bigelow EMR, Nolan BT, Faillace ME, Nadeau JH, Jepsen KJ. Genetic perturbations that impair functional trait interactions lead to reduced bone strength and increased fragility in mice. Bone. 2014; 67: 130 – 8.
dc.identifier.citedreferenceOtsu N. A threshold selection method from gray‐level histograms. IEEE Trans Syst Man Cybern. 1979;SMC‐9: 62 – 6.
dc.identifier.citedreferenceHarrigan TP, Mann RW. Characterization of microstructural anisotropy in orthotropic materials using a second rank tensor. J Mater Sci. 1984; 19: 761 – 7.
dc.owningcollnameInterdisciplinary and Peer-Reviewed


Files in this item

Name:
jbm410032.pdf
Size:
1.117MB
Format:
PDF
View/Open
Name:
jbm410032_am.pdf
Size:
931.8KB
Format:
PDF
View/Open

Show simple item record

Remediation of Harmful Language

The University of Michigan Library aims to describe library materials in a way that respects the people and communities who create, use, and are represented in our collections. Report harmful or offensive language in catalog records, finding aids, or elsewhere in our collections anonymously through our metadata feedback form. More information at Remediation of Harmful Language.

Accessibility

If you are unable to use this file in its current format, please select the Contact Us link and we can modify it to make it more accessible to you.