p47phox-Nox2-dependent ROS signaling inhibits early bone development in mice but protects against skeletal aging

Authors: CHEN, JINRAN - Arkansas Children'S Nutrition Research Center (ACNC); LAZARENKO, OXANA - Arkansas Children'S Nutrition Research Center (ACNC); BLACKBURN, MICHAEL - Arkansas Children'S Nutrition Research Center (ACNC); MERCER, KELLY - Arkansas Children'S Nutrition Research Center (ACNC); Badger, Thomas - Arkansas Children'S Nutrition Research Center (ACNC); RONIS, MARTIN - Arkansas Children'S Nutrition Research Center (ACNC)

Submitted to: Journal of Biological Chemistry
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 4/28/2015
Publication Date: 6/5/2015
Citation: Chen, J., Lazarenko, O.P., Blackburn, M.L., Mercer, K.E., Badger, T.M., Ronis, M.J. 2015. p47phox-Nox2-dependent ROS signaling inhibits early bone development in mice but protects against skeletal aging. Journal of Biological Chemistry. 290(23):14692-14704.

Interpretive Summary: It is known that bone quality changes with age, and progressive accumulation of reactive oxygen species (ROS) in the body has been suspected to be one of causes of degenerative bone disorder, as well as an important factor underlying many effects of aging. We studied if ROS is truly important for bone aging. Using mouse model, we deleted p47phox gene which is responsible for generating ROS. We find bone quality was better in young animals after p47phox deletion, but bone quality was worth after p47phox deletion in old animals compare to those control animals. We conclude that ROS play different roles in young versus old animals.

Technical Abstract: Bone remodeling is age-dependently regulated and changes dramatically during the course of development. Progressive accumulation of reactive oxygen species (ROS) has been suspected to be the leading cause of many inflammatory and degenerative diseases, as well as an important factor underlying many effects of aging. In contrast, how reduced ROS signaling regulates inflammation and remodeling in bone remains unknown. Here, we utilized a p47phox knock-out mouse model, in which an essential cytosolic co-activator of Nox2 is lost, to characterize bone metabolism at 6 weeks and 2 years of age. Compared with their age-matched wild type controls, loss of Nox2 function in p47phox/ mice resulted in age-related switch of bone mass and strength. Differences in bone mass were associated with increased bone formation in 6-week-old p47phox/ mice but decreased in 2-year-old p47phox/ mice. Despite decreases in ROS generation in bone marrow cells and p47phox-Nox2 signaling in osteoblastic cells, 2-year-old p47phox/ mice showed increased senescence-associated secretory phenotype in bone compared with their wild type controls. These in vivo findings were mechanistically recapitulated in ex vivo cell culture of primary fetal calvarial cells from p47phox/ mice. These cells showed accelerated cell senescence pathway accompanied by increased inflammation. These data indicate that the observed age-related switch of bone mass in p47phox-deficient mice occurs through an increased inflammatory milieu in bone and that p47phox-Nox2-dependent physiological ROS signaling suppresses inflammation in aging.