Lowering circulating apolipoprotein E levels improves aged bone fracture healing
Rong Huang, Xiaohua Zong, Puviindran Nadesan, Janet L. Huebner, Virginia B. Kraus, James P. White, Phillip J. White, Gurpreet S. Baht
Rong Huang, Xiaohua Zong, Puviindran Nadesan, Janet L. Huebner, Virginia B. Kraus, James P. White, Phillip J. White, Gurpreet S. Baht
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Research Article Bone biology

Lowering circulating apolipoprotein E levels improves aged bone fracture healing

Abstract

Age is a well-established risk factor for impaired bone fracture healing. Here, we identify a role for apolipoprotein E (ApoE) in age-associated impairment of bone fracture healing and osteoblast differentiation, and we investigate the mechanism by which ApoE alters these processes. We identified that, in both humans and mice, circulating ApoE levels increase with age. We assessed bone healing in WT and ApoE–/– mice after performing tibial fracture surgery: bone deposition was higher within fracture calluses from ApoE–/– mice. In vitro recombinant ApoE (rApoE) treatment of differentiating osteoblasts decreased cellular differentiation and matrix mineralization. Moreover, this rApoE treatment decreased osteoblast glycolytic activity while increasing lipid uptake and fatty acid oxidation. Using parabiosis models, we determined that circulating ApoE plays a strong inhibitory role in bone repair. Using an adeno-associated virus–based siRNA system, we decreased circulating ApoE levels in 24-month-old mice and demonstrated that, as a result, fracture calluses from these aged mice displayed enhanced bone deposition and mechanical strength. Our results demonstrate that circulating ApoE as an aging factor inhibits bone fracture healing by altering osteoblast metabolism, thereby identifying ApoE as a new therapeutic target for improving bone repair in the elderly.

Authors

Rong Huang, Xiaohua Zong, Puviindran Nadesan, Janet L. Huebner, Virginia B. Kraus, James P. White, Phillip J. White, Gurpreet S. Baht

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Figure 1

Loss of ApoE increases bone deposition during late stages of bone fracture healing.

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Loss of ApoE increases bone deposition during late stages of bone fractu...
(A) Schematic diagram of tibial fracture model and subsequent assessment of repair. WT and ApoE–/– mice underwent tibial surgery, and fracture calluses were analyzed 7, 14, and 21 days after injury. (B) Using μCT, 21-day fracture calluses were assessed to determine (C) total callus volume (TV), (D) bone volume (BV), (E) bone content (BV/TV), and (F) tissue mineral density. Scale bar: 1 mm. (G) Histological staining with Alcian blue/hematoxylin/Orange G was used to visualize decalcified tissue (fracture callus region is indicated by dashed lines). (H) Histomorphometric analysis was used to quantify the amount of new bone within the fracture site and related to the total callus size. (I) Calcein double labeling (white arrows) was used to investigate the (J) mineral apposition rate (MAR) and (K) bone formation rate relative to the bone surface (BFR/BS). For μCT, histology, and histomorphometry, WT, n = 10; ApoE–/–, n = 10. For calcein labeling, WT, n = 8; ApoE–/–, n = 8. Data are expressed as mean ± 95% confidence interval. *P < 0.05, 2-tailed t test.