Genome complexity: DNA repair contols (Introduction)

by David Turell , Monday, April 14, 2025, 21:57 (5 days ago) @ David Turell

Very specific in action:

https://www.sciencedaily.com/releases/2025/04/250414124702.htm

"The publication of two papers demonstrates how work led by laboratories from the Department of Cancer and Genomic Sciences, and School of Biosciences at the University of Birmingham has made strides in understanding how the repair process is correctly orchestrated.

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"Our cells protect their DNA by constantly monitoring and repairing any damage. When DNA is damaged, internal signals activate within the cell to pinpoint the damage and recruit specialised proteins -- DNA repair "machines" -- to fix the break. This repair process must be tightly regulated to ensure the correct proteins arrive in the right amounts and in the correct sequence.

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"The first study, published in Nature Communications today (Monday 14 April), identifies a "twisting switch" that helps turn off early repair signals by altering the shape of proteins. Without the switch, repair signals stay active too long, disrupting the correct sequencing of the repair machine arrival at and exit from the broken site so that DNA repair is blocked.

"The discovery of the twisting switch resolves a long-standing question about how the DNA repair protein RNF168, which has a tendency to cause uncontrolled signalling, is switched off. The paper outlines a four-step process that removes RNF168 from chromatin, preventing excessive DNA damage signals and demonstrates that without these steps, cells become hypersensitive to radiation.

"A second study published in Molecular Cell identified that a component previously assumed to have very little function in cells, SUMO4, has a crucial role to help prevent the DNA damage signal from being overwhelmed.

"Without SUMO4, there is an excess of one type of signalling, disrupting other signals and preventing some repair proteins from reaching the damaged site. As a result, DNA repair fails. The significance of this research comes from the way it challenges earlier assumptions about the importance of the SUM04 protein."

Comment: think about the timing of developments in DNA. Could it have appeared without these repair elements present at the same time? Very doubtful. A DNA system without a repair mechanism present would not have survived. DNA damage is a natural occurrence, so damage control is a necessity. More evidence for design.