Ageing characteristics of bone indicated by transcriptomic and exosomal proteomic analysis of cortical bone cells

Zhang, Chenyang; Xu, Shanshan; Zhang, Shufan; Liu, Mengmeng; Du, Haiming; Sun, Ruinan; Jing, Bo; Sun, Yao

doi:10.1186/s13018-019-1163-4

Cited by 25 publications

(12 citation statements)

References 73 publications

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“…Only Schoen et al implemented cumulative radiation doses to the interforaminal area, but implant‐bed‐specific differentiation in RT doses was still not implemented. The results of the present study might reflect general radiation‐induced effects on adjacent structures and tissues: The long‐term impact in particular seems to affect bone remodeling negatively by various potential mechanisms, such as reducing vascularization, causing endarteritis with tissue fibrosis and cell damage to osteoprogenitor cells (Chrcanovic et al., 2016; Magnus Jacobsson, 1985; Marx & Johnson, 1987; Scully & Epstein, 1996; Yerit et al., 2006). Therefore, the impact of RT observed in our study seems to be a long‐term effect and was measurable despite the relatively small sample size and interindividual differences.…”

Section: Discussionmentioning

confidence: 72%

Influence of implant‐specific radiation doses on peri‐implant hard and soft tissue: An observational pilot study

Neckel

Wagendorf

Sachse

et al. 2020

Clinical Oral Implants Res

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Objectives The aim of this study was to investigate the influence of real implant‐bed‐specific radiation doses on peri‐implant tissue health in head and neck cancer (HNC) patients after radiotherapy. Material and methods Specific radiation doses in the area of 81 implants, in 15 irradiated HNC patients, were analyzed by matching data from the radiotherapy planning system with those of three‐dimensional follow‐up scans after implantation. Peri‐implant bone resorption was measured radiographically after 1 and 3 years, and peri‐implant tissue health was evaluated clinically. Individual parameters, such as age, gender, and localization, regarding the implant‐specific radiation dose distribution were analyzed statistically. Results The mean implant‐bed‐specific radiation dose was high, with 45.95 Gy to the mandible and 29.02 Gy to the maxilla, but significantly lower than the mean total dose to the tumor bed. Peri‐implant bone resorption correlated with local inflammation and plaque. After 1 year, women temporarily showed significantly more bone loss than men and implant‐specific radiation dose had a significant impact on peri‐implant bone loss after 3 years. Conclusions The presented method is a feasible option to define precise implant‐bed‐specific radiation doses for research or treatment planning purposes. Implant‐based dental restoration after radiotherapy is a relatively safe procedure, but a negative radiation dose‐dependent long‐term effect on peri‐implant bone resorption calls for interdisciplinary cooperation between surgeons and radio‐oncologists to define high‐risk areas.

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Section: Discussionmentioning

confidence: 72%

Influence of implant‐specific radiation doses on peri‐implant hard and soft tissue: An observational pilot study

Neckel

Wagendorf

Sachse

et al. 2020

Clinical Oral Implants Res

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“…Mechanically loaded osteocytes release exosomes with bone regenerating potential, via Ca 2+ oscillation ( 19 ). Proteomic analysis of exosomes from cortical bone osteocytes provide a clear picture of osteocyte function in different disease conditions, including rare bone diseases ( 32 ). The osteocyte transcriptome is extensively deregulated in a mouse model of osteogenesis imperfecta ( 163 ).…”

Section: Analysis Of Osteocyte Functionmentioning

confidence: 99%

The Osteocyte as the New Discovery of Therapeutic Options in Rare Bone Diseases

2020

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Osteocytes are the most abundant (~95%) cells in bone with the longest half-life (~25 years) in humans. In the past osteocytes have been regarded as vestigial cells in bone, since they are buried inside the tough bone matrix. However, during the last 30 years it has become clear that osteocytes are as important as bone forming osteoblasts and bone resorbing osteoclasts in maintaining bone homeostasis. The osteocyte cell body and dendritic processes reside in bone in a complex lacuno-canalicular system, which allows the direct networking of osteocytes to their neighboring osteocytes, osteoblasts, osteoclasts, bone marrow, blood vessels, and nerves. Mechanosensing of osteocytes translates the applied mechanical force on bone to cellular signaling and regulation of bone adaptation. The osteocyte lacuno-canalicular system is highly efficient in transferring external mechanical force on bone to the osteocyte cell body and dendritic processes via displacement of fluid in the lacuno-canalicular space. Osteocyte mechanotransduction regulates the formation and function of the osteoblasts and osteoclasts to maintain bone homeostasis. Osteocytes produce a variety of proteins and signaling molecules such as sclerostin, cathepsin K, Wnts, DKK1, DMP1, IGF1, and RANKL/OPG to regulate osteoblast and osteoclast activity. Various genetic abnormality-associated rare bone diseases are related to disrupted osteocyte functions, including sclerosteosis, van Buchem disease, hypophosphatemic rickets, and WNT1 and plastin3 mutation-related disorders. Meticulous studies during the last 15 years on disrupted osteocyte function in rare bone diseases guided for the development of various novel therapeutic agents to treat bone diseases. Studies on genetic, molecular, and cellular mechanisms of sclerosteosis and van Buchem disease revealed a role for sclerostin in bone homeostasis, which led to the development of the sclerostin antibody to treat osteoporosis and other bone degenerative diseases. The mechanism of many other rare bone diseases and the role of the osteocyte in the development of such conditions still needs to be investigated. In this review, we mainly discuss the knowledge obtained during the last 30 years on the role of the osteocyte in rare bone diseases. We speculate about future research directions to develop novel therapeutic drugs targeting osteocyte functions to treat both common and rare bone diseases.

