Photoreactivating enzyme from Escherichia coli: isolated enzyme lacks absorption in its actinic wavelength region and its ribonucleic acid cofactor is partially double stranded when associated with apoprotein

Isolated photoreactivating enzyme (PRE) from Escherichia coli exhibits some optical density at wavelengths greater than 300 nm. After correcting for the effects of light scattering, however, we find no true absorption in the spectral region that is required for enzymatic activity (320-450 nm). At shorter wavelengths, there is an absorption maximum near 260 nm that is due primarily to an RNA cofactor. Heating to 60 degrees C and subsequently cooling to 4 degrees C release the RNA cofactor from association with apoprotein and result in hyperchromicity. Circular dichroism indicates that the RNA associated with native enzyme is partially double stranded. At low ionic strength (mu = 0.01), heating to 15 degrees C or protease treatment at 4 degrees C results in irreversible loss of part of the double strandedness. We show that the difference spectrum at 4 degrees C between the absorption spectra of native enzyme and heat-treated enzyme can be fit by a superposition of reference spectra for denaturation of A-U and G-C base pairs derived from model polynucleotides. The coefficients of the linear combination of reference spectra were used to calculate the fraction of A-U and G-C base pairs. We find that both A-U and G-C base pairs are present in equal concentrations and that about 20% are in a double-stranded conformation in the native enzyme.     

Analysis of photoenzymatic repair of UV lesions in DNA by single light flashes. XII. Evidence for enhanced photolysis enzyme-substrate complexes by a 2-photon reaction.

Yeast photoreactivating enzyme (PRE), preilluminated with wavelengths ranging from the near-UV to the red spectral region, forms with 254 nm-irradiated transforming DNA of Haemophilus influenzae enzyme-substrate complexes that are more efficiently photorepaired than complexes formed from non-preilluminated PRE. The action spectrum for this "preillumination effect", previously shown to have a maximum in the near-UV region, has another maximum near 577 nm. In complexes formed from non-preilluminated PRE the repair probability per incident photon is only about 25% of that in complexes formed from preilluminated PRE, if low-intensity photoreactivating light is applied continuously or as a sequence of flashes. However, photoreactivating light in the form of a single, high-intensity flash of 1 msec duration raises the repair probability to greater than 50%. Two light flashes, discharged with a delay of slightly more than a millisecond, may already achieve less photorepair than the same energy given as a single flash. These results are explained by the assumption that the great majority of PRE molecules in a non-preilluminated preparation have reduced activity (of the order of 1/4 of maximal activity). These less reactive molecules form enzyme-substrate complexes ("non-activated complexes") in which the repair probability per incident photon is considerably increased if 2 or more photons are absorbed within a time period of the order of milliseconds. This phenomenon, tentatively termed "2-photon photolysis" does not occur in "activated complexes" (i.e. those formed form preilluminated enzyme). The data are compatible with suggestion that the first absorption leads to a metastable excited state of the complex, during which the repair probability is increased by absorption of another photon. The generally observed heterogeneity of the photolytic response of enzyme-substrate complexes can be partly explained by heterogeneity of PRE molecules regarding their activity. In particular, uncontrolled exposure of enzyme to almost any kind of room light before its experimental use can enhance the heterogeneity.     

Evidence that the phr+ gene enhances the ultraviolet resistance of Escherichia coli recA strains in the dark

An Escherichia coli recA phr+ purA strain was more resistant to ultraviolet radiation than its isogenic derivative recA phr+ purA+ in the absence of photoreactivating light, whereas their nearly isogenic derivative recA phr showed most UV-induced lethality. The amounts of photoreactivating enzyme (PRE) per cell in the recA phr+ purA was higher than in the recA phr+ purA+. The recA phr is defective for photoreactivation. Thus, in the recA strain, UV resistance in the dark increased in proportion to the amounts of PRE per cell, suggesting that PRE participates in the process of dark repair of UV-damaged DNA.     

Damage and repair in mammalian cells after exposure to non-ionizing radiations : I. Ultraviolet and visible light irradiation of cells of the rat kangaroo (Potorous tridactylus) and determination of photorepairable damage in vitro

