Alanine screening mutagenesis establishes the critical inactivating damage of irradiated E. coli lactose repressor.

The function of the E. coli lactose operon requires the binding of lactose repressor to operator DNA. We have previously shown that γ rradiation destabilizes the repressor-operator complex because the repressor loses its DNA-binding ability.

Radiation damage to DNA in DNA-protein complexes.

The most aggressive product of water radiolysis, the hydroxyl (OH) radical, is responsible for the indirect effect of ionizing radiations on DNA in solution and aerobic conditions. According to radiolytic footprinting experiments, the resulting strand breaks and base modifications are inhomogeneously distributed along the DNA molecule irradiated free or bound to ligands (polyamines, thiols, proteins). A Monte-Carlo based model of simulation of the reaction of OH radicals with the macromolecules, called RADACK, allows calculating the relative probability of damage of each nucleotide of DNA irradiated alone or in complexes with proteins.

Comparing native and irradiated E. coli lactose repressor-operator complex by molecular dynamics simulation.

The function of the E. coli lactose operon requires the binding of the tetrameric repressor protein to the operator DNA. We have previously shown that gamma-irradiation destabilises the repressor-operator complex because the repressor gradually loses its DNA-binding ability (Radiat Res 170:604-612, 2008).

Radiation damage to a DNA-binding protein. Combined circular dichroism and molecular dynamics simulation analysis.

The E. coli lactose operon, the paradigm of gene expression regulation systems, is the best model for studying the effect of radiation on such systems. The operon function requires the binding of a protein, the repressor, to a specific DNA sequence, the operator.