An aging-independent replicative lifespan in a symmetrically dividing eukaryote

Spivey, Eric C.; Jones, Stephen K.; Rybarski, James R.; Saifuddin, Fatema A.; Finkelstein, Ilya J.

doi:10.1101/064832

Cited by 5 publications

(13 citation statements)

References 73 publications

(89 reference statements)

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“…Thus, if anything, we underestimated the prevalence of the global hotspots as sites for age-associated junction formation. Work in other systems has shown that copy numbers of rDNA repeats decrease with age, and instability in this region is linked with ageing and longevity (Spivey et al 2017;Kobayashi 2014;Lu et al 2018). The decrease of rDNA copy numbers with age could be linked to junction formation in these regions: work in primate kidney cells has demonstrated differential repair of cellular DNA sequences (Zolan et al 1982), reminiscent of the heterogeneity we observe for age-associated rearrangements.…”

Section: Similar Patterns Of Genome Rearrangements Accumulate In Old mentioning

confidence: 57%

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R-loops and regulatory changes in chronologically ageing fission yeast cells drive non-random patterns of genome rearrangements

Ellis

Reyes-Martín

Rodríguez-López

et al. 2019

Preprint

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AbstractAberrant repair of DNA double-strand breaks can recombine distant pairs of chromosomal breakpoints. Such chromosomal rearrangements are a hallmark of ageing and compromise the structure and function of genomes. Rearrangements are challenging to detect in non-dividing cell populations, because they reflect individually rare, heterogeneous events. The genomic distribution of de novo rearrangements in non-dividing cells, and their dynamics during ageing, remain therefore poorly characterized. Studies of genomic instability during ageing have focussed on mitochondrial DNA, small genetic variants, or proliferating cells. To gain a better understanding of genome rearrangements during cellular ageing, we focused on a single diagnostic measure – DNA breakpoint junctions – allowing us to interrogate the changing genomic landscape in non-dividing cells of fission yeast (Schizosaccharomyces pombe). Aberrant DNA junctions that accumulated with age were associated with microhomology sequences and R-loops. Global hotspots for age-associated breakpoint formation were evident near telomeric genes and linked to remote breakpoints on the same or different chromosomes, including the mitochondrial chromosome. An unexpected mechanism of genomic instability caused more local hotspots: age-associated reduction in an RNA-binding protein could trigger R-loop formation at target loci. This finding suggests that biological processes other than transcription or replication can drive genome rearrangements. Notably, we detected similar signatures of genome rearrangements that accumulated in old brain cells of humans. These findings provide insights into the unique patterns and potential mechanisms of genome rearrangements in non-dividing cells, which can be triggered by ageing-related changes in gene-regulatory proteins.

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Section: Similar Patterns Of Genome Rearrangements Accumulate In Old mentioning

confidence: 57%

“…Ribosomal RNA genes are highly transcribed and common sites of transcription and replication stress (Gaillard and Aguilera 2016; Aguilera and García-Muse 2013). Moreover, rDNA repeats can become unstable during ageing and cause cell death (Spivey et al 2017;Lu et al 2018;Kobayashi 2014).…”

Section: Similar Patterns Of Genome Rearrangements Accumulate In Old mentioning

confidence: 99%

R-loops and regulatory changes in chronologically ageing fission yeast cells drive non-random patterns of genome rearrangements

Ellis

Reyes-Martín

Rodríguez-López

et al. 2019

Preprint

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“…Information on how data collected using this methodology is analyzed can be found in these references ( Greenstein et al ., 2017 ; Spivey et al ., 2017 ).…”

Section: Discussionmentioning

confidence: 99%

“…However, the low-throughput and laborious nature of this assay limits our current understanding of replicative aging. Most recently, removal of progeny cells has been automated in microfluidic devices that capture and retain individual aging cells ( Wang et al ., 2010 ; Lee et al ., 2012 ; Xie et al ., 2012 ; Zhang et al ., 2012 ; Tian et al ., 2013 ; Crane et al ., 2014 ; Nobs and Maerkl, 2014 ; Jo et al ., 2015 ; Liu et al ., 2015 ; Nakaoka and Wakamoto, 2017 ; Spivey et al ., 2017 ). Using such devices, relatively large cohorts of individual cells (100 s to 1,000 s of cells) can then be tracked independently from one another.…”

Section: Introductionmentioning

confidence: 99%

“…Here, we describe the fabrication and assembly of a microfluidic device for capturing and imaging thousands of fission yeast cells over their entire replicative lifespans. The multiplexed fission yeast lifespan microdissector (multFYLM) enables the experimentalist to track the lifespan of over a thousand fission yeast cells ( Spivey et al ., 2017 ). The cells may be continuously imaged for up to six independent populations for over a week, yielding high-resolution imaging over each cell’s replicative lifespan.…”

Section: Introductionmentioning

confidence: 99%

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A Microfluidic Device for Massively Parallel, Whole-lifespan Imaging of Single Fission Yeast Cells

et al. 2018

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Whole-lifespan single-cell analysis has greatly increased our understanding of fundamental cellular processes such as cellular aging. To observe individual cells across their entire lifespan, all progeny must be removed from the growth medium, typically via manual microdissection. However, manual microdissection is laborious, low-throughput, and incompatible with fluorescence microscopy. Here, we describe assembly and operation of the multiplexed-Fission Yeast Lifespan Microdissector (multFYLM), a high-throughput microfluidic device for rapidly acquiring single-cell whole-lifespan imaging. multFYLM captures approximately one thousand rod-shaped fission yeast cells from up to six different genetic backgrounds or treatment regimens. The immobilized cells are fluorescently imaged for over a week, while the progeny cells are removed from the device. The resulting datasets yield high-resolution multi-channel images that record each cell’s replicative lifespan. We anticipate that the multFYLM will be broadly applicable for single-cell whole-lifespan studies in the fission yeast (Schizosaccharomyces pombe) and other symmetrically-dividing unicellular organisms.

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Aging, mortality and the fast growth trade-off ofSchizosaccharomyces pombe

Nakaoka

Wakamoto

2017

Preprint

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18Replicative aging has been demonstrated in asymmetrically dividing unicellular 19 organisms, seemingly caused by unequal damage partitioning. Although asymmetric 20 segregation and inheritance of potential aging factors also occurs in symmetrically 21 dividing species, it nevertheless remains controversial whether this results in aging. 22Based on large-scale single-cell lineage data obtained by time-lapse microscopy with a 23 microfluidic device, in this report, we demonstrate the absence of replicative aging in 39These results collectively indicate that protein aggregates are not a major determinant of 40 cell fate in S. pombe, and thus cannot be an appropriate molecular marker or index for 41 replicative aging under both favorable and stressful environmental conditions.

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An aging-independent replicative lifespan in a symmetrically dividing eukaryote

Cited by 5 publications

References 73 publications

R-loops and regulatory changes in chronologically ageing fission yeast cells drive non-random patterns of genome rearrangements

R-loops and regulatory changes in chronologically ageing fission yeast cells drive non-random patterns of genome rearrangements

A Microfluidic Device for Massively Parallel, Whole-lifespan Imaging of Single Fission Yeast Cells

Aging, mortality and the fast growth trade-off ofSchizosaccharomyces pombe

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