Form and function of topologically associating genomic domains in budding yeast

The genome of metazoan cells is organized into topologically associating domains (TADs) that have similar histone modifications, transcription level, and DNA replication timing. Although similar structures appear to be conserved in fission yeast, computational modeling and analysis of high-throughput chromosome conformation capture (Hi-C) data have been used to argue that the small, highly constrained budding yeast chromosomes could not have these structures. In contrast, herein we analyze Hi-C data for budding yeast and identify 200-kb scale TADs, whose boundaries are enriched for transcriptional activity. Furthermore, these boundaries separate regions of similarly timed replication origins connecting the long-known effect of genomic context on replication timing to genome architecture. To investigate the molecular basis of TAD formation, we performed Hi-C experiments on cells depleted for the Forkhead transcription factors, Fkh1 and Fkh2, previously associated with replication timing. Forkhead factors do not regulate TAD formation, but do promote longer-range genomic interactions and control interactions between origins near the centromere. Thus, our work defines spatial organization within the budding yeast nucleus, demonstrates the conserved role of genome architecture in regulating DNA replication, and identifies a molecular mechanism specifically regulating interactions between pericentric origins.

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Faculty Opinions recommendation of Conserved forkhead dimerization motif controls DNA replication timing and spatial organization of chromosomes in S. cerevisiae.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.727380810.793535287 ◽

2017 ◽

Author(s):

Catherine Fox

Keyword(s):

Dna Replication ◽

Spatial Organization ◽

Replication Timing ◽

Dna Replication Timing

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Form and function of eukaryotic unstable non-coding RNAs

Biochemical Society Transactions ◽

10.1042/bst20120040 ◽

2012 ◽

Vol 40 (4) ◽

pp. 836-841 ◽

Cited By ~ 6

Author(s):

Jonathan Houseley

Keyword(s):

Unknown Function ◽

Budding Yeast ◽

Rna Degradation ◽

Present Review ◽

Form And Function ◽

Non Coding Rna ◽

Non Coding Rnas ◽

Higher Eukaryotes ◽

And Function

Unstable non-coding RNAs are produced from thousands of loci in all studied eukaryotes (and also prokaryotes), but remain of largely unknown function. The present review summarizes the mechanisms of eukaryotic non-coding RNA degradation and highlights recent findings regarding function. The focus is primarily on budding yeast where the bulk of this research has been performed, but includes results from higher eukaryotes where available.

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Dynamic relocalization of replication origins by Fkh1 requires execution of DDK function and Cdc45 loading at origins

10.1101/538363 ◽

2019 ◽

Author(s):

Haiyang Zhang ◽

Meghan V. Petrie ◽

Yiwei He ◽

Jared M. Peace ◽

Irene E. Chiolo ◽

...

Keyword(s):

Dna Replication ◽

Spatial Organization ◽

Nuclear Periphery ◽

Replication Timing ◽

G1 Phase ◽

Replication Origins ◽

Chromosomal Dna ◽

Dna Elements ◽

Functional Dna ◽

High Level

ABSTRACTChromosomal DNA elements are organized into spatial domains within the eukaryotic nucleus. Sites undergoing DNA replication, high-level transcription, and repair of double-strand breaks coalesce into foci, although the significance and mechanisms giving rise to these dynamic structures are poorly understood. InS. cerevisiae, replication origins occupy characteristic subnuclear localizations that anticipate their initiation timing during S phase. Here, we link localization of replication origins in G1 phase with Fkh1 activity, which is required for their early replication timing. Using a Fkh1-dependent origin relocalization assay, we determine that execution of Dbf4-dependent kinase function, including Cdc45 loading, results in dynamic relocalization of a replication origin from the nuclear periphery to the interior in G1 phase. Origin mobility increases substantially with Fkh1-driven relocalization. These findings provide novel molecular insight into the mechanisms that govern dynamics and spatial organization of DNA replication origins and possibly other functional DNA elements.

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Replication timing maintains the global epigenetic state in human cells

Science ◽

10.1126/science.aba5545 ◽

2021 ◽

Vol 372 (6540) ◽

pp. 371-378

Author(s):

Kyle N. Klein ◽

Peiyao A. Zhao ◽

Xiaowen Lyu ◽

Takayo Sasaki ◽

Daniel A. Bartlett ◽

...

