DNA injection proteins are targets of acridine-sensitized photoinactivation of bacteriophage P22

Viruses and other nucleoprotein complexes are inactivated on exposure to white light in the presence of acridine and related dyes. The mechanism is thought to involve generation of singlet oxygen or related species, but the actual molecular targets of the inactivating event have not been well defined. We have re-examined the mechanism of dye-sensitized photoinactivation taking advantage of the well characterized bacteriophage P22. Though the inactivated phage absorb to their host cells, the cells are not killed and genetic markers cannot be rescued from the inactivated phage. These observations indicate that the chromosome is not injected into the host cell. However, the DNA of the damaged particles shows no evidence of double-stranded breaks or crosslinking.The DNA injection process of P22 requires three particle-associated proteins, the products of genes 7, 16 and 20. Gp16, which can act in trans during injection, is inactivated in the killed particles. Sodium dodecyl sulfate/polyacrylamide gel analysis reveals that gp16, gp7 and gp20 are progressively covalently damaged during photoinactivation. However, this damage does not occur in particles lacking DNA, indicating that it is DNA-mediated. Similar findings were obtained with acridine orange, acridine yellow, proflavin and acriflavin.These results indicate that the actual targets for inactivation are the DNA injection proteins, and that the lethal events represent absorption of photons by acridine molecules stacked in a region of DNA closely associated with the injection proteins.     

On the complex formation of acridine dyes with DNA. VII. Dependence of the binding on the dye structure

The binding constants for the complex formation of more than twenty ring nitrogen-and amino-substituted acridine derivatives with calf thymas DNA were measured by a fluorescence method. DNA quenches the fluorescence of the aminoacridine dyes so long as both amino hydrogens are not substituted. These dyes show an enhancement of their fluorescence intensity in the presence of DNA. Typical representatives of both are proflavine and acridine orange derivatives, respectively. A discussion of steric and electronic influences of various substituents attached to the ring nitrogen and amino groups on the binding led to the concept of different conformations for intercalated acridines without amino groups and the aminoacridines. The electrostatic binding site of the former seems to be the positively charged ring nitrogen, while the binding sites in the aminoacridines are so located that the amino groups are directed towards the negatively charged DNA phosphates.     

The inhibition of ribonucleic acid polymerase by acridines

1. The aminoacridines, proflavine (3,6-diaminoacridine) and 9-aminoacridine, and a hydrogenated derivative, 9-amino-1,2,3,4-tetrahydroacridine, were shown to inhibit in vitro the DNA-primed RNA polymerase of Escherichia coli. The inhibition is strong with both proflavine and 9-aminoacridine, but weak with 9-amino-1,2,3,4-tetrahydroacridine. 2. The extent to which the three acridines bind to calf-thymus DNA in the enzyme medium was studied spectrophotometrically. The extent of binding decreases in the order: proflavine, 9-aminoacridine, 9-amino-1,2,3,4-tetrahydroacridine. Some evidence was also obtained for interaction between the nucleoside triphosphate substrates and proflavine or 9-aminoacridine; no such interaction was detectable with 9-amino-1,2,3,4-tetrahydroacridine. 3. Although the amount of acridine bound to DNA increases with increasing inhibition, a stage is reached where an increase in acridine concentration still causes an increase in inhibition, with practically no increase in the amount bound to DNA. 4. Plots of reciprocal rates against the reciprocal of DNA concentration were linear and had a common intercept when proflavine or 9-aminoacridine was present. Similar relations were obtained when the reciprocal concentration of nucleoside triphosphates was plotted. The observations are interpreted kinetically in terms of a competitive inhibition of the enzyme by proflavine or 9-aminoacridine and of a kinetic role for the DNA analogous to ;activation'. 5. This suggests that inhibitory acridine molecules can occupy the sites on the RNA polymerase that are specific for binding the nucleoside triphosphate substrate or the bases of the DNA, when these become accessible during the copying process.     

