Role of Phage Capsid in the Resistance to UV-C Radiations

The conformational variation of the viral capsid structure plays an essential role both for the environmental resistance and acid nuclear release during cellular infection. The aim of this study was to evaluate how capsid rearrangement in engineered phages of M13 protects viral DNA and peptide bonds from damage induced by UV-C radiation. From in silico 3D modelling analysis, two M13 engineered phage clones, namely P9b and 12III1, were chosen for (i) chemical features of amino acids sequences, (ii) rearrangements in the secondary structure of their pVIII proteins and (iii) in turn the interactions involved in phage capsid. Then, their resistance to UV-C radiation and hydrogen peroxide (H2O2) was compared to M13 wild-type vector (pC89) without peptide insert. Results showed that both the phage clones acquired an advantage against direct radiation damage, due to a reorganization of interactions in the capsid for an increase of H-bond and steric interactions. However, only P9b had an increase in resistance against H2O2. These results could help to understand the molecular mechanisms involved in the stability of new virus variants, also providing quick and necessary information to develop effective protocols in the virus inactivation for human activities, such as safety foods and animal-derived materials.

Self-Assembled Phage-Based Colloids for High Localized Enzymatic Activity

Catalytically active colloids are model systems for chemical motors and active matter. It is desirable to replace the inorganic catalysts and the toxic fuels that are often used with biocompatible enzymatic reactions. However, compared to inorganic catalysts, enzyme-coated colloids tend to exhibit less activity. Here, we show that the self-assembly of genetically engineered M13 bacteriophages that bind enzymes to magnetic beads ensures high and localized enzymatic activity. These phage-decorated colloids provide a proteinaceous environment for directed enzyme immobilization. The magnetic properties of the colloidal carrier particle permit repeated enzyme recovery from a reaction solution, while the enzymatic activity is retained. Moreover, localizing the phage-based construct with a magnetic field in a microcontainer allows the enzyme-phage-colloids to function as an enzymatic micropump, where the enzymatic reaction generates a fluid flow. This system shows the fastest fluid flow reported to date by a biocompatible enzymatic micropump. In addition, it is functional in complex media including blood, where the enzyme-driven micropump can be powered at the physiological blood-urea concentrations.

Visible-light-driven photocatalytic inactivation of bacteriophage f2 by Cu-TiO2 nanofibers in the presence of humic acid

Pathogenic viruses in drinking water are great threats to public health. Visible-light-driven photocatalysis is a promising technology for virus inactivation. However, the existing photocatalytic antiviral research studies have mostly been carried out in single-component systems, neglecting the effect of natural organic matter, which exists widely in actual water bodies. In this paper, electrospun Cu-TiO₂ nanofibers were prepared as photocatalysts, and their photocatalytic antiviral performance in the presence of humic acid (HA) was comprehensively studied for the first time. The properties of the reaction mixture were measured during the reaction. In addition, the safety, reliability and stability of photocatalytic disinfection in the mixed system were evaluated. The results showed that the virus removal efficiency decreased with the increase of the HA concentration. The type of reaction solution, such as PBS buffer solution or water, did not affect the removal efficiency noticeably. Under acidic conditions, the electrostatic forces between photocatalysts and viruses were strengthened, leading to higher virus removal efficiency. As the reaction time went on, the pH value in the solution increased first and then tended to be stable, the conductivity remained stable, and the dissolved oxygen increased first and then decreased. The safety test showed that the concentration of Cu ions released into the solution was lower than specified by the international standards. No photoreactivation was observed, and the addition of HA significantly reduced the reutilization efficiency of the photocatalysts.

Cytotoxic and mutagenic properties of O6-alkyl-2'-deoxyguanosine lesions in Escherichia coli cells

Environmental exposure and cellular metabolism can give rise to DNA alkylation, which can occur on the nitrogen and oxygen atoms of nucleobases, as well as on the phosphate backbone. Although O6-alkyl-2'-deoxyguanosine (O6-alkyl-dG) lesions are known to be associated with cancer, not much is known about how the alkyl group structures in these lesions affect their repair and replicative bypass in vivo or how translesion synthesis DNA polymerases influence the latter process. To answer these questions, here we synthesized oligodeoxyribonucleotides harboring seven O6-alkyl-dG lesions, with the alkyl group being Me, Et, nPr, iPr, nBu, iBu, or sBu, and examined the impact of these lesions on DNA replication in Escherichia coli cells. We found that replication past all the O6-alkyl-dG lesions was highly efficient and that SOS-induced DNA polymerases play redundant roles in bypassing these lesions. Moreover, these lesions directed exclusively the G → A mutation, the frequency of which increased with the size of the alkyl group on the DNA. This could be attributed to the varied repair efficiencies of these lesions by O6-alkylguanine DNA alkyltransferase (MGMT) in cells, which involve the MGMT Ogt and, to a lesser extent, Ada. In conclusion, our study provides important new knowledge about the repair of the O6-alkyl-dG lesions and their recognition by the E. coli DNA replication machinery. Our results suggest that the lesions' carcinogenic potentials may be attributed, at least in part, to their strong mutagenic potential and their efficient bypass by the DNA replication machinery.

