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Researchers have uncovered a link between motor neurons' inability to repair oxidative genome damage in ALS, suggesting that DNA ligase-targeted therapies may prevent or slowdown disease progression. The defect found was with DNA ligase III, an important enzyme for connecting single-stranded DNA breaks in mature neurons that, once worn out, are no longer capable of new growth or being replenished in the body.
Houston Methodist researchers have discovered a repair defect in nerve cells that send messages to the brain, opening the door to a possible therapy for preventing or slowing down ALS. Also known as Lou Gehrig's disease, ALS is a terminal illness marked by rapidly progressive muscle weakness that ultimately affects a person's ability to swallow and breathe.
Led by Muralidhar Hegde, Ph.D., and Haibo Wang, Ph.D., the team described their findings in an article titled "Mutant FUS causes DNA ligation defects to inhibit oxidative damage repair in Amyotrophic Lateral Sclerosis" in the Sept. 11 issue ofNature Communications. The new pathway they uncovered suggests that a DNA Ligase-targeted therapy may prevent or slowdown disease progression.
The research was funded by the National Institute of Health, the Muscular Dystrophy Association, ALS Association and Houston Methodist Research Institute.
Other researchers collaborating with Hegde and Wang on this paper were Joy Mitra, Pavana Hegde, Bradley Eckelmann and Sankar Mitra from Houston Methodist; Wenting Guo, Tijs Vandoorne and Ludo Van Den Bosch from Leuvan Brain Institute, Belgium; and Alan Tomkinson from University of New Mexico.
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