Quantum yields and fluorescence lifetimes of acridine derivatives interacting with DNA

Interactions of several acridine dyes with DNA from different species were studied by measuring fluorescence lifetimes in the 2–30-nsec range, using the single-photon counting technique, and by measuring fluorescence quantum yields in the steady state. The results confirm the existence of two principal site classes, one in which the dye fluorescence is quenched by interaction with guanine and another in which fluorescence results from the hydrophobic environment of the A·T base pairs. The emitting sites are found, in some cases, to exhibit fluorescent decay curves which can be resolved into two exponential components corresponding to a short and to a long lifetime. The deviation from one exponential component is particularly clear with rivanol, 9-aminoacridine, and quinacrine, with which one component is two or three times longer than the other. The relative proportion of these two components depends only slightly on the DNA base composition and does not depend on the nature of the acridine derivatives. We postulate that this lifetime heterogeneity corresponds to the two discrete steps in the complex formation elucidated by kinetic studies: the first step corresponds to a semi-intercalated, or “external,” dye with a short fluorescence lifetime and the second step corresponds to a totally intercalated dye with a long lifetime. In this model, we assumed that a transient opening of the site near a semi-intercalated dye induces solvent diffusion which in turn is responsible for its short-lived fluorescence.     

Photodynamic activity of dyes with different DNA binding properties II. T4 phage inactivation.

The photosensitizing efficiency of six dyes--proflavine, 9-aminoacridine, ethidium bromide, thiopyronine, pyronine and acridine red--have been compared on the basis of the inactivation of sensitized T4 phage caused by light irradiation. This reaction was only measurable after diffusion of the dye through the phage capsid and was not observed in the presence of either chloroquine or quinacrine; it followed a single-hit kinetics as a function of the irradiation time. With each dye, a double reciprocal plot of the inactivation constant versus the dye concentration present gave rise to a linear relationship. From this relation, parameters were deduced which expressed the relative photosensitizing efficiencies. Dye-binding to the phages was measured and the proflavine-mediated inactivation appeared to be related to the amount of strongly bound molecules. Such a conclusion could not be reached in the case of 9-aminoacridine and ethidium bromide, which were much less efficient photosensitizers than proflavine, but which were also strongly bound to the phages. Thiopyronine was weakly bound to the phages; it had, however, the highest photosensitizing activity observed. These results indicate that various mechanisms are involved when the phage photosensitization is due to one dye or another.     

Studies on the structure of chemically methylated DNA

CD and melting temperature measurements on the nature of DNA with chemically methylated guanine-rich sites indicate that the stable secondary structure of DNA depicted by Ramstein et al- involves considerable distortions resulting from decreased base-base stacking interaction. Besides that quantum chemical data gained from PPP calculations are in favor of a weaker hydrogen bonding interaction in the methylated guanine-cytosine base pair. CD measurements demonstrate that methylated DNA-regions differ from the nonmethylated helical structure, since formation of a condensed conformation as occurs in the transition from B to the C-uke structure is prevented by positively charged methylated guanine residues. An increase in helix winding angle, however, can not be excluded. Binding ability of the dyes acridine orange, phenosafranine, and the antibiotic actinomycin C is lowered for methylated DNA, while binding of proflavine is, in accordance with the results of Ramstein and Leng, slightly enhanced. The reason for the opposite behavior of proflavine is at present not fully understood. In particular changes in the binding ability with dyes could not be correlated with base specificity of complex formation. It is discussed that structural changes in DNA towards a loose conformation decrease the binding tendency for acridine orange, phenosafranine, and actinomycin C.     

The Interaction of Acridine Dyes with the Densely Packed DNA of Bacteriophage

The interactions of acridine dyes with intact phage DNA differ from those with extracted DNA in the following respects. Strong binding (intercalation) is greatly reduced in intact phage but probably not eliminated. The cooperative, weak binding is stronger and the stacking tendency is increased. In gels of DNA the stacking tendency is seen to increase with decreasing hydration. These influences of the dense packing of DNA must be taken into account when using basic dyes to study chromosome structure.     

Binding of 9-aminoacridine to deoxydinucleoside phosphates of defined sequence: Preferences and stereochemistry

The effect of sequence on the binding of 9-aminoacridine to DNA has been investigated by studying its interaction with deoxydinucleoside phosphates of different sequences using proton nuclear magnetic resonance. Quantitative binding information can be obtained by comparison of the proton chemical shift behavior of 9-aminoacridine upon addition of dinucleoside phosphate to various models for the interaction using least-squares computer fitting procedures. The simplest model that fits the data includes (1) dimerization of 9-aminoacridine and (2) a mixture of 1:1 and 2:1 (dinucleoside phosphate/9-aminoacridine) complexes. The computed parameters allow comparison of binding constants and stereochemistry for different sequences. The 1:1 complexes seem to involve interaction of the ring nitrogen with the backbone phosphate and stacking of one or both chromophores on the acridine; preference in binding is observed for alternating (purine-pyrimidine or pyrimidine-purine) over non-alternating (purine-purine) dinucleoside phosphates. The 2:1 complexes involve intercalation of the acridine between two complementary dinucleoside phosphate strands with weak sequence preferences in binding. The stereochemistry of intercalation differs between non-alternating purine-purine sequences and the alternating pyrimidine-purine or purine-pyrimidine sequences in having the 9-aminoacridine stacked with the purines of one strand rather than straddling the purines on opposite strands. The difference in stereochemistry could possibly be a determining factor in frameshift sequence specificity.     