Mutation spectrum resulting in M13mp2 phage DNA exposed to N-nitrosoproline with UVA irradiation

N-nitrosoproline (NPRO) is endogenously formed from proline and nitrite. In an effort to delineate the mechanism of NPRO-induced photomutagenicity, we investigated the mutagenic spectrum of NPRO on M13mp2 DNA with UVA irradiation. Following exposure to NPRO and UVA, the mutation frequency increased significantly in an NPRO and UVA dose-dependent manner. The sequence data derived from seventy of the mutants indicated that mutagenesis resulted mainly from an increase in single-base substitutions, the most frequent being GC to CG transversions. Non-clustering of the GC to CG mutations suggests that NPRO+UVA damage to DNA is random. These transversions may be caused by guanine adducts in DNA or in part by oxidatively modified guanine in DNA exposed to NPRO and UVA.

Rheology and DWS microrheology of concentrated suspensions of the semiflexible filamentous fd virus

Microrheology measurements were performed on suspensions of bacteriophage fd with diffusive wave spectroscopy in the concentrated regime, at different values of ionic strength. Viscosity vs. shear rate was also measured, and the effect of bacteriophage concentration and salt addition on shear thinning was determined, as well as on the peaks in the viscosity vs. shear curves corresponding to a transition from tumbling to wagging flow. The influence of concentration and salt addition on the mean square displacement of microspheres embedded in the suspensions was determined, as well as on their viscoelastic moduli up to high angular frequencies. Our results were compared with another microrheology technique previously reported where the power spectral density of thermal fluctuations of embedded micron-sized particles was evaluated. Although both results in general agree, the diffusive wave spectroscopy results are much less noisy and can reach larger frequencies. A comparison was made between measured and calculated shear modulus. Calculations were made employing the theory for highly entangled isotropic solutions of semiflexible polymers using a tube model, where various ways of calculating the needed parameters were used. Although some features are captured by the model, it is far from the experimental results mainly at high frequencies.

Intracellular biogenic silver nanoparticles for the generation of carbon supported antiviral and sustained bactericidal agents

Intracellular silver nanoparticles produced by exposing silver ions to the fungus Aspergillus ochraceus were heat-treated in nitrogen environment to yield silver nanoparticles embedded in carbonaceous supports. This carbonaceous matrix embedded silver nanoparticles showed antimicrobial properties against both bacteria (Gram-positive and Gram-negative) and virus (M 13 phage virus). The bactericidal effects were noticed even after washing and repeated exposure of these carbon supported silver nanoparticles to fresh bacterial cultures, revealing their sustained activity.

Supersaturated dispersions of rodlike viruses with added attraction

The kinetics of isotropic-nematic (I-N) and nematic-isotropic (N-I) phase transitions in dispersions of rodlike fd viruses are studied. Concentration quenches were applied using pressure jumps in combination with polarization microscopy, birefringence, and turbidity measurements. The full biphasic region could be accessed, resulting in the construction of an experimental analog of the bifurcation diagram. The N-I spinodal points for dispersions of rods with varying concentrations of depletion agent (dextran) were obtained from orientation quenches using cessation of shear flow in combination with small-angle light scattering. We found that the location of the N-I spinodal point is independent of the attraction, which was confirmed by theory. Surprisingly, the experiments showed that also the absolute induction time, the critical nucleus, and the growth rate are insensitive of the attraction if the concentration is scaled to the distance to the phase boundaries.

Effect of synthetic hydroxy isothiocyanates on a bacterial virus and DNA

The Effect of hydroxy isothiocyanates on a bacterial virus and M13 DNA was examined. Hydroxy-substituted phenyl and phenyl alkyl isothiocyanates, especially 2-(3,4-dihydroxyphenyl)ethyl isothiocyanate(IT-Dop) synthesized from dopamine, showed antiviral activity on psiK. In transfection experiments with M13 mp DNA species, IT-Dop inhibited the single-stranded (SS) molecule more effectively than the double stranded replicative form (RF) DNA. These effects were dependent on reaction time, and on IT-Dop concentration. An additional experiment indicated that treatment with IT-Dop suppressed annealing (reassociation) of denatured DNA. These results indicate that IT-Dop reacts mildly with virus and SS DNA.

