Scientists discover how 'super enzyme' speeds up DNA repair

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Until now, the exact process through which DNA damage was identified and signalled was uncertain, but a recent study has discovered the actual mechanism which involves an enzyme named PARP3 that marks the site of DNA damage by adding a molecule called 'ADP-ribose' to one of the proteins (histone H2B) contained in the chromatin.

This is quite interesting in light of previous discussions on the forum about truncated flow of liquids used to alter our DNA, achieved by blocking the flow of a chemical transmitter through biogenetic engineering. Somehow the mechanism of signalling DNA damage to be repaired must have been blocked by this truncation at the time.


Scientists discover how 'super enzyme' speeds up DNA repair

In the body, mutations can arise from DNA damage that is not repaired properly, leading to disease, including cancer and neurodegenerative disease. New research funded by the MRC and Cancer Research UK, led by the laboratories of Professor Keith Caldecott and Professor Laurence Pearl at the University of Sussex's Genome Damage and Stability Centre, has identified how the enzyme PARP3, short for poly(ADP-ribose) polymerase 3, recognises and signals the presence of broken DNA strands.

Research has shown that the PARP3 enzyme is involved in the DNA repair process and helps to maintain the integrity of the genetic code, but until now the precise DNA repair activation mechanism triggered by the enzyme was unclear.

Using multi-disciplinary expertise, Sussex scientists have identified the specific steps involved in activating the DNA repair process. When the PARP3 enzyme locates a specific site of DNA damage, it 'marks' the damaged DNA with a molecular signal.

This signal is created via a chemical change, involving the addition of a molecule called 'ADP-ribose' to the DNA. The DNA is packaged up in a complex called 'chromatin' which contains proteins; the team found that the PARP3 enzyme adds the 'ADP-ribose' molecule to one of these proteins – 'histone H2B'.

By marking the precise site of damage the enzyme flags the problem up to specialised DNA repair enzymes that will move in to repair the damage, protecting the cell from potentially dangerous DNA breaks.

The researchers believe this is a vital step towards understanding how DNA breaks are detected, signalled, and repaired, which could in the future enable scientists to create drugs which can better target certain cancers.

PARP3 is one of a superfamily of enzymes that are targeted by PARP inhibitor drugs, a new class drugs used to treat hereditary cancer, including ovarian and breast cancer. Knowledge of how the PARP3 enzyme activates DNA repair will also contribute to improving the understanding, and targeting, of PARP inhibitor drugs.

The research, which took place over four years, also involved nuclear magnetic resonance expertise in Professor Steve Matthews' group at Imperial College, London, proteomics in the lab of Dr Steve Sweet in Sussex and chromatin biology in the lab of Dr Alan Thorne at the University of Portsmouth.

Professor Keith Caldecott, who led the study, said: "This discovery highlights the value of multi-disciplinary collaborations, combining molecular and cellular biology with biochemistry and structural biology. As a result of working together, we have been able to identify how PARP3 recognises and flags the presence of broken DNA.

"This will be important for our understanding of how cells protect themselves from potentially dangerous DNA breaks. It will also help to provide insight into the mechanisms of action of a new class of PARP inhibitory anti-cancer drugs."

Link to paper

 

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Another interesting paper related to the one above, which describes the protein p53 being responsible for recognising DNA damage and increasing expression of the genes involved in DNA repair and cell division, thus playing a major role in the suppression of tumours and cancer. The study found that an RNA molecule named DINO regulates the p53 protein by binding to it.

The authors discovered the role played by the RNA molecule carrying out a test where the DINO was artificially increased and the cells responded by trying to repair the DNA even in the absence of damage because of DINO's role in regulating p53.


Regulatory RNA essential to DNA damage response

Stanford researchers have found that a tumor suppressor known as p53 is stabilized by a regulatory RNA molecule called DINO. The interaction helps a cell respond to DNA damage and may play a role in cancer development and premature aging.

Knowing when to hold them, and when to fold them, is a critical skill in professional gambling. But it's also pertinent for cells assessing DNA damage.

It's essential for the cells to quickly ascertain whether it's possible to repair mistakes or to self-destruct for the good of the organism. That's because cells with a damaged genome often begin to flout the standard rules of growth and become cancerous.

Now, researchers at the Stanford University School of Medicine have discovered a new player in this high-stakes molecular game in the form of a novel regulatory RNA they've named DINO. This RNA molecule binds to and stabilizes a well-known tumor suppressor protein called p53 that mobilizes a cell's response to DNA damage. When mutated, p53 is one of the most infamous bad guys in the cancer world.

"It's so important for a cell to keep track of potentially dangerous changes to its genome," said professor of dermatology Howard Chang, MD, PhD. "But if cells reacted to every little ding, they would find themselves responding inappropriately—they would stop growing and maybe even self-destruct unnecessarily. You don't want to do this unless the DNA damage is severe. We've discovered that DINO is an integral part of this decision-making circuit."

A paper describing the research was published online Sept. 26 in Nature Genetics. Chang is the senior author. Lead authorship is shared by former radiation oncology resident Adam Schmitt, MD, graduate student Julia Garcia and former graduate student Tiffany Hung.

When DNA gets damaged

DNA damage is a natural byproduct of cell division because it is impossible to faithfully copy each of the 3 billion nucleotides that make up our genomes without making at least a few errors. Damage can also be caused by exposure to certain chemical agents, ultraviolet light and ionizing radiation.

Most of the time these problems are recognized and quickly repaired by the cell. That's where p53 comes in. When it is doing its job, p53 recognizes and responds to DNA damage by increasing the expression of genes involved in DNA repair and cell division. In this way it functions as a tumor suppressor. When mutated, however, p53 loses its ability to modulate the cell's response to DNA damage. Mutations in p53 are among the most common causes of many types of cancer.

Chang and his collaborators found that p53 also increases the expression of DINO. DINO, in turn, binds to and stabilizes p53 in a kind of positive feedback loop, amplifying its signal throughout the nucleus.

"Until now, most studies have focused only on proteins in this pathway," said Chang.

Fine-tuning the damage response

DINO is a member of a group of RNA molecules known as long noncoding RNAs, or lncRNAs. These molecules have been implicated in a growing number of critical regulatory roles throughout the cell. This is the first time that a lncRNA has been shown to be involved in this critical DNA damage-response pathway in living animals.

Chang and his colleagues found that when DINO expression is artificially increased, cells respond as if their DNA has been damaged even in the absence of any genome changes. In contrast, when DINO expression is inhibited, the cell responds less robustly to signals from p53.

"DINO expression allows the cell to fine-tune its response to DNA damage and respond appropriately," said Chang.

Because, as an RNA, DINO is made in the cell's nucleus where p53 is active, the researchers believe it may provide a more rapid and precise response to DNA damage than would a regulatory protein, which would be synthesized in the cytoplasm.

"Positive feedback loops are used in many applications, including engineering, to increase the sensitivity of systems and apply thresholds for action," said Chang. "We believe DINO may play role in cancer development and possibly premature aging by modulating how a cell responds to DNA damage."

Link to paper