Photosensitized inactivation of T7 phage as surrogate of non-enveloped DNA viruses: efficiency and mechanism of action

We investigated the efficiency and the mechanism of action of a tetraphenyl porphyrin derivative in its photoreaction with T7 phage as surrogate of non-enveloped DNA viruses. TPFP was able to sensitize the photoinactivation of T7 phage in spite of the lack of its binding to the nucleoprotein complex. The efficiency of TPFP photosensitization was limited by the aggregation and by the photobleaching of porphyrin molecules. Addition of sodium azide or 1,3-dimethyl-2-thiourea (DMTU) to the reaction mixture moderated T7 inactivation, however, neither of them inhibited T7 inactivation completely. This result suggests that both Type I and Type II reaction play a role in the virus inactivation. Optical melting studies revealed structural changes in the protein part but not in the DNA of the photochemically treated nucleoprotein complex. Polymerase chain reaction (PCR) also failed to demonstrate any DNA damage. Circular dichroism (CD) spectra of photosensitized nucleoprotein complex indicated changes in the secondary structure of both the DNA and proteins. We suggest that damages in the protein capsid and/or loosening of protein-DNA interaction can be responsible for the photodynamic inactivation of T7 phage. The alterations in DNA secondary structure might be the result of photochemical damage in phage capsid proteins.     

Competitive interaction of serotonin and the dye acridine orange with DNA

The interaction of serotonin and acridine orange dye with DNA isolated from bacterium Escherichia coli and the yeast Candida utilis has been analysed by spectrofluorimetric method. Using data on competitive binding to DNA of serotonin and acridine orange, known as DNA intercalator, a conclusion concerning the formation of intercalated complex between serotonin and DNA has been made. It is shown that for yeast DNA the constant of intercalated binding of serotonin is 3,5-fold smaller than for the bacterial one.     

Photoinactivation of bacteriophage PM2 by cyanine dyes]

Photoinactivation of the lipid-containing bacteriophage PM2 by visible light and cyanine dyes (carbo- and dicarbocyanines), aluminum phtalocyanine tetrasulfonate and methylene blue was studied. It was concluded that cyanine dye aggregates adsorbed on phage particles and oxygen are essential for phage photoinactivation.     

9-Aminoacridine mutagenesis of bacteriophage T4 intracellular DNA.

Most of the intracellular T4 DNA made in the presence of 9-aminoacridine is of lower molecular weight than mature T4 DNA and does not get packaged into phage particles. Using a T4 DNA transformation assay, we have examined this intracellular T4 DNA for its content of 9-aminoacridine-induced revertants of certain rII gene frameshift mutations. The proportion of acridine-induced revertants in the intracellular DNA population is close to that found in the phage progency made in the presence of 9-aminoacridine. Thus, the generation of low molecular weight T4 DNA in the presence of 9-aminoacridine is not, in itself, also a mutagenic process.     

Intercalation Model for DNA-Cross Linking in a 1-Nitro-9-aminoacridine Derivative,an Analog of the Antitumor Agent “Ledakrin” (Nitracrine)

Abstract

Ledakrin (nitracrine), C-283, is a 1-nitro-9-aminoacridine derivative that is used in Poland as an antitumor agent. In order to investigate the basis of the activity of this compound the structure of another analog, [9-(3-dimethyl-l-methylpropylimino)-l-nitro-9, 10-dihydroacridine], C-829, that has similar activity, was determined by X-ray crystallographic techniques and was compared with that of ledakrin, already reported in the literature. In both molecules the proximity of the 1-nitro to the substituted 9-aminoacridine group causes extensive distortions. These compounds are believed to act, after metabolic “activation”, by cross-linking DNA. Such cross-linking does not occur in the absence of the 1-nitro group or if the nitro group is moved to the 2-, 3- or 4-position. Computer-assisted model-building has been used to test possible intercalative models. It has shown that functional groups on C-829 or C-283 are, when the acridine portion of the molecule is intercalated as in a proflavine dinucleoside phosphate complex, in positions suitable for DNA cross-linking by activated 1-nitro- 9-aminoacridine derivatives.     

