Explore the vast range of titles available.

Zusammenfassung Hintergrund Ausgelöst durch potenziell protumorigene, zellschädigende Ereignisse stellt zelluläre Seneszenz eine Barriere gegen maligne Entartung dar. Seneszenzinduktion führt zu Veränderungen auf zellulärer Ebene (Chromatinstruktur, Metabolismus, Zellzyklusarrest) und alteriert die Interaktion der seneszenten (Tumor‑)Zellen mit ihrer Mikroumgebung. Seneszente Zellen modellieren die Tumor-Immunüberwachung, induzieren aber durch das veränderte Sekretom auch promaligne Prozesse. Ziel der Arbeit In dieser Arbeit werden Nachweismethoden und prognostische Implikationen zellulärer Seneszenz im kolorektalen Karzinom (CRC) untersucht und es soll zum Verständnis der Interaktion seneszenter CRC-Zellen mit dem Immunsystem beigetragen werden. Material und Methoden Seneszenz-assoziierte Moleküle wurden immunhistochemisch an einem Tissue Microarray (TMA) von n  = 598 CRC-Patienten untersucht. Eine Korrelation der Expression mit krankheitsspezifischem Überleben (DSS) und progressionsfreiem Überleben (PFS) wurde untersucht. An konsekutiven TMA-Schnitten wurde die räumliche Beziehung p21- und CD8-positiver Zellen untersucht. In vitro wurde Seneszenz an CRC-Zelllinien induziert und deren Interaktion in Ko-Kultur mit verschiedenen Immunzelllinien funktionell untersucht. Ergebnisse Die Expression Seneszenz-assoziierter Moleküle und die räumliche Beziehung zwischen p21- und CD8-positiven Zellen korrelieren signifikant mit DSS und PFS . Sowohl die Abwesenheit als auch eine extrem hohe Expression Seneszenz-assoziierter Moleküle sind mit einer negativen Prognose verknüpft. In vitro werden seneszente CRC-Zellen dosisabhängig durch Immunzellen über direkten Zell-Zell-Kontakt und Apoptoseinduktion eliminiert. Diskussion Als Nachweis einer wichtigen Barrierefunktion gegen maligne Entartung haben Seneszenzmarker signifikante prognostische Relevanz im CRC. Unsere Ergebnisse verdeutlichen darüber hinaus den pleiotropen Effekt zellulärer Seneszenz in vivo . Die Auswirkungen zellulärer Seneszenz sind abhängig von der Mikroumgebung und der Immunüberwachung seneszenter Zellen.

ABSTRACT A major aging hallmark is the accumulation of cellular senescence burden. Over time, senescent cells contribute to tissue deterioration through chronic inflammation and fibrosis driven by the senescence‐associated secretory phenotype (SASP). The human ovary is one of the first organs to age, and prominent age‐related fibroinflammation within the ovarian microenvironment is consistent with the presence of senescent cells, but these cells have not been characterized in the human ovary. We thus established a doxorubicin‐induced model of cellular senescence to establish a “senotype” (gene/protein signature of a senescence cell state) for ovarian senescent cells. Explants of human postmenopausal ovarian cortex and medulla were treated with doxorubicin for 24 h, followed by culture for up to 10 days in a doxorubicin‐free medium. Tissue viability was confirmed by histology, lack of apoptosis, and continued glucose consumption by explants. Single nuclei sequencing and proteomics revealed an unbiased signature of ovarian senescence. We identified distinct senescence profiles for the cortex and medulla, driven predominantly by epithelial and stromal cells. Proteomics uncovered subregional differences in addition to 120 proteins common to the cortex and medulla SASP. Integration of transcriptomic and proteomic analyses revealed 26 shared markers, defining a senotype of doxorubicin‐induced senescence unique to the postmenopausal ovary. A subset of these proteins: Lumican, SOD2, MYH9, and Periostin were mapped onto native tissue to reveal compartment‐specific localization. This senotype will help determine the role of cellular senescence in ovarian aging, inform biomarker development to identify, and therapeutic applications to slow or reverse ovarian aging, senescence, and cancer. Explants of human postmenopausal ovarian cortex and medulla were treated with doxorubicin for 24 h followed by culture for up to 10 days in doxorubicin‐free medium. Single nuclei sequencing and proteomics revealed an unbiased signature of ovarian senescence driven by epithelial cells in the cortex and stromal cells in the cortex and medulla. Integration of transcriptomic and proteomic analyses revealed 26 shared markers, defining a robust senotype of doxorubicin‐induced senescence unique to the postmenopausal ovary.

