Molecular characterization of Escherichia coli FtsE and FtsX

The genes ftsE and ftsX are organized in one operon together with ftsY. FtsY codes for the receptor of the signal recognition particle (SRP) that functions in targeting a subset of inner membrane proteins. We have found no indications for a structural relationship between FtsE/X and FtsY. Evidence is presented that FtsE and FtsX form a complex in the inner membrane that bears the characteristics of an ATP-binding cassette (ABC)-type transporter. FtsE is a hydrophilic nucleotide-binding protein that has a tendency to dimerize and associates with the inner membrane through an interaction with the integral membrane protein FtsX. An FtsE null mutant showed filamentous growth and appeared viable on high salt medium only, indicating a role for FtsE in cell division and/or salt transport.

TATA-binding protein promotes the selective formation of UV-induced (6-4)-photoproducts and modulates DNA repair in the TATA box

DNA-damage formation and repair are coupled to the structure and accessibility of DNA in chromatin. DNA damage may compromise protein binding, thereby affecting function. We have studied the effect of TATA-binding protein (TBP) on damage formation by ultraviolet light and on DNA repair by photolyase and nucleotide excision repair in yeast and in vitro. In vivo, selective and enhanced formation of (6-4)-photoproducts (6-4PPs) was found within the TATA boxes of the active SNR6 and GAL10 genes, engaged in transcription initiation by RNA polymerase III and RNA polymerase II, respectively. Cyclobutane pyrimidine dimers (CPDs) were generated at the edge and outside of the TATA boxes, and in the inactive promoters. The same selective and enhanced 6-4PP formation was observed in a TBP-TATA complex in vitro at sites where crystal structures revealed bent DNA. We conclude that similar DNA distortions occur in vivo when TBP is part of the initiation complexes. Repair analysis by photolyase revealed inhibition of CPD repair at the edge of the TATA box in the active SNR6 promoter in vitro, but not in the GAL10 TATA box or in the inactive SNR6 promoter. Nucleotide excision repair was not inhibited, but preferentially repaired the 6-4PPs. We conclude that TBP can remain bound to damaged promoters and that nucleotide excision repair is the predominant pathway to remove UV damage in active TATA boxes.

Sequence and time-dependent deamination of cytosine bases in UVB-induced cyclobutane pyrimidine dimers in vivo

The mutational specificity of UV-light is characterized by an abundance of C to T transition mutations at dipyrimidines containing cytosine or 5-methylcytosine. A significant percentage of these mutations are CC to TT double transitions. Of the major types of UV-induced DNA lesions, the cis-syn cyclobutane pyrimidine dimers (CPDs) are thought to be the most mutagenic lesions, at least in mammalian cells. It has been proposed that the CPDs become mutagenic perhaps only after cytosine bases within these dimers deaminate to uracil and the resulting U-containing photolesions are correctly bypassed by DNA polymerases. In order to assess the significance of this proposed mutagenic mechanism, we have developed two methods to specifically measure deaminated CPDs in UV-irradiated human cells or DNA. The first method is based on enzymatic photoreversal of CPDs, followed by cleavage of the DNA with uracil DNA glycosylase, an AP lyase activity, and ligation-mediated PCR to map the resulting strand breaks. The second method, which can be used to detect double deamination events (CC to UU), is PCR amplification of photolyase-treated DNA using primers complemetary to the deaminated sequences. We have measured deamination events in the human p53 gene, which contains a large percentage of C to T transitions in skin cancers. The deamination reactions are specific for cytosine within CPDs, are negligible immediately after irradiation, and are time-dependent and DNA sequence context-dependent. Twenty four hours after irradiation of human fibroblasts with UVB light, between 10 and 60% of most CPD signals are converted to the deaminated form, depending on the sequence. Significant deamination occurs at skin cancer mutation sites in the p53 gene. Double deamination also occurs and this reaction can involve dimers containing 5-methylcytosine or cytosine. These double events are expected to occur more frequently in cells with a DNA repair defect because there is more time for deamination in unrepaired lesions. This may explain the relatively high frequency of CC to TT mutations in skin cancers from xeroderma pigmentosum patients. In summary, these novel detection techniques demonstrate that deamination of cytosine in pyrimidine dimers is a significant event that most likely contributes to the mutational specificity of UVB irradiation in human cells.

Characterization of photolyase/blue-light receptor homologs in mouse and human cells

We isolated and characterized mouse photolyase-like genes, mCRY1 (mPHLL1) and mCRY2 (mPHLL2), which belong to the photolyase family including plant blue-light receptors. The mCRY1 and mCRY2 genes are located on chromosome 10C and 2E, respectively, and are expressed in all mouse organs examined. We raised antibodies specific against each gene product using its C-terminal sequence, which differs completely between the genes. Immunofluorescent staining of cultured mouse cells revealed that mCRY1 is localized in mitochondria whereas mCRY2 was found mainly in the nucleus. The subcellular distribution of CRY proteins was confirmed by immunoblot analysis of fractionated mouse liver cell extracts. Using green fluorescent protein fused peptides we showed that the C-terminal region of the mouse CRY2 protein contains a unique nuclear localization signal, which is absent in the CRY1 protein. The N-terminal region of CRY1 was shown to contain the mitochondrial transport signal. Recombinant as well as native CRY1 proteins from mouse and human cells showed a tight binding activity to DNA Sepharose, while CRY2 protein did not bind to DNA Sepharose at all under the same condition as CRY1. The different cellular localization and DNA binding properties of the mammalian photolyase homologs suggest that despite the similarity in the sequence the two proteins have distinct function(s).

Enzymatic reaction with unnatural substrates: DNA photolyase (Escherichia coli) recognizes and reverses thymine [2+2] dimers in the DNA strand of a DNA/PNA hybrid duplex

Peptide nucleic acids (PNA) are mimics with normal bases connected to a pseudopeptide chain that obey Watson-Crick rules to form stable duplexes with itself and natural nucleic acids. This has focused attention on PNA as therapeutic or diagnostic reagents. Duplexes formed with PNA mirror some but not all properties of DNA. One fascinating aspect of PNA biochemistry is their reaction with enzymes. Here we show an enzyme reaction that operates effectively on a PNA/DNA hybrid duplex. A DNA oligonucleotide containing a cis, syn-thymine [2+2] dimer forms a stable duplex with PNA. The hybrid duplex is recognized by photolyase, and irradiation of the complex leads to the repair of the thymine dimer. This finding provides insight into the enzyme mechanism and provides a means for the selective repair of thymine photodimers.