Ultraviolet photosensitivity of the estrogen binding protein from rat uterus. Wavelength and ligand dependence. Photocovalent attachment of estrogens to proteins.

Ultraviolet irradiation of the estrogen binding protein in rat uterine cytosol results in a progressive photoinactivation which is rapid at 254 nm and slower at greater than 315 nm. Both unfilled and estradiol-filled sites are inactivated at approimately the same rates at 254 nm (t 1/2 equals 8 min and 11 min, respectively), but at 315 nm, empty sites are consumed much more rapidly (t 1/2 equals 3.4 hr) than filled ones (t 1/2 equals 24 hr). The protective effect of the estrogen ligand at this wavelength appears to depend on its binding to the estrogen-specific binding site, as inactivation rate studies at different concentrations of estrone, estradiol, and estriol show a good correlation between the extent of protection and the fractional saturation of the high affinity estrogen binding sites. Scatchard analysis indicates that inactivation is the result of a loss of binding sites and not a decrease in their affinity, and sedimentation analysis shows that increased heterogeneity and aggregation of the estrogen binding species accompanies the photoinactivation process. Photoinactivation appears to be the result of direct irradiative damage of the animo acid residues, as the inactivation rate is the same under air and nitrogen atmospheres, and is unaffected by nucleophiles, reductants, and radical scavengers. When photoinactivation is measureed by irradiation of cytosol containing [3-H]estradiol, a concurrent photocovalent attachment process is noted; the steroid becomes linked to protein in a solvent-extractable manner (boiling ethanol inextractable). This attachment, however, does not appear to be related to the steroid binding at the estrogen binding site. Its rate is affected by reductants and scavengers. A similar photocovalent attachment reaction occurs when bovine serum albumin or ovalbumin is irradiated in the presence of [3-H]estradiol or [3-H]diethylstilbestrol. The detailed reactions involved in this photocovalent attachment process have not been defined at present.     

Layer-by-layer deposition of oppositely charged polyelectrolytes on the surface of condensed DNA particles.

DNA can be condensed with an excess of poly-cations in aqueous solutions forming stable particles of submicron size with positive surface charge. This charge surplus can be used to deposit alternating layers of polyanions and polycations on the surface surrounding the core of condensed DNA. Using poly-L-lysine (PLL) and succinylated PLL (SPLL) as polycation and polyanion, respectively, we demonstrated layer-by-layer architecture of the particles. Polyanions with a shorter carboxyl/backbone distance tend to disassemble binary DNA/PLL complexes by displacing DNA while polyanions with a longer carboxyl/backbone distance effectively formed a tertiary complex. The zeta potential of such complexes became negative, indicating effective surface recharging. The charge stoichiometry of the DNA/PLL/SPLL complex was found to be close to 1:1:1, resembling poly-electrolyte complexes layered on macrosurfaces. Recharged particles containing condensed plasmid DNA may find applications as non-viral gene delivery vectors.     

The sequence selectivity of DNA-targeted 9-aminoacridine cisplatin analogues in a telomere-containing DNA sequence

In this study, the detailed DNA sequence specificity of four acridine Pt complexes was examined and compared with that of cisplatin. The DNA sequence specificity was determined in a telomere-containing DNA sequence using a polymerase stop assay, with a fluorescent primer and an automated capillary DNA sequencer. The Pt compounds included an acridine intercalating moiety that was modified to give a 9-aminoacridine derivative, a 7-methoxy-9-aminoacridine derivative, a 7-fluoro-9-aminoacridine derivative and a 9-ethanolamine-acridine derivative. Compared with cisplatin, the DNA sequence specificity was most altered for the 7-methoxy-9-aminoacridine compound, followed by the 9-aminoacridine derivative, the 7-fluoro-9-aminoacridine compound and the 9-ethanolamine-acridine derivative. The DNA sequence selectivity for the four acridine Pt complexes was shifted away from runs of consecutive guanines towards single guanine bases, especially 5′-GA dinucleotides and sequences that contained 5′-CG. The sequence specificity was examined in telomeric and non-telomeric DNA sequences. Although it was found that telomeric DNA sequences were extensively damaged by the four acridine Pt complexes, there was no extra preference for telomeric sequences.     

