Studies on temperature-dependent ultraviolet light-sensitive mutants of bacteriophage T4: the structural gene for T4 endonuclease V.

Mutants of bacteriophage T4 which exhibit increased sensitivity to ultraviolet radiation specifically at high temperature were isolated after mutagenesis with hydroxylamine. At 42 °C the mutants are twice as sensitive to ultraviolet light as T4D, whereas at 30 °C they exhibit survival curves almost identical to that of the wild-type strain. Complementation tests revealed that the mutants possess temperature-sensitive mutations in the v gene.Evidence is presented to show that T4 endonuclease V produced by the mutants is more thermolabile than the enzyme of the wild-type. (1) Extracts of cells infected with the mutants were capable of excising pyrimidine dimers from ultraviolet irradiated T4 DNA at 30 °C, but no selective release of dimers was induced at 42 °C. (2) Endonuclease V produced by the mutant was inactivated more rapidly than was the enzyme from T4D-infected cells when the purified enzymes were incubated in a buffer at 42 °C. From these results it is evident that the v gene is the structural gene for T4 endonuclease V, which plays an essential role in the excision-repair of ultraviolet light-damaged DNA.The time of action of the repair endonuclease was determined by using the mutant. Survival of a temperature-sensitive v mutant, exposed to ultraviolet light, increased when infected cells were incubated at 30 °C for at least ten minutes and then transferred to 42 °C. It appears that repair of DNA proceeds during an early stage of phage development.     

Repair Responses to DNA Damage: Enzymatic Pathways in E coli and Human Cells

Bacteria and eukaryotic cells employ a variety of enzymatic pathways to remove damage from DNA or to lessen its impact upon cellular functions. Most of these processes were discovered in Escherichia coli and have been most extensively analyzed in this organism because suitable mutants have been isolated and characterized. Analogous pathways have been inferred to exist in mammalian cells from the presence of enzyme activities similar to those known to be involved in repair in bacteria, from the analysis of events in cells treated with DNA damaging agents, and from the analysis of the few naturally occurring mutant cell types. Excision repair of pyrimidine dimers produced by UV in E coli is initiated by an incision event catalyzed by a complex composed of uvrA, uvrB, and uvrC gene products. Multiple exonuclease and polymerase activities are available for the subsequent excision and resynthesis steps. In addition to the constitutive pathway, which produces short patches of 20–30 nucleotides, an inducible excision repair process exists that produces much longer patches. This long patch pathway is controlled by the recA-lexA regulatory circuit and also requires the recF gene. It is apparently not responsible for UV-induced mutagenesis. However, the ability to perform inducible long patch repair correlates with enhanced bacterial survival and with a major component of the Weigle reactivation of bacteriophage with double-strand DNA genomes. Mammalian cells possess an excision repair pathway similar to the constitutive pathway in E coli. Although not as well understood, the incision event is at least as complex, and repair resynthesis produces patches of about the same size as the constitutive short patches. In mammalian cells, no patches comparable in size to those produced by the inducible pathway of E coli are observed. Repair in mammalian cells may be more complicated than in bacteria because of the structure of chromatin, which can affect both the distribution of DNA damage and its accessibility to repair enzymes. A coordinated alteration and reassembly of chromatin at sites of repair may be required. We have observed that the sensitivity of digestion by staphylococcal nuclease (SN) of newly synthesized repair patches resulting from excision of furocoumarin adducts changes with time in the same way as that of patches resulting from excision of pyrimidine dimers. Since furocoumarin adducts are formed only in the SN-sensitive linker DNA between nucleosome cores, this suggests that after repair resynthesis is completed, the nucleosome cores in the region of the repair event do not return exactly to their original positions. We have also studied excision repair of UV and chemical damage in the highly repeated 172 base pair α DNA sequence in African green monkey cells. In UV irradiated cells, the rate and extent of repair resynthesis in this sequence is similar to that in bulk DNA. However, in cells containing furocoumarin adducts, repair resynthesis in α DNA is only about 30% of that in bulk DNA. Since the frequency of adducts does not seem to be reduced in α DNA, it appears that certain adducts in this unique DNA may be less accessible to repair. Endonuclease V of bacteriophage T4 incises DNA at pyrimidine dimers by cleaving first the glycosylic bond between deoxyribose and the 5′ pyrimidine of the dimer and then the phosphodiester bond between the two pyrimidines. We have cloned the gene (denV) that codes for this enzyme and have demonstrated its expression in uvrA recA and uvrB recA cells of E coli. Because T4 endonuclease V can alleviate the excision repair deficiency of xeroderma pigmentosum when added to permeabilized cells or to isolated nuclei after UV irradiation, the cloned denV gene may ultimately be of value for analyzing DNA repair pathways in cultured human cells.     

