Genome-Wide Analysis of the Arabidopsis Replication Timing Program

Concia, Lorenzo; Brooks, Ashley; Wheeler, Emily C.; Zynda, Gregory J; Wear, Emily E.; LeBlanc, Chantal; Song, Jawon; Lee, Tae Jin; Pascuzzi, Pete E.; Martienssen, Robert A.; Vaughn, Matthew; Thompson, William F.; Hanley‐Bowdoin, Linda

doi:10.1104/pp.17.01537

Cited by 38 publications

(38 citation statements)

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“…In middle S phase, replication was almost evenly dispersed along the entire chromosomes and only slightly increased in the interstitial regions of chromosome arms. These findings confirmed the recent results made in Arabidopsis and maize obtained by Repli-seq analysis and corresponded to the gene density of their chromosome profiles (Wear et al , 2017, Zynda et al , 2017; Concia et al , 2018). Kwasniewska et al (2018) showed that terminal parts of barley chromosomes replicated in early S phase, whole chromosomes were covered with EdU signal at middle S phase and centromeric parts of chromosomes were replicated in late S phase.…”

Section: Discussionsupporting

confidence: 91%

DNA replication and chromosome positioning throughout the interphase in three dimensional space of plant nuclei

Němečková

Koláčková

Vrána

et al. 2020

Preprint

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20 21 E-mail addresses: 22 Němečková A. -nemeckova@ueb.cas.cz 23 Koláčková V. -kolackova@ueb.cas.cz 24 Vrána J. -jan.vrana@osu.cz 25 Doležel J. -dolezel@ueb.cas.cz 26 27 28 Highlight 29 Telomere and centromere replication timing and interphase chromosome positioning in seven 30 grass species differing in genome size indicates a more complex relation between genome size 31 and the chromosome positioning. 32 33 34 2 Abstract 35 Despite the recent progress, our understanding of the principles of plant genome organization 36 and its dynamics in three-dimensional space of interphase nuclei remains limited. In this 37 study, DNA replication timing and interphase chromosome positioning was analyzed in seven 38 Poaceae species differing in genome size. A multidisciplinary approach combining newly 39 replicated DNA labelling by EdU, nuclei sorting by flow cytometry, three-dimensional 40 immuno-FISH, and confocal microscopy revealed similar replication timing order for 41 telomeres and centromeres as well as for euchromatin and heterochromatin in all seven 42 species. The Rabl configuration of chromosomes that lay parallel to each other and their 43 centromeres and telomeres are localized at opposite nuclear poles, was observed in wheat, oat, 44 rye and barley with large genomes, as well as in Brachypodium with a small genome. On the 45 other hand, chromosomes of rice with a small genome and maize with relatively large genome 46 did not assume proper Rabl configuration. In all species, the interphase chromosome 47 positioning inferred from the location of centromeres and telomeres was stable throughout the 48 interphase. These observations extend earlier studies indicating a more complex relation 49 between genome size and interphase chromosome positioning, which is controlled by factors 50 currently not known. 51 52 53 65 Interestingly, a different arrangement of chromosomes in interphase nuclei was 66 observed in Arabidopsis thaliana, a model plant with small genome (1C~157 Mbp). Here, the 67 centromeres are located at the nuclear periphery, whereas the telomeres congregate around 68 3 nucleolus (Armstrong et al., 2001; Fransz et al., 2002). Centromeric heterochromatin forms 69 dense bodies called chromocenters, while euchromatin domains form 0.2 -2 Mb loops that 70 are organized into Rosette-like structures (Fransz et al., 2002; Pecinka et al., 2004; Tiang et 71 al., 2012; Schubert et al., 2014). 72 Some earlier studies suggested that chromatin arrangement in interphase nuclei of 73 wheat, oat and rice, and in particular the centromere -telomere orientation, may be tissue-74 specific and cell cycle-dependent (Dong and Jiang 1998; Prieto et al., 2004; Santos and Show, 75 2004). While a majority of nuclei in somatic cells of rice (Oryza sativa), which has a small 76 genome (1C~490 Mbp, Bennett et al., 1976) lack Rabl configuration, chromosomes in the 77 nuclei of some rice tissues, e.g., pre-meiotic cells in anthers or xylem -vessel precursor cells 78 seem to assume the configuration (Prieto et al., 2004; San...

