This year's Nobel Prize in chemistry was given to three scientists who each focused on one piece of the
DNA1 repair puzzle. Now a new study, reported online Oct. 28 in the journal Nature, reports the discovery of a new class of DNA repair
enzyme2. When the structure of DNA was first discovered, scientists imagined it to be extremely chemically stable, which allowed it to act as a
blueprint3 for passing the basic traits of parents along to their offspring. Although this view has remained prevalent among the public, biologists have since learned that the double helix is in fact a highly reactive
molecule4 that is constantly being damaged and that cells must make unceasing repair efforts to protect the
genetic5 information that it contains.
"It's a double-edged sword," said Brandt Eichman, associate professor of biological sciences and biochemistry at Vanderbilt University, who headed the research team that made the new discovery. "If DNA were too reactive then it wouldn't be capable of storing genetic information. But, if it were too stable, then it wouldn't allow organisms to evolve."
The DNA double-helix has a spiral staircase structure with the outer edges made from sugar and phosphate
molecules6 joined by stair steps composed of pairs of four nucleotide bases (adenine, cytosine, guanine and thymine) that serve as the basic letters in the genetic code.
There are two basic sources of DNA damage or lesions: environmental sources including ultraviolet light,
toxic7 chemicals and ionizing radiation and internal sources, including a number of the cell's own metabolites (the chemicals it produces during normal metabolism), reactive oxygen species and even water.
"More than 10,000 DNA damage events occur each day in every cell in the human body that must be repaired for DNA to function properly," said first author Elwood Mullins, a postdoctoral research associate in the Eichman lab.
The newly discovered DNA repair enzyme is a DNA glycosylase, a family of
enzymes8 discovered by Tomas Lindahl, who received this year's Nobel prize for recognizing that these enzymes removed damaged DNA bases through a process called base-excision repair. It was the first of about 10 different DNA repair pathways that biologists have identified to date.