Partial complementation of the UV sensitivity of E. coli and yeast excision repair mutants by the cloned denV gene of bacteriophage T4

Summary The denV gene of bacteriophage T4 was reconstituted from two overlapping DNA fragments cloned in M13 vectors. The coding region of the intact gene was tailored into a series of plasmid vectors containing different promoters suitable for expression of the gene in E. coli and in yeast. Induction of the TAC promoter with IPTG resulted in overexpression of the gene, which was lethal to E. coli. Expression of the TACdenV gene in the absence of IPTG, or the use of the yeast GAL1 or ADH promoters resulted in partial complementation of the UV sensitivity of uvrA, uvrB, uvrC and recA mutants of E. coli and rad1, rad2, rad3, rad4 and rad10 mutants of S. cerevisiae. The extent of denV-mediated reactivation of excision-defective mutants was approximately equal to that of photoreactivation of such strains. Excision proficient E. coli cells transformed with a plasmid containing the denV gene were slightly more resistant to ultraviolet (UV) radiation than control cells without the denV gene. On the other hand, excision proficient yeast cells were slightly more sensitive to killing by UV radiation following transformation with a plasmid containing the denV gene. This effect was more pronounced in yeast mutants of the RAD52 epistasis group.     

Restriction in vivo

Summary Degradation products of restricted T4 DNA induced filamentation, mutagenesis, and to a lesser extent, synthesis of recA protein in wild type cells but not in recA, lexA or recBC mutants of Escherichia coli. We conclude that the structural damage to the DNA caused by restriction cleavage and exonuclease V degradation can induce SOS functions. Degradation of restricted nonglucosylated T4 DNA by exonuclease V delayed cell division and induced filament formation and mutagenesis in lexA ⁺ but not in lexA ^- cells. Delay of cell division was also dependent upon recA and recBC funtions. Such degradation of DNA also dramatically increased mutagenesis in tif ^- Sfi^- cells at 42°C. The synthesis of recA protein continued in the restricting host after infection by the nonglucosylated T4 phage, but enhanced synthesis is not induced to the extent seen in SOS induced tif ^- cells grown at 42°. We also found that restriction of nonglucosylated T4 was alleviated in UV irradiated cells. The UV induced alleviation of rgl and r _K restriction depended upon post irradiation protein synthesis and was not observed in recA, lexA or recBC mutants.     

Weigle reactivation of the single-stranded DNA phage f1

Summary The survival of ultraviolet light (UV) damaged single-stranded DNA bacteriophage f1 is increased when the Escherichia coli host is irradiated with UV prior to infection. This repair, called Weigle reactivation, is multiplicity independent and is absent in recA and in lexA mutants. The function of the recA-lexA repair system needed is repair and not recombination, as demonstrated by the absence of Weigle reactivation in mutants that are recombination proficient but defective in repair of double-stranded DNA. Weigle reactivation of f1 requires high levels of the recA protein, and in addition activation of recA or another protein. This activation can be produced by UV irradiation, or by the tif-1 allele of recA together with the spr allele of lexA. Mutagenesis of f1 has the same requirements as W-reactivation, and in addition requires UV irradiation of the phage.     

