Cellular senescence in musculoskeletal homeostasis, diseases, and regeneration

The musculoskeletal system (MSK), including bone, cartilaginous tissues, skeletal muscle, tendon, ligament, intervertebral disc, and others, is the structural framework for the body and enables movement. Bones are held in position by ligaments. Skeletal muscles power the movement of bones. Muscles and bones are connected through tendons. These tissues together form the articulating joints. In addition to providing physical support, MSK tissues have endocrine functions and communicate with other tissues to affect organism homeostasis and overall physiological health. The skeleton is a highly dynamic structure that changes in shape and composition throughout life. Skeletal muscle fiber also has high remodeling plasticity on demand. Not surprisingly, bone, cartilage, and skeletal muscle cell homeostasis is tightly controlled, as is the maintenance of tissue structure and mass. Aging, characterized by a gradual functional decline, is the greatest risk factor for many chronic musculoskeletal conditions, such as osteoporosis, osteoarthritis, and sarcopenia. As common musculoskeletal complications, these three disorders share genetic, endocrine, and mechanical risk factors, and are also closely connected both mechanically and metabolically. These age-associated musculoskeletal conditions leads to MSK structural degeneration, mechanical pain, decreased mobility, and limited function. 1 , 2 Particularly, among patients aged 65 years or older, chronic skeletal diseases, such as osteoporosis and associated bone fracture and osteoarthritis, are the most prevalent conditions leading to frailty and a decline in mobility. An estimated 10 million Americans have osteoporosis, and another 43 million have low bone density. Osteoporosis will be responsible for more than $25 billion in annual health care spending by 2025 in the United States. 3 Osteoarthritis is the most prevalent chronic joint disease affecting the knees, hands, hips, and spine, and is the fourth most common cause of hospitalization among adults in the United States, resulting in enormous health care costs. 4 Sarcopenia is present in an estimated 5%–13% of individuals older than 60 and 50% of persons older than 80, 5 and can cause severe adverse clinical outcomes. 6 Despite substantial social demand, no medications for osteoarthritis or sarcopenia disease treatment have been approved by the US Food and Drug Administration. Related to their structural function, MSK tissues are susceptible to trauma and injury, and aging also adversely affects the tissue regenerative capacity, resulting in delayed tissue repair, disability, and pain. In the past few years, the MSK research community has been considerably interested in cellular senescence, which represents a series of diverse, dynamic, and heterogeneous cellular states with the senescence‐associated secretory phenotype (SASP). In this review, we provide a comprehensive summary of cellular senescence known to be involved in MSK homeostasis, disease, and regeneration. As senescent cells (SnCs) appear to have dual roles in physiologic tissue homeostasis/repair as well as pathologic responses, this review highlights the functional heterogeneity and the molecular pathways responsible for senescence induction in distinct physiological settings.

In addition to stable cell cycle arrest, the SASP or senescence-messaging secretome is another key feature of SnCs that distinguishes the cells from other cell cycle-arrested cells. SnCs secrete hundreds of factors that include proinflammatory cytokines, chemokines, growth factors, and proteases. 9 , 56 – 59 A recent study reported that oxylipins, a class of biologically active lipids that arise from the oxygenation of polyunsaturated fatty acids, are a component of the SASP. 60 Not only do SnCs with SASP induce autocrine reinforcement, but they also communicate with neighboring cells in a paracrine manner to propagate the stress response in the tissue microenvironment. 56 , 61 , 62 Of note, the paracrine effects of the SASP can be beneficial or detrimental depending on the tissue context. 63 On the one hand, the SASP prevents cancer progression by inducing paracrine senescence in neighboring cells, 61 , 62 promoting embryogenesis, tissue repair, and regeneration, 58 , 64 , 65 and activating the immune system, which facilitates clearance of damaged cells. 66 , 67 On the other hand, the SASP promotes tumorigenic processes such as angiogenesis and invasion 56 , 68 and induces chronic inflammation that drives aged-related abnormalities in various tissues. 69 , 70 The SASP factors produced by SnCs are highly cell specific and vary substantially even in the same type of cells, depending on the duration of senescence and origin of the pro-senescence stimulus. 53 Through mass spectrometry, a core set of SASP proteins that are commonly produced by different types of SnCs were identified, 54 which is helpful for the prediction of senescence-associated functions. It is important to note that despite the existence of certain core proteins, the expression and secretion of most SASP factors remain variable and context dependent. SASP induction and cell proliferative arrest appear to be regulated through separate signaling pathways because SASP is not induced by the expression of master cell cycle arrest regulatory genes p16 Ink4a or p21 Waf1/Cip1 . 57 , 71 Reportedly, transcriptional activation, chromatin remodeling, damaged DNA sensing, and extracellular vesicles, such as exosomes, may cause the activation of the SASP gene and promote the development of SASP. This aspect of SnCs has been summarized in several recent review articles. 72 – 76 Although multiple pathways have been reported for SASP initiation and regulation of SnCs, the precise mechanisms regulating SASP induction are far from understood. Further defining the senescent secretome and its heterogeneity in function in various biological contexts and better understanding the temporospatial regulation of the SASP will help identify more biomarkers of SnCs, enabling the development of specific senescence modulatory therapies.

