G.M. Makrigiorgos

Radiotoxicity of 5-[123I]iodo-2'-deoxyuridine in V79 cells: a comparison with 5-[125I]iodo-2'-deoxyuridine

The toxic effects of the short-lived (T 1/2 = 13.2 h) Auger-electron-emitting isotope 123I, incorporated in the form of 123IUdR into the DNA of V79 cells in vitro, have been investigated and compared to those of 125IUdR. For the concentrations tested, the rate of incorporation of 123IUdR at any time is proportional to the concentration of extracellular radioactivity. The curve for survival of clonogenic cells decreases exponentially and exhibits no shoulder at low doses. The mean lethal dose (D37) to the nucleus is 79 +/- 9 cGy and is about the same as that obtained previously with 125IUdR. However, the total number of decays needed to produce this D37 with 123IUdR is about twice that required with 125IUdR, approximately equal to the ratio of the energy deposited in microscopic volumes by 125I and 123I, respectively. This correlation suggests that nuclear recoil, electronic excitation, and chemical transmutation are probably of minor importance to the observed biological toxicity with either isotope. The results also indicate that there are no saturation effects in the decay of 125IUdR in the DNA of V79 cells (i.e., all of the emitted energy is biologically effective) and that each of the two steps involved in the 125I decay is equally effective in causing biological damage.

A Method for Detection of Hydroxyl Radicals in the Vicinity of Biomolecules Using Radiation-induced Fluorescence of Coumarin

A novel method is described to quantitate radiation-induced hydroxyl radicals in the vicinity of biomolecules in aqueous solutions. Coumarin-3-carboxylic acid (CCA) is a non-fluorescent molecule that, upon interaction with radiation in aqueous solution, produces fluorescent products. CCA was derivatized to its succinimidyl ester (SECCA) and coupled to free primary amines of albumin, avidin, histone-H1, polylysine, and an oligonucleotide. When SECCA-biomolecule conjugates were irradiated, the relationship between induced fluorescence and dose was linear in the dose range examined (0.01-10 Gy). The fluorescence excitation spectrum of irradiated SECCA-biomolecule conjugates was very similar to that of 7-hydroxy-SECCA-biomolecule conjugates, indicating the conversion of SECCA to 7-hydroxy-SECCA following irradiation. Control studies in environments that excluded certain radiation-induced water radicals for both the conjugated and unconjugated forms of irradiated SECCA demonstrated that: (1) the induction of fluorescence is mediated by the hydroxyl radical; (2) the presence of oxygen enhances induced fluorescence by a factor of about 1.4, and (3) other primary water radicals and secondary radicals caused by interaction of primary water radicals with biomolecules do not significantly influence the induced fluorescence. The data indicate that the induction of fluorescence on SECCA-biomolecule conjugates records specifically the presence of the hydroxyl radical in the immediate vicinity of the irradiated biomolecule. The method is rapid and sensitive, uses standard instrumentation, and the sample remains available for further studies.

Auger electron emitters: Insights gained from in vitro experiments

SummaryThis paper outlines the evolution of the current rationale for research into the biological effects of tissue-incorporated Auger electron emitters. The first section is a brief review of the research conducted by several groups in the last fifteen years. The second section describes the in vitro model used in our studies, dosimetric calculations, experimental techniques and recent findings. The third section focuses on the use of Auger electron emitters as in vitro microprobes for the investigation of the radiosensitivity of distinct subcellular components. Examination of the biological effects of the Auger electron emitter125I located in different cellular compartments of a single cell line (V79 hamster lung fibroblast) verifies that DNA is the critical cell structure for radiation damage and that the sensitive sites are of nanometer dimensions. The data from incorporation of several Auger electron emitters at the same location within DNA suggest that there are no saturation effects from the decay of these isotopes (i.e. all the emitted energy is biologically effective) and provide some insight into which of the numerous physical mechanisms accompanying the Auger decay are most important in causing cell damage. Finally the implications of Auger electron emission for radiotherapy and radiation protection in diagnostic nuclear medicine are detailed and further research possibilities are suggested.

Fluorescent labelling of abasic sites: a novel methodology to detect closely-spaced damage sites in DNA

