Litcius/Paper detail

Genome-wide mapping of individual replication fork velocities using nanopore sequencing

Bertrand Theulot, Laurent Lacroix, Jean‐Michel Arbona, Gaël A. Millot, Étienne Jean, Corinne Cruaud, Jade Pellet, Florence Proux, Magali Hennion, Stéfan Engelen, Arnaud Lemainque, Benjamin Audit, Olivier Hyrien, Benoît Le Tallec

2022Nature Communications60 citationsDOIOpen Access PDF

Abstract

Little is known about replication fork velocity variations along eukaryotic genomes, since reference techniques to determine fork speed either provide no sequence information or suffer from low throughput. Here we present NanoForkSpeed, a nanopore sequencing-based method to map and extract the velocity of individual forks detected as tracks of the thymidine analogue bromodeoxyuridine incorporated during a brief pulse-labelling of asynchronously growing cells. NanoForkSpeed retrieves previous Saccharomyces cerevisiae mean fork speed estimates (≈2 kb/min) in the BT1 strain exhibiting highly efficient bromodeoxyuridine incorporation and wild-type growth, and precisely quantifies speed changes in cells with altered replisome progression or exposed to hydroxyurea. The positioning of >125,000 fork velocities provides a genome-wide map of fork progression based on individual fork rates, showing a uniform fork speed across yeast chromosomes except for a marked slowdown at known pausing sites.

Topics & Concepts

Fork (system call)Nanopore sequencingGenomeReplication (statistics)Tuning forkBiologyNanoporeSaccharomyces cerevisiaeGeneticsComputational biologyYeastComputer scienceGeneNanotechnologyPhysicsMaterials scienceVirologyVibrationQuantum mechanicsOperating systemDNA Repair MechanismsGenomics and Chromatin DynamicsGenomics and Phylogenetic Studies
Genome-wide mapping of individual replication fork velocities using nanopore sequencing | Litcius