Bone aging is a normal process caused by the disrupted balance between bone resorption and formation as a result of the changes in osteoblast and osteoclast activity, leading to bone loss. In fact, peak bone mass (PBM) occurs during the third decade of life, after which bone mass plateaus and then declines. Men and women have different rates of bone loss after PBM. Markedly accelerated bone loss in women occurs during perimenopause and the early postmenopausal period. In men, bone loss with aging is less profound but is maintained at a persistent lower rate. 2 , 85 , 86 In humans and mice, bone loss differs between the trabecular and cortical compartments with age. Trabecular bone aging is associated with reduced trabecular number, increased spacing, and decreased thickness. 87 , 88 In cortical bone, endocortical resorption and periosteal bone formation often occur during aging, leading to cortical thinning with marrow cavity expansion and increased cortical porosity. 2 , 89 , 90 In addition to the reduction in bone quantity, bone quality and strength also diminish during aging, leading to increased fracture risk, especially from falls. Bone aging is mediated by complex interactions of cells at multiple levels with the combination of intrinsic changes and extrinsic factors. Intrinsic changes include alterations in hormone status, cell components, and gene expression, as well as local microenvironmental changes caused by the altered production of growth factors, cytokines, and inflammatory factors. Extrinsic factors include nutrition and comorbid medical conditions. At the molecular level, it has been proposed that genomic instability, epigenetic alterations, telomere attrition, loss of proteostasis, mitochondrial dysfunction, deregulated nutrient sensing, and cellular senescence gene activation may contribute to age-related dysfunction in bone. 91 – 93 In the past few years, there is growing evidence to suggest that cellular senescence is a major player in the pathogenesis of osteoporosis, a prevalent age-related bone disorder characterized by deterioration of bone microarchitecture and low bone mineral density (BMD). SnC accumulation has been observed in bone/bone marrow, as shown by increased SA-βGal, SADS, telomere dysfunction-induced foci, p16INK4a, or p21CIP1 expression in many types of cells in aged mice, including bone marrow myeloid cells, T cells, B cells, MSCs, osteoprogenitors, osteoblasts, and osteocytes. 42 , 89 , 94 These SnCs also acquire SASP and secrete various factors to affect their microenvironment, leading to the loss of bone mass and architecture. SASP secretion of bone marrow MSCs and osteoblastic cells mediates enhanced osteoclastogenesis and the development of osteoporosis. 42 , 95 The study of senescence and the SASP of osteocytes, the longest-living bone cells embedded in the bone matrix, has drawn much attention. Senescent osteocyte accumulation has been found in the aged bone environment of mice and humans, 42 , 89 and induction of osteocyte senescence is sufficient to stimulate receptor activator of nuclear factor kappa-B ligand production, leading to increased osteoclast formation and activity. 96 The presence of SnCs and the corresponding SASP in osteoporotic bone has also been confirmed in elderly people. 42 Importantly, the genetic elimination of the SnCs using INK-ATTAC mice or administration of senolytic drugs was able to inhibit production of SASP in the bone marrow microenvironment, leading to increased bone mass and microarchitecture in aged osteoporotic mice. 97 Therefore, targeting cellular senescence may represent a new therapeutic strategy to prevent or treat osteoporosis in the elderly. However, activation of p16-3MR transgene failed to eliminate senescent osteocytes and alleviate age-associated bone loss, 98 indicating that genetic approaches used for the elimination of p16‐expressing cells are generally tissue selective. Another interesting question is the role of cellular senescence in accelerated skeletal aging in response to sex steroid deficiency. Estrogen has a crucial effect on bone metabolism, and its decline is causal in the pathogenesis of osteoporosis. In one report, ovariectomy led to the generation of premature T-cell senescence in mice, and estrogen treatment reversed the phenotype. 99 However, recent work by Farr et al. 100 using multiple approaches in mice and humans suggests no evidence of changes in senescence biomarkers or SASP factors in mouse or human bone in response to estrogen deficiency. Moreover, elimination of SnCs during young adulthood does not restore the bone loss caused by estrogen deficiency. Therefore, it is likely that estrogen deficiency-induced bone loss occurs independently of cellular senescence.

