Senescent cells and osteoarthritis: a painful connection

Jeon, Ok Hee; David, Nathaniel E.; Campisi, Judith; Elisseeff, Jennifer H.

doi:10.1172/jci95147

Cited by 229 publications

(169 citation statements)

References 126 publications

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“…However, the increase in senescent cells with age and a chronic SASP are now known to be key drivers of many pathological hallmarks of aging, including chronic inflammation, tumorigenesis, impaired stem cell renewal, and others (Neves et al, 2015;Tominaga, 2015). Using either or both of two transgenic mouse models that allow the selective elimination of senescent cells (Baker et al, 2011;Demaria et al, 2014), or compounds that mimic the effect of these transgenes, data from several laboratories strongly support the idea that the presence of senescent cells drives multiple age-related phenotypes and pathologies, including age-related atherosclerosis , osteoarthritis (Jeon et al, 2018), cancer metastasis and cardiac dysfunction (Baar et al, 2017;Demaria et al, 2017), myeloid skewing in the bone marrow (Abdul-Aziz et al, 2018;Chang et al, 2016), kidney dysfunction (Valentijn et al, 2018), and overall decrements in healthspan .…”

Section: Introductionmentioning

confidence: 92%

A Proteomic Atlas of Senescence-Associated Secretomes for Aging Biomarker Development

Basisty

Kale

Jeon

et al. 2019

Preprint

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171

276

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The senescence-associated secretory phenotype (SASP) has recently emerged as both a driver of, and promising therapeutic target for, multiple age-related conditions, ranging from neurodegeneration to cancer. The complexity of the SASP, typically monitored by a few dozen secreted proteins, has been greatly underappreciated, and a small set of factors cannot explain the diverse phenotypes it produces in vivo. Here, we present 'SASP Atlas', a comprehensive proteomic database of soluble and exosome SASP factors originating from multiple senescence inducers and cell types. Each profile consists of hundreds of largely distinct proteins, but also includes a subset of proteins elevated in all SASPs. Based on our analyses, we propose several candidate biomarkers of cellular senescence, including GDF15, STC1 and SERPINs. This resource will facilitate identification of proteins that drive specific senescence-associated phenotypes and catalog potential senescence biomarkers to assess the burden, originating stimulus and tissue of senescent cells in vivo. Figure 4. Renal epithelial cells and fibroblasts express distinct sSASPs. A) Venn diagram comparing proteins increased in the sSASP of senescent fibroblasts vs senescent epithelial cells induced by X-irradiation. B) Venn diagram comparing protein increases in the fibroblast sSASP vs decreases in the epithelial sSASP. C) Pathway and network analysis of proteins highly secreted by senescent fibroblasts and epithelial cells. C) Pathway and network analysis of proteins significantly increased in the fibroblast sSASP but significantly decreased in the epithelial cell sSASP.

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Section: Introductionmentioning

confidence: 92%

A Proteomic Atlas of Senescence-Associated Secretomes for Aging Biomarker Development

Basisty

Kale

Jeon

et al. 2019

Preprint

Self Cite

171

276

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“…Biological aging is controlled partly by evolutionarily conserved mechanisms that represent the so‐called nine hallmarks of aging: genomic instability, telomere attrition, epigenetic alterations, loss of proteostasis, deregulated nutrient sensing, mitochondrial dysfunction, stem cell exhaustion, altered intercellular communications, and cellular senescence . Senescence was initially defined as loss of replicative capacity associated with the accumulated shortening of telomeres with every cellular division (replicative senescence); but we now know that there are forms of senescence that are driven by the exposure to stress signals and do not correlate with the older age of the organism or the number of the cellular divisions (stress‐induced premature senescence) . The latter is especially relevant in cells with limited replicative ability that are involved in the long‐term maintenance of tissue homeostasis, like articular chondrocytes.…”

Section: Osteoarthritismentioning

confidence: 99%

“…84 Senescence was initially defined as loss of replicative capacity associated with the accumulated shortening of telomeres with every cellular division (replicative senescence); but we now know that there are forms of senescence that are driven by the exposure to stress signals and do not correlate with the older age of the organism or the number of the cellular divisions (stress-induced premature senescence). 84,85 The latter is especially relevant in cells with limited replicative ability that are involved in the long-term maintenance of tissue homeostasis, like articular chondrocytes. Recent studies showed that OA chondrocytes display features of premature epigenetic aging 86 and the senescenceassociated secretory phenotype.…”

Section: Osteoarthritismentioning

confidence: 99%

Phenotypic instability of chondrocytes in osteoarthritis: on a path to hypertrophy

Singh

Marcu

Goldring

et al. 2018

Annals of the New York Academy of Sciences

113

130

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Articular chondrocytes are quiescent, fully differentiated cells responsible for the homeostasis of adult articular cartilage by maintaining cellular survival functions and the fine-tuned balance between anabolic and catabolic functions. This balance requires phenotypic stability that is lost in osteoarthritis (OA), a disease that affects and involves all joint tissues and especially impacts articular cartilage structural integrity. In OA, articular chondrocytes respond to the accumulation of injurious biochemical and biomechanical insults by shifting toward a degradative and hypertrophy-like state, involving abnormal matrix production and increased aggrecanase and collagenase activities. Hypertrophy is a necessary, transient developmental stage in growth plate chondrocytes that culminates in bone formation; in OA, however, chondrocyte hypertrophy is catastrophic and it is believed to initiate and perpetuate a cascade of events that ultimately result in permanent cartilage damage. Emphasizing changes in DNA methylation status and alterations in NF-κB signaling in OA, this review summarizes the data from the literature highlighting the loss of phenotypic stability and the hypertrophic differentiation of OA chondrocytes as central contributing factors to OA pathogenesis.

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“…fibroblasts, chondrocytes), blood, and local and migrating inflammatory cells [57, 47, 58, 59]. These factors may promote disease progression and pathology in disease states such as arthritis or cancer-induced bone pain.…”

Section: Site Of Injury or Pathologymentioning

confidence: 99%

Mechanisms Underlying Bone and Joint Pain

Havelin

King

2018

Curr Osteoporos Rep

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Purpose of Review. The goal of this review is to provide a broad overview of the current understanding of mechanisms underlying bone and joint pain. Recent Findings. Bone or joint pathology is generally accompanied by local release of pro-inflammatory cytokines, growth factors and neurotransmitters that activate and sensitize sensory nerves resulting in an amplified pain signal. Modulation of the pain signal within the spinal cord and brain that result in net increased facilitation is proposed to contribute to the development of chronic pain. Summary. Great strides have been made in our understanding of mechanisms underlying bone and joint pain that will guide development of improved therapeutic options for these patients. Continued research is required for improved understanding of mechanistic differences driving different components of bone and/or joint pain such as movement related pain compared to persistent background pain. Advances will guide development of more individualized and comprehensive therapeutic options.

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Senescent cells and osteoarthritis: a painful connection

Cited by 229 publications

References 126 publications

A Proteomic Atlas of Senescence-Associated Secretomes for Aging Biomarker Development

A Proteomic Atlas of Senescence-Associated Secretomes for Aging Biomarker Development

Phenotypic instability of chondrocytes in osteoarthritis: on a path to hypertrophy

Mechanisms Underlying Bone and Joint Pain

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