Inhibition of bacteriophage m13 replication with esterified milk proteins

Esterified milk proteins [methylated (Met) or ethylated (Et) alpha-lactalbumin (ALA), beta-lactoglobulin (BLG), and beta-casein (BCN)], unmodified native milk proteins, and native basic proteins (calf thymus histone and hen egg white lysozyme) were tested for their antiviral activity against the bacteriophage M13 and for their influence on its replication (except BCN). All esterified milk proteins showed an antiviral activity against the bacteriophage M13, proportional to the extent of esterification and, hence, to the increased basicity of the modified proteins. Antiviral activity of 100% Met-BLG disappeared after its pepsinolysis but not after its trypsinolysis. The antiviral activity of Met-BLG was much higher than that of native basic proteins (histone and lysozyme). One hundred percent Met-BLG and 73% Et-BLG inhibited the replication of bacteriophage M13 completely, whereas 60% Met-ALA inhibited phage replication partially. Calf thymus histone inhibited the replication of bacteriophage M13 at a lower extent (20%) than Met- and Et-BLG (100% inhibition). Protein concentration, pH, and concentration of the Escherichia coli culture in the preincubation medium of the virus were other factors influencing antiviral activity. Interactions of esterified proteins with the phage DNA (phenol extracted) followed the same pattern as observed during studies of the inhibition of the phage replication: Met-BLG > Et-BLG > or = Met-ALA.

Cobalt Ion Mediated Self-Assembly of Genetically Engineered Bacteriophage for Biomimetic Co−Pt Hybrid Material

Biological scaffolds are used for the synthesis of inorganic materials due to their ability to self-assemble and nucleate crystal formation. We report the self-assembly of engineered M13 bacteriophage as a template for Co-Pt crystals. A M13 phage library with an octapeptide library on the major coat protein (pVIII) was used for selection of binders to cobalt ions. Fibrous structures with directionally ordered M13 phage were obtained by interaction with cobalt ions. Co-Pt alloys were synthesized on the fibrous scaffold, and their magnetic properties were characterized. The mineralization showed organized nanoparticles on fibrous bundles. This approach using the phage pVIII library allows for genetic selection that both induces assembly of the phage and directs mineralization of the selected inorganic material.

Two-triplet CGA repeats impede DNA replication in bacteriophage M13 in Escherichia coli

Expansion and contraction instabilities associated with CAG, CGG, GAA and CGA (GAC) repeats propagation cause more than a dozen human genetic diseases and cancers. In this work, the propagation behavior of a bacteriophage M13 carrying a calf prochymosin cDNA fragment with a (CGA)2 repeat in a small hairpin forming region is reported. Such a M13 derivative when propagated in Escherichia coli, produces small plaques by decreasing phage yield and also mitigates the inhibition on host cell growth, compared to those control bacteriophages either containing a "CTGCTA" sequence or wildtype, suggesting that CGA2 repeat impedes DNA replication in vivo. Moreover, an increased internal free energy is found associated with (CGA)2 sequence compared to those "CTGCTA" and wildtype, which ruled out a possibility of CGA2 repeat effects on propagation is through influencing the hairpin structure formation.

The effect of an agglutogen on virus infection: biotinylated filamentous phages and avidin as a model

To address the effect of an agglutogen on virus infection, we studied the avidin-associated inhibition of infection by biotinylated M13 phages (BIO-phages). Microscopic observation of mixtures of BIO-phages and avidin-fluorescein conjugates revealed many aggregates. Even at low phage concentrations, avidin induced inhibition of infection significantly. Anti-M13 phage antibody also made aggregates and inhibited the infection but in a different manner from avidin. The inhibition by avidin was at > or = 2 microg/ml, time dependent and marked until 10 min after the mixing of the BIO-phages and Escherichia coli. On the other hand, antibody inhibited the infection at > or = 0.1 microg/ml dose dependently, and the inhibition was time dependent and marked until 45 min after the mixing at moderate and low phage concentrations. These results indicate that avidin against BIO-phages and antibodies are agglutogens, and the inhibition of the BIO-phages by avidin is closely related to the tetramerization of avidin. Agglutogens may be novel alternative antiviral drugs.

Novel peptides that inhibit the propagation of Newcastle disease virus

A disulfide constrained random heptapeptide library displayed on filamentous bacteriophage M13 was applied to select specific ligands that interact with Newcastle disease virus (NDV). A fusion phage carrying the amino acid sequence TLTTKLY was selected from the panning procedure. An antibody competition assay showed that the selected phage was capable of competing with the polyclonal antibodies raised against NDV for binding sites on the virus. Determination of the binding affinity of this phage with NDV by an equilibrium binding assay in solution revealed two different dissociation constants, suggesting that there could be two distinct binding sites for the phage on NDV. Synthetic peptides with the sequence CTLTTKLYC, either in linear or cyclic conformations inhibited the binding of phage bearing the same sequence to NDV. These peptides also inhibited the hemolytic activity of the virus as well as its propagation in embryonated chicken eggs.