Action of T4 endonuclease V on DNA containing various photoproducts

The action of T4 endonuclease V on DNA containing various photoproducts was investigated. (1) The enzyme introduced strand breaks in DNA from ultraviolet-irradiated vegetative cells of Bacillus subtilis but not in DNA from irradiated spores of the same organism. DNA irradiated with long wavelength (360 nm peak) ultraviolet light in the presence of 4,5',8-trimethylpsoralen was not attacked by the enzyme. These results indicate that 5-thyminyl 5,6-dihydrothymine (spore photoproduct) and psoralen mediated cross-links in DNA are not recognized by T4 endonuclease V. (2) DNA of phage PBS1, containing uracil in place of thymine, and DNA of phage SPO1, containing hydroxymethyluracil in place of thymine, were fragmented by the enzyme when the DNA's had been irradiated with ultraviolet light. T4 endonuclease V seems to act on DNA with pyrimidine dimers whether the dimers contain thymine residues or not.     

Alteration of cyanobacterial glutamine synthetase activity in vivo in response to light and NH 4 +

Extractable glutamine synthetase activity of the cyanobacterium Anabaena cylindrica was reduced by approximately 50% when N₂-fixing cultures were treated with 10 mM NH ₄ ⁺ or were placed in darkness. The deactivated enzyme could be rapidly reactivated (within 5 min) by adding 40 mM 2-mercaptoethanol to the biosynthetic reaction mixture. The enzyme could also be reactivated in vivo by replacing the culture in light or by removing NH ₄ ⁺ . When the enzyme was deactivated by simultaneously adding NH ₄ ⁺ and placing the culture in darkness, reactivation occurred on reillumination and removal of NH ₄ ⁺ . The removal of NH ₄ ⁺ in darkness did not result in reactivation. On in vitro reactivation of glutamine synthetase from dark or NH ₄ ⁺ -treated cultures the maximum glutamine synthetase activity observed frequently exceeded that of glutamine synthetase extracted from untreated cultures. Anacystis nidulans showed a similar type of reversible dark deactivation to A. cylindrica but Plectonema boryanum and a Nostoc did not. With A. cylindrica, a direct positive correlation between the size of the intracellular pool of glutamate and biosynthetic glutamine synthetase activity occurred during light/dark shifts, and on treatment with NH ₄ ⁺ . The changes in activity of glutamine synthetase in A. cylindrica in response to light resemble in some respects the light modulation of enzymes of the oxidative and reductive pentose phosphate pathways noted in cyanobacteria by others.     

Differences in host controlled reactivation of lambdoid and T phages

Summary Phages 434, T4, T5 and T7 are studied with regard to host controlled reactivation of damage produced by UV or photodynamic action sensitized by thiopyronine. Repair of 434 phages proceeds under control of both hcr and rec genes. UV irradiated T5 and T7 phages are reactivated under control of the host's hcr genes only. If these phages are inactivated by photodynamic action they are reactivated not at all. T4 phages inactivated by both treatments are also refractory to host controlled reactivation. These differences might reflect different degrees of autarchy and different abilities of phage DNAs to serve as substrate for recombination enzymes of the host.These results were presented in an abstracted version at the V. International UV colloquium Grundlagen der UV-Wirkung, Kühlungsborn, DDR, in October 1969. The experiments with T5 were done by Mrs. E. Marx.     

W-reactivation of phage lambda in X-irradiated mutants ofEscherichia coli K-12

Summary The survival of UV irradiated phage lambda was increased on X-irradiatedE. coli K-12 host cells over that on unirradiated cells. The frequency of c mutants among the surviving phages was to a similar extent increased by the X-ray exposure of the host cells as by UV light. This W-reactivation of phage lambda occurred inuvrA, polA, andrecB mutants besides the wild type at about equal X-ray doses, however, at a reduced reactivation efficiency compared with the wild type. W-reactivation was undetectable inrecA mutants. While maximal UV induced W-reactivation occurred 30 min after irradiation, the maximal X-ray induced reactivation was found immediately after irradiation. Chloramphenicol (100 µg/ml) and nitrofurantoin (50 µg/ml) inhibited W-reactivation of phage lambda if added before irradiation of the host cells, indicating the necessity of protein synthesis for W-reactivation.     

