Sensors such as cGAS in the cell evolved to detect invading pathogens and then interact with inflammatory regulators such as STING to produce an appropriate response. With age, however, many of the dysfunctions that arise in a cell can produce a maladaptive response on the part of cGAS and STING. The example noted here is the activation of dormant transposons in the genome, a feature of aging that emerges as epigenetic control over the structure of nuclear DNA and expression of nuclear genes changes for the worse. Retrotransposons like LINE-1 make up a sizable fraction of the genome as a result of their ability to copy themselves. They are most likely the remnants of ancient viral infections, important in aging as they become active, and likely important as a source of evolutionary change to genetic sequences as well. Retrotransposons can cause harm not just by damaging the genome as they copy themselves, but also via inflammatory reactions on the part of cGAS, STING, and other mechanisms evolved to react to anything that looks like viral machinery.
Aging is characterized by systemic inflammation and progressive cognitive decline, yet the molecular pathways linking peripheral aging signals to central nervous system dysfunction remain elusive. Here, we identify plasma extracellular vesicle (EV)-derived long interspersed nuclear element-1 (LINE-1) RNA as a potent systemic aging factor mediating neuroinflammation and cognitive impairment in humans and mice.
Plasma EV LINE-1 RNA levels markedly increase with age and strongly correlate with established brain aging biomarkers, including neurofilament light chain (NFL). Utilizing mouse models, we demonstrate that EVs from aged individuals penetrate the blood-brain barrier, deliver LINE-1 RNA to microglia, and initiate cGAS-STING signaling, leading to pronounced neuroinflammation, neuronal damage, and impaired cognition.
Pharmacological blockade of LINE-1 reverse transcription by 3TC or inhibition of STING signaling with H151 significantly ameliorates these age-associated deficits. Notably, aged peripheral tissues, especially brain and lung, emerge as primary sources of pro-aging EVs enriched with LINE-1 RNA, revealing a novel mechanism of inter-organ communication in aging. Our findings position EV-derived LINE-1 RNA and its downstream cGAS-STING pathway as critical systemic drivers of brain aging, presenting promising therapeutic targets for mitigating cognitive decline and age-related neurodegenerative diseases.
Link: https://doi.org/10.1111/acel.70350
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