Oxidative damage and induced mutations in m13mp2 phage DNA exposed to N-nitrosopyrrolidine with UVA radiation

N:-Nitrosopyrrolidine (NPYR) is carcinogenic in rodents and undergoes alpha-hydroxylation upon microsomal CYP450 metabolism, giving rise to mutations. Previously, we reported the direct mutagenicity of NPYR, under ultraviolet A (UVA) irradiation, towards Salmonella typhimurium and phage M13mp2. In the present study, we measured the formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodGuo) in a replicative form of M13mp2 DNA exposed to NPYR plus UVA. Formation of 5-hydroxy-2'-deoxycytidine in calf thymus DNA treated with NPYR plus UVA was also observed. Singlet oxygen is likely to account for the formation of 8-oxodGuo. We analyzed the spectrum of mutations in lacZalpha of M13mp2 phages produced on transfecting Escherichia coli with the replicative form of phage DNA that had been treated with NPYR plus UVA. The role of oxidative DNA damage in mutagenesis was explored using mutM-proficient and -deficient E.coli strains as the hosts. A higher level of mutation was observed with the mutM-deficient host than with the -proficient host. Base substitutions at GC pairs predominated in both mutM-proficient and -deficient hosts. With the mutM-deficient host, we observed an overall increase in the percentage of GC-->TA transversions. In addition we noted that there were fewer GC-->AT transitions than in the mutM-proficient host. With these hosts, different hot spots were observed and a new GC-->TA hot spot was produced. The formation of 8-oxodGuo in DNA, which is known to induce GC-->TA transversion, may contribute to mutagenesis by NPYR plus UVA.

The efficiency of Escherichia coli selenocysteine insertion is influenced by the immediate downstream nucleotide

Selenocysteine (Sec) incorporation requires the TGA opal codon and a downstream Sec insertion sequence (SECIS), which can be partially randomized and cloned into M13 pIII fusion constructs for phage display. This combinatorial approach provides a convenient non-radioactive assay that couples phage production to opal suppression. Two SECIS libraries were prepared, with the immediate downstream nucleotide either randomized (TGAN) or fixed as thymidine (TGAT). The TGAN library resulted in a majority of clones with a downstream purine and selenium-independent phage production, implicating the endo-genous tryptophan-inserting opal suppression pathway. Although the addition of sodium selenite to the growth medium did not affect phage production, it did increase the level of Sec insertion, as shown by the chemical reactivity of the resulting phage. The TGAT phage library yielded clones with strictly selenium-dependent phage production and reactivity consistent with the presence of Sec. These clones were prone to spontaneous mutation upon further propagation, however, resulting in loss of the selenium-dependent phenotype. We conclude that the immediate downstream nucleotide determines whether the endogenous opal suppression pathway competes with co-translational Sec insertion.

SOS-dependent A-->G transitions induced by hydroxyl radical generating system hypoxanthine/xanthine oxidase/Fe3+/EDTA are accompanied by the increase of Fapy-adenine content in M13 mp18 phage DNA

Gas chromatography/isotope dilution-mass spectrometry with selected ion monitoring (GC/IDMS-SIM) was used to measure oxidised bases in hypoxanthine/xanthine oxidase/Fe3+/EDTA modified ss M13 mp18 phage DNA. A dose-dependent increase of oxidised bases content in DNA was observed with the biggest augmentation of FapyGua, thymine glycol and FapyAde. The amount of 8-OH-Gua was relatively high both in non-oxidised and oxidised DNA, and increased to the same extent as FapyAde and ThyGly. DNA oxidation caused a dramatic decrease in phage survival after transfection to E. coli. Survival was improved 2.8-fold after induction of the SOS system by UV irradiation of bacteria and mutation frequency of the lacZ gene in SOS conditions increased 7-fold over that in non-irradiated bacteria. Spectrum of mutations was different from those reported previously and mutations were distributed rather randomly within M13 lacZ sequence, which was in contrast to previous findings, where with non-chelated metal ions other types of mutations were found in several clusters. Thus, conditions of DNA oxidation and accessibility of metal ions for DNA bases might be important factors for generating different DNA damages and mutations. Major base substitutions found both in SOS-induced and non-induced E. coli but with higher mutation frequency in SOS-induced cells were C-->A (approximately 20-fold increase in SOS-conditions), G-->A (9-fold increase) and G-->C (4.5-fold increase). Very few G-->T transitions were found. A particularly large group of A-->G transitions appeared only in SOS-induced bacteria and was accompanied by augmentation of FapyAde content in the phage DNA with undetectable 2-OH-Ade. It is then possible that imidazole ring-opened adenine mimics guanine during DNA replication and pairs with cytosine yielding A-->G transitions in SOS-induced bacteria.

