EC:4.1.99.3 - FACTA Search

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Query: EC:4.1.99.3 (PRE)
1,923 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Pyrimidine dimers are eliminated from DNA by a number of different mechanisms known as DNA repair. Photoreactivation, the reversal of the harmful effects of short wavelength radiation by subsequent exposure to longer wavelengths, is one such mechanism. In photoreactivation, the enzyme DNA photolyase utilises light in order to catalyse the cleavage of the cyclobutane ring of the pyrimidine dimer. The results of recent studies of E. coli DNA photolyase and model systems using techniques such as steady state and flash photolysis, time resolved fluorescence and photo CIDNP are surveyed. A mechanism is proposed for the in vitro reaction of E. coli DNA photolyase which involves photoreduction of the FAD radical cofactor followed by electron donation to the dimer from the excited singlet state of reduced FAD.
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PMID:The photo repair of pyrimidine dimers by DNA photolyase and model systems. 849 39

Animal-type photolyases have very limited sequence homology to microbial-type photolyases. We wanted to find out whether the two types of enzymes have different or similar biochemical and photochemical properties. In particular, the chromophore/cofactor composition of animal photolyases is of special interest since the presence and nature of a second chromophore in these enzymes are not known in contrast to the microbial photolyases which contain FAD cofactor, and folate or deazaflavin as second chromophores. We overproduced the Drosophila melanogaster photolyase in Escherichia coli using the cloned gene. The enzyme contains FAD and folate and thus belongs in the folate class of enzymes but with an action spectrum peak at 420 nm.
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PMID:Purification and characterization of Drosophila melanogaster photolyase. 867 30

Recently, a human cDNA clone with high sequence homology to the photolyase/blue-light photoreceptor family was identified. The putative protein encoded by this gene exhibited a strikingly high (48% identity) degree of homology to the Drosophila melanogaster (6-4) photolyase [Todo et al. (1996) Science 272, 109-112]. We have now identified a second human gene whose amino acid sequence displays 73% identity to the first one and have named the two genes CRY1 and CRY2, respectively. The corresponding proteins hCRY1 and hCRY2 were purified and characterized as maltose-binding fusion proteins. Similar to other members of the photolyase/blue-light photoreceptor family, both proteins were found to contain FAD and a pterin cofactor. Like the plant blue-light photoreceptors, both hCRY1 and hCRY2 lacked photolyase activity on the cyclobutane pyrimidine dimer and the (6-4) photoproduct. We conclude that these newly discovered members of the photolyase/photoreceptor family are not photolyases and instead may function as blue-light photoreceptors in humans.
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PMID:Putative human blue-light photoreceptors hCRY1 and hCRY2 are flavoproteins. 890 83

(6-4)Photolyase catalyzes light-dependent repair of UV-induced pyrimidine (6-4) pyrimidone photoproducts. A human cDNA clone which has high sequence homology to the (6-4)photolyase gene (H64PRH gene) was identified. In this paper we also isolated a genomic clone corresponding to the H64PRH cDNA and mapped it to chromosome 12q24.1 by fluorescence in situ hybridization (FISH). Northern-blot analysis revealed transcription of this gene in all human tissues examined. The H64PRH protein was overproduced in E. coli, partially purified and characterized. Like (6-4)photolyase, the enzyme contains two chromophores, one of which is FAD. However, the enzyme does not show any detectable photolyase activity.
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PMID:Characterization of a human homolog of (6-4) photolyase. 933 Jun 15

