New Method Offers Insight into Radiation Damage to DNA

The research could help clarify the risks faced by future astronauts flying long-term missions to the moon or Mars. It will be published in the March 19, 2008 issue of the journal Nucleic Acids Research.

The technique uses different colored fluorescent "tags" instead of radioactive ones to monitor repair of damage to DNA, life's genetic instruction molecule. Because these fluorescent tags reduce the amount of hazardous waste associated with the research (and its cost) the Brookhaven scientists, Betsy Sutherland and Brigitte Paap, now at Arizona State University, have been recognized by DOE's Office of Science for their "Best in Class" pollution prevention innovation.

"Understanding the effects on humans of radiation exposure - whether in the natural environment, in outer space, in the workplace, or due to radiation therapy - requires insight into the induction and repair of damage to DNA," said Sutherland, an expert in the study of space radiation. "It's very rewarding to come up with a new technique that helps us understand this process while at the same time reducing the waste associated with traditional techniques."

Radiation can damage the DNA "double helix" - a two-stranded, twisting molecule - in a variety of ways: 1) by knocking off one or more of the DNA "bases" known by the letters A, T, G, and C, which form the bonds between the two strands of the double helix; 2) by oxidizing these bases; or 3) by breaking through one or both strands. All can result in a failure of the molecule to perform its main task - telling cells which proteins to make. That can lead to out-of-control cell growth (cancer) or death. Cells can often repair radiation-damaged DNA, using specialized enzymes to excise and patch up the damaged segments.

But damage from ionizing particle radiation appears to be harder to repair than that caused by lower-energy forms of radiation such as x-rays and gamma rays. Scientists have long hypothesized that the reason for this difference was that the high-energy ionizing particles caused more complex damage containing many lesions close together on the DNA, leading to slower and less-accurate repair. The technique developed by Sutherland and Paap allowed them to test this hypothesis.

Using standard techniques of molecular biology, the scientists created synthetic DNA with known lesions in a variety of spatial arrangements with a red fluorescent tag attached to one end of the strand and a green fluorescent tag at the other end. They then applied a DNA repair enzyme, which clips the DNA at damaged sites. The scientists then used gel electrophoresis to separate the fragments according to their length. By looking at the red- and green-tagged bands, and determining their length, the scientists were able to measure how well the repair enzyme recognized and repaired the DNA damage.

The results were surprising: Instead of being dependent on the number of lesions, the ability of the repair enzyme to recognize the damaged sites appeared to be most affected by the spatial arrangement of lesions on the DNA strands. The scientists found that the enzyme readily recognized and repaired lesions on one of the DNA's two strands that occurred all to one side of a reference lesion on the opposite strand (think of it as "upstream"). These upstream lesions were successfully repaired regardless of whether there were only two or many lesions in the damage. If the lesions occurred "downstream" from the reference lesion, however, the repair enzyme was unable to work properly, no matter whether the clustered damage was a simple, two-lesion cluster, similar to those caused by x-rays, or a complex multi-lesion cluster like those induced by space radiation. When the lesions occurred in a two-sided cluster both up and downstream from the reference lesion, again the repair enzyme worked poorly.

"Since x-rays produce about half upstream, easily repaired clusters and about half downstream, repair-resistant clusters, about half of them would be readily repaired," Sutherland said. "The heavy, charged particles in space radiation, on the other hand, produce much more complex, two-sided clusters, containing so many lesions that most of them are repair-resistant. This directional dependence of the ability to repair lesions explains why damage from charged-particle radiation, such as that encountered in outer space, is more harmful," she said.

Pollution prevention award

The technique using fluorescently labeled synthetic DNA fragments replaces a technique in which radioactive isotopes are used as tags. While efficient, radioactive isotopes are more expensive than the fluorescent tags. Also, using radioactive tracers requires frequent preparation of freshly labeled DNA, and disposal of the experimental samples as hazardous waste - which further increases the cost of the research.

Fluorescently labeled molecules can be stored frozen for long periods. So the new method minimizes waste generation and improves worker safety by avoiding the handling of radioactive material.

The technique may now be used throughout the DOE labs and in universities and industry, and may be considered for other awards, including the White House "Closing the Circle" award competition.

Source: Brookhaven National Laboratory

Indian medicinal plant Acanthus ilicifolius may combat liver cancer
Liver cancer is the fifth most common cancer in the world with a poor prognosis. About three quarters of the cases of liver cancer are found in Southeast Asia, including China, Hong Kong, Taiwan, Korea, India, and Japan. The frequency of liver cancer in Southeast Asia and sub-Saharan Africa is greater than 20 cases per 100,000 population. Moreover, recent data show the frequency of liver cancer in the U.S. overall is rising.
Findings point to molecular 'Achilles heel' for half of breast cancer tumors
Researchers at Lombardi Comprehensive Cancer Center at Georgetown University Medical Center have shown why a protein known as cyclin D1 may be the Achilles heel for breast tumors that are estrogen receptor positive (ER+) − which is the most common type of breast cancer.
Cigarette smoke, alcohol damage hearts worse as combo
Tobacco smoke-filled air is bad for cardiovascular health, and drinking alcohol at the same time only makes it worse, according to researchers at the University of Alabama at Birmingham (UAB).
Get in touch
When the genetic material inside a cell’s nucleus starts to fall apart, a protein called ATM takes charge and orchestrates the rescue mission. Surprisingly, for ATM to kick into full gear, the stretches of DNA flanking a chromosomal break are just as important as the damaged site itself, report scientists at the Salk Institute for Biological Studies.
Yale scientists to study DNA repair in cancer cells
Yale School of Medicine researchers have received $8.4 million to study how cancer cells mend their own chromosomes and DNA after damage caused by radiation and chemotherapy.
DNA damage response confers a barrier for viral tumorigenesis
Kaposi’s sarcoma herpesvirus (KSHV) is a human tumor virus and an etiological agent for Kaposi’s sarcoma (KS). KSHV infection is endemic in sub-Saharan Africa where KS is nowadays the most common malignancy, due to widespread infection with KSHV and human immunodeficiency virus (HIV). Importantly, KS also occurs in HIV-negative individuals. Researchers at the University of Helsinki, Finland, have discovered that activation of the DNA damage response in the early stages of KS development functions as an anti-cancer barrier also in virus induced malignancies.
A new century of Alzheimer's disease research
Imagine the day when a routine visit to the family doctor includes a simple blood test to predict the risk for developing Alzheimer’s disease (AD). If the test returns a worrisome result -- too many sticky brain proteins that might begin to gum up memory and thought in 10 to 15 years -- a person could be offered an aspirin-like pill to keep those proteins in check.
Scientists discover role of enzyme in DNA repair
Scientists from the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS), National Cancer Institute (NCI), and Integrative Bioinformatics Inc. have made an important discovery about the role of an enzyme called ataxia telangiectasia mutated protein (ATM) in the body’s ability to repair damaged DNA. NIAMS and NCI are part of the National Institutes of Health (NIH).

New Method Offers Insight into Radiation Damage to DNA

Related stories:

News discussion: