Aging is associated with the accumulation of several types of damage: in particular, damage to the proteome. Recent work points to a conserved replicative rejuvenation mechanism that works by preventing the inheritance of damaged and misfolded proteins by specific cells during division. Asymmetric inheritance of misfolded and aggregated proteins has been shown in bacteria and yeast, but relatively little evidence exists for a similar mechanism in mammalian cells. Here, we demonstrate, using long-term 4D imaging, that the vimentin intermediate filament establishes mitotic polarity in mammalian cell lines and mediates the asymmetric partitioning of damaged proteins. We show that mammalian JUNQ inclusion bodies containing soluble misfolded proteins are inherited asymmetrically, similarly to JUNQ qualitycontrol inclusions observed in yeast. Mammalian IPOD-like inclusion bodies, meanwhile, are not always inherited by the same cell as the JUNQ. Our study suggests that the mammalian cytoskeleton and intermediate filaments provide the physical scaffold for asymmetric inheritance of dynamic quality-control JUNQ inclusions. Mammalian IPOD inclusions containing amyloidogenic proteins are not partitioned as effectively during mitosis as their counterparts in yeast. These findings provide a valuable mechanistic basis for studying the process of asymmetric inheritance in mammalian cells, including cells potentially undergoing polar divisions, such as differentiating stem cells and cancer cells.inclusion body | spatial quality control A ging is universally associated with a global decline in cellular function (1-3). Due to the multiplicity of mechanisms that undergo aging-related dysfunction, its mechanistic basis, or "senescence factor," has been difficult to pinpoint. Several studies have provided key insight into the identities of senescence factors by studying the asymmetric segregation of damage in singlecell organisms that rejuvenate the emerging generation by preventing the inheritance of damaged factors such as DNA, lipids, and proteins (1, 4, 5). In particular, a number of seminal studies have demonstrated that bacteria and yeast use a complex and multifaceted machinery to prevent the inheritance of damaged and aggregated proteins by the new generation by restricting them to the older lineage during cell division (1,6,7).Although the precise mechanism for asymmetric inheritance of aggregates has been a matter of much debate (1, 7), the emerging model is that the spatial arrangement of misfolded proteins into quality control-associated IB (inclusion body)-like structures plays an essential role in asymmetric inheritance (1, 7). A key property of some quality-control IBs and other IBlike structures, which allows the cell to retain them in a specific lineage during mitosis, is their association and interaction with cellular organelles and cytoskeleton. In bacteria, for example, aggregated proteins are collected at the old pole of a dividing cell (5). A similar mechanism has been proposed in fission yeast (8). In the budd...