PURPOSE To test the ability of a new fluorescent reagent to label abasic sites in DNA and to use fluorescent energy transfer as a measure of closely-spaced abasic sites in DNA. MATERIALS AND METHODS A fluorescein-conjugated hydroxylamine derivative (FARP, 5-(((2-(carbohydrazino)-methyl)thio)acetyl)aminofluorescein, aminooxyacetyl hydrazide) that reacts covalently with open chain aldehydes in DNA has been synthesized. Upon depurination of plasmid DNA and reaction with FARP a stable oxime bond is formed between FARP and the generated open chain aldehydes. RESULTS By independently quantitating the generated abasic sites, it is shown that most of the generated abasic sites under acidic conditions become fluorescently labelled. The limit of sensitivity with the fluorometer used is approximately 90 femtomole abasic sites, corresponding to 1 abasic site per 17000 base pairs. DNA can be fluorescently labelled over a wide range of FARP:base pair ratios following different extent of depurination, and fluorescent loadings of 1 FARP:20000 base pairs up to 1 FARP:10 base pairs are demonstrated. The heavily labelled samples display significant fluorescence quenching due to the proximity of abasic sites labelled with FARP, that undergo fluorescence energy transfer. Treatment of heavily labelled DNA samples with nuclease P1 results in an increase in fluorescence due to the release of the fluorescent labels in the solution. The relative increase in fluorescence is a quantitative measure of the proximity of labelled abasic sites. Furthermore it is shown that if only 1% of DNA contains abasic sites generated in close proximity (within 10-20 base pairs or less of each other) the resulting quenching is significant enough to detect, even if the rest of the DNA contains isolated abasic sites. CONCLUSIONS The present approach constitutes a novel fluorescence-based method to detect abasic sites in nucleic acids and demonstrates the feasibility of detecting the presence of closely-spaced damage sites in DNA via fluorescence energy transfer. The technique also comprises a general and convenient method to fluorescently label nucleic acids without introducing strand breaks as a result of the labelling procedure.

Quantification of radiation-induced hydroxyl radicals within nucleohistones using a molecular fluorescent probe.

We present a method that specifically records .OH formation within histones and possibly at other sites in irradiated nucleohistone. The approach uses the radiation-induced fluorescence emissions from a chromatin-conjugated .OH detector, SECCA (a succinylated derivative of coumarin), that is converted to a fluorescent derivative, 7-hydroxy-SECCA (7-OH-SECCA), after interaction with .OH in neutral aqueous solutions. It is shown that (a) the fluorescent product 7-OH-SECCA cannot be generated by direct radiation effects after gamma or neutron irradiation of SECCA; (b) when SECCA-labeled histone is complexed with DNA to form nucleohistone, the physical properties of the modified nucleohistone are similar to those of unlabeled nucleoprotein; and (c) after irradiation of SECCA-labeled nucleohistone, a linear induction of the fluorescence signal is observed within the radiation doses examined (0.3-30 Gy). Since the sample remains available for further studies after registration of the optical signal, the current approach should permit the investigator to correlate in a single sample the localization and frequency of .OH formation with the results of other assays.

The Effects of Indium- 111 Decay on pBR322 DNA

We have compared the effectiveness in causing DNA strand breaks of 111In bound to DNA or free in aqueous solution with that of gamma rays. Supercoiled DNA from pBR322 plasmid labeled with [3H]thymidine was purified and mixed with 111InCl3 in the absence or presence of diethylenetriaminepentaacetic dianhydride (DTPA), a metal chelator which prevents the binding of indium to DNA. The reaction mixtures were stored at 4 degrees C to accumulate radiation dose from the decay of 111In. The DNA was then resolved by gel electrophoresis into supercoiled, nicked circular and linear forms, representing undamaged DNA, single-strand breaks (SSBs) and double-strand breaks (DSBs), respectively. The D0 values of pBR322 DNA exposed to gamma radiation from an external 137Cs source and the decay of 111In dispersed in solution (+DTPA) are 3.1 +/- 0.1 and 2.8 +/- 0.1 Gy, respectively. In terms of accumulated 111In disintegrations cm-3 of plasmid DNA solution, the D0 value is 15.3 (+/- 0.7) x 10(10) disintegrations in the absence of DTPA and 38.2 (+/- 1.1) x 10(10) disintegrations in its presence. Since only 14.6 +/- 5% of the 111In was bound to DNA in the absence of DTPA, an effective D0 for bound 111In of 3.4 (+/- 1.1) x 10(10) disintegrations is obtained. The 11-fold (range 9- to 17-fold) increased effectiveness of this Auger electron emitter when in proximity to DNA appears to be due mainly to the higher yield of SSBs.

Continuous detection of radiation or metal generated hydroxyl radicals within core chromatin particles

PURPOSE The aim of this work was to adapt a recently developed fluorometric method for use in the detection of hydroxyl radical (HO.) generated in the immediate vicinity of chromatin core particles reconstituted from pUC19 plasmid DNA and isolated core histones. MATERIALS AND METHODS The procedure followed involves labelling nucleosomal histones with SECCA, a non-fluorescent coumarin derivative that generates the fluorescent 7-hydroxy-SECCA after reaction with HO.. Core particles are formed using histones and pUC19 DNA in a salt-dialysis procedure. RESULTS Electron microscopy and micrococcal nuclease digestion are consistent with successful formation of core particles. No significant differences between core particle formation in the unlabelled and SECCA-labelled samples were detected. Exposure to HO. generated by radiation or copper--ascorbic acid--hydrogen peroxide results in a gradual induction of fluorescence. Studies using dimethyl sulphoxide (DMSO) demonstrate that, unlike HO. produced by radiation, the majority of HO. generated by copper--ascorbic acid--hydrogen peroxide occurs primarily in the immediate vicinity of core particles and DNA and cannot be scavenged. CONCLUSIONS The present procedure demonstrates the feasibility to quantitate HO. generated by several agents in the immediate vicinity of nucleosomes (chromatin-associated HO.) or associated with specific regions within the genome.