Acute myeloid leukaemia (AML) is a common and highly aggressive haematological malignancy in adults. Senescence‐associated secretory phenotype (SASP) plays important roles in tumorigenesis and progression of tumour. However, the prognostic value of SASP in patients with AML has not been clarified. The present study aims to explore the prognostic value of SASP and develop a prognostic risk signature for AML. The RNA‐sequencing data was collected from the TCGA, GTEx and TARGET databases. Subsequently, differentially expressed gene analysis, univariate Cox regression and LASSO regression were applied to identified prognostic SASP‐related genes and construct a prognostic risk‐scoring model. The risk score of each patient were calculated and patients were divided into high‐ or low‐risk groups by the median risk score. This novel prognostic signature included 11 genes: G6PD, CDK4, RPS6KA1, UBC, H2BC12, KIR2DL4, HSF1, IFIT3, PIM1, RUNX3 and TRIM21. The patients with AML in the high‐risk group had shorter OS, demonstrating that the risk score acted as a prognostic predictor, which was validated in the TAGET‐AML dataset. Univariate and multivariate analysis revealed the risk score was an independent prognostic factor in patients with AML. Furthermore, the present study revealed that the risk score was associated with immune landscape, immune checkpoint gene expression and chemotherapeutic efficacy. In the present study, we constructed and validated a unique SASP‐related prognostic model to assess therapeutic effect and prognosis in patients with AML, which might contribute to understanding the role of SASP in AML and guiding the treatment for AML.

Aging exhibits several hallmarks in common with cancer, such as cellular senescence, dysbiosis, inflammation, genomic instability, and epigenetic changes. In recent decades, research into the role of cellular senescence on tumor progression has received widespread attention. While how senescence limits the course of cancer is well established, senescence has also been found to promote certain malignant phenotypes. The tumor‐promoting effect of senescence is mainly elicited by a senescence‐associated secretory phenotype, which facilitates the interaction of senescent tumor cells with their surroundings. Targeting senescent cells therefore offers a promising technique for cancer therapy. Drugs that pharmacologically restore the normal function of senescent cells or eliminate them would assist in reestablishing homeostasis of cell signaling. Here, we describe cell senescence, its occurrence, phenotype, and impact on tumor biology. A “one‐two‐punch” therapeutic strategy in which cancer cell senescence is first induced, followed by the use of senotherapeutics for eliminating the senescent cells is introduced. The advances in the application of senotherapeutics for targeting senescent cells to assist cancer treatment are outlined, with an emphasis on drug categories, and the strategies for their screening, design, and efficient targeting. This work will foster a thorough comprehension and encourage additional research within this field. Senescent cells exert a double‐edged sword effect on tumor progression. Amplification beneficial effects while inhibition related protumorigenic pathways of senescence will help improve antitumor efficacy.

The blind mole rat (Spalax) is a wild, long‐lived rodent that has evolved mechanisms to tolerate hypoxia and resist cancer. Previously, we demonstrated high DNA repair capacity and low DNA damage in Spalax fibroblasts following genotoxic stress compared with rats. Since the acquisition of senescence‐associated secretory phenotype (SASP) is a consequence of persistent DNA damage, we investigated whether cellular senescence in Spalax is accompanied by an inflammatory response. Spalax fibroblasts undergo replicative senescence (RS) and etoposide‐induced senescence (EIS), evidenced by an increased activity of senescence‐associated beta‐galactosidase (SA‐β‐Gal), growth arrest, and overexpression of p21, p16, and p53 mRNAs. Yet, unlike mouse and human fibroblasts, RS and EIS Spalax cells showed undetectable or decreased expression of the well‐known SASP factors: interleukin‐6 (IL6), IL8, IL1α, growth‐related oncogene alpha (GROα), SerpinB2, and intercellular adhesion molecule (ICAM‐1). Apparently, due to the efficient DNA repair in Spalax, senescent cells did not accumulate the DNA damage necessary for SASP activation. Conversely, Spalax can maintain DNA integrity during replicative or moderate genotoxic stress and limit pro‐inflammatory secretion. However, exposure to the conditioned medium of breast cancer cells MDA‐MB‐231 resulted in an increase in DNA damage, activation of the nuclear factor κB (NF‐κB) through nuclear translocation, and expression of inflammatory mediators in RS Spalax cells. Evaluation of SASP in aging Spalax brain and intestine confirmed downregulation of inflammatory‐related genes. These findings suggest a natural mechanism for alleviating the inflammatory response during cellular senescence and aging in Spalax, which can prevent age‐related chronic inflammation supporting healthy aging and longevity. The uncoupling of senescence phenotype and the inflammatory component of SASP was discovered in long‐lived blind mole rat, Spalax, adapted to extreme environments. Cellular senescence in Spalax, evidenced by increased SA‐β‐Gal activity, upregulation of p21/p16/p53, is not accompanied by accumulation of DNA damage nor by secretion of SASP factors. We suggest that genome integrity, inhibition of NF‐κB nuclear translocation, and IL1α suppression are involved in overcoming the inflammatory response in aging Spalax.