Dark Repair of Ultraviolet-Irradiated Deoxyribonucleic Acid by Bacteriophage T4: Purification and Characterization of a Dimer-Specific Phage-Induced Endonuclease

The purification and properties of an ultraviolet (UV) repair endonuclease are described. The enzyme is induced by infection of cells of Escherichia coli with phage T4 and is missing from extracts of cells infected with the UV-sensitive and excision-defective mutant T4V(1). The enzyme attacks UV-irradiated deoxyribonucleic acid (DNA) containing either hydroxymethylcytosine or cytosine, but does not affect native DNA. The specific substrate in UV-irradiated DNA appears to be pyrimidine dimer sites. The purified enzyme alone does not excise pyrimidine dimers from UV-irradiated DNA. However, dimer excision does occur in the presence of the purified endonuclease plus crude extract of cells infected with the mutant T4V(1).     

Cyclobutane pyrimidine dimer formation is a molecular trigger for solar-simulated ultraviolet radiation-induced suppression of memory immunity in humans.

We tested the hypothesis that DNA is a target for solar-simulated ultraviolet radiation (ssUVR)-induced suppression of the reactivation of memory immunity in humans. T4N5 liposomes contain the DNA repair enzyme T4 endonuclease V. This cleaves DNA at the site of ultraviolet radiation (UVR)-induced cyclobutane pyrimidine dimers (CPD), initiating DNA repair. It has previously been used to show that CPDs are a key molecular trigger for UVR-induced immunosuppression in mice. To determine whether CPD formation is involved in UVR immunosuppression in humans, nickel-allergic volunteers were irradiated with a range of doses of ssUVR. T4N5 or empty liposomes were then applied after irradiation. Nickel-induced recall immunity was assessed by reflectance spectrometry. T4N5 liposomes inhibited immunosuppression and prevented ssUVR from reducing the number of epidermal dendritic cells. T4N5 liposomes also reduced macrophage infiltration into irradiated epidermis. These studies show that enhanced removal of CPDs from human skin protects from immunosuppression, hence demonstrating that these photolesions are an important molecular event in ssUVR-induced immunosuppression in humans. CPDs also triggered loss of dendritic cells and infiltration by macrophages. It is possible that these changes to antigen presenting cells contribute to ssUVR induced suppression of recall immunity to nickel in humans.     

Reversibility of Acid-Inactivation of Bacillus subtilis’ α-Amylase

The inactivation of Bacillus subtilis’ α-amylase by acid was shown to be reversible. In the experiment, two different Bac. subtilis’ α-amylases, saccharifying and liquefying types, were used and the reversibility was investigated deviding into two processes of inactivation and reactivation. Both amylases showed the reversibility in a similar degree and in general the inactivated enzymes by acid were reactivated only by adjusting the pH to slightly alkaline values followed by incubation under certain conditions. However, the reversibility, especially, the reactivation was greatly influenced by several chemicals, the effect of certain chemicals being different according to the type of the bacterial amylase. Contrary to liquefying amylase, saccharifying amylase was insensitive to metal chelators but, nevertheless, the reactivation of the amylase was prevented by metal chelators. Also the reactivation of saccharifying amylase was inhibited by sulfhydryl reagents, although the native enzyme was quite insensitive to the chemicals. In the acid-inactivation and reactivation process, a reversible change in the ultraviolet absorption spectra of the enzymes was observed, and some discussion of the implication was presented.     

Mechanism of transient inhibition of DNA synthesis in ultraviolet-irradiated E. coli: inhibition is independent of recA whilst recovery requires RecA protein itself and an additional, inducible SOS function

Summary The mechanism of the inhibition and of the recovery of DNA synthesis in E. coli following UV-irradiation was analysed in several mutants defective in repair or in the regulation of the RecA-LexA dependent SOS response. Several lines of evidence indicated that inhibition is not an inducible function and is probably due to the direct effect of lesions in the template blocking replisome movement.Recovery of DNA synthesis after UV was largely unaffected by mutations in the uvrA, recB or umuC genes. Resumption of DNA synthesis does however require protein synthesis and the regulatory action of recA. Experiments with a recA constitutive mutant and recA 200 (temperature sensitive RecA) demonstrated that RecA protein itself is directly required but is not sufficient for recovery of DNA synthesis. We therefore propose that recovery of DNA synthesis depends upon the concerted activity of RecA and the synthesis of an inducible Irr (induced replisome reactivation) factor under RecA control. We suggest that the mechanism of recovery involves the action of Irr and RecA to promote movement of replisomes past non-instructive lesions, uncoupled from polymerisation and/or that Irr and RecA are required to promote re-initiation of a stalled replication complex downstream of a UV-lesion subsequent to such an uncoupling step.     