Isolation of chloroform-resistant mutants of filamentous phage: localization in models of phage structure

Interaction of fd or M13 filamentous phage with a chloroform/water interface induces morphological change, contracting the filaments sequentially into shortened rods (I-forms), and then into spheroidal particles (S-forms). To further investigate this phage contraction, 34 and 26 chloroform-resistant isolates of fd and M13, respectively, were selected after chloroform treatment of wild-type phages at pH 8. 2 and 4 degrees C. DNA sequencing of gene VIII of the 34 fd isolates revealed five different mutants: these were D5H, M28L, V31L, I37T, and S50T. All 26 M13 isolates were I37T. These mutants exhibited variable sensitivity to chloroform, but all contracted much more slowly than wild-type phage during treatment at 4 degrees C. They all contracted like wild-type phage at 37 degrees C. Site-directed mutagenesis showed that the indicated single mutations carried the chloroform resistance. In structural models of the phage, the D5H locus is on the outside and the S50T locus is on the inside. The M28L and I37T loci are buried in a mostly hydrophobic region in the middle. Although these four mutants are spread out radially, they are localized in the axial direction into a thin disk in the model. The last mutant locus, V31L, is out of this disk, but this locus is proximal to the M28L and I37T loci and also in contact with the surface via a deep hydrophobic hole or depression. These five mutants, their locations, and their variable affects on contraction suggest that chloroform-induced contraction involves a specific mechanism rather than a generalized solvent-induced denaturation and that the critical structural changes occur in a localized level in the phage. These results add weight to suggestions that the sequential contraction of filaments-->I-forms-->S-forms mimic corresponding steps in phage penetration, and, in the reverse order, for phage assembly.

Sunlight mutagenesis: changes in mutational specificity during the irradiation of phage M13mp2

We reported previously that the mutations in phage M13mp2, a single-stranded DNA phage, induced by sunlight exposure are predominated by G-to-C transversions. We have now made an unexpected observation that an exposure to sunlight for a short period of time results in induction mainly of C-to-T transitions while a longer exposure results in the induction of G-to-C transversions. This peculiar phenomenon suggests that DNA damage formed by initial sunlight exposure can be transformed during an elongated exposure. 7, 8-Dihydro-8-oxoguanine (8-oxoG) in DNA might be involved in the shift of the mutational specificity, as 8-oxoG was formed in the phage DNA upon the sunlight exposure. We also compared the mutagenic activity of UVB irradiation with that of sunlight exposure. The results demonstrate that the genotoxic properties of sunlight and UVB in phage M13mp2 mutagenesis are different. The shift in the mutational specificity associated with the dose of the sunlight may call for general cautions in the studies of agent-induced mutagenesis.

Mutagenesis by peroxy radical is dominated by transversions at deoxyguanosine: evidence for the lack of involvement of 8-oxo-dG1 and/or abasic site formation

Oxidative damage of DNA by endogenously generated oxygen radicals contributes to the mutagenic process. Hydroxy, alkoxy, and peroxy radicals all have the potential to react with DNA, giving rise to strand breaks and potentially mutagenic oxidative base damage. Although reactions of the hydroxy radical with DNA have been well studied, far less is known about the reactivities of these other radicals with DNA and their mutation-inducing potential. Frequencies of DNA base modifications and strand break densities caused by peroxy radical (ROO*) oxidation were measured by glyoxal gel electrophoretic analysis. We report the spectrum of mutations induced in Escherichia coli upon transfection with peroxy radical treated DNA carrying the lacZ alpha gene as a reporter. Transfection of DNA exposed to micromolar amounts of peroxy radical resulted in a 30-fold increase in mutation frequency in non-SOS-inducible cells. Sequencing analysis of DNA isolated from mutants showed that among base substitution mutants 88% consisted of transversions at G, with a nearly equal number of G --> C and G --> T mutants. Transition mutations were rarely detected, in contrast to control experiments. Electrophoretic analysis of peroxy radical treated DNA exposed to NaOH, Nth, and Fpg proteins demonstrated that abasic sites are not formed to any detectable degree. The oxidative G lesions are sensitive to digestion by the Fpg protein. We were unable to detect the formation of 8-oxo-dG by HPLC/electrochemical analysis of peroxy radical oxidation of dG, suggesting that the G --> T transversions were not caused by this base lesion.

