Author
Listed:
- Nicolas Agier
(Laboratory of Computational and Quantitative Biology)
- Stéphane Delmas
(Laboratory of Computational and Quantitative Biology)
- Qing Zhang
(Laboratory of Computational and Quantitative Biology)
- Aubin Fleiss
(Laboratory of Computational and Quantitative Biology)
- Yan Jaszczyszyn
(Université Paris-Saclay)
- Erwin van Dijk
(Université Paris-Saclay)
- Claude Thermes
(Université Paris-Saclay)
- Martin Weigt
(Laboratory of Computational and Quantitative Biology)
- Marco Cosentino-Lagomarsino
(Laboratory of Computational and Quantitative Biology
IFOM (FIRC Institute of Molecular Oncology))
- Gilles Fischer
(Laboratory of Computational and Quantitative Biology)
Abstract
Genome replication is highly regulated in time and space, but the rules governing the remodeling of these programs during evolution remain largely unknown. We generated genome-wide replication timing profiles for ten Lachancea yeasts, covering a continuous evolutionary range from closely related to more divergent species. We show that replication programs primarily evolve through a highly dynamic evolutionary renewal of the cohort of active replication origins. We found that gained origins appear with low activity yet become more efficient and fire earlier as they evolutionarily age. By contrast, origins that are lost comprise the complete range of firing strength. Additionally, they preferentially occur in close vicinity to strong origins. Interestingly, despite high evolutionary turnover, active replication origins remain regularly spaced along chromosomes in all species, suggesting that origin distribution is optimized to limit large inter-origin intervals. We propose a model on the evolutionary birth, death, and conservation of active replication origins.
Suggested Citation
Nicolas Agier & Stéphane Delmas & Qing Zhang & Aubin Fleiss & Yan Jaszczyszyn & Erwin van Dijk & Claude Thermes & Martin Weigt & Marco Cosentino-Lagomarsino & Gilles Fischer, 2018.
"The evolution of the temporal program of genome replication,"
Nature Communications, Nature, vol. 9(1), pages 1-12, December.
Handle:
RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-04628-4
DOI: 10.1038/s41467-018-04628-4
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