Inducible, error-free DNA repair in tsl recA mutants of E. coli

Summary Host cell reactivation and UV reactivation and mutagenesis of UV-irradiated phage were measured in tsl recA ⁺ and tsl recA host mutants. Host cell reactivation was slightly more efficient in the tsl recA strain compared to the tsl ⁺ recA strain. Phage was UV-reactivated in the tsl recA strain with about one-half the efficiency of that in the wild type strain, but there was no corresponding mutagenesis of phage. UV-reactivation was also slightly lower and mutagenesis several-fold lower than normal in the tsl recA ⁺ strain. To account for these observations, we propose that there is an inducible, error-free pathway of DNA repair in E. coli that competes with error-prone repair for repair of phage lesions.     

The Escherichia coli recA gene increases resistance of the yeast Saccharomyces cerevisiae to ionizing and ultraviolet radiation

Summary The Escherichia coli recA protein coding region was ligated into an extrachromosomally replicating yeast expression vector downstream of the yeast alcohol dehydrogenase promoter region to produce plasmid pADHrecA. Transformation of the wild-type yeast strains YNN-27 and 7799-4B, as well as the recombination-deficient rad52-t C5-6 mutant, with this shuttle plasmid resulted in the expression of the bacterial 38 kDa RecA protein in exponential phase cells. The wild-type YNN27 and 7799-4B transformants expressing the bacterial recA gene showed increased resistance to the toxic effects of both ionizing and ultraviolet radiation. RecA moderately stimulated the UV-induced mutagenic response of 7799-4B cells. Transformation of the rad52-t mutant with plasmid pADHrecA did not result in the complementation of sensitivity to ionizing radiation. Thus, the RecA protein endows the yeast cells with additional activities, which were shown to be error-prone and dependent on the RAD52 gene.     

Plasmolysis of Pteridium protoplasts: A study using light and scanning-electron microscopy

A study was undertaken using gametophytes of the fern Pteridium aquilinum to examine the effects of plasmolysis on the topography of protoplasts. Methods are described whereby the surfaces of non-isolated protoplasts can be observed in the plasmolysed condition using scanning electron microscopy. Plasmolysed gametophytes were also examined in the light microscope using differential interference contrast and ultra-violet fluorescence microscopy after staining with fluorescein diacetate. With scanning electron microscopy, plasmolysed protoplast surfaces appeared smooth with no evidence of wrinkling or infolding of excess membrane. The formation of irregular-shaped protoplasts, protoplasmic threads, subprotoplasts, and protoplasmic networks covering internal wall surfaces all provided evidence for strong wall adhesion of the protoplasm. The availability of membrane for uptake into folds or vesicles is therefore thought to be minimal. Transmission electron microscopy showed some protoplasmic threads to be plasmodesmata, the remainder being cell-wall contact points. Remnants of these threads were occasionally observed on isolated protoplasts in both the light and electron microscopes.     

Nucleotide excision repair and recombination are engaged in repair of trans-4-hydroxy-2-nonenal adducts to DNA bases in Escherichia coli