The (6-4) photolyase catalyzes the photoreversal of the (6-4) dipyrimidine photoproducts induced in DNA by ultraviolet light. Using the cloned Drosophila melanogaster (6-4) photolyase gene, we overproduced and purified the recombinant enzyme. The binding and catalytic properties of the enzyme were investigated using natural substrates, T[6-4]T and T[6-4]C, and the Dewar isomer of (6-4) photoproduct and substrate analogs s5T[6-4]T/thietane, mes5T[6-4]T, and the N-methyl-3'T thietane analog of the oxetane intermediate. The enzyme binds to the natural substrates and to mes5T[6-4]T with high affinity (KD approximately 10(-9)-10(-10) M) and produces a DNase I footprint of about 20 base pairs around the photolesion. Several lines of evidence suggest that upon binding by the enzyme, the photoproduct flips out of the duplex. Of the four substrates that bind with high affinity to the enzyme, T[6-4]T and T[6-4]C are repaired with relatively high quantum yields compared with the Dewar isomer and the mes5T[6-4]T which are repaired with 300-400-fold lower quantum yield than the former two photoproducts. Reduction of the FAD cofactor with dithionite increases the quantum yield of repair. Taken together, the data are consistent with photoinduced electron transfer from reduced FAD to substrate, in a manner analogous to the cyclobutane pyrimidine dimer photolyase.
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PMID:Reaction mechanism of (6-4) photolyase. 940 73

The major UV-B photoproduct in DNA is the cyclobutane pyrimidine dimer (CPD). CPD-photolyases repair this DNA damage by a light-driven electron transfer. The chromophores of the class II CPD-photolyase from Arabidopsis thaliana, which was cloned recently [Taylor, R., Tobin, A. & Bray, C. (1996) Plant Physiol. 112, 862; Ahmad, M., Jarillo, J.A., Klimczak, L.J., Landry, L.G., Peng, T., Last, R.L. & Cashmore, A.R. (1997) Plant Cell 9, 199-207], have not been characterized so far. Here we report on the overexpression of the Arabidopsis CPD photolyase in Escherichia coli as a 6 x His-tag fusion protein, its purification and the analysis of the chromophore composition and enzymatic activity. Like class I photolyase, the Arabidopsis enzyme contains FAD but a second chromophore was not detectable. Despite the lack of a second chromophore the purified enzyme has photoreactivating activity.
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PMID:Class II DNA photolyase from Arabidopsis thaliana contains FAD as a cofactor. 1044 84

Ultraviolet radiation promotes the formation of a cyclobutane ring between adjacent pyrimidine residues on the same DNA strand to form a pyrimidine dimer. Such dimers may be restored to their monomeric forms through the action of a light-absorbing enzyme named DNA photolyase. The redox-active cofactor involved in the light-induced electron transfer reactions of DNA repair and enzyme photoactivation is a noncovalently bound FAD. In this paper, the FAD cofactor of Escherichia coli DNA photolyase was characterized as the neutral flavin semiquinone by EPR spectroscopy at 9.68 and 94.5 GHz. From the high-frequency/high-field EPR spectrum, the principal values of the axially symmetric g-matrix of FADH(*) were extracted. Both EPR spectra show an emerging hyperfine splitting of 0.85 mT that could be assigned to the isotropic hyperfine coupling constant (hfc) of the proton at N(5). To obtain more information about the electron spin density distribution ENDOR and TRIPLE resonance spectroscopies were applied. All major proton hfc's could be measured and unambiguously assigned to molecular positions at the isoalloxazin moiety of FAD. The isotropic hfc's of the protons at C(8alpha) and C(6) are among the smallest values reported for protein-bound neutral flavin semiquinones so far, suggesting a highly restricted delocalization of the unpaired electron spin on the isoalloxazin moiety. Two further hfc's have been detected and assigned to the inequivalent protons at C(1'). Some conclusions about the geometrical arrangement of the ribityl side chain with respect to the isoalloxazin ring could be drawn: Assuming tetrahedral angles at C(1') the dihedral angle between the C(1')-C(2') bond and the 2p(z)() orbital at N(10) has been estimated to be 170.4 degrees +/- 1 degrees.
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PMID:EPR, ENDOR, and TRIPLE resonance spectroscopy on the neutral flavin radical in Escherichia coli DNA photolyase. 1060 5