Cellular senescence in the pathogenesis of osteoarthritis The articular cartilage in human joints is subject to extreme biologic and biomechanical demands in allowing movement and function. The term “articular cartilage” typically refers to hyaline cartilage, which must be maintained within a narrow range of biochemical composition and morphologic architecture to maintain its integrity, and the intrinsic healing potential of articular cartilage is very limited. Therefore, any insult, such as injury, aging, or metabolic dysregulation, can initiate a cascade of events that lead to degradation and erosion of articular cartilage and the development of osteoarthritis. Osteoarthritis is a common chronic musculoskeletal disease and a leading cause of disability with no effective disease-modified therapy. 41 , 106 , 107 Increasing evidence in the past several years has shown that SnCs accumulate in mouse and human osteoarthritic joint tissue, and SASP has been implicated in osteoarthritis progression. 108 – 111 SnCs typically develop in response to cellular stress, preventing the proliferation of damaged or dysfunctional cells, thereby protecting organisms against diseases. Initially, SnCs are a crucial component of the wound-healing process; however, if they are not cleared in a timely manner, their persistence can lead to tissue deterioration that causes aging, as well as many chronic conditions and age-related diseases. 56 , 58 , 112 Senescent chondrocytes, for example, have been linked to post-traumatic osteoarthritis (PTOA) and age-related osteoarthritis since they were identified in the cartilage tissue isolated from patients with osteoarthritis undergoing joint replacement surgery. 11 , 108 , 113 As osteoarthritis progresses, the chondrocyte phenotype is skewed toward matrix degradation accompanied by SnC-associated SASP factors, specifically matrix metalloproteinases (MMP)-13 and aggrecan-degrading ADAMTS-5. 114 , 115 In addition, oxidative stress promotes chondrocyte senescence, mainly by activating p38 MAPK and PI3K/Akt signaling, leading to SASP factor production and increased inflammation and tissue deterioration. 116 Macrophages, in response to the SASP, are recruited to the articular space, secrete proinflammatory factors interleukin (IL)-1β, IL-6, and tumor necrosis factor α (TNFα), as well as growth factors TGFβ and BMPs, which activate synovial fibroblasts to upregulate MMPs and ADAMTS and promote osteophyte formation and drive osteoarthritis progression. 117 – 119 More recently, we have shown that damage to the joint (anterior cruciate ligament transection [ACLT]) results in increased cellular senescence (p16 + ), upregulated SnC-associated proinflammatory factors, as well as a Th17-type immune signature in the joint and draining lymph nodes, and ultimately osteoarthritis development. 108 , 110 Historically, osteoarthritis has been defined as a primarily localized disease, but through in vitro and in vivo studies we have identified a systemic Th17-SnC feedback where Th17 T cells induce senescence in healthy fibroblasts and SnCs skew naive T cells toward a Th17 phenotype in the presence of TGFβ. 110 Thus, with this new understanding of the systemic immunological feedback that exacerbates cartilage degeneration leading to osteoarthritis, more effective therapeutics can be developed to combat not only the pathological SnC, but also the greater effects of their SASP. The immune system initiates and conducts critical responses to tissue damage. SnCs, through their SASP, secrete several cytokines that influence the immune response orchestrating the balance between a proinflammatory and pro-regenerative response to injury or trauma. 56 , 112 , 120 Trauma induces a cascade of local and systemic immune events that recruit various cells to the injured site to protect the tissue from infection and promote tissue repair. Cartilage, however, because of its avascular composition, has limited self-repair capacity. Therefore, SnC accumulation and SASP signaling leading to chronic inflammation in the joint after trauma not only results in the inability for cartilage repair and osteoarthritis development but also induces systemic immune changes, possibly exacerbating responses to other injuries or diseases and promoting further tissue deterioration. The canonical proinflammatory molecules associated with SnC accumulation and their SASP in osteoarthritis are cytokines (IL-1β, IL-6, TNFα), chemokines (CCL2, CCL4), proteases (MMPs, ADAMTS), and growth factors (TGFβ, IGFBP). 109 The identification of the SnCs in the osteoarthritic joints and their contribution to the disease development have also been discussed in recent comprehensive review articles. 109 , 121 Osteoarthritis has heterogeneous causes that lead to accelerated structural damage and has long been considered as the unique consequence of a “wear and tear” process leading to cartilage degradation. Indeed, direct joint injury and mechanical overloading are im

