TopBP1 assembles nuclear condensates to switch on ATR signaling.

ATR checkpoint signaling is crucial for cellular responses to DNA replication impediments. Using an optogenetic platform, we show that TopBP1, the main activator of ATR, self-assembles extensively to yield micrometer-sized condensates. These opto-TopBP1 condensates are functional entities organized in tightly packed clusters of spherical nano-particles.

PCNA Deubiquitylases Control DNA Damage Bypass at Replication Forks.

DNA damage tolerance plays a key role in protecting cell viability through translesion synthesis and template switching-mediated bypass of genotoxic polymerase-blocking base lesions. Both tolerance pathways critically rely on ubiquitylation of the proliferating-cell nuclear antigen (PCNA) on lysine 164 and have been proposed to operate uncoupled from replication. We report that Ubp10 and Ubp12 ubiquitin proteases differentially cooperate in PCNA deubiquitylation, owing to distinct activities on PCNA-linked ubiquitin chains.

Analysis of Cohesin Association to Newly Replicated DNA Through Nascent Strand Binding Assay (NSBA).

Replication forks engage chromatin-bound cohesin complexes during chromosome replication. Interfacing between cohesin and replication forks influences both cohesion establishment and fork functionality. However, the mechanisms mediating this process are scarcely understood.

Cohesin Ubiquitylation and Mobilization Facilitate Stalled Replication Fork Dynamics.

Replication fork integrity is challenged in conditions of stress and protected by the Mec1/ATR checkpoint to preserve genome stability. Still poorly understood in fork protection is the role played by the structural maintenance of chromosomes (SMC) cohesin complex. We uncovered a role for the Rsp5 ubiquitin ligase in promoting survival to replication stress by preserving stalled fork integrity.

Nucleolytic processing of aberrant replication intermediates by an Exo1-Dna2-Sae2 axis counteracts fork collapse-driven chromosome instability.

Problems during DNA replication underlie genomic instability and drive malignant transformation. The DNA damage checkpoint stabilizes stalled replication forks thus counteracting aberrant fork transitions, DNA breaks and chromosomal rearrangements. We analyzed fork processing in checkpoint deficient cells by coupling psoralen crosslinking with replication intermediate two-dimensional gel analysis.

The replication checkpoint protects fork stability by releasing transcribed genes from nuclear pores.

Transcription hinders replication fork progression and stability, and the Mec1/ATR checkpoint protects fork integrity. Examining checkpoint-dependent mechanisms controlling fork stability, we find that fork reversal and dormant origin firing due to checkpoint defects are rescued in checkpoint mutants lacking THO, TREX-2, or inner-basket nucleoporins. Gene gating tethers transcribed genes to the nuclear periphery and is counteracted by checkpoint kinases through phosphorylation of nucleoporins such as Mlp1.