Keyword(s):

Dna Replication ◽

Histone Modifications ◽

Temporal Order ◽

Three Dimensional ◽

Replication Timing ◽

Human Cells ◽

Genome Architecture ◽

Chromatin Modifications ◽

Complete Elimination ◽

Epigenetic State

The temporal order of DNA replication [replication timing (RT)] is correlated with chromatin modifications and three-dimensional genome architecture; however, causal links have not been established, largely because of an inability to manipulate the global RT program. We show that loss of RIF1 causes near-complete elimination of the RT program by increasing heterogeneity between individual cells. RT changes are coupled with widespread alterations in chromatin modifications and genome compartmentalization. Conditional depletion of RIF1 causes replication-dependent disruption of histone modifications and alterations in genome architecture. These effects were magnified with successive cycles of altered RT. These results support models in which the timing of chromatin replication and thus assembly plays a key role in maintaining the global epigenetic state.

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Cohesin-Mediated Genome Architecture Does Not Define DNA Replication Timing Domains

Genes ◽

10.3390/genes10030196 ◽

2019 ◽

Vol 10 (3) ◽

pp. 196 ◽

Cited By ~ 6

Author(s):

Phoebe Oldach ◽

Conrad A. Nieduszynski

Keyword(s):

Dna Replication ◽

Genome Organization ◽

Mammalian Cells ◽

Replication Timing ◽

S Phase ◽

Genome Architecture ◽

3D Genome ◽

Synchronized Cells ◽

Dna Replication Timing ◽

Phase Entry

3D genome organization is strongly predictive of DNA replication timing in mammalian cells. This work tested the extent to which loop-based genome architecture acts as a regulatory unit of replication timing by using an auxin-inducible system for acute cohesin ablation. Cohesin ablation in a population of cells in asynchronous culture was shown not to disrupt patterns of replication timing as assayed by replication sequencing (RepliSeq) or BrdU-focus microscopy. Furthermore, cohesin ablation prior to S phase entry in synchronized cells was similarly shown to not impact replication timing patterns. These results suggest that cohesin-mediated genome architecture is not required for the execution of replication timing patterns in S phase, nor for the establishment of replication timing domains in G1.

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Understanding the enzymology of archaeal DNA replication: progress in form and function

Molecular Microbiology ◽

10.1046/j.1365-2958.2001.02390.x ◽

2001 ◽

Vol 40 (3) ◽

pp. 520-529 ◽

Cited By ~ 11

Author(s):

Stuart A. MacNeill

Keyword(s):

Dna Replication ◽

Form And Function ◽

And Function ◽

Archaeal Dna Replication

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DNA methylation is required to maintain DNA replication timing precision and 3D genome integrity

10.1101/2020.10.15.338855 ◽

2020 ◽

Author(s):

Qian Du ◽

Grady C. Smith ◽

Phuc Loi Luu ◽

James M. Ferguson ◽

Nicola J. Armstrong ◽

...

Keyword(s):

Dna Methylation ◽

Dna Replication ◽

Replication Timing ◽

Genome Architecture ◽

Genome Organisation ◽

Dna Hypomethylation ◽

3D Genome ◽

Timing Precision ◽

The Impact ◽

Dna Replication Timing

AbstractDNA replication timing and three-dimensional (3D) genome organisation occur across large domains associated with distinct epigenome patterns to functionally compartmentalise genome regulation. However, it is still unclear if alternations in the epigenome, in particular cancer-related DNA hypomethylation, can directly result in alterations to cancer higher order genome architecture. Here, we use Hi-C and single cell Repli-Seq, in the colorectal cancer DNMT1 and DNMT3B DNA methyltransferases double knockout model, to determine the impact of DNA hypomethylation on replication timing and 3D genome organisation. First, we find that the hypomethylated cells show a striking loss of replication timing precision with gain of cell-to-cell replication timing heterogeneity and loss of 3D genome compartmentalisation. Second, hypomethylated regions that undergo a large change in replication timing also show loss of allelic replication timing, including at cancer-related genes. Finally, we observe the formation of broad ectopic H3K4me3-H3K9me3 domains across hypomethylated regions where late replication is maintained, that potentially prevent aberrant transcription and loss of genome organisation after DNA demethylation. Together, our results highlight a previously underappreciated role for DNA methylation in maintenance of 3D genome architecture.

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