Identification of long-lived proteins retained in cells undergoing repeated asymmetric divisions

Thayer, Nathaniel H.; Leverich, Christina K.; Fitzgibbon, Matthew; Nelson, Zara W.; Henderson, Kiersten A.; Gafken, Philip R.; Hsu, Jessica J.; Gottschling, Daniel E.

doi:10.1073/pnas.1416079111

Cited by 77 publications

(89 citation statements)

References 81 publications

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“…Thayer et al (35) recently used isotope labeling and total proteome MS to identify long-lived asymmetrically retained proteins (LARPs). They identified several full-length proteins (Mrh1, Pma1, Sur7, Thr1, and Hsp26) and many protein fragments.…”

Section: Discussionmentioning

confidence: 99%

Systematic analysis of asymmetric partitioning of yeast proteome between mother and daughter cells reveals “aging factors” and mechanism of lifespan asymmetry

Yang

McCormick

Zheng

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Budding yeast divides asymmetrically, giving rise to a mother cell that progressively ages and a daughter cell with full lifespan. It is generally assumed that mother cells retain damaged, lifespan limiting materials ("aging factors") through asymmetric division. However, the identity of these aging factors and the mechanisms through which they limit lifespan remain poorly understood. Using a flow cytometry-based, high-throughput approach, we quantified the asymmetric partitioning of the yeast proteome between mother and daughter cells during cell division, discovering 74 mother-enriched and 60 daughterenriched proteins. While daughter-enriched proteins are biased toward those needed for bud construction and genome maintenance, mother-enriched proteins are biased towards those localized in the plasma membrane and vacuole. Deletion of 23 of the 74 motherenriched proteins leads to lifespan extension, a fraction that is about six times that of the genes picked randomly from the genome. Among these lifespan-extending genes, three are involved in endosomal sorting/endosome to vacuole transport, and three are nitrogen source transporters. Tracking the dynamic expression of specific mother-enriched proteins revealed that their concentration steadily increases in the mother cells as they age, but is kept relatively low in the daughter cells via asymmetric distribution. Our results suggest that some mother-enriched proteins may increase to a concentration that becomes deleterious and lifespan-limiting in aged cells, possibly by upsetting homeostasis or leading to aberrant signaling. Our study provides a comprehensive resource for analyzing asymmetric cell division and aging in yeast, which should also be valuable for understanding similar phenomena in other organisms.aging | asymmetric cell division | proteome C ellular aging and asymmetric cell division are intimately linked. In budding yeast, asymmetric cell division yields a mother cell and a daughter cell that are easily distinguishable under the microscope. Tracking the fate of the mother lineage led to the discovery that individual mother cells have a finite replicative lifespan, defined by the number of daughters a mother cell produced before senescence (1). It is known that although the mother cell ages with each division, their daughters retain the same full lifespan independent of the age of the mother at least until the last few mother cell divisions (2, 3). Thus, the asymmetry in cell division leads to asymmetry of aging.Even in single-celled organisms in which cell division is seemingly morphologically symmetric, such as fission yeast or Escherichia coli, asymmetric partitioning of cellular contents can still occur and have a differential impact on the aging/death fate of the two offspring (4-8). Asymmetric cell division is also a general phenomenon in mammalian cells (e.g., during development or in mitotically active tissues), where cell division typically leads to two cells with distinct fates, often with different replicative potential. It has been argued...

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Section: Discussionmentioning

confidence: 99%

Systematic analysis of asymmetric partitioning of yeast proteome between mother and daughter cells reveals “aging factors” and mechanism of lifespan asymmetry

Yang

McCormick

Zheng

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

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“…Even at the superficial descriptive level, single-cell RNA-seq cannot capture post-translational modifications (PTMs). Well-characterized regulatory mechanisms, such as long-lived proteins [23] and translational regulation [24] make mRNAs poor surrogates for functional proteins. Munsky et al [25] simulated the distributions of mRNA and protein levels for a number of gene regulatory motifs, and showed that depending on the motif, mRNA levels were not necessarily correlated to the corresponding protein’s level.…”

Section: New Technology Can Enable New Biologymentioning

confidence: 99%

Single cell protein analysis for systems biology

Levy

Slavov

2018

Essays in Biochemistry

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The cellular abundance of proteins can vary even between isogenic single cells. This variability between single-cell protein levels can have regulatory roles, such as controlling cell fate during apoptosis induction or the proliferation/quiescence decision. Here, we review examples connecting protein levels and their dynamics in single cells to cellular functions. Such findings were made possible by the introduction of antibodies, and subsequently fluorescent proteins, for tracking protein levels in single cells. However, in heterogeneous cell populations, such as tumors or differentiating stem cells, cellular decisions are controlled by hundreds, even thousands of proteins acting in concert. Characterizing such complex systems demands measurements of thousands of proteins across thousands of single cells. This demand has inspired the development of new methods for single-cell protein analysis, and we discuss their trade-offs, with an emphasis on their specificity and coverage. We finish by highlighting the potential of emerging mass-spec methods to enable systems-level measurement of single-cell proteomes with unprecedented coverage and specificity. Combining such methods with methods for quantitating the transcriptomes and metabolomes of single cells will provide essential data for advancing quantitative systems biology.

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“…Pma1 is an ATP-dependent proton pump that generates the essential pH gradient across the plasma membrane, consuming as much as 40% of the cell’s ATP to pump protons from the cytoplasm to the external environment (Capieaux et al, 1989), which in turn facilitates selective transport of a variety of critical molecules into and out of the cell (Cyert and Philpott, 2013). Pma1 has an unusual property: it is a very long lived protein and continues to accumulate at the plasma membrane over the first several divisions of a mother cell’s life (Thayer et al, 2014). The vacuole pH increase appears to be tied to Pma1 by mass action.…”

Section: The Downside Of Interconnectivity: a Cascade Of Declinementioning

confidence: 99%

The Upsides and Downsides of Organelle Interconnectivity

Gottschling

Nyström

2017

Cell

Self Cite

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Interconnectivity and feedback control are hallmarks of biological systems. This includes communication between organelles, which allows them to function and adapt to changing cellular environments. While the specific mechanisms for all communications remain opaque, unraveling the wiring of organelle networks is critical to understand how biological systems are built and why they might collapse, as occurs in aging. A comprehensive understanding of all the routes involved in inter-organelle communication is still lacking but important themes are beginning to emerge, primarily in budding yeast. These routes are reviewed here in the context of sub-system proteostasis and Complex Adaptive Systems theory.

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Identification of long-lived proteins retained in cells undergoing repeated asymmetric divisions

Cited by 77 publications

References 81 publications

Systematic analysis of asymmetric partitioning of yeast proteome between mother and daughter cells reveals “aging factors” and mechanism of lifespan asymmetry

Systematic analysis of asymmetric partitioning of yeast proteome between mother and daughter cells reveals “aging factors” and mechanism of lifespan asymmetry

Single cell protein analysis for systems biology

The Upsides and Downsides of Organelle Interconnectivity

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