Cornea cells of the rat kangaroo or “potoroo” (Potorous tridactylus) were exposed to far-UV (254 or 302 nm) radiation, with or without subsequent illumination by near-UV or visible light. The DNA of these cells was extracted and tested for the presence of photoproducts binding yeast photoreactivating enzyme (PRE). The criterion for the latter was competitive inhibition of an in vitro photorepair system, consisting of UV-irradiated transforming DNA of Haemophilus influenzae and an extract containing yeast PRE. The effects on repair kinetics of the transforming DNA indicate that in UV-irradiated potoroo cornea cells up to approximately 90% of photorepairable DNA damage can be photorepaired within 15 min. However, the extent of cellular photorepair, assessed by the reduction in competitive inhibition of the in vitro repair system depends appreciably on experimental parameters during photoreactivating treatment. Control experiments with non-UV-irradiated cells indicated that, depending on specific conditions, the photoreactivating treatment itself produces a varying amount of DNA damage, which reacts with the PRE in vitro. To avoid most of this kind of damage, cells are nitrogen-gassed and kept at 5°C during illumination, and the photoreactivating light must not contain wavelengths shorter than 380–400 nm. Our results show that wavelengths >470 nm are still very effective, whereas wavelengths >555 nm are ineffective in photorepairing potoroo DNA. For unknown reasons, one particular strain of potoroo cornea cells lost its potential for photorepair. Treatment of unirradiated potoroo cells, or their extracted DNA, with hydrogen peroxide also results in competitive inhibition of photorepair in vitro, resembling that observed after near-UV illumination. Because of the occurrence of synergistic effects it is not clear whether the damage only interacts with PRE or can actually be photorepaired under appropriate conditions.

The results presented in this paper suggest that the expression of photorepair in mammalian cells, unlike that in prokaryotes, greatly depends on a number of experimental parameters, including the spectral composition of photoreactivating light. Apparently superposition of damage by the photoreactivating treatment itself is the critical factor. This may explain experimental discrepancies existing in different laboratories studying photorepair in UV-irradiated cells of placental mammals.     

Cloning of the phr gene and amplification of photolyase in Escherichia coli.

A new technique is developed for physically enriching recombinant DNA molecules in an in vitro recombination mixture. UV-irradiation of the donor DNA before recombination enables photoreactivating enzyme (PRE) (deoxyribodipyrimidine photolyase, EC 4.1.99.3) to attach to the donor segments in recombinant molecules. This attached protein causes retention of the recombinant molecules on a nitrocellulose filter, while molecules not containing donor DNA pass through. The bound DNA is repaired of its UV damage and released for insertion into cells by exposure to photoreactivating light in situ, yielding approx. 350-fold enrichment. Although applicable to any gene, this procedure has been used in cloning the Escherichia coli phr gene itself, permitting 100-fold amplification of the gene product in vivo.     

A multicopy phr-plasmid increases the ultraviolet resistance of a recA strain of Escherichia coli

It has been previously reported that the ultraviolet sensitivity of recA strains of Escherichia coli in the dark is suppressed by a plasmid pKY1 which carries the phr gene, suggesting that this is due to a novel effect of photoreactivating enzyme (PRE) of E. coli in the dark (Yamamoto et al., 1983a). In this work, we observed that an increase of UV-resistance by pKY1 in the dark is not apparent in strains with a mutation in either uvrA, uvrB, uvrC, lexA, recBC or recF. The sensitivity of recA lexA and recA recBC multiple mutants to UV is suppressed by the plasmid but that of recA uvrA, recA uvrB and recA uvrC is not. Host-cell reactivation of UV-irradiated lambda phage is slightly more efficient in the recA/pKY1 strain compared with the parental recA strain. On the other hand, the recA and recA/pKY1 strains do not differ significantly in the following properties: Hfr recombination, induction of lambda by UV, and mutagenesis. We suggest that dark repair of PRE is correlated with its capacity of excision repair.     

Photochemical properties of Escherichia coli DNA photolyase: a flash photolysis study

Escherichia coli DNA photolyase contains a stable flavin neutral blue radical that is involved in photosensitized repair of pyrimidine dimers in DNA. We have investigated the effect of illumination on the radical using light of lambda greater than 520 nm from either a camera flash or laser. We find that both types of irradiations result in the photoreduction of the flavin radical with a quantum yield of 0.10 +/- 0.02. While photoreduction with the camera flash is minimal in the absence of an electron donor (dithiothreitol), laser flash photolysis at 532 nm reduces the flavin to the same extent in the presence or absence or an electron donor. Thus, it is concluded that the primary step in photoreduction involves an electron donor that is a constituent of the enzyme itself. Laser flash photolysis produces a transient absorption band at 420 nm that probably represents the absorption of the lowest excited doublet state (2(1)IIII*) of the radical and decays with first-order kinetics with k1 = 0.8 X 10(6) s-1. The photoreduction data combined with the results of recent studies on the activity of dithionite-reduced enzyme suggest that electron donation by excited states of E-FADH2 is the mechanism of flavin photosensitized dimer repair by E. coli DNA photolyase.     