Potential involvement of both type I and type II mechanisms in M13 virus inactivation by methylene blue photosensitization

We have investigated the mechanism of virus photoinactivation with methylene blue (MB) by conducting deuterium oxide (D2O), azide ion (N3-) and oxygen-dependent studies. Inactivation of M13 bacteriophage and singlet oxygen (1O2) generation by MB photosensitization were irradiation dose dependent. Inactivation of M13 was enhanced by D2O and inhibited by N3-, suggesting that 1O2 participates in M13 inactivation by MB photosensitization. However, N3- did not inhibit M13 inactivation completely. On the other hand, deoxygenating the reaction solution still caused 52-67% of M13 inactivation observed in the presence of oxygen. These results suggest that 1O2-mediated (Type II) and sensitizer-mediated (Type I) reactions may both play roles in M13 inactivation by MB photosensitization.

Nebularine (9-2'-deoxy-beta-D-ribofuranosylpurine) has the template characteristics of adenine in vivo and in vitro

Nebularine (9-beta-D-ribofuranosylpurine; Nb) is a naturally occurring nucleoside with structural features suggestive of a universal base. However, previous observations based on thermal melting characteristics of oligonucleotides suggested that Nb formed stable pairs only with thymine. To determine the template characteristics of Nb, we constructed M13 viral single-stranded DNA (ssDNA) molecules bearing a single site-specific deoxynebularine (9-2'-deoxy-beta-D-ribofuranosylpurine) residue. The ssDNA constructs were transfected into Escherichia coli cells to determine the specificity of base insertion opposite Nb, as well as to determine the effect of Nb on the replicability of the transfected DNA. Base insertion opposite Nb, analyzed by a multiplex sequencing technology, suggests that Nb has the template characteristics of adenine. Analysis of DNA replicability, measured as transfection efficiency, indicates that Nb does not block DNA replication. UV irradiation of host cells before transfection did not significantly affect survival or base insertion specificity within the limits of multiplex sequencing technology employed, suggesting that inducible mutagenic phenomena appear to have only minor effects on translesion synthesis across Nb. In addition, in vitro DNA elongation experiments on oligonucleotide templates using E. coli DNA polymerase I (Klenow fragment) as the model polymerase showed that Nb templates for T, but not for other bases under the tested conditions. The data reported in this communication underscore the importance of base-pair geometry as a specificity-determinant during base insertion by replicative polymerases.

Factors affecting M13 bacteriophage inactivation by methylene blue photosensitization

We have investigated the factors that affect the virucidal activity of methylene blue (MB) photosensitization. The M13 bacteriophage was more rapidly inactivated at higher temperatures (6 degrees C < 24 degrees C < 38 degrees C). Rate constants for inactivation were 0.072, 0.139 and 0.260 (log10 inactivation)/ (J/cm2) at 6 degrees C, 24 degrees C and 38 degrees C, respectively. On the other hand, dye penetration into virus particles, which was monitored by the fluorescence of YOYO-1, was unchanged with incubation temperature. These data suggest that temperature dependency of M13 inactivation was due to factors other than dye permeability. The pH of the virus suspension also affected the rate of M13 inactivation by MB. The M13 bacteriophage was inactivated faster in basic suspensions and slower in acidic suspensions compared with neutral buffers. These results suggest that temperature and pH are factors that influence the extent of MB photosensitization, and hence, the control of these factors will be necessary for MB phototreatment of plasma products in transfusion medicine.

Role of G-->T transversions in the mutagenicity of alkylperoxyl radicals: induction of alkali-labile sites in bacteriophage M13mp19

The mutagenicity of peroxyl radicals, ubiquitous products of lipid peroxidation, was assessed using an in vitro M13 forward mutational assay. Single-stranded M13mp19 plasmids were incubated with a range of concentrations of the azo initiator 2,2'-azobis(2-amidinopropane) hydrochloride, and then transfected into competent, SOS-induced Escherichia coli JM105 cells. Incubation with peroxyl radicals produced a concentration-dependent decrease in phage survival, with a 500 microM concentration of the azo initiator reducing the transfection efficiency by more than 90% while inducing a corresponding 6-fold increase in lacZ alpha mutation frequencies. Peroxyl radical-induced mutagenesis was completely prevented by the peroxyl radical scavenger Trolox. Automated DNA sequence analysis of the lacZ alpha gene of 100 peroxyl radical-induced mutants revealed that the most frequent sequence changes were base pair substitutions (92/95), with G-->T transversions predominating (73/92). Alkaline treatment prior to transfection diminished the mutagenicity of damaged plasmids to a level resembling that of unmodified DNA. While abasic sites might account for the sensitivity to alkaline cleavage, the possibility that unidentified nonabasic alkaline-labile lesions also contribute to peroxyl radical mutagenesis cannot be excluded. Collectively, these findings raise the possibility that DNA damage caused by a major class of endogenous radicals contributes to one of the most common spontaneous mutational events, the G-->T transversion.

