ANP32A regulates ATM expression and prevents oxidative stress in cartilage, brain, and bone.
Frederique M F CornelisSilvia MonteagudoLaura-An K A GunsWouter den HollanderRob R G H H NelissenLies StormsTine PeetersIlse JonkersIngrid MeulenbeltRik Ju LoriesPublished in: Science translational medicine (2019)
Osteoarthritis is the most common joint disorder with increasing global prevalence due to aging of the population. Current therapy is limited to symptom relief, yet there is no cure. Its multifactorial etiology includes oxidative stress and overproduction of reactive oxygen species, but the regulation of these processes in the joint is insufficiently understood. We report that ANP32A protects the cartilage against oxidative stress, preventing osteoarthritis development and disease progression. ANP32A is down-regulated in human and mouse osteoarthritic cartilage. Microarray profiling revealed that ANP32A protects the joint by promoting the expression of ATM, a key regulator of the cellular oxidative defense. Antioxidant treatment reduced the severity of osteoarthritis, osteopenia, and cerebellar ataxia features in Anp32a-deficient mice, revealing that the ANP32A/ATM axis discovered in cartilage is also present in brain and bone. Our findings indicate that modulating ANP32A signaling could help manage oxidative stress in cartilage, brain, and bone with therapeutic implications for osteoarthritis, neurological disease, and osteoporosis.
Keyphrases
- oxidative stress
- dna damage
- bone mineral density
- rheumatoid arthritis
- extracellular matrix
- ischemia reperfusion injury
- knee osteoarthritis
- poor prognosis
- resting state
- diabetic rats
- white matter
- reactive oxygen species
- dna repair
- induced apoptosis
- postmenopausal women
- cerebral ischemia
- dna damage response
- endothelial cells
- single cell
- soft tissue
- bone loss
- binding protein
- stem cells
- signaling pathway
- functional connectivity
- early onset
- bone regeneration
- combination therapy
- endoplasmic reticulum stress
- induced pluripotent stem cells