Damage and repair in mammalian cells after exposure to non-ionizing radiations. II. Photoreactivation and killing of rat kangaroo cells (Potorous tridactylus) and Herpes simplex virus-1 by exposure to fluorescent "white" light or sunlight

Photoreactivation (PR) of ultraviolet (254 nm)-inactivated cornea cells of the potoroo (or rat kangaroo; Potorous tridacylus) has been studied at wavelengths greater than 375 nm from either fluorescent "white" light or sunlight. In both cases the PR kinetics curves pass through maxima, which most likely result from the superposition of concomitant inactivation by the photoreactivating light. The inactivating effect of light was directly demonstrated for non-UV-irradiated cells, permitting correction of the PR curves. Wavelengths greater than 475 nm, and even greater than 560 nm, which do not noticeably damage cells, still photoreactivate, though less effectively than shorter wavelengths. Light treatment of UV-inactivated Herpes simplex Virus-1 (HSV-1) after infection leads to PR effects resembling those observed for cells, while light treatment of unirradiated virus after infection likewise causes inactivation. The "fluence-reduction factor" of PR, which is greater than 3 for the virus, exceeds that for the cells, where it decreases with increasing UV fluence. In vitro tests have indicated that sunlight greater than 375 nm causes photorepairable DNA lesions which are virtually fully repaired by the same light. Thus cell inactivation resulting from these solar wavelengths must be due to non-photorepairable damage.     

Unscheduled DNA synthesis in xeroderman pigmentosum cells after microinjection of yeast photoreactivity enzyme

Photoreactivating enzyme (PRE) from yeast causes a light-dependent reduction of UV-induced unscheduled DNA synthesis (UDS) when injected into the cytoplasm of repair-proficieint human fibroblasts (Zwetsloot et al., 1985). This result indicates that the exogenous PRE monomerizers UV-induced dimers in these cells competing with the endogenous excision repair. In this paper we present the results of the injection of yeast PRE on (residual) UDS in fibroblasts from different excision-deficient XP-strains representing complementation groups A, C, D, E, F, H and I (all displaying more than 10% of the UDS of wild-type cells) and in fibroblasts from two excision-proficient XP-variant strains.In fibroblasts belonging to complementation groups C, F and I and in fibroblasts from the XP-variant strains UDS was significantly reduced, indicating that pyrimidine dimers in these cells are accessible to and can be monomerized by the injected yeast PRE. The UDS reduction in the XP-variant strains is comparable with the effect in wild-type cells. In cells from complementation groups C, F and I the reduction is less than in wild-type and XP-variant cells. Fibroblasts belonging to groups A, D, E and H did not show any reduction in UDS level after PRE injection and illumination with photoreactivating light. These result give evidence that the genetic repair defect in some XP-strains is probably due to an altered accessibility of the UV-damaged sites.     

Photochemical cross-linking of protein and DNA in chromatin. Synthesis and application of a photosensitive cleavable derivative of 9-aminoacridine with two photoprobes connected through a disulphide-containing linker.

A novel cleavable photo-cross-linking reagent, N-(2-methoxy-6-azidoacridin-9-yl)-N'-(4-azidobenzoyl)cystamine, for analysis of protein-nucleic acid interactions, has been synthesized. The reagent contains two photosensitive groups that can be activated sequentially. The azidoacridinyl moiety is sensitive to u.v. and visible light (lambda less than or equal to 450 nm), whereas the azidobenzoyl part needs higher-energy light (lambda less than or equal to 350 nm). Furthermore, the disulphide bridge connecting the two photoactive groups can be cleaved by reduction with mercaptans. The reagent is shown to induce cleavable cross-links between all five major histones and DNA in chromatin from Ehrlich ascites cells on activation with long-wavelength u.v. light (lambda greater than 300 nm) at an efficiency of approximately 3% of the added reagent.     

Luria effect in bacteriophages and the role of the products of recA+ and lexA+ genes in its induction

An analysis of UV-damages accumulation in the phages as revealed by delay of intracellular growth is represented using temperate lambda phage. The maximum of growth delay of phage lambda at given UV-dose was found with lambda red+, infecting Escherichia coli AB1886 uvrA strain. The growth delay was absent, when a strain RH-1 uvrA-recA- was infected with UV-irradiated phage lambda red3. A moderate growth delay was obtained with the phages lambda red+, infecting E. coli RH-1 uvrA-recA- or phage lambda red3, infecting E. coli AB1886 uvrA-. THe growth delay was also absent when wild type, recA- and uvrA mutants of E. coli were infected with phage lambda after 8-metnoxypsoralen + light (lambda > 310 nm) treatment. It is known that the crosslinks appear to be the DNA defects which give rise to the observed biological inactivation following psoralen + light treatment. However, a considerable growth delay of phage lambda, treated by 8-metnoxypsoralen + light, was only found under condition of crosslinks repair (W-reactivation and prophage-reactivation). The results obtained are best explained by the assumption that the growth delay reflects the time required for the postreplication repair (RecA, LexA, Red) of any lethal UV-lesion.     