Analysis of viral DNA, protein and envelope damage after methylene blue, phthalocyanine derivative or merocyanine 540 photosensitization

Although numerous photosensitizers have been used experimentally to decontaminate viruses in cellular blood components, little is known about their mechanisms of photoinactivation. Using M13 bacteriophage and vesicular stomatitis virus (VSV) as model viruses, we have investigated alteration of the viral genome, protein and envelope after phototreatment. Methylene blue (MB) and aluminum phthalocyanine tetrasulfonate (AlPcS4) phototreatment inactivated bacteriophage M13 and decreased the fraction of single-stranded circular genomic DNA (sc-DNA) by converting it to linear form. This conversion was enhanced by treating the extracted DNA with piperidine at 55 degrees C. Piperidine-labile breaks were well correlated to phage survival (5.1% sc-DNA at 1.7% phage survival for MB) under conditions where only minor differences were seen in the relative abundance of M13 coat protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Neither aluminum phthalocyanine (AlPc) nor merocyanine 540 (MC540) inactivated M13 nor were there significant changes observed in DNA and coat protein. Methylene blue, AlPcS4 and AlPc inactivated VSV and inhibited fusion of the virus envelope to Vero cells at pH 5.7 (i.e. with plasma membrane). However, the degree of this inhibition was small compared to the extent of virus inactivation (43% inhibition vs. 4.7 log10 or 99.998% inactivation, for MB). In contrast, an antibody to VSV G-spike protein inhibited fusion at pH 5.7 by 52% with a concomitant decline in VSV infectivity of 0.15 log10 (30%). Few changes were observed in the relative abundance of G protein for MB and AlPcS4 phototreated samples and no additional protein bands were observed on SDS-PAGE.(ABSTRACT TRUNCATED AT 250 WORDS)

Quencher-enhanced specificity of psoralen-photosensitized virus inactivation in platelet concentrates

BACKGROUND

Treatment with psoralens and UVA (PUVA) has been shown to be efficacious in eliminating the risk of virus transmission by platelet concentrates (PCs). It has previously been demonstrated that, during the inactivation of cell-free vesicular stomatitis virus (VSV) by aminomethyltrimethylpsoralen (AMT) and UVA in PCs, platelet function could be protected either by oxygen removal before irradiation or by inclusion of a type I free radical quencher, such as mannitol.

STUDY DESIGN AND METHODS

Under previous PUVA treatment conditions for PCs (25 micrograms/mL AMT; 30 min UVA at 7 mW/cm2; 2 mM [2 mmol/L] mannitol), more than 6 log10 of added cell-free VSV was completely inactivated. In the current study, various PUVA conditions are evaluated for efficacy in inactivating other viral forms that could be present in PCs. Maintenance of platelet integrity (i.e., platelet number, solution pH, and aggregation response during initial storage after treatment) and kill of cell-associated VSV are examined.

RESULTS

While cell-free viruses were inactivated efficiently under previous PUVA conditions, cell-associated VSV and the non-lipid-enveloped bacteriophage M13 were not. Effective inactivation of these viruses was achieved by raising the concentration of AMT to 50 micrograms per mL and extending the period of irradiation to 90 minutes (39 J/cm2). However, for maintenance of platelet integrity under these conditions, the prior removal of oxygen or the inclusion of compounds known to quench both type I and type II photoreactants (e.g., flavonoids such as rutin) was required.

CONCLUSION

These findings suggest that the viral safety of PCs may be enhanced through treatment with AMT and UVA in the presence of flavonoids, and that flavonoid use may prove beneficial in other systems where oxygen-mediated damage occurs.

Mutagenic and genotoxic effects of three vinyl chloride-induced DNA lesions: 1,N6-ethenoadenine, 3,N4-ethenocytosine, and 4-amino-5-(imidazol-2-yl)imidazole

The mutagenic and genotoxic properties of 1,N6-ethenoadenine (epsilon Ade), 3,N4-ethenocytosine (epsilon Cyt), and 4-amino-5-(imidazol-2-yl)imidazole (beta) were investigated in vivo. The former two modified bases are known DNA adducts formed by the human carcinogen vinyl chloride; beta is formed by pyrimidine ring-opening of epsilon Ade. Chemically synthesized deoxyhexanucleotides containing epsilon Ade and beta, d[GCT-(epsilon A)GC], and d[GCT(beta)GC], respectively, were described previously [Biochemistry (1987) 26, 5626-5635]. epsilon Cyt was inserted into an oligonucleotide, d[GCTAG(epsilon C)], by a mild enzymatic synthetic procedure, which avoided exposure of the base to alkaline conditions. 3,N4-Etheno-2'-deoxycytidine 3',5'-bisphosphate coupled with reasonable efficiency (30-40%) to the 3'-nucleoside of an acceptor pentamer, d(GCTAG), in a reaction catalyzed by T4 RNA ligase in the presence of ATP. Each of the three modified hexanucleotides and an unmodified control were inserted into a six-base gap positioned at a known site in the genome of bacteriophage M13-NheI. A nick was placed in the DNA strand opposite that containing the single DNA lesions, enabling the formation of singly adducted single-stranded genomes by denaturation. After transfection of the adducted phage DNAs into Escherichia coli, each of the adducts was found to be genotoxic. The most toxic lesion was beta, which reduced survival of the genome by 97%. epsilon Cyt and epsilon Ade reduced survival by 90% and 65%, respectively. An examination of the surviving phage populations revealed that each of the three adducts was mutagenic. The least mutagenic lesion was epsilon Ade (0.1% of the survivors were mutant), which showed primarily A-->G transitions.(ABSTRACT TRUNCATED AT 250 WORDS)