Evasion of UVC-induced apoptosis by photorepair of cyclobutane pyrimidine dimers

Cyclobutyl pyrimidine dimer (CPD) photolyase is known to reverse pyrimidine dimers specifically under illumination with visible light. OCP13, a Medaka cell line showing a high level expression of the gene for CPD photolyase, completely reversed pyrimidine dimers induced by 20 J/m2 UVC by 1 h of photorepair. When OCP13 cells were irradiated with 20 J/m2 UVC, morphological changes such as shrinkage of cells, distorted nuclear shape, and decrease in the number of nucleoli appeared 2 to 4 h after UVC irradiation. Thereafter, the irradiated cells began to detach from the substratum, and DNA ladders were observed in the DNA extracted from detached cells. Thus, these changes in cells after UVC exposure were used to characterize the progression of UV-induced apoptosis in OCP13 cells. Although formation of DNA ladders and cell detachment were blocked by cycloheximide treatment prior to UVC exposure, the morphological changes were not. With photorepair treatment, even after the morphological changes appeared cells were still able to restore their normal morphological features and remained attached. On the other hand, the cell-cycle progression in UVC-irradiated cells was arrested even after photorepair of pyrimidine dimers. Thus, photorepair can rescue cells from UV-induced apoptosis, although DNA damage other than that of pyrimidine dimers, as well as additional non-DNA damage, possibly remained, and DNA replication was left inhibited. Among the various kinds of damage induced by UVC irradiation, the presence of pyrimidine dimers is proposed to be the major trigger for UVC-induced apoptosis.

(6-4) photolyase: light-dependent repair of DNA damage

DNA photolyase represents a phenomenal class of DNA repair enzymes in that it harvests the light energy to repair DNA lesions caused by ultraviolet light. Mother Nature evolves two types of photolyases, one specific for repairing cyclobutane pyrimidine dimers and the other for pyrimidine-(6-4)-pyrimidone photoproducts. Together, these two kinds of DNA photolesions account for the majority of ultraviolet light-induced DNA lesions. So far, the basic chemical steps of the enzyme mechanism of the two classes of photolyases appear to be very similar. Therefore, it will be very interesting to uncover the determinants of the different substrate specificity between the two photolyases. In this review, we focus on the discussion of the photolyase specific for repairing pyrimidine-(6-4)-pyrimidone photoproducts mainly because the research of the cyclobutane pyrimidine dimer photolyase has recently been reviewed quite extensively.

Detection of thymine [2+2] photodimer repair in DNA: selective reaction of KMnO4

The specific reaction of potassium permanganate with thymine in single-stranded DNA was employed to analyze thymine [2+2] dimer repair in DNA and in DNA/peptide nucleic acid hybrid duplexes. This simple and highly sensitive chemical assay is convenient for monitoring repair of thymine dimers in oligonucleotides.

Spore photoproduct lyase from Bacillus subtilis spores is a novel iron-sulfur DNA repair enzyme which shares features with proteins such as class III anaerobic ribonucleotide reductases and pyruvate-formate lyases

The major photoproduct in UV-irradiated spore DNA is the unique thymine dimer 5-thyminyl-5,6-dihydrothymine, commonly referred to as spore photoproduct (SP). An important determinant of the high UV resistance of Bacillus subtilis spores is the accurate in situ reversal of SP during spore germination by the DNA repair enzyme SP lyase. To study the molecular aspects of SP lyase-mediated SP repair, the cloned B. subtilis splB gene was engineered to encode SP lyase with a molecular tag of six histidine residues at its amino terminus. The engineered six-His-tagged SP lyase expressed from the amyE locus restored UV resistance to spores of a UV-sensitive mutant B. subtilis strain carrying a deletion-insertion mutation which removed the entire splAB operon at its natural locus and was shown to repair SP in vivo during spore germination. The engineered SP lyase was purified both from dormant B. subtilis spores and from an Escherichia coli overexpression system by nickel-nitrilotriacetic acid (NTA) agarose affinity chromatography and was shown by Western blotting, UV-visible spectroscopy, and iron and acid-labile sulfide analysis to be a 41-kDa iron-sulfur (Fe-S) protein, consistent with its amino acid sequence homology to the 4Fe-4S clusters in anaerobic ribonucleotide reductases and pyruvate-formate lyases. SP lyase was capable of reversing SP from purified SP-containing DNA in an in vitro reaction either when present in a cell-free extract prepared from dormant spores or after purification on nickel-NTA agarose. SP lyase activity was dependent upon reducing conditions and addition of S-adenosylmethionine as a cofactor.

Direct visualization of dynamic protein-DNA interactions with a dedicated atomic force microscope

Photolyase DNA interactions and the annealing of restriction fragment ends are directly visualized with the atomic force microscope (AFM). To be able to interact with proteins, DNA must be loosely bound to the surface. When MgCl2 is used to immobilize DNA to mica, DNA is attached to the surface at distinct sites. The pieces of DNA in between are free to move over the surface and are available for protein interaction. After implementation of a number of instrumental improvements, the molecules can be visualized routinely, under physiological conditions and with molecular resolution. Images are acquired reproducibly without visible damage for at least 30 min, at a scan rate of 2 x 2 microm2/min and a root mean square noise of less than 0.2 nm. Nonspecific photolyase DNA complexes were visualized, showing association, dissociation, and movement of photolyase over the DNA. The latter result suggests a sliding mechanism by which photolyase can scan DNA for damaged sites. The experiments illustrate the potential that AFM presents for modern molecular biology.

Impairment of nucleotide excision repair by apoptosis in UV-irradiated mouse cells

We investigated the relationship between nucleotide excision repair (NER) activity and apoptosis in UV-irradiated cells. Mouse erythroleukemia (MEL) and lymphoma (GRSL) cells exhibited enhanced sensitivity to the cytotoxic effects of UV radiation compared to hamster cell lines, although normal UV-induced hprt mutation frequencies were found. Determination of UV-induced repair replication revealed a limited capacity of MEL and GRSL cells to perform NER consistent with poor removal of cyclobutane pyrimidine dimers and pyrimidine 6-4 pyrimidone photoproducts from transcriptionally active genes during the first 8 h after UV exposure. However, both cyclobutane pyrimidine dimers and pyrimidine 6-4 pyrimidone photoproducts appeared to be processed to almost normal level 24 h after UV treatment. In parallel, we observed that the UV-irradiated MEL and GRSL cells suffered from severe DNA fragmentation particularly 24 h after UV exposure. Taken together, these data indicate a reduced repair of UV-induced photolesions in apoptotic cells, already established at the early onset of apoptosis. To test whether inhibition of repair in cells was due to inactivation of NER or to apoptosis-induced chromatin degradation, we performed in vitro excision assays using extracts from UV-irradiated MEL cells. These experiments showed that the NER capacity during early apoptosis was intact, indicating that slow removal of UV-induced photolesions in apoptotic cells is due to substrate modification (presumably degradation of chromatin) rather than direct inhibition of factors involved in NER.

