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

Basisty, Nathan; Kale, Abhijit; Jeon, Ok Hee; Kuehnemann, Chisaka; Payne, Therese; Rao, Chirag; Holtz, Anja; Shah, Samah; Ferrucci, Luigi; Campisi, Judith; Schilling, Birgit

doi:10.1101/604306

Cited by 171 publications

(291 citation statements)

References 73 publications

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“…[ 42,43 ] A number of hallmarks of senescent cells have been recognized (including upregulated expression of p16 Ink4A and/or p21) [ 44 ] of which the senescence‐associated secretory phenotype (SASP) is a well‐characterized one. [ 45 ] It is important to note that depending on the tissues of origin and inducers of senescence, cells display a range of non‐overlapping hallmarks including secreted SASP factors (e.g., TGF‐β, IL‐6, and IL‐8). An important feature of senescent cells is also their dysregulated metabolome.…”

Section: Application Of Metabolomics For Biomarker Discovery In Agingmentioning

confidence: 99%

The Aging Metabolome—Biomarkers to Hub Metabolites

Sharma

Ramanathan

2020

Proteomics

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Aging biology is intimately associated with dysregulated metabolism, which is one of the hallmarks of aging. Aging‐related pathways such as mTOR and AMPK, which are major targets of anti‐aging interventions including rapamcyin, metformin, and exercise, either directly regulate or intersect with metabolic pathways. In this review, numerous candidate bio‐markers of aging that have emerged using metabolomics are outlined. Metabolomics studies also reveal that not all metabolites are created equally. A set of core “hub” metabolites are emerging as central mediators of aging. The hub metabolites reviewed here are nicotinamide adenine dinucleotide, reduced nicotinamide dinucleotide phosphate, α‐ketoglutarate, and β‐hydroxybutyrate. These “hub” metabolites have signaling and epigenetic roles along with their canonical roles as co‐factors or intermediates of carbon metabolism. Together these hub metabolites suggest a central role of the TCA cycle in signaling and metabolic dysregulation associated with aging.

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Section: Application Of Metabolomics For Biomarker Discovery In Agingmentioning

confidence: 99%

The Aging Metabolome—Biomarkers to Hub Metabolites

Sharma

Ramanathan

2020

Proteomics

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“…(Kandhaya-Pillai et al, 2017). CST3, which increased in smoker monocytes, is associated with subclinical atherosclerosis (Chung et al, 2018) and cellular senescence (Basisty et al, 2019). Among the monocyte smoking DEGs, we also identified TNFSF13B, a critical regulator of atherogenic B cell proliferation and differentiation (Kyaw et al, 2013a).…”

Section: Discussionmentioning

confidence: 69%

Single-cell analyses identify tobacco smoke exposure-associated, dysfunctional CD16⁺ CD8 T cells with high cytolytic potential in peripheral blood

Martos

Campbell

Lozoya

et al. 2019

Preprint

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Tobacco smoke exposure has been found to impact immune response, leukocyte subtypes, DNA methylation, and gene expression in human whole blood. Analysis with single cell technologies will resolve smoking associated (sub)population compositions, gene expression differences, and identification of rare subtypes masked by bulk fraction data. To characterize smoking-related gene expression changes in primary immune cells, we performed single-cell RNA sequencing (scRNAseq) on >45,000 human peripheral blood mononuclear cells (PBMCs) from smokers (n=4) and nonsmokers (n=4). Major cell type population frequencies showed strong correlation between scRNAseq and mass cytometry. Transcriptomes revealed an altered subpopulation of Natural Killer (NK)like T lymphocytes in smokers, which expressed elevated levels of FCGR3A (gene encoding CD16) compared to other CD8 T cell subpopulations. Relatively rare in nonsmokers (median: 1.8%), the transcriptionally unique subset of CD8 T cells comprised 7.3% of PBMCs in smokers. Mass cytometry confirmed a significant increase (p = 0.03) in the frequency of CD16+ CD8 T cells in smokers. The majority of CD16+ CD8 T cells were CD45RA positive, indicating an effector memory reexpressing CD45RA T cell (TEMRA) phenotype. We expect that cigarette smoke alters CD8 T cell composition by shifting CD8 T cells toward differentiated functional states. Pseudotemporal ordering of CD8 T cell clusters revealed that smokers' cells were biased toward later pseudotimes, and characterization of established markers in CD8 T cell subsets indicates a higher frequency of terminally differentiated cells in smokers than in nonsmokers, which corresponded with a lower frequency in naïve CD8 T cells. Consistent with an endstage TEMRA phenotype, FCGR3A-expressing CD8 T cells were inferred as the most differentiated cluster by pseudotime analysis and expressed markers linked to senescence. Examination of differentially expressed genes in other PBMCs uncovered additional senescenceassociated genes in CD4 T cells, NKT cells, NK cells, and monocytes. We also observed elevated Tregs, inducers of T cell senescence, in smokers. Taken together, our results suggest smoking-induced, senescenceassociated immune cell dysregulation contributes to smoking-mediated pathologies.