Accessibility of nucleic acid-complexed biomolecules to hydroxyl radicals correlates with their conformation: A fluorescence polarization spectroscopy study

A fluorescence methodology has been developed to examine the relationship between the conformational state of specific biomolecules in simple chromatin models and their accessibility to hydroxyl radicals (OH). Polylysine and histone H1 were labelled with SECCA, the succinimidyl ester of coumarin-3-carboxylic acid, which generates the fluorescent derivative 7-OH-SECCA following its interaction with radiation-induced OH in aqueous solution. The fluorescence induced per unit gamma-ray dose reflecting the accessibility of OH to such SECCA-conjugated biomolecules was recorded. The biomolecules were also labelled with the fluorescent derivative 7-OH-SECCA in trace amounts to study their conformation under identical conditions via fluorescence polarization spectroscopy. When these biomolecules were complexed with a polynucleotide or DNA, a major increase in polarization anisotropy was recorded. Upon salt-induced dissociation of these biomolecules from the nucleic acids, the increase in anisotropy was reversed. The histone H1-DNA complexes also exhibited an initial increase in anisotropy with increasing NaCl concentration (maximum at 100 mmol dm-3) indicating the possible formation of a more compact conformation. The fluctuations in anisotropy were inversely proportional to the recorded fluorescence/Gy. The data indicate a direct correlation between the accessibility of OH to polylysine or histone H1 complexed with nucleic acids and the conformation of these biomolecules.

Fluorescent labelling of closely-spaced aldehydes induced in DNA by bleomycin-Fe(III).

PURPOSE To test the ability of FARPhC and FARP, two novel fluorescent reagents, to label aldehyde-containing sites (principally abasic sites) generated in DNA by the radiomimetic drug bleomycin, and to use fluorescent energy transfer from FARPhc (donor) to FARP (acceptor) to quantitate such closely-spaced sites. MATERIALS AND METHODS FARPhc, 7-hydroxycoumarin-3-carboxylic acid (((((amino-oxymethyl) carbonyl) hydrazino) carbonylethyl) amide) was synthesized with a protocol similar to the one recently reported for FARP (a fluorescein-based probe). RESULTS Both FARPhc and FARP form stable oxime bonds with the open-chain aldehydes generated upon acidic depurination of DNA. Plasmid DNA exposed to bleomycin-Fe(III)-ascorbate undergoes extensive strand breakage, and upon subsequent reaction with FARPhc and/or FARP it becomes fluorescently labelled, indicating the generation of aldehyde-containing sites. The binding of the probes to calf thymus or plasmid DNA results in significant fluorescent energy transfer among closely-spaced fluorophores, as revealed by the fluorescence increase following digestion of fluorescently labelled samples with nuclease P1. The fluorescent quenching is most evident when both FARPhc and FARP are used simultaneously to trap aldehyde sites. When single-stranded oligonucleotides engineered to contain either one or two closely spaced bleomycin binding sites are exposed to bleomycin and then fluorescently labelled, the oligonucleotides demonstrate significantly increased fluorescent energy transfer with two binding sites indicating a dependence of aldehyde site generation and clustering on the local sequence of a single strand. CONCLUSIONS A new detection method for DNA damage induced by bleomycin following fluorescent labelling of aldehyde group-containing sites (FLAGS) and their clustering via fluorescent energy transfer is demonstrated. The method is applicable to any form of DNA. This work may lead to a general approach for the quantification of multiply damaged sites in DNA, a subset of DNA lesions that may have major biological significance.

Measurements of neutron energy using a recoil-proton telescope and a high-pressure ionization chamber

Two very different techniques for measuring the energy of neutrons in the energy range 0.1-10 MeV are presented and compared. A recoil-proton spectrometer is used to determine the energy spectra of neutrons produced by the d(4)-Be and p(4)-Be reactions down to the low-energy threshold of 0.7 MeV. The same radiation fields are also measured with a recently developed method using a high-pressure ionization chamber that can be used to determine the mean energy of the neutrons in a mixed neutron-gamma radiation field provided the gamma-ray absorbed dose fraction is determined independently. An intercomparison of the two methods shows that the high-pressure ionization chamber compares well and supplements the established recoil-proton spectrometer technique. The almost isotropic response of the chamber has enabled measurements to be made of the variation of mean neutron energy with depth in water for the two radiation fields.