Site-specific repair of cyclobutane pyrimidine dimers in a positioned nucleosome by photolyase and T4 endonuclease V in vitro

Since genomic DNA is folded into nucleosomes, and DNA damage is generated all over the genome, a central question is how DNA repair enzymes access DNA lesions and how they cope with nucleosomes. To investigate this topic, we used a reconstituted nucleosome (HISAT nucleosome) as a substrate to generate DNA lesions by UV light (cyclobutane pyrimidine dimers, CPDs), and DNA photolyase and T4 endonuclease V (T4-endoV) as repair enzymes. The HISAT nucleosome is positioned precisely and contains a long polypyrimidine region which allows one to monitor formation and repair of CPDs over three helical turns. Repair by photolyase and T4-endoV was inefficient in nucleosomes compared with repair in naked DNA. However, both enzymes showed a pronounced site-specific modulation of repair on the nucleosome surface. Removal of the histone tails did not substantially enhance repair efficiency nor alter the site specificity of repair. Although photolyase and T4-endoV are different enzymes with different mechanisms, they exhibited a similar site specificity in nucleosomes. This implies that the nucleosome structure has a decisive role in DNA repair by exerting a strong constraint on damage accessibility. These findings may serve as a model for damage recognition and repair by more complex repair mechanisms in chromatin.

Binding and catalytic properties of Xenopus (6-4) photolyase

Xenopus (6-4) photolyase binds with high affinity to DNA bearing a (6-4) photoproduct and repairs it in a light-dependent reaction. To clarify its repair mechanism of (6-4) photolyase, we determined its binding and catalytic properties using synthetic DNA substrate which carries a photoproduct at a single location. The (6-4) photolyase binds to T[6-4]T in double-stranded DNA with high affinity (KD = 10(-9)) and to T[6-4]T in single-stranded DNA and T[Dewar]T in double- and single-stranded DNA although with slightly lower affinity (KD = approximately 2 x 10(-8)). Majority of the T[6-4]T-(6-4) photolyase complex dissociates very slowly (koff = 2.9 x 10(-5) s-1). Its absolute action spectrum without a second chromophore in the 350-600 nm region closely matches the absorption spectrum of the enzyme. The quantum yield (phi) of repair is approximately 0.11. The fully reduced form (E-FADH-) of (6-4) photolyase is catalytically active. Direct analysis of the photoreactivated product showed that (6-4) photolyase restores the original pyrimidines. These findings demonstrate that cis, syn-cyclobutane pyrimidine dimer photolyase and (6-4) photolyase are quite similar, but they are different with regard to the binding properties.

Reaction mechanism of (6-4) photolyase

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.

Ambient UV-B radiation causes deformities in amphibian embryos

There has been a great deal of recent attention on the suspected increase in amphibian deformities. However, most reports of amphibian deformities have been anecdotal, and no experiments in the field under natural conditions have been performed to investigate this phenomenon. Under laboratory conditions, a variety of agents can induce deformities in amphibians. We investigated one of these agents, UV-B radiation, in field experiments, as a cause for amphibian deformities. We monitored hatching success and development in long-toed salamanders under UV-B shields and in regimes that allowed UV-B radiation. Embryos under UV-B shields had a significantly higher hatching rate and fewer deformities, and developed more quickly than those exposed to UV-B. Deformities may contribute directly to embryo mortality, and they may affect an individual's subsequent survival after hatching.

Anti-mutagenic activity of DNA damage-binding proteins mediated by direct inhibition of translesion replication

DNA lesions that block replication can be bypassed in Escherichia coli by a special DNA synthesis process termed translesion replication. This process is mutagenic due to the miscoding nature of the DNA lesions. We report that the repair enzyme formamido-pyrimidine DNA glycosylase and the general DNA damage recognition protein UvrA each inhibit specifically translesion replication through an abasic site analog by purified DNA polymerases I and II, and DNA polymerase III (alpha subunit) from E. coli. In vivo experiments suggest that a similar inhibitory mechanism prevents at least 70% of the mutations caused by ultraviolet light DNA lesions in E. coli. These results suggest that DNA damage-binding proteins regulate mutagenesis by a novel mechanism that involves direct inhibition of translesion replication. This mechanism provides anti-mutagenic defense against DNA lesions that have escaped DNA repair.

Non-mutagenic repair of (6-4)photoproducts by (6-4)photolyase purified from Drosophila melanogaster

The (6-4)photoproduct DNA photolyase ((6-4)photolyase) repairs UV-induced pyrimidine (6-4) pyrimidone photoproduct ((6-4)photoproduct, pyr[6,4]pyr) in a light dependent manner. Drosophila (6-4)photolyase was purified to near homogeneity from Drosophila embryonic cells and is shown to be a 62 kDa protein as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified (6-4)photolyase repairs (6-4)photoproducts induced at 5'-CC-3' site (C[6,4]C) as well as T[6,4]T and T[6,4]C. Photoreactivation of (6-4)photoproduct constructed in M13 phage eliminates the replication block and abolishes induced mutagenesis in E. coli cells, suggesting that the (6-4)photolyase repairs the photoproduct to the unmodified form.

Characterization of a thermostable DNA photolyase from an extremely thermophilic bacterium, Thermus thermophilus HB27

The photolyase gene from Thermus thermophilus was cloned and sequenced. The characteristic absorption and fluorescence spectra of the purified T. thermophilus photolyase suggested that the protein has flavin adenine dinucleotide as a chromophore. The second chromophore binding site was not conserved in T. thermophilus photolyase. The purified enzyme showed light-dependent photoreactivation activity in vitro at 35 and 65 degrees C and was stable when subjected to heat and acidic pH.

RNA polymerase II transcription inhibits DNA repair by photolyase in the transcribed strand of active yeast genes

Yeast uses nucleotide excision repair (NER) and photolyase (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs) generated by ultraviolet light. In active genes, NER preferentially repairs the transcribed strand (TS). In contrast, we recently showed that photolyase preferentially repairs the non-transcribed strands (NTS) of the URA3 and HIS3 genes in minichromosomes. To test whether photoreactivation depends on transcription, repair of CPDs was investigated in the transcriptionally regulated GAL10 gene in a yeast strain deficient in NER [AMY3 (rad1Delta)]. In the active gene (cells grown in galactose), photoreactivation was fast in the NTS and slow in the TS demonstrating preferential repair of the NTS. In the inactive gene (cells grown in glucose), both strands were repaired at similar rates. This suggests that RNA polymerases II blocked at CPDs inhibit accessibility of CPDs to photolyase. In a strain in which both pathways are operational [W303-1a (RAD1)], no strand bias was observed either in the active or inactive gene, demonstrating that photoreactivation of the NTS compensates preferential repair of the TS by NER. Moreover, repair of the NTS was more quickly in the active gene than in the repressed gene indicating that transcription dependent disruption of chromatin facilitates repair of an active gene.

