Project description:Forkhead transcription factors establish origin timing and long-range clustering in S. cerevisiae [Sequence Data]

Project description:Forkhead transcription factors establish origin timing and long-range clustering in S. cerevisiae

Project description:The S. cerevisiae Forkhead Box (FOX) proteins, Fkh1 and Fkh2, regulate diverse cellular processes including transcription, long-range DNA interactions during homologous recombination, and replication origin timing and long-range origin clustering. As stimulators of early origin activation, we hypothesized that Fkh1 and Fkh2 abundance limits the rate of origin activation genome-wide. Existing methods, however, were not well suited to quantitative, genome-wide measurements of origin firing between strains and conditions. To overcome this limitation, we developed qBrdU-seq, a quantitative method for BrdU incorporation analysis of replication dynamics, and applied it to show that overexpression of Fkh1 and Fkh2 advance the initiation timing of many origins throughout the genome resulting in a higher total level of origin initiations in early S phase. The higher initiation rate is accompanied by slower replication fork progression, thereby maintaining a normal length of S phase without causing detectable Rad53 checkpoint kinase activation. The advancement of origin firing time, including that of origins in heterochromatic domains, was established in late G1 phase, indicating that origin timing can be reset subsequently to origin licensing. These results provide novel insights into the mechanisms of origin timing regulation by identifying Fkh1 and Fkh2 as rate-limiting factors for origin firing that determine the ability of replication origins to accrue limiting factors and have the potential to reprogram replication timing late in G1 phase. 5 total experiments with replicates

Project description:The S. cerevisiae Forkhead Box (FOX) proteins, Fkh1 and Fkh2, regulate diverse cellular processes including transcription, long-range DNA interactions during homologous recombination, and replication origin timing and long-range origin clustering. As stimulators of early origin activation, we hypothesized that Fkh1 and Fkh2 abundance limits the rate of origin activation genome-wide. Existing methods, however, were not well suited to quantitative, genome-wide measurements of origin firing between strains and conditions. To overcome this limitation, we developed qBrdU-seq, a quantitative method for BrdU incorporation analysis of replication dynamics, and applied it to show that overexpression of Fkh1 and Fkh2 advance the initiation timing of many origins throughout the genome resulting in a higher total level of origin initiations in early S phase. The higher initiation rate is accompanied by slower replication fork progression, thereby maintaining a normal length of S phase without causing detectable Rad53 checkpoint kinase activation. The advancement of origin firing time, including that of origins in heterochromatic domains, was established in late G1 phase, indicating that origin timing can be reset subsequently to origin licensing. These results provide novel insights into the mechanisms of origin timing regulation by identifying Fkh1 and Fkh2 as rate-limiting factors for origin firing that determine the ability of replication origins to accrue limiting factors and have the potential to reprogram replication timing late in G1 phase.

Project description:The S. cerevisiae Forkhead Box (FOX) proteins, Fkh1 and Fkh2, regulate diverse cellular processes including transcription, long-range DNA interactions during homologous recombination, and replication origin timing and long-range origin clustering. As stimulators of early origin activation, we hypothesized that Fkh1 and Fkh2 abundance limits the rate of origin activation genome-wide. Existing methods, however, were not well suited to quantitative, genome-wide measurements of origin firing between strains and conditions. To overcome this limitation, we developed qBrdU-seq, a quantitative method for BrdU incorporation analysis of replication dynamics, and applied it to show that overexpression of Fkh1 and Fkh2 advance the initiation timing of many origins throughout the genome resulting in a higher total level of origin initiations in early S phase. The higher initiation rate is accompanied by slower replication fork progression, thereby maintaining a normal length of S phase without causing detectable Rad53 checkpoint kinase activation. The advancement of origin firing time, including that of origins in heterochromatic domains, was established in late G1 phase, indicating that origin timing can be reset subsequently to origin licensing. These results provide novel insights into the mechanisms of origin timing regulation by identifying Fkh1 and Fkh2 as rate-limiting factors for origin firing that determine the ability of replication origins to accrue limiting factors and have the potential to reprogram replication timing late in G1 phase.

Project description:The replication of eukaryotic chromosomes is organized temporally and spatially within the nucleus through epigenetic regulation of replication origin function. The characteristic initiation timing of specific origins is thought to reflect their chromatin environment or sub-nuclear positioning, however the mechanism remains obscure. Here we show that the yeast Forkhead transcription factors, Fkh1 and Fkh2, are global determinants of replication origin timing. Forkhead regulation of origin timing is independent of local levels or changes of transcription. Instead, we show that Fkh1 and Fkh2 are required for the clustering of early origins and their association with the key initiation factor Cdc45 in G1-phase, suggesting that Fkh1 and Fkh2 selectively recruit origins to emergent replication factories. Fkh1 and Fkh2 bind Fkh-activated origins, and interact physically with ORC, providing a plausible mechanism to cluster origins. These findings add a new dimension to our understanding of the epigenetic basis for differential origin regulation and its connection to chromosomal domain organization.