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Section: Discussionsupporting

confidence: 91%

DNA replication and chromosome positioning throughout the interphase in three dimensional space of plant nuclei

Němečková

Koláčková

Vrána

et al. 2020

Preprint

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“…Similarly, studies comparing chromatin regions with different replication timing patterns in maize root tip nuclei showed that open chromatin and densely packed heterochromatin domains tend to be duplicated in early and late S phases, respectively [61,62]. The same correlation was seen in Arabidopsis suspension cells, that repressed chromatin were enriched in late replicated loci [63,64]. Further, live imaging of Arabidopsis replisomes revealed their dynamic distribution in early and late S phase [65].…”

Section: Dna Replication Timingmentioning

confidence: 73%

Chromatin domains in space and their functional implications

Pontvianne

Liu

2020

Current Opinion in Plant Biology

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Genome organization exhibits functional compartmentalization. Several factors, including epigenetic modifications, transcription factors, chromatin remodelers, and RNAs shape chromatin domains and the three-dimensional genome organization. Various types of chromatin domains with distinct epigenetic and spatial features exhibit different transcriptional activities. As part of the efforts to better understand plant functional genomics, over the past a few years, spatial distribution patterns of plant chromatin domains have been brought to light. In this review, we discuss chromatin domains associated with the nuclear periphery and the nucleolus, as well as chromatin domains staying in proximity and showing physical interactions. The functional implication of these domains is discussed, with a particular focus on the transcriptional regulation and replication timing. Finally, from a biophysical point of view, we discuss potential roles of liquid-liquid phase separation in plant nuclei in the genesis and maintenance of spatial chromatin domains.

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“…Use of relatively unexplored organisms for studying replication is also effective, especially when one focuses on unique developmental stages. Due to the availability and feasibility of NGS, non-mammalian organisms without much information about DNA replication regulation have recently been utilized for genome-wide DNA replication studies, including chicken [76,77], zebrafish [78], Caenorhabditis elegans [79], maize [80], Arabidopsis [81], Drosophila [82] and others [83,84]. In particular, DNA replication profiling during early zebrafish embryogenesis demonstrated the presence of a DNA replication timing program prior to the mid-blastula transition (MBT) [78].…”

Section: Unraveling the Complex Relationship: Replication Timing mentioning

confidence: 99%

DNA Replication Timing Enters the Single-Cell Era

Hiratani

Takahashi

2019

Genes

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In mammalian cells, DNA replication timing is controlled at the level of megabase (Mb)-sized chromosomal domains and correlates well with transcription, chromatin structure, and three-dimensional (3D) genome organization. Because of these properties, DNA replication timing is an excellent entry point to explore genome regulation at various levels and a variety of studies have been carried out over the years. However, DNA replication timing studies traditionally required at least tens of thousands of cells, and it was unclear whether the replication domains detected by cell population analyses were preserved at the single-cell level. Recently, single-cell DNA replication profiling methods became available, which revealed that the Mb-sized replication domains detected by cell population analyses were actually well preserved in individual cells. In this article, we provide a brief overview of our current knowledge on DNA replication timing regulation in mammals based on cell population studies, outline the findings from single-cell DNA replication profiling, and discuss future directions and challenges.

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Genome-Wide Analysis of the Arabidopsis Replication Timing Program

Cited by 38 publications

References 91 publications

DNA replication and chromosome positioning throughout the interphase in three dimensional space of plant nuclei

DNA replication and chromosome positioning throughout the interphase in three dimensional space of plant nuclei

Chromatin domains in space and their functional implications

DNA Replication Timing Enters the Single-Cell Era

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