Analysis of spore photoproduct lyase operon (splAB) function using targeted deletion-insertion mutations spanning the Bacillus subtilis operons ptsHI and splAB

Germinating Bacillus subtilis spores repair UV-induced DNA damage in part using the enzyme spore photoproduct (SP) lyase. SP lyase is encoded by splB, the second cistron of the splAB operon. The splAB operon is transcribed during sporulation from the P1 promoter, which partially overlaps the transcriptional terminator of the upstream ptsHI operon, which in turn encodes the Hpr protein and Enzyme I components of the PEP:sugar phosphotransferase (PTS) system. In order to determine the physical and functional boundaries of these contiguous operons, null mutations were generated in the region by in vitro site-directed mutagenesis, in which parts of the cloned ptsI-splAB region were removed and replaced with an ermC antibiotic resistance cassette, then introduced by transformation into B. subtilis. A deletion-insertion spanning ptsI, splA, and splB abolished the ability of the resulting mutant to utilize the PTS sugar glucose. Deletions removing either splB alone or both splA and splB did not affect glucose utilization, thus indicating that splAB gene products are not involved in PTS function. A complementation system was developed using the deletion-insertion mutant lacking splAB which allows placement of alleles of the cloned splAB operon at the chromosomal amyE locus. The complementation system was used to explore the role of SP lyase in determining spore UV resistance.

Photorepair mutants of Arabidopsis

UV radiation induces two major DNA damage products, the cyclobutane pyrimidine dimer (CPD) and, at a lower frequency, the pyrimidine (6-4) pyrimidinone dimer (6-4 product). Although Escherichia coli and Saccharomyes cerevisiae produce a CPD-specific photolyase that eliminates only this class of dimer, Arabidopsis thaliana, Drosphila melanogaster, Crotalus atrox, and Xenopus laevis have recently been shown to photoreactivate both CPDs and 6-4 products. We describe the isolation and characterization of two new classes of mutants of Arabidopsis, termed uvr2 and uvr3, that are defective in the photoreactivation of CPDs and 6-4 products, respectively. We demonstrate that the CPD photolyase mutation is genetically linked to a DNA sequence encoding a type II (metazoan) CPD photolyase. In addition, we are able to generate plants in which only CPDs or 6-4 products are photoreactivated in the nuclear genome by exposing these mutants to UV light and then allowing them to repair one or the other class of dimers. This provides us with a unique opportunity to study the biological consequences of each of these two major UV-induced photoproducts in an intact living system.

Photoreactivating enzyme for (6-4) photoproducts in cultured goldfish cells

We previously reported that when cultured goldfish cells are illuminated with fluorescent light, photorepair ability for both cyclobutane pyrimidine dimers and (6-4) photoproducts increased. In the present study, it was found that the duration of the induced photorepair ability for cyclobutane pyrimidine dimers was longer than that for (6-4) photoproducts, suggesting the presence of different photolyases for repair of these two major forms of DNA damage. A gel shift assay was then performed to show the presence of protein(s) binding to (6-4) photoproducts and its dissociation from (6-4) photoproducts under fluorescent light illumination. In addition, at 8 h after fluorescent light illumination of the cell, the binding of protein(s) to (6-4) photoproducts increased. The restriction enzymes that have recognition sites containing TT or TC sequences failed to digest the UV-irradiated DNA photoreactivated by using Escherichia coli photolyase for cyclobutane pyrimidine dimers, indicating that restriction enzymes could not function because (6-4) photoproducts remained in recognition sites. But, when UV-irradiated DNA depleted of cyclobutane pyrimidine dimers was incubated with extract of cultured goldfish cells under fluorescent light illumination, it was digested with those restriction enzymes. These results suggested the presence of (6-4) photolyase in cultured goldfish cells as in Drosophila, Xenopus and Crotalus.

Comparative action spectrum for ultraviolet light killing of mouse melanocytes from different genetic coat color backgrounds

The photobiology of mouse melanocyte lines with different pigment genotypes was studied by measuring colony-forming ability after irradiation. The cell lines were wild-type black (melan-a) and the mutants brown (melan-b) and albino (melan-c). Four lamps emitting various UV wavelengths were used. These were germicidal (UVC, 200-280 nm), 82.3% output at 254 nm, TL01 (UVB, 280-320 nm), 64.2% at 310-311 nm, FS20, broadband with peak output at 312 nm and Alisun-S (UVA, 320-400 nm), broadband with peak output at 350-354 nm. Appropriate filtration reduced the contaminating UVC to nonlethal levels for the longer waverange lamps. Wild-type melan-a was resistant to UVC and UVA compared to the other two cell lines, but the differences were small. The melan-c cell line was more resistant to UVB and markedly more resistant to FS20 than the pigmented lines. With the exception of FS20 responses, melan-b was more sensitive than melan-a to killing by the various UV lamps. There were more pyrimidine dimers (cyclobutane dimers and 6-4 photoproducts) produced in melan-a than in melan-c cells by UVC, UVB and FS20 lamps. Unlike melan-c, melan-a and melan-b showed a strong free radical signal of melanin character with a detectable contribution of pheomelanin-like centers. The contribution of pheomelanin was higher in melan-b than in melan-a, while the total melanin content in these two cell lines was comparable. The abundant melanin granules of wild-type melan-a melanocytes were well melanized and ellipsoidal, whereas those of melan-b melanocytes tended to be spherical. In the albino line (melan-c) the melanocytes contained only early-stage melanosomes, all of which were devoid of melanin. The results indicate that pigment does not protect against direct effect DNA damage in the form of pyrimidine dimers nor does it necessarily protect against cell death. High pigment content is not very protective against killing by UVC and UVA, and it may photosensitize in UVB the very wavelength range that is of greatest concern with respect to the rising incidence in skin cancer, especially melanoma. It is clear from these studies that, in pigment cells, monochromatic results cannot predict polychromatic responses and that cell death from solar irradiations is a complex phenomenon that depends on more than DNA damage.

