Substrate Electric Dipole Moment Exerts a Ph-Dependent Effect On Electron Transfer in Escherichia Coli Photolyase

Transient absorption spectroscopy is used to demonstrate that the electric dipole moment of the substrate cyclobutane thymine dimer affects the charge recombination reaction between fully reduced flavin adenine dinucleotide (FADH-) and the neutral radical tryptophan 306 (Trp306•) in Escherichia coli DNA photolyase. At pH 7.4, the charge recombination is slowed by a factor of 1.75 in the presence of substrate, but not at pH 5.4. Photolyase does bind substrate at pH 5.4, and it seems that this pH effect originates from the conversion of FADH- to FADH2 at lower pH. The free-energy changes calculated from the electric field parameters and from the change in electron transfer rate are in good agreement and support the idea that the substrate electric dipole is responsible for the observed change in electron transfer rate. It is expected that the substrate electric field will also modify the physiologically important from excited 1FADH- to the substrate in the DNA repair reaction

Binding of Substrate Locks the Electrochemistry of CRY-DASH into DNA Repair

VcCry1, a member of the CRY-DASH family, may serve two diverse roles <i>in vivo</i>, including blue-light signaling and repair of UV-damaged DNA. We have discovered that the electrochemistry of the flavin adenine dinucleotide cofactor of VcCry1 is locked to cycle only between the hydroquinone and neutral semiquinone states when UV-damaged DNA is present. Other potential substrates, including undamaged DNA and ATP, have no discernible effect on the electrochemistry, and the kinetics of the reduction is unaffected by damaged DNA. Binding of the damaged DNA substrate determines the role of the protein and prevents the presumed photochemistry required for blue-light signaling

Evidence from Thermodynamics that DNA Photolyase Recognizes a Solvent-Exposed CPD Lesion

Binding of a <i>cis</i>,<i>syn</i>-cyclobutane pyrimidine dimer (CPD) to <i>Escherichia coli</i> DNA photolyase was examined as a function of temperature, enzyme oxidation state, salt, and substrate conformation using isothermal titration calorimetry. While the overall Δ<i>G</i>° of binding was relatively insensitive to most of the conditions examined, the enthalpic and entropic terms that make up the free energy of binding are sensitive to the conditions of the experiment. Substrate binding to DNA photolyase is generally driven by a negative change in enthalpy. Electrostatic interactions and protonation are affected by the oxidation state of the required FAD cofactor and substrate conformation. The fully reduced enzyme appears to bind approximately two additional water molecules as part of substrate binding. More significantly, the experimental change in heat capacity strongly suggests that the CPD lesion must be flipped out of the intrahelical base stacking prior to binding to the protein; the DNA repair enzyme appears to recognize a solvent-exposed CPD as part of its damage recognition mechanism