Photolyases (PHRs) utilize near-ultraviolet (UV)-blue light to specifically repair the major photoproducts (PPs) of UV-induced damaged DNA. The cyclobutane pyrimidine dimer PHR (CPD-PHR) from Escherichia coli binds flavin adenine dinucleotide (FAD) as a cofactor and 5,10-methenyltetrahydrofolate as a light-harvesting pigment and specifically repairs CPD lesions. By comparison, a second photolyase known as (6-4) PHR, present in a range of higher organisms, uniquely repairs (6-4) PPs. To understand the repair mechanism and the substrate specificity that distinguish CPD-PHR from (6-4) PHR, we applied Fourier transform infrared (FTIR) spectroscopy to bacterial CPD-PHR in the presence or absence of a well-defined DNA substrate, as we have studied previously for vertebrate (6-4) PHR PHRs show light-induced reduction of FAD, and photorepair by CPD-PHR involves the transfer of an electron from the photoexcited reduced FAD to the damaged DNA for cleaving the dimers to maintain the DNA%26apos;s integrity. Here, we measured and analyzed difference FTIR spectra for the photoactivation and DNA photorepair processes of CPD-PHR We identified light-dependent signals only in the presence of substrate. The signals, presumably arising from a protonated carboxylic acid or the DNA substrate, implicate conformational rearrangements of the protein and substrate during the repair process. Deuterium exchange FTIR measurements of CPD-PHR highlight potential differences in the photoactivation and photorepair mechanisms in comparison to those of (6-4) PHR Although CPD-PHR and (6-4) PHR appear to exhibit similar overall structures, our studies indicate that distinct conformational rearrangements, especially in the alpha-helices, are initiated within these enzymes upon binding of their respective DNA substrates.

• 出版日期2013-2-12