Dominic Bazzano scite author profile

DNA double strand breaks (DSBs) are cytotoxic lesions repaired by non-homologous end joining (NHEJ) and homologous recombination (HR), with 5' strand resection being the committed step in transition from NHEJ to HR. We previously discovered that gal1 yeast, which cannot metabolize galactose, were unable to perform efficient 5' resection even though DSBs were formed. Adding glucose or restoring GAL1 restored resection, suggesting that carbon source metabolism signals to DSB repair. Here we demonstrate that any fermentable carbon source, including raffinose, can stimulate resection and that the stimulatory effect of glucose was associated with decreased, not increased, cellular ATP. The effect was cell cycle dependent and did not occur in G1, while glucose augmented the G2/M checkpoint arrest even in cells deficient in resection. AMP-activated protein kinase pathway mutants showed only low basal resection despite glucose addition but had normal checkpoint arrest, indicating a primary role for Snf1 specifically in glucose-stimulated resection. The metabolic inputs to resection were multifactorial, however, with loss of the transcriptional repressor Mig1 leading to increased basal resection, three distinct patterns of deficiency with loss of the protein kinase A catalytic subunits, Tpk1, Tpk2 andTpk3, and a resection delay in yeast lacking the lysine demethylase Rph1 that helped separate early and late phase responses to glucose. These results reveal multiple interrelated metabolic signals that optimize DSB resection efficiency while independently amplifying the G2/M checkpoint response.

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Mapping yeast mitotic 5’ resection at base resolution reveals the sequence and positional dependence of nucleasesin vivo

Bazzano

Lomonaco

Wilson

2021

Preprint

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Resection of the 5'-terminated strand at DNA double strand breaks (DSBs) is the critical regulated step in the transition to homologous recombination. Biochemical and genetic studies have led to a multi-step model of DSB resection in which endonucleolytic cleavage mediated by Mre11 in partnership with Sae2 is coupled with exonucleolytic cleavage mediated by redundant pathways catalyzed by Exo1 and Sgs1/Dna2. These models have not been well tested at mitotic DSBs in vivo because most methods commonly used to monitor resection cannot precisely map early cleavage events. Here we report resection monitoring with next-generation sequencing in which unique molecular identifiers allow exact counting of cleaved 5' ends at base pair resolution. Mutant strains, including exo1Δ, mre11-H125N, exo1Δ and exo1Δ sgs1Δ, revealed a major Mre11-dependent cleavage position 60 to 70 bp from the DSB end whose exact position depended on local sequence and tracked an apparent motif. They further revealed an Exo1-dependent pause point approximately 200 bp from the DSB. Suppressing resection extension in exo1Δ sgs1Δ yeast exposed a footprint of regions where cleavage was restricted within 119 bp of the DSB and near the Exo1 pause point and where it was much less restrained. These results provide detailed in vivo support of prevailing models of DSB resection and extend them to show the combined influence of sequence specificity and access restrictions on Mre11 and Exo1 nucleases.

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Mapping yeast mitotic 5′ resection at base resolution reveals the sequence and positional dependence of nucleases in vivo

Bazzano

Lomonaco²,

Wilson

2021

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Resection of the 5′-terminated strand at DNA double-strand breaks (DSBs) is the critical regulated step in the transition to homologous recombination. Recent studies have described a multi-step model of DSB resection where endonucleolytic cleavage mediated by Mre11 and Sae2 leads to further degradation mediated by redundant pathways catalyzed by Exo1 and Sgs1/Dna2. These models have not been well tested at mitotic DSBs in vivo because most methods used to monitor resection cannot precisely map early cleavage events. Here we report resection monitoring with high-throughput sequencing using molecular identifiers, allowing exact counting of cleaved 5′ ends at base resolution. Mutant strains, including exo1Δ, mre11-H125N and exo1Δ sgs1Δ, revealed a major Mre11-dependent cleavage position 60–70 bp from the DSB end whose exact position depended on local sequence. They further revealed an Exo1-dependent pause point approximately 200 bp from the DSB. Suppressing resection extension in exo1Δ sgs1Δ yeast exposed a footprint of regions where cleavage was restricted within 119 bp of the DSB. These results provide detailed in vivo views of prevailing models of DSB resection and extend them to show the combined influence of sequence specificity and access restrictions on Mre11 and Exo1 nucleases.

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Dominic Bazzano

Multiple metabolic signals including AMPK and PKA regulate glucose-stimulated double strand break resection in yeast

Mapping yeast mitotic 5’ resection at base resolution reveals the sequence and positional dependence of nucleasesin vivo

Mapping yeast mitotic 5′ resection at base resolution reveals the sequence and positional dependence of nucleases in vivo

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