Scientists have unlocked a crucial part of the mystery as to how our DNA can replicate and repair itself, something which is essential for all life forms.
The new research, conducted by leading scientists at the University of Sheffield in the UK, has revealedhow branched DNA molecules are removed from the iconic double-helical structure, a process which scientists have been looking to unlock for over 20 years.
"Branched DNA features in several episodes of the X-Files as Agent Scully suspects aliens inserted it in her blood," Jon Sayers, Professor of Functional Genomics at the University of Sheffield and lead authorof the study said.
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The interdisciplinary team from the University's Departments of Infection, Immunity and Cardiovascular Disease, and Molecular Biology and Biotechnology captured never-before- seen snapshots of the molecular events in incredible detail.
They show how Flap EndoNuclease enzymes (FENs) trim branched DNA molecules after cells have divided.
The scientists found the FEN threads the free end of thebranch through a hole in the enzyme before slidingalong to the trunk where it acts like a pair of molecular secateurs, trimming the branch and restoring the iconic double-helix.
The team made the discovery using the Diamond Light Source - the UK's synchrotron which works like a giant microscope harnessing the power of electrons to produce bright X-ray light which scientists can use to study anything from fossils and jet engines to viruses and vaccines.
Professor Sayers said, "The FENs analysed in the study are very similar to those used in diagnostic tests for genetic diseases, bacteria and viruses. Understanding how they work will help to engineer better and more reliable tests and tools for laboratory research and hospital diagnostics labs".
"Because DNA replication is essential for all life forms, understanding how it works at a molecular level provides insight into one of the most basic cellular processes common to all life. The enzymes that carry out this process are sometimes involved incancer. They have been linked to tumour progression and mutation, so this discovery could pave the way for better diagnostics or new drugs.
"Knowing how these enzymes work could aid development of new antimicrobial drugs that may one day be used to fight antibiotic resistant bacteria," Sayers said.
Results of the pioneering study were published yesterday in Nature Structural and Molecular Biology.
"We can now see the details of how cells have evolved to tidy up after themselves as they copy their DNA, which reduces their risk of harmful mutations. This sort of information is fundamental in helping us understand and maybe treat those cells where occasionally things do go wrong," John Rafferty of the University of Sheffield's Department of Molecular Biology and Biotechnology and author on the study said.