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DNA: Supercoiling pushes molecular handcuffs along chromatin fibres

Date:
December 14, 2017
Source:
Swiss Institute of Bioinformatics
Summary:
As it squeezes down the chromatin fiber, the cohesin protein complex extrudes a growing loop of DNA -- a bit like the quick-lacing system of trail-running shoes. But what is powering the movement of the protein? A team of scientists has found that the driving force could be the supercoiling of upstream DNA. Their research is thereby adding a key piece to the puzzle of gene expression regulation.
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As it squeezes down the chromatin fibre, the cohesin protein complex extrudes a growing loop of DNA -- a bit like the quick-lacing system of trail-running shoes. But what is powering the movement of the protein? A team of SIB scientists has found that the driving force could be the supercoiling of upstream DNA. Their research, published in Nucleic Acids Research, is thereby adding a key piece to the puzzle of gene expression regulation.

Chromatin loop extrusion -- a 'quick-lacing system' enabling gene regulation

Gene regulation relies on complex structural arrangements and processes at the molecular level. One of them, called 'chromatin loop extrusion' (see Box 1), strikingly resembles the quick-lacing system of some trail running shoes: as the buckle is pushed downward, a larger loop is extruded on the top. This is where the transcription takes place.

Recent advances in the field of genome structure have identified that cohesin -- a protein complex forming a pair of molecular bracelets, or handcuffs -- plays the buckle part. By binding tightly to the chromatin fibres, cohesin initially traps small DNA loops. These loops grow as the cohesin handcuffs slides along the fibres.

"Cohesin is a central piece of the gene regulation puzzle," says SIB Group Leader Andrzej Stasiak. "There is a hot debate ongoing as to what is triggering the movement of this protein complex along the chromatin."

Cohesin is known to play several key roles in chromosome structure. And, indeed, should something go wrong with cohesin, severe developmental anomalies or forms of cancers can appear.

Supercoiling as the motor of chromatin loop extrusion

Andrzej Stasiak's DNA and Chromosome Modelling Group at SIB set out to understand the nature of the motor that is pushing cohesin along the fibres.

One of their hints came from a growing number of studies showing that transcription induces an axial rotation of transcribed DNA. This in turn is known to result in the coiling of chromatin loops around themselves, similarly to shoe laces.

So the team simulated what happens when transcription-induced supercoiling is generated in small chromatin loops flanked by cohesin handcuffs.

"We observed that supercoiling started to accumulate in the chromatin portion flanked by the cohesin handcuffs," says Stasiak, "and, to our surprise, that supercoiling was physically pushing cohesin handcuffs along embraced chromatin fibres, so that the chromatin loop they were gripping was actively growing, exactly as required to form TADs."

This modelling study establishes the basis of a new chemo-mechanical process of transduction operating in chromosomes, and shaping them into structures required for optimal regulation of gene expression.


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Materials provided by Swiss Institute of Bioinformatics. Note: Content may be edited for style and length.


Journal Reference:

  1. Dusan Racko, Fabrizio Benedetti, Julien Dorier, Andrzej Stasiak. Transcription-induced supercoiling as the driving force of chromatin loop extrusion during formation of TADs in interphase chromosomes. Nucleic Acids Research, 2017; DOI: 10.1093/nar/gkx1123

Cite This Page:

Swiss Institute of Bioinformatics. "DNA: Supercoiling pushes molecular handcuffs along chromatin fibres." ScienceDaily. ScienceDaily, 14 December 2017. <www.sciencedaily.com/releases/2017/12/171214101352.htm>.
Swiss Institute of Bioinformatics. (2017, December 14). DNA: Supercoiling pushes molecular handcuffs along chromatin fibres. ScienceDaily. Retrieved March 18, 2024 from www.sciencedaily.com/releases/2017/12/171214101352.htm
Swiss Institute of Bioinformatics. "DNA: Supercoiling pushes molecular handcuffs along chromatin fibres." ScienceDaily. www.sciencedaily.com/releases/2017/12/171214101352.htm (accessed March 18, 2024).

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