Differential Chromosome Conformations as Hallmarks of Cellular Identity Revealed by Mathematical Polymer Modeling

Lassadi, Imen; Kamgoué, Alain; Goiffon, Isabelle; Tanguy-le-Gac, Nicolas; Bystricky, Kerstin

doi:10.1371/journal.pcbi.1004306

Cited by 30 publications

(34 citation statements)

References 44 publications

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“…The existence and role of pre-folding of chromosome III to the directionality of the mating type switch has been debated, because the motion of HML α was mating type and RE-dependent in strains disomic for chromosome III (Bressan et al, 2004), but in contrast tethering the HM loci to MAT did not alter donor preference (Simon et al, 2002). Also, nuclear positioning of the mating type loci did not seem to differ in a and α cells (Bystricky et al, 2009a) while mating type specific features of the folding of chromosome III could be seen in a subset of cells (Lassadi et al, 2015). …”

Section: Introductionmentioning

confidence: 92%

The Conformation of Yeast Chromosome III Is Mating Type Dependent and Controlled by the Recombination Enhancer

et al. 2015

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Summary Mating type switching in yeast occurs through gene conversion between the MAT locus and one of two silent loci (HML or HMR) on opposite ends of the chromosome. MATa cells choose HML as template, while MATα cells use HMR. The Recombination Enhancer (RE), located on the left arm regulates this process. One long-standing hypothesis is that switching is guided by mating type-specific, and possibly RE-dependent chromosome folding. Here we use Hi-C, 5C, and live cell imaging to characterize the conformation of chromosome III in both mating types. We discovered a mating type-specific conformational difference in the left arm. Deletion of a 1 kb subregion within the RE, which is not necessary during switching, abolished mating type-dependent chromosome folding. The RE is therefore a composite element with one subregion essential for donor selection during switching, and a separate region involved in modulating chromosome conformation.

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Section: Introductionmentioning

confidence: 92%

The Conformation of Yeast Chromosome III Is Mating Type Dependent and Controlled by the Recombination Enhancer

et al. 2015

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“…One noteworthy difference between a cells and a cells is the spatial conformation of chromosome III (Belton et al 2015;Lassadi et al 2015). In comparison to a cells, a cells show more frequent interactions between the left arm of chromosome III, which contains HML and the RE, and a region on the right arm that extends from the centromere to the MAT locus.…”

Section: Action At a Distancementioning

confidence: 99%

“…Given that a cells and a cells show similar patterns of DNase-I sensitivity throughout this chromosome arm, the RE does not dramatically alter the local chromatin structure (Ercan and Simpson 2004). Remarkably, the RE does effect a change in the higher-order folding of chromosome III; however, this function is genetically separable from the recombination function (Belton et al 2015;Lassadi et al 2015). The mechanism by which the RE acts at a distance remains unresolved.…”

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confidence: 99%

Donor Preference Meets Heterochromatin: Moonlighting Activities of a Recombinational Enhancer in Saccharomyces cerevisiae

Dodson

Rine

2016

Genetics

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In Saccharomyces cerevisiae, a small, intergenic region known as the recombination enhancer regulates donor selection during mating-type switching and also helps shape the conformation of chromosome III. Using an assay that detects transient losses of heterochromatic repression, we found that the recombination enhancer also acts at a distance in cis to modify the stability of gene silencing. In a mating-type-specific manner, the recombination enhancer destabilized the heterochromatic repression of a gene located 17 kbp away. This effect depended on a subregion of the recombination enhancer that is largely sufficient to determine donor preference. Therefore, this subregion affects both recombination and transcription from a distance. These observations identify a rare example of long-range transcriptional regulation in yeast and raise the question of whether other cis elements also mediate dual effects on recombination and gene expression.

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“…Such a result would be disappointing in 499 terms of the reconstruction algorithm, but fascinating in terms of how such chromosomal 500 domains are created and maintained. However, the extended conformation of many 501 chromosomes seen previously [31], along with the distribution of their contacts to the 502 nuclear lamina [32], suggest that overall compaction is an unlikely configuration, except 503 for specific cases such as mitotic chromosomes or the inactive X chromosome. The 504 second outcome is that the more highly packed regions are interspersed with more 505 extended regions.…”

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confidence: 97%

“…Within territories and across the whole nucleus euchromatin 29 and heterochromatin are generally spatially separated [9], leading to heterochromatin 30 rich and gene expression poor domains at the nuclear periphery and around nucleoli. 31 Gene expression is intrinsically linked to the 3D structure of chromosomes, chromatin 32 packing densities and the accessibility of DNA by e.g. the transcriptional machinery.…”

mentioning

confidence: 99%

ChromoTrace: Computational Reconstruction of 3D Chromosome Configurations for Super-Resolution Microscopy

Barton

Morganella

Ødegård-Fougner

et al. 2017

Preprint

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Motivation: The 3D structure of chromatin plays a key role in genome function, including gene expression, DNA replication, chromosome segregation, and DNA repair. Furthermore the location of genomic loci within the nucleus, especially relative to each other and nuclear structures such as the nuclear envelope and nuclear bodies strongly correlates with aspects of function such as gene expression. Therefore, determining the 3D position of the 6 billion DNA base pairs in each of the 23 chromosomes inside the nucleus of a human cell is a central challenge of biology. Recent advances of superresolution microscopy in principle enable the mapping of specific molecular features with nanometer precision inside cells. Combined with highly specific, sensitive and multiplexed fluorescence labeling of DNA sequences this opens up the possibility of mapping the 3D path of the genome sequence in situ.

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Differential Chromosome Conformations as Hallmarks of Cellular Identity Revealed by Mathematical Polymer Modeling

Cited by 30 publications

References 44 publications

The Conformation of Yeast Chromosome III Is Mating Type Dependent and Controlled by the Recombination Enhancer

The Conformation of Yeast Chromosome III Is Mating Type Dependent and Controlled by the Recombination Enhancer

Donor Preference Meets Heterochromatin: Moonlighting Activities of a Recombinational Enhancer in Saccharomyces cerevisiae

ChromoTrace: Computational Reconstruction of 3D Chromosome Configurations for Super-Resolution Microscopy

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