Shaping the metaphase chromosome: coordination of cohesion and condensation

Losada, Ana; Hirano, Takeshi

doi:10.1002/bies.1133

Cited by 89 publications

(66 citation statements)

References 87 publications

(92 reference statements)

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“…The results discussed above, combined with conclusions of Marsden & Laemmli (1979), Losada & Hirano (2001), Lavoie et al (2002), Maeshima & Laemmli (2003), Strukov et al (2003), Kireeva et al (2004), Lavoie et al (2004), Polyakov et al (2006), and Sheval and Polyakov (2006), suggest the follow-ing scenario for vertebrate chromosome condensation ( Figure 13). Numbers are approximate, and apply to the human case.…”

Section: Smc-crosslinked-chromatin-network Model Of Mitotic Chromosommentioning

confidence: 65%

“…The larger is the distance between cohesin domains, the greater will be the length compaction. Metaphase cohesin interdomain distances in vertebrates must be much greater than the 15 kb distance observed in yeast; for Xenopus the cohesin density has been estimated to be one per 400 kb (Losada & Hirano 2001). Cohesin interdomain distances should correlate with mitotic loop size, and possibly with convergent transcription domain size (Lengronne et al 2004) and replicon size (Buongiorno-Nardelli et al 1982).…”

Section: Smc-crosslinked-chromatin-network Model Of Mitotic Chromosommentioning

confidence: 99%

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Micromechanical studies of mitotic chromosomes

2008

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Mitotic chromosomes respond elastically to forces in the nanonewton range, a property important to transduction of stresses used as mechanical regulatory signals during cell division. In addition to being important biologically, chromosome elasticity can be used as a tool for investigating the folding of chromatin. This paper reviews experiments studying stretching and bending stiffness of mitotic chromosomes, plus experiments where changes in chromosome elasticity resulting from chemical and enzyme treatments were used to analyse connectivity of chromatin inside chromosomes. Experiments with nucleases indicate that non-DNA elements constraining mitotic chromatin must be isolated from one another, leading to the conclusion that mitotic chromosomes have a chromatin Fnetwork_ or Fgel_ organization, with stretches of chromatin strung between Fcrosslinking_ points. The as-yet unresolved questions of the identities of the putative chromatin crosslinkers and their organization inside mitotic chromosomes are discussed.

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Section: Smc-crosslinked-chromatin-network Model Of Mitotic Chromosommentioning

confidence: 65%

Section: Smc-crosslinked-chromatin-network Model Of Mitotic Chromosommentioning

confidence: 99%

Micromechanical studies of mitotic chromosomes

2008

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“…These events require dramatic changes in chromatin structure that are achieved through histone tail modifications by chromatinmodifying enzymatic complexes and by the action of several other enzymatic activities such as condensins and cohesins, topoisomerase II, and the securin/separin pathway (reviewed in Hans and Dimitrov, 2001;Losada and Hirano, 2001;Nasmyth, 2002). Our results discover new aspects of the interplay between histone modifications, sister chromatid condensation and cohesion, and chromosome segregation, and they provide new mechanistic insights into the origin of genome instability in mammalian cells.…”

Section: Discussionmentioning

confidence: 80%

“…However, the majority of chromosomes producing chromatin bridges showed persistent cohesion along sister chromatid arms but proper centromere separation, demonstrating that inhibition of histone deacetylation in mitosis affects chromosome cohesion along chromatid arms more than at the centromere. It is now becoming clear that chromatin dynamics in mitosis is regulated by the coordinated action of cohesin and condensin activities and that condensin loading on DNA promotes cohesin dissociation (Losada and Hirano, 2001;Nasmyth, 2002). It has been proposed that chromosome arm cohesion in mammalian cells is removed in prophase through a separin-independent mechanism and that centromeric cohesion is released by Scc1 cleavage at the metaphase to anaphase transition (Waizenegger et al, 2000).…”

Section: Histone Hyperacetylation Prevents Sister Chromatid Resolutiomentioning

confidence: 99%

Histone Hyperacetylation in Mitosis Prevents Sister Chromatid Separation and Produces Chromosome Segregation Defects

Cimini

Mattiuzzo

Torosantucci

et al. 2003

MBoC

167

160

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Posttranslational modifications of core histones contribute to driving changes in chromatin conformation and compaction. Herein, we investigated the role of histone deacetylation on the mitotic process by inhibiting histone deacetylases shortly before mitosis in human primary fibroblasts. Cells entering mitosis with hyperacetylated histones displayed altered chromatin conformation associated with decreased reactivity to the anti-Ser 10 phospho H3 antibody, increased recruitment of protein phosphatase 1-δ on mitotic chromosomes, and depletion of heterochromatin protein 1 from the centromeric heterochromatin. Inhibition of histone deacetylation before mitosis produced defective chromosome condensation and impaired mitotic progression in living cells, suggesting that improper chromosome condensation may induce mitotic checkpoint activation. In situ hybridization analysis on anaphase cells demonstrated the presence of chromatin bridges, which were caused by persisting cohesion along sister chromatid arms after centromere separation. Thus, the presence of hyperacetylated chromatin during mitosis impairs proper chromosome condensation during the pre-anaphase stages, resulting in poor sister chromatid resolution. Lagging chromosomes consisting of single or paired sisters were also induced by the presence of hyperacetylated histones, indicating that the less constrained centromeric organization associated with heterochromatin protein 1 depletion may promote the attachment of kinetochores to microtubules coming from both poles

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“…37 The linear chromosome compaction ratio in interphase falls between 70-100 in both yeast 32 and mammalian cells. 38,39 For mitotic chromosomes this number is estimated to be 3,000-2,00,000 in vertebrates [39][40][41] but only 140 in S. cerevisiae 32 and 700 in S. pombe. 42 Thus, the degree of chromosome compaction in mitosis compared to interphase rises dramatically in higher eukaryotes.…”

Section: Regulation Of Chromosome Segregation In Anaphasementioning

confidence: 99%