Tissue specificity of senescent cell accumulation during physiologic and accelerated aging of mice

Yousefzadeh, Matthew J.; Zhao, Jing; Bukata, Christina; Wade, Erin A.; McGowan, Sara J.; Angelini, Luise; Bank, Michael P.; Gurkar, Aditi U.; McGuckian, Collin A.; Calubag, Mariah F.; Kato, Jonathan; Burd, Christin E.; Robbins, Paul D.; Niedernhofer, Laura J.

doi:10.1111/acel.13094

Cited by 179 publications

(102 citation statements)

References 47 publications

(86 reference statements)

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“…A recent study revealed that in both aged wild type mice (30 months) and progeroid mice, males express significantly greater levels of p16 and p21 mRNA in the liver, kidney, and spleen than age-matched females. This sex disparity was decreased in wild-type mice at the extremes of old age (35 months): p16 mRNA levels remained significantly lower in the liver and spleen of females compared to males, while p21 mRNA levels in the spleen were significantly greater in females than males [287]. These results suggest that males bear a larger load of senescent cells than females throughout aging, which may be influencing the increased male risk for various age-related pathologies, including cancer.…”

Section: Sex Differences In Senescencementioning

confidence: 87%

Sex differences in cancer mechanisms

et al. 2020

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We now know that cancer is many different diseases, with great variation even within a single histological subtype. With the current emphasis on developing personalized approaches to cancer treatment, it is astonishing that we have not yet systematically incorporated the biology of sex differences into our paradigms for laboratory and clinical cancer research. While some sex differences in cancer arise through the actions of circulating sex hormones, other sex differences are independent of estrogen, testosterone, or progesterone levels. Instead, these differences are the result of sexual differentiation, a process that involves genetic and epigenetic mechanisms, in addition to acute sex hormone actions. Sexual differentiation begins with fertilization and continues beyond menopause. It affects virtually every body system, resulting in marked sex differences in such areas as growth, lifespan, metabolism, and immunity, all of which can impact on cancer progression, treatment response, and survival. These organismal level differences have correlates at the cellular level, and thus, males and females can fundamentally differ in their protections and vulnerabilities to cancer, from cellular transformation through all stages of progression, spread, and response to treatment. Our goal in this review is to cover some of the robust sex differences that exist in core cancer pathways and to make the case for inclusion of sex as a biological variable in all laboratory and clinical cancer research. We finish with a discussion of lab-and clinic-based experimental design that should be used when testing whether sex matters and the appropriate statistical models to apply in data analysis for rigorous evaluations of potential sex effects. It is our goal to facilitate the evaluation of sex differences in cancer in order to improve outcomes for all patients.

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Section: Sex Differences In Senescencementioning

confidence: 87%

Sex differences in cancer mechanisms

et al. 2020

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“…In satellite cells isolated from young (15‐24) and old (72‐80) humans, the rate of division, maximum number of divisions, p16 mRNA, and telomere length are not different 70,73 . Further, skeletal muscle from aged wild‐type and progeroid mice do not exhibit an increase in p16 or p21 expression 67 . However, although aging does not increase the absolute number of γH2AX+ satellite cells in human muscle, the percentage of satellite cells that are γH2AX+ is higher with age (3.5% compared to 7%), due to lower satellite cell abundance in aged muscle.…”

Section: Discussionmentioning

confidence: 98%

“…A recent paper by Yousefzadeh and colleagues 67 quantified p16 and p21 expression in various tissues using two animal models: 1) mice that developed senescence at a rapid rate (Ercc1 ‐/Δ ) and 2) young and old wild‐type mice. Relative to 10 other tissues, p16 and p21 expression in muscle tissues (heart, gastrocnemius, and quadriceps) were, overall, unchanged in the Ercc1 ‐/Δ model, whereas fat, aorta, kidney, liver, and large intestine had >10‐folder higher expression of p16 and p21 67 . Moreover, p16 and p21 expression were the lowest in the gastrocnemius and quadriceps, and were not higher in old wild‐type mice.…”