Genetic exchanges caused by ultraviolet photoproducts in phage λ DNA molecules: The role of DNA replication

Summary Genetic recombination induced by structural damage in DNA molecules was investigated in E. coli K12 () lysogens infected with genetically marked phage . Photoproducts were induced in the phage DNA before infection by exposing them either to 313 nm light in the presence of acetophenone or to 254 nm light. To test the role of the replication of the damaged phage DNA on the frequency of the induced recombination, both heteroimmune and homoimmune crosses were performed.First, samples of a heteroimmune phage imm434 P80 exposed to these treatments were allowed to infect cells lysogenic for prophage cI857 P3. Phage DNA replication and maturation took place, and the resulting progeny phages were assayed for the frequency of P ⁺ recombinants. Recombination was less frequent in infected cells exposed to visible light and in wild type cells able to perform excision repair than in excision-defective lysogens. Therefore, much of the induced recombination can be atributed to the pyrimidine dimers in the phage DNA, the only photoproducts known to be dissociated by photoreactivating enzyme.Second, in homoimmune crosses, samples of similarly treated homoimmune P3 phages were allowed to infect lysogens carrying cI857 P80. Replication of the phage DNA containing ultraviolet photoproducts was repressed by immunity, and was futher blocked by the lack of the P gene product needed for replication. The lysogens were purified and scored for both colony forming ability and for P ⁺ recombinant prophages. The 254 nm photoproducts increased the frequency of recombination in these homimmune crosses, even though phage DNA replication was blocked. Irradiation with 313 nm light and acetophenone M, which produces dimers and unknown photoproducts, was not as effective per dimer as the 254 nm light.It is concluded from these results that certain unidentified 254 nm photoproducts can cause recombination even in the absence of DNA replication. They are not pyrimidine dimers, as they are not susceptible to excision repair or photoreactivation. In contrast, pyrimidine dimers appear to cause recombination only when the DNA containing them undergoes replication.     

Multiple loci affecting photoreactivation in Escherichia coli.

Sutherland et al. mapped a phr gene in Escherichia coli at 17 min and found that induction of an E. coli strain lysogenic for a lambda phage carrying this gene increased photoreactivating enzyme levels 2,000-fold. Recently, Smith and Youngs and Sancar and Rupert located a phr gene at 15.9 min. We have therefore investigated the properties of photoreactivating enzyme and cellular photoreactivation in cells containing deletions of the gene at 17 min. Cells with this deletion photoreactivated ultraviolet-induced killing at a rate 20% of normal; they also contained approximately 20% of the normal photoreactivating enzyme level. The residual enzyme in these cells was characterized to determine whether the reduced cellular photoreactivation rate and photoreactivating enzyme levels resulted from reduced numbers of normal enzymes or from an altered enzyme. Photoreactivating enzymes from strains carrying a deletion of the region at 17 min had an apparent Km about two- to threefold higher than normal enzyme and showed markedly increased heat lability. The gene at 17 min thus contains information determining the function of the E. coli photoreactivating enzyme rather than the quantity of the enzyme. It is proposed that the gene at 17 min be termed phrA and that located at 15.9 min be termed phrB.     

Photorepair of ultraviolet radiation-induced pyrimidine dimers in corneal DNA

The induction and photorepair of pyrimidine dimers in DNA have been measured in the ultraviolet-irradiated, corneal epithelium of the marsupial, Monodelphis domestica, using damage-specific nucleases from Micrococcus luteus in conjunction with agarose gel electrophoresis. We observed that FS-40 sunlamps (280-400 nm) induced 7.2 +/- 1.0 X 10(-5) pyrimidine dimers per kilobase (kb) of DNA per J/m2. Following 100 J/m2, 50% and greater than 90% of the dimers were photorepaired during a 10- and 30-min exposure to photoreactivating light (320-400 nm), respectively. In addition, approximately 70% and approximately 60% of the dimers induced by 300 and 500 J/m2, respectively, were repaired by a 60-min exposure to photoreactivating light. The capacity of the corneal epithelium of M. domestica to photorepair pyrimidine dimers identifies this animal as a potentially useful model with which to determine whether pyrimidine dimers are involved in pathological changes of the irradiated eye.     