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“…Combined, the findings presented in our model recapitulate the major elements described in the pathogenesis of IPF. For instance, the presence of senescence phenotype in lung epithelium has emerged as a major contributor to aging and multiple respiratory diseases, including lung fibrosis (3,24,28). We reported the presence of cellular senescence markers, such as p21, p53, γ-H2AX and SA-βgal staining, which along with the expression of SASP components represent a source of chronic profibrotic signaling through the activation of Il-6, Mcp1, TNF-α, and IL-1α.…”

Section: Discussionmentioning

confidence: 93%

Transcriptomics, metabolomics and lipidomics of chronically injured alveolar epithelial cells reveals similar features of IPF lung epithelium

Roque

Cuevas-Mora²,

Sales³

et al. 2020

Preprint

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The current hypothesis suggests that Idiopathic pulmonary fibrosis (IPF) arises as a result of chronic injury to alveolar epithelial cells and aberrant activation of multiple signaling pathways. Dysfunctional IPF lung epithelium manifests many hallmarks of aging tissues, including cellular senescence, mitochondrial dysfunction, metabolic dysregulation, and loss of proteostasis. Unfortunately, this disease is often fatal within 3-5 years from diagnosis, and there is no effective treatment. One of the major limitations to the development of novel treatments in IPF is that current models of the disease fail to resemble several features seen in elderly IPF patients. In this study, we sought to develop an in vitro epithelial injury model using repeated low levels of bleomycin to mimic the phenotypic and functional characteristics of the IPF lung epithelium. Consistent with the hallmarks of the aging lung epithelium, we found that chronic-injured epithelial cells exhibited features of senescence cells, including an increase in β-galactosidase staining, induction of p53 and p21, mitochondrial dysfunction, excessive ROS production, and proteostasis alteration. Next, combined RNA sequencing, untargeted metabolomics, and lipidomics were performed to investigate the dynamic transcriptional, metabolic, and lipidomic profiling of our in vitro model. We identified that a total of 8,484 genes with different expression variations between the exposed group and the control group. According to our GO enrichment analysis, the down-regulated genes are involved in multiple biosynthetic and metabolic processes. In contrast, the up-regulated genes in our treated cells are responsible for epithelial cell migration and regulation of epithelial proliferation. Furthermore, metabolomics and lipidomics data revealed that overrepresented pathways were amino acid, fatty acid, and glycosphingolipid metabolism. This result suggests that by using our in vitro model, we were able to mimic the transcriptomic and metabolic alterations of those seen in the lung epithelium of IPF patients. We believe this model will be ideally suited for use in uncovering novel insights into the gene expression and molecular pathways of the IPF lung epithelium and performing screening of pharmaceutical compounds.

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

Cited by 171 publications

References 73 publications

The Aging Metabolome—Biomarkers to Hub Metabolites

The Aging Metabolome—Biomarkers to Hub Metabolites

Single-cell analyses identify tobacco smoke exposure-associated, dysfunctional CD16⁺ CD8 T cells with high cytolytic potential in peripheral blood

Transcriptomics, metabolomics and lipidomics of chronically injured alveolar epithelial cells reveals similar features of IPF lung epithelium

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

Cited by 171 publications

References 73 publications

The Aging Metabolome—Biomarkers to Hub Metabolites

The Aging Metabolome—Biomarkers to Hub Metabolites

Single-cell analyses identify tobacco smoke exposure-associated, dysfunctional CD16+ CD8 T cells with high cytolytic potential in peripheral blood

Transcriptomics, metabolomics and lipidomics of chronically injured alveolar epithelial cells reveals similar features of IPF lung epithelium

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Single-cell analyses identify tobacco smoke exposure-associated, dysfunctional CD16⁺ CD8 T cells with high cytolytic potential in peripheral blood