Section: Discussionmentioning

confidence: 99%

In vivo analysis of γH2AX+ cells in skeletal muscle from aged and obese humans

et al. 2020

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Over the past 20 years, various identifiers of cellular senescence have been used to quantify the abundance of these cells in different tissues. These include classic markers such as p16, senescence-associated β-gal, and γH2AX, in addition to more recent markers (Sudan Black B and HMGB1). In vivo data on the usefulness of these markers in skeletal muscle are very limited and inconsistent. In the present study, we attempted to identify senescent cells in frozen human skeletal muscle biopsies using these markers to determine the effects of age and obesity on senescent cell burden; however, we were only able to assess the abundance of DNA-damaged nuclei using γH2AX immunohistochemistry. The abundance of γH2AX+ cells, including satellite cells, was not higher in muscle from old compared to young individuals; however, γH2AX+ cells were higher with obesity. Additionally, terminally differentiated, postmitotic myofiber nuclei from obese individuals had elevated γH2AX abundance compared to muscle from lean individuals. Analyses of gene expression support the conclusion that the elevated DNA damage and the senescence-associated secretory phenotype are preferentially associated with obesity in skeletal muscle. These data implicate obesity as a larger contributor to DNA damage in skeletal muscle than aging; however, more sensitive senescence markers for human skeletal muscle are needed to determine if these cells are in fact senescent. K E Y W O R D SDNA damage, postmitotic, satellite cells, senescence, γH2AX | 7019 DUNGAN et Al.

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“…However, senescent fibroblasts, smooth muscle cells, and/or alveolar epithelial cells have been implicated in the etiology or progression of several human diseases, including chronic obstructive pulmonary disease, idiopathic pulmonary fibrosis and emphysema [39]. In mice, aging does not contribute to the induction of cellular senescence by cigarette smoke in the lung of a mouse model of COPD/emphysema [40], but other studies using aged wild type mice display an increase of p16Ink4a mRNA and senescence-associated-β-galactosidase (SA-β-Gal) activity in the lung compared to young controls [41,42]. The stimuli that drive lung cells into senescence are still incompletely understood and may include infection or inflammation due to infection.…”

Section: Cellular Senescence and Inflammatory Responsementioning

confidence: 99%

Exploring the Relevance of Senotherapeutics for the Current SARS-CoV-2 Emergency and Similar Future Global Health Threats

Malavolta

Giacconi

Brunetti

et al. 2020

Cells

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The higher death rate caused by COVID-19 in older people, especially those with comorbidities, is a challenge for biomedical aging research. Here we explore the idea that an exacerbated inflammatory response, in particular that mediated by IL-6, may drive the deleterious consequences of the infection. Data shows that other RNA viruses, such as influenza virus, can display enhanced replication efficiency in senescent cells, suggesting that the accumulation of senescent cells with aging and age-related diseases may play a role in this phenomenon. However, at present, we are completely unaware of the response to SARS-CoV and SARS-COV-2 occurring in senescent cells. We deem that this is a priority area of research because it could lead to the development of several therapeutic strategies based on senotherapeutics or prevent unsuccessful attempts. Two of these senotherapeutics, azithromycin and ruxolitinib, are currently undergoing testing for their efficacy in treating COVID-19. The potential of these strategies is not only for ameliorating the consequences of the current emergence of SARS-CoV-2, but also for the future emergence of new viruses or mutated ones for which we are completely unprepared and for which no vaccines are available.

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Tissue specificity of senescent cell accumulation during physiologic and accelerated aging of mice

Cited by 179 publications

References 47 publications

Sex differences in cancer mechanisms

Sex differences in cancer mechanisms

In vivo analysis of γH2AX+ cells in skeletal muscle from aged and obese humans

Exploring the Relevance of Senotherapeutics for the Current SARS-CoV-2 Emergency and Similar Future Global Health Threats

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