LINE1 Derepression in Aged Wild-Type and SIRT6-Deficient Mice Drives Inflammation

Simon, Matthew; Meter, Michael Van; Ablaeva, Julia; Ke, Zhonghe; González, Raúl; Taguchi, Taketo; Cecco, Marco De; Leonova, Katerina I.; Kogan, V. R.; Helfand, Stephen L.; Neretti, Nicola; Roichman, Asael; Cohen, Haim Y.; Meer, Margarita; Gladyshev, Vadim N.; Antoch, Marina P.; Gudkov, Andrei V.; Sedivy, John M.; Seluanov, Andrei; Gorbunova, Vera

doi:10.1016/j.cmet.2019.02.014

Cited by 308 publications

(330 citation statements)

References 55 publications

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“…Beyond its ability to enhance DSB repair, a major role of SIRT6 is to repress the expression of ancient retroviral elements (LINE1 or L1) that account for a significant fraction of mammalian genomes . The importance of LINE1 elements in aging as well as in the context of SIRT6 as a promoter of overall genome integrity was bolstered by two recent reports showing that showed that L1 elements become transcriptionally derepressed during aging and that this derepression activates a type‐I interferon (IFN‐I) inflammatory response . The effect can be suppressed by reverse transcriptase (RT) inhibitors to block expansion/reintegration of L1s.…”

Section: Proteomics and The Hallmarks Of Agingmentioning

confidence: 99%

“…The effect can be suppressed by reverse transcriptase (RT) inhibitors to block expansion/reintegration of L1s. Furthermore, loss of L1 suppression is a major contributor to aging in SIRT6 knockout mice that can be partially rescued by adding RT inhibitors . Upon the loss of SIRT6, the copy number of cytoplasmic L1 species accumulate triggering type‐I interferon response via cGAS/STING pathway.…”

Section: Proteomics and The Hallmarks Of Agingmentioning

confidence: 99%

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Proteomics of Long‐Lived Mammals

et al. 2020

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Mammalian species differ up to 100‐fold in their aging rates and maximum lifespans. Long‐lived mammals appear to possess traits that extend lifespan and healthspan. Genomic analyses have not revealed a single pro‐longevity function that would account for all longevity effects. In contrast, it appears that pro‐longevity mechanisms may be complex traits afforded by connections between metabolism and protein functions that are impossible to predict by genomic approaches alone. Thus, metabolomics and proteomics studies will be required to understand the mechanisms of longevity. Several examples are reviewed that demonstrate the naked mole rat (NMR) shows unique proteomic signatures that contribute to longevity by overcoming several hallmarks of aging. SIRT6 is also discussed as an example of a protein that evolves enhanced enzymatic function in long‐lived species. Finally, it is shown that several longevity‐related proteins such as Cip1/p21, FOXO3, TOP2A, AKT1, RICTOR, INSR, and SIRT6 harbor posttranslational modification (PTM) sites that preferentially appear in either short‐ or long‐lived species and provide examples of crosstalk between PTM sites. Prospects of enhancing lifespan and healthspan of humans by altering metabolism and proteoforms with drugs that mimic changes observed in long‐lived species are discussed.

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Section: Proteomics and The Hallmarks Of Agingmentioning

confidence: 99%

Section: Proteomics and The Hallmarks Of Agingmentioning

confidence: 99%

Proteomics of Long‐Lived Mammals

et al. 2020

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“…Increased L1 activity results in the accumulation of L1 ‐derived cytosolic DNA from extrachromosomal copies that fail to integrate, which is detected by innate immune systems that recognize cytosolic DNA from invading viruses. This promotes interferon production, contributing to a chronic state of low‐grade inflammation that plays a role in ageing . Somatic L1 activity has been implicated in age‐related pathologies, including neurodegeneration and cancer, and small molecule inhibition of L1 reverse transcriptase activity maintains genome stability .…”