Cellular senescence in sarcopenia Skeletal muscle attaches to bone via strong connective tissues and therefore is key to controlling locomotion. Skeletal muscle is also a critical factor in whole-body metabolism and energy expenditure and is essential for maintaining quality of life. 159 – 162 Skeletal muscle contains several cell populations, including myocytes, skeletal stem cells, fibroblasts, nerve fibers, and blood vessel cells. Adult muscle stem cells are referred to as satellite cells, which are responsible for muscle maintenance, repair, and regeneration in aging and injured muscles. 160 , 163 Loss of lean muscle mass begins at a slow rate around the fifth decade of life and accelerates over time, resulting in 30%–50% of lean mass reduction by age 70. 164 , 165 Muscle strength deficiency precedes muscle loss and declines much faster than muscle mass. Age-related decline in muscle mass and associated muscle weakness are referred to as sarcopenia. 166 Preliminary studies have linked increased senescence, not only of the muscle cells themselves, but also of their SASP, to the characteristic muscle-fiber thinning of sarcopenia. A recent study sought to determine whether SnC-implanted adjacent to skeletal muscle would affect healthy surrounding muscle cells via the “bystander effect” and senescent-like signaling. 167 SnC transplantation adjacent to skeletal muscle induced an increase in senescent markers in the muscle, as well as muscle-fiber thinning, indicative of sarcopenia. 167 SASP factors have also been linked to the induction of several factors, such as sarcolipin, that have been shown to promote skeletal muscle fibrosis and, ultimately, sarcopenia. 168 Other factors, such as endothelin-1, TRIM32, and GSK-3α have been shown to induce muscle stem cell senescence and suppress autophagy in mouse models. Knockout of each of these factors results in muscle degeneration and sarcopenia development. 169 – 171 In addition, aberrant p38α/β ΜΑPK signaling has also been observed in aged muscle stem cells, leading to reduced regenerative capacity and functional decline. 172 Pharmacologic inhibition of this p38α/β signaling in preclinical studies enhances aged muscle stem cell proliferation, restores aged muscle stem cell regenerative capacity, and provides long-term functionality and increased strength. Furthermore, in murine muscle stem cells, a recent study reported reduced expression of the transcription factor Slug and identified Slug as a transcriptional repressor of senescence-initiating gene p16 Ink4a . 173 The authors proposed to develop therapeutics to overexpress Slug as a potential inhibitor of age-related skeletal muscle degeneration and even sarcopenia development. Wnt-3 is another therapeutic target against skeletal muscle senescence and deterioration. Wnt-3 was increased in the serum of elderly people, and Wnt-3 expression induces CCN1 expression. 174 Any of these molecules could serve as promising potential targets for combatting age-related muscle degeneration and promote muscle regeneration in cases of sarcopenic development. Autophagy is the organized degradation and recycling of dysfunctional cellular components. Typically, in muscle stem cells, autophagy activity declines with age, resulting in accumulation of damaged cell components and a transition from quiescence to senescence. 175 Maintenance of basal autophagy in muscle stem cells is critical for preventing senescence and maintaining regenerative capacity. 176 Therefore, promotion of basal autophagy in aged muscle is a promising therapy to reverse senescence in muscle stem cells in elderly populations. 175 Some disorders in which autophagy is impaired lead to sarcopenia via senescence induction. For example, hyperphosphatemia, an electrolyte disorder in which circulating phosphate levels are higher than normal, induces myoblast senescence via autophagy impairment and integrin-linked kinase overexpression, which could propagate muscle degeneration and sarcopenia. 177 Recent studies have begun investigating immunogenic changes that can be influenced by SnCs in the development of sarcopenia. Preliminary studies have shown that bone marrow transplants from young mice into old mice prevent sarcopenia. 178 , 179 Macrophages present in muscle repair have been shown to secrete nicotinamide phosphoribosyltransferase (NAMPT) to stimulate muscle stem cells and promote myoblast proliferation. 180 Because NAMPT has been shown to inhibit senescence in endothelial progenitor cells via SIRT1 regulation, 181 the study suggests that macrophages, by producing NAMPT, may prevent/inhibit cellular senescence and the corresponding SASP and therefore positively regulate muscle regeneration. Metabolic irregularities, which disrupt typical metabolic homeostasis, can lead to systemic inflammation and senescence. Aberrant metabolic signaling in skeletal muscle, a critical metabolic tissue, contributes to senescence and the SASP, which accelerates sarcopenia. 182