A specific and efficient photoreaction between E. coli RNA polymerase and T+1 in the lacUV5 or deoP1 promoter.

Upon irradiation of the RNA polymerase-lacUV5 or deoP1 promoter complex with short wavelength ultraviolet light (lambda less than or equal to 300 nm) the polymerase is covalently crosslinked at an efficiency of greater than 10% to the first transcribed base of the template DNA strand when this is a thymine. The temperature dependence of this RNA polymerase-T+1 photoreaction strongly indicates a relation to the formation of the open complex. It is suggested that open complex formation is preceded or accompanied by a specific contact between the RNA polymerase and the first transcribed base of the DNA template.     

Use of primer-restriction-end adapters in a novel cDNA cloning strategy

We introduce a class of synthetic oligonucleotides, referred to as primer-restriction-end (PRE) adapters, which are bifunctional, one end serving as a primer for a polymerase reaction, while the other end can be ligated to restriction endonuclease digested DNA. Use of such adapters forms the basis of a new method for inserting single-stranded cDNA into cloning vectors, which involves very few separate biochemical modifications of the cDNA and so is appropriate when extensive fractionation of cDNA is desired prior to cloning. This novel methodology is highly efficient in producing full-length cDNA cloned in a predictable orientation within vectors, as we demonstrate by constructing and analysing clones of immunoglobulin lambda light chain cDNA in Escherichia coli.     

Photoreactivation in phr mutants of Escherichia coli K-12.

We have investigated the genetics of photoreactivation in Escherichia coli K-12. We found that strains with point mutations or deletions in the phr gene showed a significant residual level of photoreactivation after exposure to large fluences of photoreactivating light. It had been previously proposed that a gene in the gal-att lambda interval is also involved in photoreactivation and that the residual photoreactivating activity might be due to this so-called phrA gene located at this interval. We found that deletions of the gal-att lambda region had no effect on either the rate or the final extent of photoreactivation observed in phr+ cells or phr mutants; however strains carrying the delta (gal-att lambda) deletions displayed increased sensitivity to near-UV radiation.     

Replacement of potassium chloride by potassium glutamate dramatically enhances protein-DNA interactions in vitro

Although protein-nucleic acid interactions exhibit dramatic dependences on both ion concentration and type in vitro, large variations in intracellular ion concentrations can occur in Escherichia coli and other organisms without apparent effects on gene expression in vivo. E. coli accumulates K+ and glutamate as cytoplasmic osmolytes. The cytoplasmic K+ concentration in E. coli varies from less than 0.2 to greater than 0.9 m as a function of external osmolarity; corresponding cytoplasmic glutamate concentrations range from less than 0.03 to greater than 0.25 m. Only low levels of chloride occur in the cytoplasm of E. coli at all osmotic conditions. Since most in vitro studies have been performed in chloride salts, whereas glutamate is the more relevant physiological anion, we have measured the effects of the substitution of potassium glutamate (KGlu) for KCl on the kinetics and equilibria of a variety of site-specific protein-DNA interactions in vitro. Both the interaction of E. coli RNA polymerase with two phage lambda promoters and the interactions of various restriction enzymes with their DNA cleavage sites are enhanced by this substitution. Using the abortive initiation assay, we find a greater than 30-fold increase in the second-order rate constant for open complex formation at the lambda PR promoter and a 10-fold increase at the lambda PR' promoter, when KGlu is substituted for KCl. Replacement of KCl by KGlu does not affect the strong salt dependences of these interactions; increasing either KCl or KGlu concentrations decreases both reaction rates and extents. Substitution of glutamate for chloride does, however, shift the range of salt concentrations over which these interactions are observable to higher K+ concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Photoreactivation of pyrimidine dimers in the DNA of normal and xeroderma pigmentosum cells.

Photoproducts formed in the DNA of human cells irradiated with ultraviolet light (uv) were identified as cyclobuytl pyrimidine dimers by their chromatographic mobility, reversibility to monomers upon short wavelength uv irradiation, and comparison of the kinetics of this monomerization with that of authentic cis-syn thymine-thymine dimers prepared by irradiation of thymine in ice. The level of cellular photoreactivation of these dimers reflects the level of photoreactivating enzyme measured in cell extracts. Action spectra for cellular dimer photoreactivation in the xeroderma pigmentosum line XP12BE agree in range (300 nm to at least 577 nm) and maximum (near 400 nm) with that for photoreactivation by purified human photoreactivating enzyme. Normal human cells can also photoreactivate dimers in their DNA. The action spectrum for the cellular monomerization of dimers is similar to that for photoreactivation by the photoreactivating enzyme in extracts of normal human fibroblasts.