Chromatin structure modulates DNA repair by photolyase in vivo

Yeast and many other organisms use nucleotide excision repair (NER) and photolyase in the presence of light (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs), a major class of DNA lesions generated by UV light. To study the role of photoreactivation at the chromatin level in vivo, we used yeast strains which contained minichromosomes (YRpTRURAP, YRpCS1) with well-characterized chromatin structures. The strains were either proficient (RAD1) or deficient (rad1 delta) in NER. In contrast to NER, photolyase rapidly repairs CPDs in non-nucleosomal regions, including promoters of active genes (URA3, HIS3, DED1) and in linker DNA between nucleosomes. CPDs in nucleosomes are much more resistant to photoreactivation. These results demonstrate a direct role of chromatin in modulation of a DNA repair process and an important role of photolyase in repair of damaged promoters with presumptive effects on gene regulation. In addition, photoreactivation provides an in vivo test for chromatin structure and stability. In active genes (URA3, HIS3), photolyase repairs the non-transcribed strand faster than the transcribed strand and can match fast removal of lesions from the transcribed strand by NER (transcription-coupled repair). Thus, the combination of both repair pathways ensures efficient repair of active genes.

Solar UVB-induced DNA damage and photoenzymatic DNA repair in antarctic zooplankton

The detrimental effects of elevated intensities of mid-UV radiation (UVB), a result of stratospheric ozone depletion during the austral spring, on the primary producers of the Antarctic marine ecosystem have been well documented. Here we report that natural populations of Antarctic zooplankton also sustain significant DNA damage [measured as cyclobutane pyrimidine dimers (CPDs)] during periods of increased UVB flux. This is the first direct evidence that increased solar UVB may result in damage to marine organisms other than primary producers in Antarctica. The extent of DNA damage in pelagic icefish eggs correlated with daily incident UVB irradiance, reflecting the difference between acquisition and repair of CPDs. Patterns of DNA damage in fish larvae did not correlate with daily UVB flux, possibly due to different depth distributions and/or different capacities for DNA repair. Clearance of CPDs by Antarctic fish and krill was mediated primarily by the photoenzymatic repair system. Although repair rates were large for all species evaluated, they were apparently inadequate to prevent the transient accumulation of substantial CPD burdens. The capacity for DNA repair in Antarctic organisms was highest in those species whose early life history stages occupy the water column during periods of ozone depletion (austral spring) and lowest in fish species whose eggs and larvae are abundant during winter. Although the potential reduction in fitness of Antarctic zooplankton resulting from DNA damage is unknown, we suggest that increased solar UV may reduce recruitment and adversely affect trophic transfer of productivity by affecting heterotrophic species as well as primary producers.

Flavin adenine dinucleotide as a chromophore of the Xenopus (6-4)photolyase

Two types of enzyme utilizing light from the blue and near-UV spectral range (320-520 nm) are known to have related primary structures: DNA photolyase, which repairs UV-induced DNA damage in a light-dependent manner, and the blue light photoreceptor of plants, which mediates light-dependent regulation of seedling development. Cyclobutane pyrimidine dimers (CPDs) and pyrimidine (6-4) pyrimidone photoproducts [(6-4)photoproducts] are the two major photoproducts produced in DNA by UV irradiation. Two types of photolyases have been identified, one specific for CPDs (CPD photolyase) and another specific for (6-4)photoproducts [(6-4)photolyase]. (6-4)Photolyase activity was first found in Drosophila melanogaster and to date this gene has been cloned only from this organism. The deduced amino acid sequence of the cloned gene shows that (6-4)photolyase is a member of the CPD photolyase/blue light photoreceptor family. Both CPD photolyase and blue light photoreceptor are flavoproteins and bound flavin adenine dinucleotides (FADs) are essential for their catalytic activity. Here we report isolation of a Xenopus laevis(6-4)photolyase gene and show that the (6-4)photolyase binds non- covalently to stoichiometric amounts of FAD. This is the first indication of FAD as the chromophore of (6-4)photolyase.

An enzyme similar to animal type II photolyases mediates photoreactivation in Arabidopsis

The important issue of photoreactivation DNA repair in plants has become even more interesting in recent years because a family of genes that are highly homologous to photoreactivating DNA repair enzymes but that function as blue light photoreceptors has been isolated. Here, we report the isolation of a novel photolyase-like sequence from Arabidopsis designated PHR1 (for photoreactivating enzyme). It shares little sequence similarity with either type I photolyases or the cryptochrome family of blue light photoreceptors. Instead, the PHR1 gene encodes an amino acid sequence with significant homology to the recently characterized type II photolyases identified in a number of prokaryotic and animal systems. PHR1 is a single-copy gene and is not expressed in dark-grown etiolated seedlings: the message is light inducible, which is similar to the expression profile for photoreactivation activity in plants. The PHR1 protein complements a photolyase-deficient mutant of Escherichia coli and thus confers photoreactivation activity. In addition, an Arabidopsis mutant that is entirely lacking in photolyase activity has been found to contain a lesion within this Arabidopsis type II photolyase sequence. We conclude that PHR1 represents a genuine plant photolyase gene and that the plant genes with homology to type I photolyases (the cryptochrome family of blue light photoreceptors) do not contribute to photoreactivation repair, at least in the case of Arabidopsis.

DNA repair functions in heterologous cells

Our genetic information is constantly challenged by exposure to endogenous and exogenous DNA-damaging agents, by DNA polymerase errors, and thereby inherent instability of the DNA molecule itself. The integrity of our genetic information is maintained by numerous DNA repair pathways, and the importance of these pathways is underscored by their remarkable structural and functional conservation across the evolutionary spectrum. Because of the highly conserved nature of DNA repair, the enzymes involved in this crucial function are often able to function in heterologous cells; as an example, the E. coli Ada DNA repair methyltransferase functions efficiently in yeast, in cultured rodent and human cells, in transgenic mice, and in ex vivo-modified mouse bone marrow cells. The heterologous expression of DNA repair functions has not only been used as a powerful cloning strategy, but also for the exploration of the biological and biochemical features of numerous enzymes involved in DNA repair pathways. In this review we highlight examples where the expression of DNA repair enzymes in heterologous cells was used to address fundamental questions about DNA repair processes in many different organisms.

