Scientists have known for many years that an enzyme called Dam (DNA adenine methyltransferase) plays a role in regulating gene expression in many bacteria. Each time the bacteria reproduce, Dam modifies the A (adenine) nucleotide in the DNA sequence GATC through a chemical reaction known as methylation. Methylation is a biological process used to tag a variety of molecules, including DNA, and is important in cellular processes such as regulating gene expression, DNA replication and repair. In humans DNA methylation occurs on the C (cytosine) rather than the A (adenine) nucleotide.
Recently scientists have discovered a new role for Dam methylation. Dam also is essential for regulating the expression of genes responsible for bacterial virulence. When the gene responsible for Dam is defective, bacteria lose their disease-causing potency. Using the X-ray diffraction facility at the Argonne National Laboratory in Chicago, Xiaodong Cheng, PhD, professor of biochemistry at Emory University School of Medicine and Georgia Research Alliance Eminent Scholar, and John Horton, PhD, Research Assistant Professor, have now solved the co-crystal structure of the Dam enzyme in complex with DNA, which has allowed them to observe exactly how the enzyme finds its target on bacterial DNA.
The Dam enzyme begins by binding non-specifically to DNA, but once it fastens tightly, it glides smoothly down the entire DNA molecule like fingers sliding down a guitar neck searching for the right chord, examining each base pair as it goes. Each time it finds the sequence GATC it stops and methylates the A nucleotide. Dam must move quickly, because if the bacteri
Contact: Holly Korschun
Emory University Health Sciences Center