Project description:Aging is one of the greatest risk factors for chronic diseases. Research on aging at the cellular level, especially in adult stem cells, is conducive to a comprehensive understanding of the molecular processes of aging. We performed multiple systematic genome-wide CRISPR interference (CRISPRi) screenings in human primary mesenchymal stem cells (MSC) derived from adipose tissues. Notably, we identified potential novel regulators in the progress of MSC senescence in terms of both replicative senescence and inflammatory induced senescence. Combining the functional genomic data with 405 GWAS datasets, including 50 aging-related studies, we observed that the inflammatory aging signatures identified from the CRISPRi screenings were significantly associated with diverse aging processes, suggesting novel signatures to analyze and predict aging status and aging-related disease. These novel signatures verified from the comprehensive functional genomics and genetic datasets may provide targets to interfere with the aging process as well as to improve cell therapy products.

Project description:Identification of replicative aging and inflammatory aging signatures via whole-genome CRISPRi screens

Project description:Identification of replicative aging and inflammatory aging signatures via whole-genome CRISPRi screens

Project description:Epigenomic changes and stem cell exhaustion are two hallmarks of aging. Accumulating evidence suggest that MSC senescence could perpetuate aging or age-related diseases. Here we report that two H3K9 demethylases KDM3A and KDM4C regulate heterochromatin reorganization via transcriptionally activating condensin components NCAPD2 and NCAPG2 in aging MSCs. Suppression of KDM3A or KDM4C leads to robust DNA damage response and aggravates cellular senescence, whereas overexpression of KDM3A/KDM4C or NCAPD2 directly promotes heterochromatin reorganization and blunts DNA damage response. MSCs derived from kdm3a-/- mice exhibit compromised heterochromatin organization machinery and are more susceptible to genotoxic damage, which are associated with accelerated bone aging. Consistently, analysis of human bone marrow MSCs and transcriptome database for other human adult stem cells reveals inverse correlation of KDM3A and KDM4C with aging. Taken together, the present finding unveils a novel function of histone demethylases as a surveillance mechanism to restrain DNA damage accumulation via transcriptionally activating condensins during stem cell aging, which provides potential targets for the diagnosis and intervention of human aging and geriatric diseases.

Project description:Investigation of the whole genome expression levels from dissected adult cardiac tubes at 10 days and 40 day. We describe a functional genomic investigation of the genetic control of cardiac senescence in Drosophila. Molecular signatures of heart aging were identified by differential transcriptome analysis followed by a detailed bio-informatic analysis. This approach implicated the JNK/dJun pathway and the transcription factor Vri/dNFIL3 in the transcription regulatory network involved in cardiac senescence and suggested the possible involvement of oxidative stress (OS) in the aging process. 4 biological replicates for each time point (10 days and 40 days) were used. Dye-swap replications, in which each hybridization is done twice, with dye assignments reversed in the second hybridization, were used with a design which allows direct comparison between time points . This method allows technical replicates and eliminates variation that might result from differences in fluorescence dye intensities.

Project description:To determine miRNA expression changes during in vitro senescence of mesenchymal stem cells (MSC) we have analyzed differential expression of the corresponding early passage (P2) and senescent passage (PX). Keywords: miRNA, senescence, mesenchymal stromal cells, mesenchymal stem cells, MSC

Project description:Little is known about tissue specific changes that occur with aging in humans. Using the description of 33 million histological samples we extract thousands of age- and mortality-associated features from text narratives that we call The Human Pathome (pathoage.com). Notably, we can broadly determine when pathological aging starts, indicating a sexual dimorphism with females aging earlier but slower and males aging later but faster. Using machine learning, we employ unsupervised topic-modelling to identify terms and themes that predict age and mortality. As a proof of principle, we cross reference these terms in PubMed to identify nintedanib as a potential aging intervention and show that nintedanib reduces markers of cellular senescence, reduces pro-fibrotic gene pathways in senescent cells and extends the lifespan of fruit flies. Our findings pave the way for expanded exploitation of population datasets towards discovery of novel aging interventions.

Project description:Investigation of the whole genome expression levels from dissected adult cardiac tubes at 10 days and 40 day. We describe a functional genomic investigation of the genetic control of cardiac senescence in Drosophila. Molecular signatures of heart aging were identified by differential transcriptome analysis followed by a detailed bio-informatic analysis. This approach implicated the JNK/dJun pathway and the transcription factor Vri/dNFIL3 in the transcription regulatory network involved in cardiac senescence and suggested the possible involvement of oxidative stress (OS) in the aging process.

Project description:Aging and senescence-associated signatures of aged kidney glomerular cells

Project description:Skeletal muscle allows voluntary movement and plays a key role in regulating metabolism and homeostasis in the organism. Adult muscle stem cells, MuSCs, are responsible for muscle growth and regeneration. Skeletal muscle suffers from sarcopenia (muscle mass and function loss) during the aging process. Burgeoning evidence suggests that cellular senescence drives MuSC dysfunction in muscle aging. Activation of senescence-associated secretory phenotype (SASP) factors, which is one of the hallmarks of senescence, may be a driving mechanism of sarcopenia but no study so far has clearly defined cellular senescence atlas and SASP components in aging human muscles. Here in this study we propose to profile aging and senescence atlases in aging muscles using the state-of-art multiomics approaches. Our pilot results demonstrate the prevalence of cellular senescence and the dynamics/heterogeneity of SASPs in aging human muscle. Furthermore, regulators governing senescence state and SASP induction were defined. Moreover, we demonstrated the potential of senotherapeutic targeting for sarcopenia treatment. In the project we propose (1) To complete single cell multiomics mapping of aging muscle atlas. (2) To further elucidate cellular senescence in aging muscle. (3) To investigate JUNB regulation of MuSC SASP induction in aging muscle. (4) To test the potential use of senotherapeutics on aging muscle. Once completed, findings from this study will uncover novel knowledge of how MuSC senescence is involved in niche alteration and muscle aging through SASPs and demonstrate the possibility of developing senotherapeutics for treating sarcopenia.