Developmental responses of amphibians to solar and artificial UVB sources: a comparative study

Many amphibian species, in widely scattered locations, currently show population declines and/or reductions in range, but other amphibian species show no such declines. There is no known single cause for these declines. Differential sensitivity to UVB radiation among species might be one contributing factor. We have focused on amphibian eggs, potentially the most UVB-sensitive stage, and compared their resistance to UVB components of sunlight with their levels of photolyase, typically the most important enzyme for repair of the major UV photoproducts in DNA, cyclobutane pyrimidine dimers. Photolyase varied 100-fold among eggs/oocytes of 10 species. Among three species-Hyla regilla, Rana cascadae, and Bufo boreas-for which resistance of eggs to solar UVB irradiance in their natural locations was measured, hatching success correlated strongly with photolyase. Two additional species, Rana aurora and Ambystoma gracile, now show similar correlations. Among the low-egg-photolyase species, R. cascadae and B. boreas are showing declines, and the status of A. gracile is not known. Of the two high-photolyase species, populations of H. regilla remain robust, but populations of R. aurora are showing declines. To determine whether levels of photolyase or other repair activities are affected by solar exposures during amphibian development, we have initiated an extended study of H. regilla and R. cascadae, and of Xenopus laevis, laboratory-reared specimens of which previously showed very low photolyase levels. Hyla regilla and R. cascadae tadpoles are being reared to maturity in laboratories supplemented with modest levels of UV light or light filtered to remove UVB wavelengths. Young X. laevis females are being reared indoors and outdoors. Initial observations reveal severe effects of both UVA and UVB light on H. regilla and R. cascadae tadpoles and metamorphs, including developmental abnormalities and high mortalities. Assays of photolyase levels in the skins of young animals roughly parallel previous egg/oocyte photolyase measurements for all three species.

Accelerated deamination of cytosine residues in UV-induced cyclobutane pyrimidine dimers leads to CC-->TT transitions

The rate of UV-induced deamination of cytosine to uracil at a specific site in double-stranded (ds) DNA was monitored using a genetic reversion assay. M13mp2C141 ds DNA was exposed to 160 J/m2 UV (254 nm), incubated at 37 degrees C, pH 7.4, for various time intervals to allow for deamination, and treated with Escherichia coli photolyase in the presence of 365 nm light to reverse cyclobutane-type pyrimidine dimers. Upon transfection into uracil-glycosylase deficient (ung-) E. coli cells, the mutation (i.e., reversion) frequencies in the CCCC target sequence increased greatly with post-UV time of incubation at 37 degrees C, nearly doubling every day that the DNA had been held at 37 degrees C. After 8 days, the reversion frequencies had increased by two orders of magnitude upon transfection into ung- cells, relative to isogenic ung+ cells, indicating that most of the mutations arising in UV/photolyase-treated ds DNA were C-->T mutations mediated by a uracil intermediate. Sequencing of the revertants revealed that all mutations were single C-->T or tandem double CC-->TT mutations. An increasing percentage of tandem double CC-->TT mutations was found with longer post-UV incubation times, yet none occurred if the post-UV delay time step was omitted before photoreversal. After a 4-day delay between UV and photoreversal at 37 degrees C, greater than 84% of the total revertants had tandem double CC-->TT mutations. Thus, the generation of a tandem double mutation is a time-dependent process that arises in DNA after the initial UV exposure. The rate of appearance (with a pseudo-first-order rate constant ca. 10(-6) s-1) of tandem double mutations during incubation of UV-irradiated DNA is inconsistent with two random, independently occurring mutational events and suggests a concerted deamination of both residues in a tandem cytosine pyrimidine (C < > C) dimer. Considering that deamination in a C < > C dimer occurred here with a half-life of ca. 5 days, in contrast to the measured half-life of ca. 20,000 years for spontaneous (non-UV-treated) cytosine deamination for the same target, these studies show that the formation of pyrimidine dimers in DNA increases the rate of deamination by six orders of magnitude, leading to the accelerated formation of single C-->T and tandem double CC-->TT mutations.

The two major spore DNA repair pathways, nucleotide excision repair and spore photoproduct lyase, are sufficient for the resistance of Bacillus subtilis spores to artificial UV-C and UV-B but not to solar radiation

Bacterial endospores are 1 to 2 orders of magnitude more resistant to 254-nm UV (UV-C) radiation than are exponentially growing cells of the same strain. This high UV resistance is due to two related phenomena: (i) DNA of dormant spores irradiated with 254-nm UV accumulates mainly a unique thymine dimer called the spore photoproduct (SP), and (ii) SP is corrected during spore germination by two major DNA repair pathways, nucleotide excision repair (NER) and an SP-specific enzyme called SP lyase. To date, it has been assumed that these two factors also account for resistance of bacterial spores to solar UV in the environment, despite the fact that sunlight at the Earth's surface consists of UV-B, UV-A, visible, and infrared wavelengths of approximately 290 nm and longer. To test this assumption, isogenic strains of Bacillus subtilis lacking either the NER or SP lyase DNA repair pathway were assayed for their relative resistance to radiation at a number of UV wavelengths, including UV-C (254 nm), UV-B (290 to 320 nm), full-spectrum sunlight, and sunlight from which the UV-B portion had been removed. For purposes of direct comparison, spore UV resistance levels were determined with respect to a calibrated biological dosimeter consisting of a mixture of wild-type spores and spores lacking both DNA repair systems. It was observed that the relative contributions of the two pathways to spore UV resistance change depending on the UV wavelengths used in a manner suggesting that spores irradiated with light at environmentally relevant UV wavelengths may accumulate significant amounts of one or more DNA photoproducts in addition to SP. Furthermore, it was noted that upon exposure to increasing wavelengths, wild-type spores decreased in their UV resistance from 33-fold (UV-C) to 12-fold (UV-B plus UV-A sunlight) to 6-fold (UV-A sunlight alone) more resistant than mutants lacking both DNA repair systems, suggesting that at increasing solar UV wavelengths, spores are inactivated either by DNA damage not reparable by the NER or SP lyase system, damage caused to photosensitive molecules other than DNA, or both.