Influence of Drug Binding on DNA Flexibility: A Normal Mode Analysis

Abstract

DNA-drug complexes are important because of their pharmacological interest but, in addition, they provide a useful model to study the essential aspects of DNA recognition processes. In order to investigate the influence of ligand binding on the dynamic properties of DNA we have carried out normal mode analysis for complexes with drugs of two types: a typical intercalator, 9-aminoacridine, and a typical groove binder, netropsin. Normal modes are analysed in terms of helicoidal parameter variations with special attention being paid to global deformations of the double helix. The results show that the influence of these two drugs is very different. Intercalation of 9-aminoacridine leads to an increase in the flexibility of the intercalated dinucleotide step, with notably larger vibrational amplitudes for both roll and twist parameters compared to free DNA. In contrast, the groove binding of netropsin induces a stiffening of the DNA segment which is in contact with the drug reflected by decreased vibrational amplitudes for backbone angles and inter base pair helicoidal parameters and an increase in vibrations for adjacent base pairs in terms of buckle and propeller twist.     

De-intercalation of ethidium bromide and acridine orange by xanthine derivatives and their modulatory effect on anticancer agents: a study of DNA-directed toxicity enlightened by time correlated single photon counting

Time Correlated Single Photon Counting (TCSPC) was used for the first time to analyze the effect/changes in the mode of intercalation of ethidium bromide (EtBr) and acridine orange (AO) to calf thymus DNA brought about due to interaction of naturally occurring methylxanthines such as theophylline (X1), theobromine (X2) and caffeine (X3). UV absorption and fluorescence studies were also carried to observe the behaviour of these xanthines on the modulation of the binding mode of anticancer agents (cisplatin, novantrone, and actinomycin D) and certain intercalating dyes (EtBr and AO) to DNA. In TCSPC analysis we found that when the concentration of the drugs (X1, X2 and X3) increased from 0.025 mM to 2 mM i.e. P/D 2.4 to P/D 0.03 reduction in intercalation of EtBr and AO was observed, suggesting that xanthine derivatives could play very important role in reducing the DNA-directed toxicity in a dose dependent manner. In TCSPC, the amplitude of smaller lifetime component A(1) and higher lifetime component A(2) are attributed to free and intercalated dye concentration and their variation could indicate the process of intercalation or reduced intercalation of EtBr and AO by xanthine derivatives. We found that at the maximum drug concentration the smaller lifetime component A(1) was increased by 7-8% and 17-37% in EtBr and AO intercalated complex respectively. Also the changes in lifetime and fluorescence decay profile were observed for the DNA-intercalated dyes before and after treatment with xanthines. Especially, at maximum P/D 0.03 the lifetime of DNA-intercalated EtBr and AO reduced by 1-2 ns. The present analysis reveals that xanthines are able to interact with free dyes and also with intercalated dyes, suggesting that when they interact with free dyes they might inhibit the further intercalation of dye molecules to DNA and the interaction with intercalated dyes might lead to displacement of the dyes resulting in de-intercalation. The results obtained from UV and fluorescence spectroscopy also support the present investigation of probable interaction of xanthines with the DNA damaging agents in modulating/reducing the DNA-directed toxicity.     

Complexes of derivatives of 1-nitro-9-aminoacridine with DNA.

Substituted 1-nitro-9-aminoacridine derivatives were shown to inhibit RNA and to a lesser extent protein synthesis in cultured human cells. Complex formation between the compounds studied and DNA were considered to be responsible for their cytostatic action. Two types of complexes differing in their binding forces were found. The biological activity of the studied compounds seems not to be dependent on the existence of a positive charge on the acridine ring.     

Study of the interaction of DNA and acridine orange by various optical methods

The degree of binding of acridine orange to DNA, native or denatured, has been determined by equilibrium dialysis in 0.1M and 0.001M NaCl at 20°. The nature of the binding process has been investigated by studying various optical properties of the dye–DNA complexes and by relating them to the binding ratio. All these properties were found to vary quantitatively and qualitatively according to the successive stages of the process. These stages were assumed to be a strong binding of intercalated monomers followed by formation of bound dimers and finally by external binding of aggregates of native DNA. Absorption spectra of the complexes could be interpreted on that basis. Circular dichroism spectra were resolved into components: one band for intercalated monomers without interactions, two excition splittings for interacting monomers and bound dimers, respectively, weak bands and exciton splitting for external aggregates. The fluorescence intensity was greatly enhanced in intercallated monomers; its quenching at higher binding ratio was quantitatively related to dimer fixation. The value of the anisotropy of fluorescence at low binding ratio suggested a limited mobility of intercalated monomers; the decrease of polarization at higher binding was attributed to energy transfer between monomers. Electric dichroism displayed by the complexes in the dye absorption bands indicated an orientation of the bound molecules quite parallel to the base rings at low binding. In the range of fixation of dimers and external molecules, the dichroism was lower but still indicated an important degree of ordering.