DNA Repair System
Observing the Initial Stages of TCR Repair Mechanisms in a Bacterial Model
DNA is constantly being damaged by environmental agents such as ultraviolet light or certain compounds present in cigarette smoke. Cells unceasingly implement repair mechanisms for this DNA, which are of redoubtable efficacy. A team from Institut Jacques Monod (CNRS/Université Paris Diderot), in collaboration with scientists from the Universities of Bristol in the UK and Rockefeller in the USA, has for the first time managed to follow real-time the initial steps in one of these hitherto little known DNA repair systems. Working in a bacterial model, and thanks to an innovative technique applied to a single molecule of DNA, the scientists were able to understand how several actors interact to ensure the reliable repair of DNA. Published in Nature on 9 September 2012, their work aims to better understand the onset of cancers and how they become resistant to chemotherapies.
Ultraviolet light, tobacco smoke or even the benzopyrenes contained in over-cooked meat can cause changes to the DNA in our cells, which may lead to the onset of cancers. These environmental agents deteriorate the actual structure of the DNA, notably causing so-called "bulky" lesions (like the formation of chemical bonds between DNA bases). In order to identify and repair this type of damage, the cell can call on several systems, such as transcription-coupled repair (TCR), whose complex mechanism of action still remains poorly understood today. Abnormalities affecting this TCR mechanism - which permits permanent monitoring of the genome - are the cause of some hereditary diseases such as Xeroderma pigmentosum, sufferers from which are hypersensitive to the Sun's ultraviolet rays and are commonly referred to as "children of the night".
For the first time, a team from Institut Jacques Monod (CNRS/Université Paris Diderot), in collaboration with scientists at the Universities of Bristol in the UK and Rockefeller in the USA, has succeeded in observing the initial stages of TCR repair mechanisms in a bacterial model. To achieve this, they employed a novel technique for the nanomanipulation of individual molecules, which allowed them to detect and follow real-time the interactions between the molecules in play in a single damaged DNA molecule.
They elucidated the interactions between different actors during the first steps of this TCR process. A first protein, RNA polymerase, usually crosses DNA without mishap, but is stalled when it meets a bulky lesion (like a train blocked on its rails by a landslide). A second protein, Mfd, binds to the stalled RNA polymerase and removes it from the damaged "rail" so that it can then replace it with the other proteins necessary to repair the damage. Measurements of the reaction speeds enabled the observation that Mfd acts particularly slowly on RNA polymerase, pushing it out of the way in about twenty seconds. Furthermore, Mfd does indeed displace stalled RNA polymerase, but then remains associated with the DNA for a longer period (of about five minutes), allowing it to coordinate the arrival of other repair proteins at the damaged site.
Although the scientists were able to explain how this system can achieve almost 100% reliability, a even clearer understanding of these repair processes is still essential in order to determine how cancers appear and subsequently may become resistant to chemotherapies.
Kevin Howan, Abigail J. Smith, Lars F. Westblade, Nicolas Joly, Wilfried Grange, Sylvain Zorman, Seth A. Darst, Nigel J. Savery and Terence R. Strick: Initiation of transcription-coupled repair characterized at single-molecule resolution. Nature, 9 September 2012