An unnatural folate stereoisomer is catalytically competent in DNA photolyase

The folate chromophore in native Escherichia coli DNA photolyase ([6R]-5,10-CH+-H4Pte(Glu)n=3-6) serves as an antenna, transferring light energy to the fully reduced flavin (FADH2) reaction center at high efficiency (EET = 0.92). Apophotolyase reconstituted after an overnight incubation with [6R,S]-5,10-CH+-H4folate (a monoglutamate analogue of the native cofactor) contains equimolar amounts of the [6R]- and [6S]-isomers, suggesting similar binding affinities. A rapid, biphasic increase in fluorescence (approximately 100-fold) is observed upon binding of 5,10-CH+-H4folate to apophotolyase at 5 degrees C; the [6S]-isomer binds about 25-fold faster than the [6R]-isomer. Although identical absorption and fluorescence emission maxima are observed for enzyme reconstituted with [6S]-, [6R]-, or [6R,S]-5,10-CH+-H4folate, folate fluorescence quantum yield values vary depending on the stereochemical configuration at the 6 position (theta = 0.18, 0.82, or 0.46, respectively, at 5 degrees C), a feature not seen with free folate. The fluorescence of enzyme-bound folate is quenched upon flavin binding; the efficiency of quenching by flavin radical (EQ = 0.96) or FADH2 (EQ = 0.89) is the same for both folate isomers. In contrast, energy transfer from folate to FADH2 is sensitive to the stereochemical configuration at the 6 position. The efficiency of energy transfer observed for enzyme containing FADH2 and [6S]-, [6R]-, or [6R,S]-5,10-CH+-H4folate (theta = 0.26, 0.66, or 0.44, respectively) is directly proportional to the fluorescence quantum yield observed for folate in the absence of FADH2, as expected for Förster-type energy transfer. Although less efficient, the unnatural [6S]-isomer is catalytically functional, a feature not previously observed with other folate-dependent enzymes. Fluorescence quantum yield studies at 77 K with free (theta = 0.67) and enzyme-bound (theta = 1.0) folate suggest that differences in solvent exposure may contribute to the fluorescence efficiency differences observed with the enzyme-bound folate isomers at 5 degrees C.

Purification and characterization of Drosophila melanogaster photolyase

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.

On the roles of urocanic acid in photoimmunosuppression: attempted photorepair of urocanic acid-DNA cyclobutane adducts with DNA photolyase

It has been reported that UV-induced immunosuppression can be reversed by photoreactivation or exposure to T4 endonuclease V, two treatments that can repair cyclobutane pyrimidine dimers. These observations, together with the known role of urocanic acid (UA) in UV-induced immune suppression, prompted us to study the ability of DNA photolyase to repair UA-DNA cyclobutane photoadducts in single-stranded calf thymus DNA. We did not detect any release of UA, with a sensitivity implying that photolyase is at least 2900 times less active toward UA-DNA adducts than toward cis-syn thymine-thymine dimers. This indicates that any reversal of photoimmunosuppression by photoreactivation cannot significantly involve cleavage of UA-DNA cyclobutane adducts.

Similarity among the Drosophila (6-4)photolyase, a human photolyase homolog, and the DNA photolyase-blue-light photoreceptor family

Ultraviolet light (UV)-induced DNA damage can be repaired by DNA photolyase in a light-dependent manner. Two types of photolyase are known, one specific for cyclobutane pyrimidine dimers (CPD photolyase) and another specific for pyrimidine (6-4) pyrimidone photoproducts[(6-4)photolyase]. In contrast to the CPD photolyase, which has been detected in a wide variety of organisms, the (6-4)photolyase has been found only in Drosophila melanogaster. In the present study a gene encoding the Drosophila(6-4)photolyase ws cloned, and the deduced amino acid sequence of the product was found to be similar to the CPD photolyase and to the blue-light photoreceptor of plants. A homolog of the Drosophila (6-4)photolyase gene was also cloned from human cells.

Purification and partial characterization of (6-4) photoproduct DNA photolyase from Xenopus laevis

The (6-4) photoproduct DNA photolyase was detected in two vertebrate animals Crotalus atrox (rattlesnake) and Xenopus laevis (South African clawed toad). The enzyme was extensively purified from X. laevis and characterized. The highly purified enzyme is fluorescent with an excitation maximum at 420-440 nm and emission maximum at 460-480 nm. The photorepair action spectrum matches the fluorescence excitation spectrum with a 430 nm maximum.

The other function of DNA photolyase: stimulation of excision repair of chemical damage to DNA

DNA photolyase is a light-dependent DNA repair enzyme. It binds to cyclobutane pyrimidine dimers <PyrPyr> in DNA and upon excitation with a blue light photon splits the cyclobutane ring and restores the pyrimidines to native forms. The enzyme is specific for pyrimidine dimers, and it is not known to catalyze any other reaction either in ground or in excited state. However, when photolyase binds to <PyrPyr> but cannot catalyze repair because of lack of photoreactivating light, it still aids DNA repair by stimulating the nucleotide excision repair system. Recently, it was found that yeast photolyase binds to other lesions in DNA. In particular, the binding to cisplatin damaged DNA was highly specific. However, in vivo experiments revealed that this binding, in contrast to <PyrPyr> binding, did not stimulate but actually inhibited the removal of cisplatin damage by excision repair and hence photolyase sensitized cells to killing by cisplatin. In the present study, it is demonstrated that Escherichia coli DNA photolyase binds specifically to cisplatin 1,2-d(GpG) intrastrand cross-link and stimulates the removal of the lesion by E. coli excision nuclease in vitro. In agreement with the in vitro data, in vivo experiments revealed that photolyase makes cells more resistant to cisplatin killing.

Stereospecificity of folate binding to DNA photolyase from Escherichia coli

DNA photolyase from Escherichia coli contains folate ([6S]-5,10-CH(+)-H4Pte(Glu)n = 3-6) and reduced FAD. The folate chromophore acts as an antenna, harvesting light energy which is transferred to the reduced flavin where DNA repair occurs. The folate binding stereospecificity of the enzyme was investigated by reconstituting the apoenzyme with [6R,S]-5,10-CH(+)-H4folate and reduced FAD. The isomer composition of [methyl-3H]-5-CH3-H4folate, released into solution upon reduction of the reconstituted enzyme with [3H]NaBH4, was analyzed by enzymatic and chiral chromatographic methods. Both methods showed that the reconstituted enzyme contained nearly equimolar amounts of [6R]- and [6S]-5,10-CH(+)-H4folate.

Association of flavin adenine dinucleotide with the Arabidopsis blue light receptor CRY1

The arabidopsis thaliana HY4 gene encodes CRY1, a 75-kilodalton flavoprotein mediating blue light-dependent regulation of seedling development. CRY1 is demonstrated here to noncovalently bind stoichiometric amounts of flavin adenine dinucleotide (FAD). The redox properties of FAD bound by CRY1 include an unexpected stability of the neutral radical flavosemiquinone (FADH.). The absorption properties of this flavosemiquinone provide a likely explanation for the additional sensitivity exhibited by CRY1-mediated responses in the green region of the visible spectrum. Despite the sequence homology to microbial DNA photolyases, CRY1 was found to have no detectable photolyase activity.

