How chromosome topologies get their shape: views from proximity ligation and microscopy methods

Publication date

2020-11

Authors

Huang, Yike
Neijts, Roel
de Laat, WouterISNI 0000000388639337

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Article

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Abstract

The 3D organization of our genome is an important determinant for the transcriptional output of a gene in (patho)physiological contexts. The spatial organization of linear chromosomes within nucleus is dominantly inferred using two distinct approaches, chromosome conformation capture (3C) and DNA fluorescent in situ hybridization (DNA-FISH). While 3C and its derivatives score genomic interaction frequencies based on proximity ligation events, DNA-FISH methods measure physical distances between genomic loci. Despite these approaches probe different characteristics of chromosomal topologies, they provide a coherent picture of how chromosomes are organized in higher-order structures encompassing chromosome territories, compartments, and topologically associating domains. Yet, at the finer topological level of promoter-enhancer communication, the imaging-centered and the 3C methods give more divergent and sometimes seemingly paradoxical results. Here, we compare and contrast observations made applying visual DNA-FISH and molecular 3C approaches. We emphasize that the 3C approach, due to its inherently competitive ligation step, measures only 'relative' proximities. A 3C interaction enriched between loci, therefore does not necessarily translates into a decrease in absolute spatial distance. Hence, we advocate caution when modeling chromosome conformations.

Keywords

DNA fluorescent in situ hybridization, chromosome conformation capture, gene regulation, genome organization, live-cell imaging, loop extrusion, promoter–enhancer interaction, Biophysics, Structural Biology, Biochemistry, Molecular Biology, Genetics, Cell Biology

Citation

Huang, Y, Neijts, R & de Laat, W 2020, 'How chromosome topologies get their shape : views from proximity ligation and microscopy methods', FEBS letters, vol. 594, no. 21, pp. 3439-3449. https://doi.org/10.1002/1873-3468.13961