Aging is a universal feature of life that is a major focus of scientific research and a risk factor in many diseases. A comprehensive understanding of the cellular and molecular mechanisms of aging are critical to the prevention of diseases associated with the aging process. Here, it is shown that MYSM1 is a key suppressor of aging and aging‐related pathologies. MYSM1 functionally represses cellular senescence and the aging process in human and mice primary cells and in mice organs. MYSM1 mechanistically attenuates the aging process by promoting DNA repair processes. Remarkably, MYSM1 deficiency facilitates the aging process and reduces lifespan, whereas MYSM1 over‐expression attenuates the aging process and increases lifespan in mice. The functional role of MYSM1 is demonstrated in suppressing the aging process and prolonging lifespan. MYSM1 is a key suppressor of aging and may act as a potential agent for the prevention of aging and aging‐associated diseases. Aging is a universal feature of life and a risk factor for many diseases. This study reveals that MYSM1 plays a key role in the suppression of the aging process and in the prolongation of lifespan. Thus, MYSM1 may act as a potential agent for the prevention of the aging process and the treatment of age‐associated diseases.

Cellular senescence is a stable cell cycle arrest that can be triggered in normal cells in response to various intrinsic and extrinsic stimuli, as well as developmental signals. Senescence is considered to be a highly dynamic, multi-step process, during which the properties of senescent cells continuously evolve and diversify in a context dependent manner. It is associated with multiple cellular and molecular changes and distinct phenotypic alterations, including a stable proliferation arrest unresponsive to mitogenic stimuli. Senescent cells remain viable, have alterations in metabolic activity and undergo dramatic changes in gene expression and develop a complex senescence-associated secretory phenotype. Cellular senescence can compromise tissue repair and regeneration, thereby contributing toward aging. Removal of senescent cells can attenuate age-related tissue dysfunction and extend health span. Senescence can also act as a potent anti-tumor mechanism, by preventing proliferation of potentially cancerous cells. It is a cellular program which acts as a double-edged sword, with both beneficial and detrimental effects on the health of the organism, and considered to be an example of evolutionary antagonistic pleiotropy. Activation of the p53/p21 WAF1/CIP1 and p16 INK4A /pRB tumor suppressor pathways play a central role in regulating senescence. Several other pathways have recently been implicated in mediating senescence and the senescent phenotype. Herein we review the molecular mechanisms that underlie cellular senescence and the senescence associated growth arrest with a particular focus on why cells stop dividing, the stability of the growth arrest, the hypersecretory phenotype and how the different pathways are all integrated.

Osteoarthritis (OA) is an age-related cartilage degenerative disease, and chondrocyte senescence has been extensively studied in recent years. Increased numbers of senescent chondrocytes are found in OA cartilage. Selective clearance of senescent chondrocytes in a post-traumatic osteoarthritis (PTOA) mouse model ameliorated OA development, while intraarticular injection of senescent cells induced mouse OA. However, the means and extent to which senescence affects OA remain unclear. Here, we review the latent mechanism of senescence in OA and propose potential therapeutic methods to target OA-related senescence, with an emphasis on immunotherapies. Natural killer (NK) cells participate in the elimination of senescent cells in multiple organs. A relatively comprehensive discussion is presented in that section. Risk factors for OA are ageing, obesity, metabolic disorders and mechanical overload. Determining the relationship between known risk factors and senescence will help elucidate OA pathogenesis and identify optimal treatments.

P21 and p16 have been identified as inducers of senescence. Many transgenic mouse models have been developed to target cells expressing high levels of p16Ink4a (p16[sup.high]) and investigate their potential contribution to tissue dysfunction in aging, obesity, and other pathological conditions. However, the specific roles of p21 in various senescence-driven processes remain unclear. To gain a deeper understanding of p21, we built a p21-3MR mouse model containing a p21 promoter-driven module that allowed us to target cells with high p21Chip expression (p21[sup.high]). Using this transgenic mouse, we monitored, imaged, and eliminated p21[sup.high] cells in vivo. We also applied this system to chemically induced weakness and found that the clearance of p21[sup.high] cells improved doxorubicin (DOXO)-induced multi-organ toxicity in mice. By recognizing p21 transcriptional activation spatially and temporally, the p21-3MR mouse model can be a valuable and powerful tool for studying p21[sup.high] cells to further understand senescence biology.

Cellular senescence is a complex cell state that can occur during physiological ageing or after exposure to stress signals, regardless of age. It is a dynamic process that continuously evolves in a context-dependent manner. Senescent cells interact with their microenvironment by producing a heterogenous and plastic secretome referred to as the senescence-associated secretory phenotype (SASP). Hence, understanding the cross-talk between SASP and the microenvironment can be challenging due to the complexity of signal exchanges. In this review, we first aim to update the definition of senescence and its associated biomarkers from its discovery to the present day. We detail the regulatory mechanisms involved in the expression of SASP at multiple levels and develop how SASP can orchestrate microenvironment modifications, by focusing on extracellular matrix modifications, neighboring cells’ fate, and intercellular communications. We present hypotheses on how these microenvironmental events may affect dynamic changes in SASP composition in return. Finally, we discuss the various existing approaches to targeting SASP and clarify what is currently known about the biological effects of these modified SASPs on the cellular environment.