Age-dependent topoisomerase I depletion alters recruitment of rDNA silencing complexes
Lindsey N. Power, Natalia Zawrotna, Manikarna Dinda, Abigail E. Weir, B. Bishal Paudel, Oshil Ghimire, Karolina Kisiel, Christopher T. Letai, Kevin A. Janes, Jeffrey S. Smith

TL;DR
This study shows that depletion of topoisomerase I during aging disrupts rDNA silencing and affects lifespan in yeast.
Contribution
The study identifies topoisomerase I as a novel age-depleted nuclear protein and reveals its role in rDNA silencing.
Findings
Top1 depletion in aging is not due to transcriptional or turnover changes.
Overexpression of Top1 disrupts the RENT complex and reduces rDNA silencing.
Top1's catalytic activity is crucial for rDNA silencing and chromatin structure.
Abstract
Genomic instability and loss of proteostasis are two of the primary Hallmarks of Aging. Although these hallmarks are well-defined in the literature, the mechanisms that drive genomic instability and loss of proteostasis as cells age are still incompletely understood. Using budding yeast replicative lifespan as a model for aging in actively dividing cells, we identify nuclear proteins that are depleted in the earliest stages of aging. We find that many age-depleted proteins are involved in ribosome biogenesis, specifically in ribosome processing, or in maintenance of chromatin stability. We focus on topoisomerase I (Top1) as a novel age-depleted nuclear protein and determine that its depletion in the early stages of aging is not a result of transcriptional changes or changes in protein turnover. Despite the stark depletion of Top1 in early aging, we find that rescue of this age-dependent…
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Taxonomy
TopicsGenomics and Chromatin Dynamics · RNA modifications and cancer · DNA Repair Mechanisms