Crystal structure of DNA photolyase from Escherichia coli

Photolyase repairs ultraviolet (UV) damage to DNA by splitting the cyclobutane ring of the major UV photoproduct, the cis, syn-cyclobutane pyrimidine dimer (Pyr <> Pyr). The reaction is initiated by blue light and proceeds through long-range energy transfer, single electron transfer, and enzyme catalysis by a radical mechanism. The three-dimensional crystallographic structure of DNA photolyase from Escherichia coli is presented and the atomic model was refined to an R value of 0.172 at 2.3 A resolution. The polypeptide chain of 471 amino acids is folded into an amino-terminal alpha/beta domain resembling dinucleotide binding domains and a carboxyl-terminal helical domain; a loop of 72 residues connects the domains. The light-harvesting cofactor 5,10-methenyltetrahydrofolylpolyglutamate (MTHF) binds in a cleft between the two domains. Energy transfer from MTHF to the catalytic cofactor flavin adenine dinucleotide (FAD) occurs over a distance of 16.8 A. The FAD adopts a U-shaped conformation between two helix clusters in the center of the helical domain and is accessible through a hole in the surface of this domain. Dimensions and polarity of the hole match those of a Pyr <> Pyr dinucleotide, suggesting that the Pyr <> Pyr "flips out" of the helix to fit into this hole, and that electron transfer between the flavin and the Pyr <> Pyr occurs over van der Waals contact distance.

Putative blue-light photoreceptors from Arabidopsis thaliana and Sinapis alba with a high degree of sequence homology to DNA photolyase contain the two photolyase cofactors but lack DNA repair activity

The putative blue-light photoreceptor genes of Arabidopsis thaliana and Sinapis alba (mustard) are highly homologous to the DNA repair genes encoding DNA photolyases. The photoreceptors from both organisms were overexpressed in Escherichia coli, purified, and characterized. The photoreceptors contain two chromophores which were identified as flavin adenine dinucleotide and methenyltetrahydrofolate. This chromophore composition suggests that the blue light photoreceptor may initiate signal transduction by a novel pathway which involves electron transfer. Despite the high degree of sequence identity to and identical chromophore composition with photolyases, neither photoreceptor has any photoreactivating activity.

Preferential inhibition of nucleosome assembly by ultraviolet-induced (6-4)photoproducts

We reconstituted nucleosomes in vitro using two kinds of damaged pBR322 plasmid DNA carrying cyclobutane pyrimidine dimers (CPD) or (6-4)photoproducts. The results indicate that nucleosome assembly is inhibited preferentially by (6-4)photoproducts compared with CPD, suggesting that the regions carrying (6-4)photoproducts retain their nucleosome-free form, i.e. linker-like conformation until completion of the repair processes.

Interactions between photolyase and dark repair processes in Chlamydomonas reinhardtii

The participation of DNA photolyase in dark repair processes has been reported in some heterotrophic organisms. To assess the role of photolyase in dark repair in photoautotrophs, double mutants of Chlamydomonas reinhardtii deficient in dark repair and photoreactivation were constructed and assayed for UV sensitivity in different posttreatment light conditions (with or without subsequent photoreactivation). We found that a functional PHR1 gene enhanced dark survival in the excision deficient (uvs9, uvs12) and in the recombination deficient (uvs10) genetic backgrounds but failed to do so in the strain deficient in a repair pathway other than excision and recombination (uvs13). Therefore we can conclude that photolyase may stimulate dark repair processes in C. reinhardtii also via pathway(s) other than nucleotide excision repair. The fact that some of the double mutants deficient in dark repair and photoreactivation survived better in the light than in the dark supports the idea that additional photorepair might be active and may enhance survival in a specific genetic background.

Photoinduced spin-polarized radical pair formation in a DNA photolyase.substrate complex at low temperature

Electron spin polarization is a phenomenon characterized by anomalous line intensities (emission or enhanced absorption) in the EPR spectrum. It is highly diagnostic of radical pairs, such as those formed in photoinduced electron transfer reactions. Electron spin polarization behavior (E/A pattern) is observed in light-modulated EPR spectra obtained at 4 K with fully reduced DNA photolyase.substrate complexes. Similar results are obtained with complexes formed with native enzyme or reconstituted enzyme containing fully reduced flavin as its only chromophore. No signal is observed for fully reduced enzyme or substrate alone. The results suggest that the electron spin polarization signal is due to photoinduced formation of a flavin/substrate radical pair (FADH./T < > T.-); splitting of T < > T.- does not occur at 4 K, and the radical pair can only undergo back-electron-transfer reactions. The data are consistent with the proposal that electron transfer initiates DNA repair in the photolyase reaction.

Photorepair of nonadjacent pyrimidine dimers by DNA photolyase

Photolyases reverse the harmful effects of UV light on cells by converting pyrimidine dimers (Pyr[]Pyr) into two pyrimidine monomers by utilizing near-UV and visible light. Previous work has shown that photolyase repairs T[c,s]T and T[t,s]T in DNA as well as U[]U in RNA, all of which are formed by joining the two adjacent pyrimidines in a light-dependent reaction. In this report, we show that Pyr[]Pyr formed in nonadjacent pyrimidines are also substrates for DNA photolyase.

Affinity probing of flavin binding sites. 2. Identification of a reactive cysteine in the flavin domain of Escherichia coli DNA photolyase

8-(Methylsulfonyl)FAD reacts with a single cysteine residue (Cys293) in the flavin domain of Escherichia coli DNA photolyase to form an 8-(cysteinyl)FAD derivative covalently bound to the protein. About 80% protection against covalent attachment with 8-(methylsulfonyl)FAD was observed in the presence of an equimolar amount of FAD. Flavinylated photolyase retains the ability to repair pyrimidine dimers (15% of native activity) and to bind its antenna chromophore, 5,10-methenyltetrahydrofolate. Comparison of the properties of flavinylated enzyme with photolyase containing noncovalently bound 8-(methylthio)-FAD indicate that a perturbation is necessary to accommodate covalent bond formation. 8-(Methylthio)-FAD-reconstituted enzyme exhibits 95% of native activity. The aerobic stability of fully reduced and radical forms of 8-(methylthio)FAD enzyme is similar to that of native enzyme, whereas a radical form is not detected with flavinylated enzyme and the fully reduced enzyme is more easily oxidized by oxygen. The flavin in 8-(methylthio)FAD enzyme or flavinylated photolyase is shielded from solvent. However, the flavin environment in flavinylated enzyme is less hydrophobic as judged by spectral comparison with model 8-(alkylthio)flavins in various solvents. Enzyme containing noncovalently bound 8-(methylsulfonyl)-FAD was prepared by reconstitution with the fully reduced flavin which does not undergo covalent attachment. Covalent attachment was observed after reoxidation but probably involved dissociation and rebinding of oxidized 8-(methylsulfonyl)FAD. The results show that 8-(cysteinyl)FAD in flavinylated photolyase is at or near the normal flavin binding site.(ABSTRACT TRUNCATED AT 250 WORDS)