One of the major products of lipid peroxidation is trans-4-hydroxy-2-nonenal (HNE). HNE forms highly mutagenic and genotoxic adducts to all DNA bases. Using M13 phage lacZ system, we studied the mutagenesis and repair of HNE treated phage DNA in E. coli wild-type or uvrA, recA, and mutL mutants. These studies revealed that: (i) nucleotide excision and recombination, but not mismatch repair, are engaged in repair of HNE adducts when present in phage DNA replicating in E. coli strains; (ii) in the single uvrA mutant, phage survival was drastically decreased while mutation frequency increased, and recombination events constituted 48 % of all mutations; (iii) in the single recA mutant, the survival and mutation frequency of HNE-modified M13 phage was slightly elevated in comparison to that in the wild-type bacteria. The majority of mutations in recA^- strain were G:C → T:A transversions, occurring within the sequence which in recA⁺ strains underwent RecA-mediated recombination, and the entire sequence was deleted; (iv) in the double uvrA recA mutant, phage survival was the same as in the wild-type although the mutation frequency was higher than in the wild-type and recA single mutant, but lower than in the single uvrA mutant. The majority of mutations found in the latter strain were base substitutions, with G:C → A:T transitions prevailing. These transitions could have resulted from high reactivity of HNE with G and C, and induction of SOS-independent mutations.     

Chainia Penicillin V Acylase: Strain Characteristics, Enzyme Immobilization, and Kinetic Studies

Aerobic cultures of an actinomycete were found to produce penicillin V acylase (PVA) (PA, EC-3.5.1.11) extracellularly. The presence of L-2-3 diamino-propionic acid in cell wall and formation of sclerotia on culture media led to its identification as Chainia, a sclerotial Streptomyces. Partially purified acylase was adsorbed on kieselguhr and entrapped in polyacrylamide gel. The immobilized preparation proved effective with respect to retention of enzyme and enzyme activity even after 15 successful cycles. The pH optimum for crude enzyme was in the range of pH 7.5–8.0, and for the (NH4)₂ SO₄ fraction it was pH 8.5. The immobilized enzyme showed maximal activity at pH 9.5. The optimum temperature for acylase activity was at 55°C. The crude enzyme, ammonium sulfate fraction, and immobilized enzyme showed K _m value for penicillin V of 6.13 mM, 14.3 mM, and 17.1 mM, respectively. Received: 11 December 1997 / Accepted: 9 April 1998     

Gene 49 endonuclease VII is not essential for multiplicity reactivation of bacteriophage T4

Summary Endonuclease VII, the product of phage T4 gene 49, has been shown previously to resolve Holliday structures in vitro. Two different processes, genetic recombination and multiplicity reactivation are presumed to have Holliday structure intermediates. Other workers have shown that genetic recombination is reduced in a gene 49 mutant infection. However, in the present study, multiplicity reactivation of UV-irradiated ts or amber mutant phage defective in gene 49 was nearly identical to that of UV-irradiated wild-type phage T4. Thus endonuclease VII is not thought to be essential for multiplicity reactivation of phage T4.     

Interaction of RecBCD enzyme with DNA damaged by gamma radiation

Summary The DNA of a gene 2 mutant (T4 2 ^–) of phage T4 is degraded by RecBCD enzyme in the bacterial cytoplasm. Under normal conditions, recBCD ⁺ cells are therefore incapable of supporting the growth of phage T4 2 ^–. Only if the nucleolytic activity of RecBCD enzyme is absent from the cytoplasm are T4 2 ^–-infected bacteria able to form plaques. We found that recBCD ⁺ cells can form plaques if, before infection with T4 2 ^–, they have been exposed to gamma radiation. It is suggested that gamma ray-induced lesions of the bacterial DNA (e.g., double-strand breaks) bind RecBCD enzyme. This binding enables the enzyme to begin to degrade the bacterial chromosome, but simultaneously prevents its degradative action on the ends of minor DNA species, such as unprotected infecting phage chromosomes. Degradation of the chromosomal DNA, which occurs during the early postirradiation period, ceases about 60 min after gamma ray exposure. The reappearance of the nucleolytic action of RecBCD enzyme on T4 2 ^– DNA accompanies the cessation of degradation of bacterial DNA. Both, this cessation and the reappearance of the nucleolytic action of RecBCD enzyme on T4 2 ^– DNA depend on a functional recA gene product. These results suggest that postirradiation DNA degradation is controlled by the recA-dependent removal of RecBCD enzyme from the damaged chromosome. By making use of the temperature-sensitive mutant recB270, we showed that RecBCD-mediated repair of gamma ray-induced lesions occurs during the early postirradiation period, i.e. during postirradiation DNA degradation. It is shown that the RecD subunit of RecBCD enzyme also participates in this repair.