Mutagenic and recombinagenic effects of diethylstilbestrol quinone

Estrogens are believed to be major contributors to many cancers of the human female genital tract, but the mechanism of their carcinogenic action is not well-understood. While a tumor-promoting role for estrogens is well-supported, whether they also act as tumor initiators has remained controversial. Here, we have sought to examine the mutagenic potential of diethylstilbestrol, a synthetic estrogen that is a powerful carcinogen in hamsters, and is suspected to be a human carcinogen. Phage M13 single-stranded DNA was treated in vitro with diethylstilbestrol quinone (DES Q: 1.25 mM) and transfected into Escherichia coli cells. DES Q treatment resulted in an apparent enhancement of mutagenesis in the LacZ(alpha) gene segment. DNA sequence analysis of LacZ(alpha) mutants obtained by transfection of DES Q-treated DNA revealed that the major effect of DES Q treatment has been a 6-fold elevation of recombination between the phage-borne LacZ(alpha) sequence and the LacZ delta M15 sequence on the E. coli fertility plasmid F. To confirm whether DES Q treatment is recombinagenic, we used an experimental system that allows the detection of recombination between a defective E. coli chromosomal LacY gene and a normal counterpart borne on a plasmid. Transfection of DES Q (0.06-12 mM) treated plasmid DNA showed significant enhancement (2-100-fold) in recombination, but not in mutagenesis. These results raise the possibility that estrogen quinones may induce recombinagenic DNA damage.

Mutagenicity and genotoxicity of the major DNA adduct of the antitumor drug cis-diamminedichloroplatinum(II)

The mutagenicity and genotoxicity of cis-[Pt(NH3)2[d(GpG)-N7(1),-N7(2)]] (G*G*), the major DNA adduct of the antitumor drug cisplatin, has been investigated in Escherichia coli. A duplex bacteriophage M13 genome was constructed to contain the G*G* adduct at a specific site in the (-) strand. The singly platinated duplex genome exhibited a survival of 22% relative to that of the unplatinated control genomes, and this value rose to 38% in cells treated with ultraviolet light to induce the SOS response. Singly platinated single-stranded genomes were also produced. Replication of the single- and double-stranded genomes in vivo yielded SOS-dependent, targeted mutations at frequencies of 1.3% and 0.16%, respectively. The mutagenic specificity of G*G* in both single- and double-stranded DNA was striking in that 80-90% of the mutations occurred at the 5'-platinated G. Approximately 80% of the mutations were G-->T transversions at that site. A model of mutagenesis is presented to explain this mutational specificity with respect to current understanding of platinum-DNA adduct structure.

SOS-independent mutagenesis in lacZ induced by methylene blue plus visible light

In vitro photosensitization by visible light in the presence of methylene blue (MB-light) produces lesions in M13mp18 lacZ phage DNA, the lethal and mutagenic potential of which was analyzed after transfection into various bacterial hosts. Mutagenesis was determined with a forward mutation assay using the lacZ gene of M13mp18 as a target. When, MB-light-treated double-stranded (ds) M13mp18 DNA was used to transfect wild-type cells which were not induced for SOS functions, a fivefold increase in mutation frequency was observed at 10% survival compared to that observed with untreated DNA. Mutation frequency obtained with MB-light-treated ds M13mp18 DNA was greater when transfected into the uvr A fpg-1 double mutant than that seen in uvr A, fpg-1, or umuC single mutants or in the wild-type. Sequence analysis shows that in the wild-type strain, MB-light treatment of ds M13mp18 DNA results mostly in single base substitutions. The most frequent base change is the GC-->TA transversion. MB-light treatment of single-stranded (ss) M13mp18 DNA also results in an increased mutation frequency after transfection into the wild-type strain, yielding mostly G-->T transversions. Our results show that MB-light-induced mutagenesis is at least partially independent of the induction of SOS functions in Escherichia coli. The mutation spectra suggest that 8-oxo-7,8-dihydroguanine is the major promutagenic lesion in DNA.