Project description:The replication of eukaryotic chromosomes is organized temporally and spatially within the nucleus through epigenetic regulation of replication origin function. The characteristic initiation timing of specific origins is thought to reflect their chromatin environment or sub-nuclear positioning, however the mechanism remains obscure. Here we show that the yeast Forkhead transcription factors, Fkh1 and Fkh2, are global determinants of replication origin timing. Forkhead regulation of origin timing is independent of local levels or changes of transcription. Instead, we show that Fkh1 and Fkh2 are required for the clustering of early origins and their association with the key initiation factor Cdc45 in G1-phase, suggesting that Fkh1 and Fkh2 selectively recruit origins to emergent replication factories. Fkh1 and Fkh2 bind Fkh-activated origins, and interact physically with ORC, providing a plausible mechanism to cluster origins. These findings add a new dimension to our understanding of the epigenetic basis for differential origin regulation and its connection to chromosomal domain organization.

Project description:The replication of eukaryotic chromosomes is organized temporally and spatially within the nucleus through epigenetic regulation of replication origin function. The characteristic initiation timing of specific origins is thought to reflect their chromatin environment or sub-nuclear positioning, however the mechanism remains obscure. Here we show that the yeast Forkhead transcription factors, Fkh1 and Fkh2, are global determinants of replication origin timing. Forkhead regulation of origin timing is independent of local levels or changes of transcription. Instead, we show that Fkh1 and Fkh2 are required for the clustering of early origins and their association with the key initiation factor Cdc45 in G1-phase, suggesting that Fkh1 and Fkh2 selectively recruit origins to emergent replication factories. Fkh1 and Fkh2 bind Fkh-activated origins, and interact physically with ORC, providing a plausible mechanism to cluster origins. These findings add a new dimension to our understanding of the epigenetic basis for differential origin regulation and its connection to chromosomal domain organization. These files contain BrdU-IP-seq files (2 replicates for each strain; 5 strains total where WT was used as control). These files also contain RNA-seq data from Asynchronous and G1 arrested WT and Mutant cells (2 replicates per strain and condition; paired end). These files also contain RNA-pol-chip-seq data from Asynchronous and G1 arrested WT and Mutant cells (2 replicates per strain/condition).

Project description:Forkhead Box (Fox) proteins share the Forkhead domain, a winged-helix DNA binding module, which is conserved among eukaryotes from yeast to humans. These sequence-specific DNA binding proteins have been primarily characterized as transcription factors regulating diverse cellular processes from cell cycle control to developmental fate, deregulation of which contributes to developmental defects, cancer, and aging. We recently identified S. cerevisiae Fkh1 and Fkh2 as required for the clustering of a subset of replication origins in G1 phase and for the early initiation of these origins in the ensuing S phase, suggesting a mechanistic role linking the spatial organization of the origins and their activity. Here we show that Fkh1 and Fkh2 share a unique structural feature of human FoxP proteins that enables FoxP2 and FoxP3 to form domain-swapped dimers capable of bridging two DNA molecules in vitro. Accordingly, Fkh1 self-associates in vitro and in vivo in a manner dependent on the conserved domain-swapping region, strongly suggestive of homo-dimer formation. Fkh1- and Fkh2-domain-swap-minus (dsm) mutations are functional as transcription factors yet are defective in replication origin timing control. Fkh1-dsm binds replication origins in vivo but fails to cluster them, supporting the conclusion that Fkh1 and Fkh2 dimers perform a structural role in the spatial organization of chromosomal elements with functional importance.

Project description:Forkhead Box (Fox) proteins share the Forkhead domain, a winged-helix DNA binding module, which is conserved among eukaryotes from yeast to humans. These sequence-specific DNA binding proteins have been primarily characterized as transcription factors regulating diverse cellular processes from cell cycle control to developmental fate, deregulation of which contributes to developmental defects, cancer, and aging. We recently identified S. cerevisiae Fkh1 and Fkh2 as required for the clustering of a subset of replication origins in G1 phase and for the early initiation of these origins in the ensuing S phase, suggesting a mechanistic role linking the spatial organization of the origins and their activity. Here we show that Fkh1 and Fkh2 share a unique structural feature of human FoxP proteins that enables FoxP2 and FoxP3 to form domain-swapped dimers capable of bridging two DNA molecules in vitro. Accordingly, Fkh1 self-associates in vitro and in vivo in a manner dependent on the conserved domain-swapping region, strongly suggestive of homo-dimer formation. Fkh1- and Fkh2-domain-swap-minus (dsm) mutations are functional as transcription factors yet are defective in replication origin timing control. Fkh1-dsm binds replication origins in vivo but fails to cluster them, supporting the conclusion that Fkh1 and Fkh2 dimers perform a structural role in the spatial organization of chromosomal elements with functional importance.