Cyclobutane uridine and thymidine dimers with cis-syn-structure are DNA lesions, which are efficiently repaired in many species by DNA photolyases. The essential step of the repair reaction is a light driven electron transfer from a reduced FAD cofactor (FADH ) to the dimer lesion, which splits spontaneously into the monomers. Repair studies with UV-light damaged DNA revealed significant rate differences for the various dimer lesions. In particular the effect of the almost eclipsed positioned methyl groups at the thymidine cyclobutane dimer moiety on the splitting rates is unknown. In order to investigate the cleavage vulnerability of thymine and uracil cyclobutane photodimers outside the protein environment, two model compounds, containing a thymine or a uracil dimer and a covalently connected flavin, were prepared and comparatively investigated. Cleavage investigations under internal competition conditions revealed, in contrast to all previous findings, faster repair of the sterically less encumbered uracil dimer. Stereoelectronic effects are offered as a possible explanation. Ab initio calculations and X-ray crystal structure data reveal a different cyclobutane ring pucker of the uracil dimer, which leads to a better overlap of the pi*-C(4)-O(4)-orbital with the sigma*-C(5)-C(5')-orbital. Enzymatic studies with a DNA photolyase (A. nidulans) and oligonucleotides, which contain either a uridine or a thymidine dimer analogue, showed comparable repair efficiencies for both dimer lesions. Under internal competition conditions significantly faster repair of uridine dimers is observed.
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PMID:A comparative repair study of thymine- and uracil-photodimers with model compounds and a photolyase repair enzyme. 1074 89

Density functional theory is used to calculate the electronic structure of the neutral flavin radical, FADH(*), formed in the light-induced electron-transfer reaction of DNA repair in cis,syn-cyclobutane pyrimidine dimer photolyases. Using the hybrid B3LYP functional together with the double-zeta basis set EPR-II, (1)H, (13)C, (15)N, and (17)O isotropic and anisotropic hyperfine couplings are calculated and explained by reference to the electron densities of the highest occupied molecular orbital and of the unpaired spin distribution on the radical. Comparison of calculated and experimental hyperfine couplings obtained from EPR and ENDOR/TRIPLE resonance leads to a refined structure for the FAD cofactor in Escherichia coli DNA photolyase. Hydrogen bonding at N3H, O4, and N5H results in significant changes in the unpaired spin density distribution and hyperfine coupling constants. The calculated electronic structure of FADH(*) provides evidence for a superexchange-mediated electron transfer between the cyclobutane pyrimidine dimer lesion and the 7,8-dimethyl isoalloxazine moiety of the flavin cofactor via the adenine moiety.
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PMID:The electronic structure of the flavin cofactor in DNA photolyase. 1145 11

DNA photolyase is a flavoprotein that repairs cyclobutylpyrimidine dimers by ultrafast photoinduced electron transfer. One unusual feature of this enzyme is the configuration of the FAD cofactor, where the isoalloxazine and adenine rings are nearly in vdW contact. We have measured the steady-state and transient absorption spectra and excited-state decay kinetics of oxidized (FAD-containing, folate-depleted) Escherichia coli DNA photolyase with and without dinucleotide and polynucleotide single-stranded thymidine dimer substrates. The steady-state absorption spectrum for the enzyme-polynucleotide substrate complex showed a blue shift, as seen previously by Jorns et al. (1). No shift was observed for the dinucleotide substrate, suggesting that there are significant differences in the binding geometry of dinucleotide versus polynucleotide dimer lesions. Evidence was obtained from transient absorption experiments for a long-lived charge-transfer complex involving the isoalloxazine of the FAD cofactor. No evidence of excited-state quenching was measurable upon binding either substrate. To explain these data, we hypothesize the existence of a large substrate electric field in the cavity containing the FAD cofactor. A calculation of the magnitude and direction of this dipolar electric field is consistent with electrochromic band shifts for both S(0) --> S(1) and S(0) --> S(2) transitions. These observations suggest that the substrate dipolar electric field may be a critical component in its electron-transfer-mediated repair by photolyase and that the unique relative orientation of the isoalloxazine and adenine rings may have resulted from the consequences of the dipolar substrate field.
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PMID:Evidence of powerful substrate electric fields in DNA photolyase: implications for thymidine dimer repair. 1173 3

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