Section: Introductionmentioning

confidence: 98%

“…L1 elements replicate through an RNA transcript that is reverse transcribed, and are capable of re‐integration into the genome, allowing for expansion in their copy numbers if de‐repressed during ageing or genotoxic stress . Importantly, the insertion of additional L1 elements into the genome following their de‐repression induces DNA breaks, and this damage further drives the migration of transcriptional repressors, leading to further de‐repression of other endogenous TEs, initiating a “vicious cycle” that could drive ageing . Increased L1 activity results in the accumulation of L1 ‐derived cytosolic DNA from extrachromosomal copies that fail to integrate, which is detected by innate immune systems that recognize cytosolic DNA from invading viruses.…”

Section: Introductionmentioning

confidence: 99%

“…This promotes interferon production, contributing to a chronic state of low‐grade inflammation that plays a role in ageing . Somatic L1 activity has been implicated in age‐related pathologies, including neurodegeneration and cancer, and small molecule inhibition of L1 reverse transcriptase activity maintains genome stability . Together, these data suggest that the ability to prevent or break this cycle of transposon activity could slow age‐related dysfunction.…”

Section: Introductionmentioning

confidence: 99%

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Transposable Elements Cross Kingdom Boundaries and Contribute to Inflammation and Ageing

Chalmers

2020

BioEssays

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The de‐repression of transposable elements (TEs) in mammalian genomes is thought to contribute to genome instability, inflammation, and ageing, yet is viewed as a cell‐autonomous event. In contrast to mammalian cells, prokaryotes constantly exchange genetic material through TEs, crossing both cell and species barriers, contributing to rapid microbial evolution and diversity in complex communities such as the mammalian gut. Here, it is proposed that TEs released from prokaryotes in the microbiome or from pathogenic infections regularly cross the kingdom barrier to the somatic cells of their eukaryotic hosts. It is proposed this horizontal transfer of TEs from microbe to host is a stochastic, ongoing catalyst of genome destabilization, resulting in structural and epigenetic variations, and activation of well‐evolved host defense mechanisms contributing to inflammation, senescence, and biological ageing. It is proposed that innate immunity pathways defend against the horizontal acquisition of microbial TEs, and that activation of this pathway during horizontal transposon transfer promotes chronic inflammation during ageing. Finally, it is suggested that horizontal acquisition of prokaryotic TEs into mammalian genomes has been masked and subsequently under‐reported due to flaws in current sequencing pipelines, and new strategies to uncover these events are proposed.

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Transposable elements as new players in neurodegenerative diseases

et al. 2021

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Neurodegenerative diseases (NDs), including the most prevalent Alzheimer’s disease and Parkinson disease, share common pathological features. Despite decades of gene‐centric approaches, the molecular mechanisms underlying these diseases remain widely elusive. In recent years, transposable elements (TEs), long considered ‘junk’ DNA, have gained growing interest as pathogenic players in NDs. Age is the major risk factor for most NDs, and several repressive mechanisms of TEs, such as heterochromatinization, fail with age. Indeed, heterochromatin relaxation leading to TE derepression has been reported in various models of neurodegeneration and NDs. There is also evidence that certain pathogenic proteins involved in NDs (e.g., tau, TDP‐43) may control the expression of TEs. The deleterious consequences of TE activation are not well known but they could include DNA damage and genomic instability, altered host gene expression, and/or neuroinflammation, which are common hallmarks of neurodegeneration and aging. TEs might thus represent an overlooked pathogenic culprit for both brain aging and neurodegeneration. Certain pathological effects of TEs might be prevented by inhibiting their activity, pointing to TEs as novel targets for neuroprotection.

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LINE1 Derepression in Aged Wild-Type and SIRT6-Deficient Mice Drives Inflammation

Cited by 308 publications

References 55 publications

Proteomics of Long‐Lived Mammals

Proteomics of Long‐Lived Mammals

Transposable Elements Cross Kingdom Boundaries and Contribute to Inflammation and Ageing

Transposable elements as new players in neurodegenerative diseases

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