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“…A recent study demonstrated that senescence-associated upregulation of EV biogenesis, along with autophagy, can block apoptosis and thus has a critical impact on cell homeostasis (Hitomi et al, 2020 ). RNA-sequencing and liquid chromatography-mass (LCM) spectrometry analysis revealed that several SASP proteins, including TGF-β2, osteoprotegrin (OPG), MMP-9, TIMP1, macrophage migration inhibitory factor (MIF)-1, peroxiredoxins (PRDXs), and insulin-like growth factor binding protein (IGFBP) 3, were upregulated in EVs derived from aged mouse osteocytes (Zhang et al, 2019 ; Aquino-Martinez et al, 2020 ). A proteomic analysis of the senescence-associated secretome of fibroblasts further revealed a significant abundance of plasma membrane proteins in EVs (Basisty et al, 2020 ).…”

Section: Role Of Evs In Musculoskeletal Regeneration—from Pro-regenermentioning

confidence: 99%

“…EVs derived from osteocytes isolated from 3 and 20 months old mice, revealed similar distribution of “exosomal proteins,” including tetraspanins, flotillin, caveolin, integrins, annexins, transcription factors (EF1A and EF2), heat shock proteins and phosphatidylserine-binding protein, while “aged” osteocyte-EVs lacked proteins involved in the maintenance of cell homeostasis, regulation of cellular metabolism and osteoblast as well as osteoclast differentiation. Furthermore, EVs from “aged” osteocytes contained several factors, including CD44, CD47, CD59, TGF-β2, and gelsolin, which regulate the activities of both immune cells and bone cells, implying important communication between “aged” osteocytes and immune cells (Zhang et al, 2019 ).…”

Section: Role Of Evs In Musculoskeletal Regeneration—from Pro-regenermentioning

confidence: 99%

Extracellular Vesicles in Musculoskeletal Pathologies and Regeneration

Herrmann

Diederichs

Melnik

et al. 2021

Front. Bioeng. Biotechnol.

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The incidence of musculoskeletal diseases is steadily increasing with aging of the population. In the past years, extracellular vesicles (EVs) have gained attention in musculoskeletal research. EVs have been associated with various musculoskeletal pathologies as well as suggested as treatment option. EVs play a pivotal role in communication between cells and their environment. Thereby, the EV cargo is highly dependent on their cellular origin. In this review, we summarize putative mechanisms by which EVs can contribute to musculoskeletal tissue homeostasis, regeneration and disease, in particular matrix remodeling and mineralization, pro-angiogenic effects and immunomodulatory activities. Mesenchymal stromal cells (MSCs) present the most frequently used cell source for EV generation for musculoskeletal applications, and herein we discuss how the MSC phenotype can influence the cargo and thus the regenerative potential of EVs. Induced pluripotent stem cell-derived mesenchymal progenitor cells (iMPs) may overcome current limitations of MSCs, and iMP-derived EVs are discussed as an alternative strategy. In the last part of the article, we focus on therapeutic applications of EVs and discuss both practical considerations for EV production and the current state of EV-based therapies.

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Ageing characteristics of bone indicated by transcriptomic and exosomal proteomic analysis of cortical bone cells

Cited by 25 publications

References 73 publications

Influence of implant‐specific radiation doses on peri‐implant hard and soft tissue: An observational pilot study

Influence of implant‐specific radiation doses on peri‐implant hard and soft tissue: An observational pilot study

The Osteocyte as the New Discovery of Therapeutic Options in Rare Bone Diseases

Extracellular Vesicles in Musculoskeletal Pathologies and Regeneration

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