Gary F. Strniste

Studies on Escherichia coli X-Ray Endonuclease Specificity: Roles of Hydroxyl and Reducing Radicals in the Production of DNA Lesions

DNA strand breakage induced by X irradiation, by X irradiation and alkali treatment, or by X irradiation and subsequent incubation with Escherichia coli X-ray endonuclease was measured by the conversion of PM2 Type I DNA to Type II. The hydroxyl radical was found to mediate the formation of alkali-labile lesions and to a lesser extent simple strand breaks. All alkali-labile lesions were found also to be enzyme-sensitive sites. In addition, when the effective concentration of hydroxyl radicals was reduced by radical scavenging, reducing species appeared to produce enzyme sensitive sites which were not alkali labile. Tryptone-glucose-yeast extract medium, which was used in an attempt to simulate cellular conditions, protected against strand breakage, alkali-labile lesions, and non-alkali-labile enzyme-sensitive damages. Last, the E. coli X-ray endonuclease recognized osmium tetroxide-induced DNA damages which are identical to the radiolysis products of thymine produced by ionizing radiation.

Effect of dose rate on the survival of irradiated human skin fibroblasts

The survival of cells in density-inhibited, confluent cultures maintained at 37 degrees C was examined following exposure to 137Cs gamma rays at low dose rates (0.023 or 0.153 Gy/h) or to 60Co gamma rays at a single high dose rate (0.70-0.75 Gy/min). Cells from an ataxia telangiectasia (AT) homozygote showed no dose-rate effect, whereas a three- to fivefold increase in D0 was observed for all other cell strains exposed at low dose rates. The magnitude of the dose-rate effect did not differ significantly among cells from persons with hereditary retinoblastoma, basal cell nevus syndrome, or AT-heterozygote compared with normal cell strains, and was not related to the size of the shoulder (extrapolation number) of the survival curve. Furthermore, no differences in the capacity for the repair of potentially lethal damage during confluent holding were observed among these latter cell strains.

XPG protein has a structure-specific endonuclease activity

Biochemically active human DNA repair protein, xeroderma pigmentosum G (XPG), was overexpressed in insect cells by a recombinant baculovirus. The recombinant baculovirus produced XPG with a mobility of approximately 185 kDa in a denaturing polyacrylamide gel. Indirect immunofluorescence studies demonstrated that the recombinant full-length XPG protein was expressed predominantly as a nuclear protein. The recombinant XPG protein was purified to apparent homogeneity using Q-sepharose, S-300 size exclusion, and Mono Q column chromatography. XPG protein showed a structure-specific DNA endonuclease activity, and a preferential affinity to single-stranded DNA and RNA compared to double-stranded DNA.

The genotoxicity of alpha particles in human embryonic skin fibroblasts

Cell inactivation and induced mutation frequencies at the hypoxanthine-guanine phosphoribosyl transferase (HGPRT) locus have been measured in cultured human fibroblasts (GM10) exposed to alpha particles from 238Pu (LET at the cell surface was 100 keV/microns) and 250 kVp X rays. The survival curves resulting from exposure to alpha particles are exponential. The mean lethal dose, D0, is approximately 1.3 Gy for X rays and 0.25 Gy for alpha particles. As a function of radiation dose, mutation induction at the HGPRT locus was linear for alpha particles whereas the X-ray-induced mutation data were better fitted by a quadratic function. When mutation frequencies were plotted against the log of survival, mutation frequency at a given survival level was greater in cells exposed to alpha particles than to X rays.

Heritable genetic alterations in a xeroderma pigmentosum group G/Cockayne syndrome pedigree.

A search for genetic alterations within the XPG gene has been conducted on skin and blood cells cultured from a newly characterized xeroderma pigmentosum (XP) patient (XP20BE). This patient is the ninth known case that falls into the extremely rare XP complementation group G. Four genetic markers within the XPG gene (including two polymorphisms) demonstrated the Mendelian distribution of this gene from the parents to the patient and to an unaffected sibling. The patient (XP20BE) inherited a G to T transversion from his father in exon 1 of the XPG gene that resulted in the conversion of a glutamic acid at codon 11 to a termination codon. The patient also inherited an XP-G allele from his mother that produces an unstable or poorly expressed message. The cause of the latter defect is still uncertain. In addition to these alterations, XP20BE cDNA contained an mRNA species with a large splicing defect that encompassed a deletion from exon 1 to exon 14. This splicing defect, however, appears to be a naturally occurring low-frequency event that results from abnormal splicing that occurs between certain conserved non-consensus splicing signals within the human XPG gene.

Cytogenetic effects of extremely low doses of plutonium-238 alpha-particle irradiation in CHO K-1 cells.

CHO K-1 cells were irradiated during the G1 phase with 0.5-6 rad of alpha particles. There was no appreciable cell killing in this low dose range. Significantly increased frequencies of sister-chromatid exchanges were induced by doses as low as 0.5 rad of alpha-particle irradiation, whereas increased numbers of chromosomal aberrations were observed following exposure to 2 rad. These results suggest that very low doses of alpha radiation may lead to radiation-induced genetic alterations.

Photochemical oxidation of 2-aminofluorene: correlation between the induction of direct-acting mutagenicity and the formation of nitro and nitroso aromatics.

The kinetics of near ultraviolet light-mediated phototransformation of 2-aminofluorene (2-AF) was studied using high performance liquid chromatography (HPLC) and the Ames/Salmonella mutagenicity bioassay. Employing tester strains TA98, TA1538, and the nitroreductase-deficient TA98NR without the addition of exogenous metabolic enzymes, we were able to detect and discriminate between the UVA exposure-dependent formation of two stable photoproducts, 2-nitrosofluorene (2-NOF) and 2-nitrofluorene (2-NO2F). Mutagenicity of irradiated 2-AF solutions (using dimethyl sulfoxide as a solvent) in the various tester strains indicates the rapid formation of the photo-labile 2-NOF, after which 2-NO2F accounts for the preponderance of mutagenic activity. Continued UVA irradiation (greater than 72 h at 6.8 J/m2/s) of 2-AF results in the formation of greater than 30 photoproducts resolvable on HPLC, several of which, in addition to 2-NOF and 2-NO2F, are mutagenic on Salmonella but are chemically undefined to date. Prolonged irradiation ultimately destroys the photo-induced mutagenicity of 2-AF. However, UVA-induced 2-AF photoproducts are stable for several weeks when stored in sealed vials in the dark. Light potentiated oxidation of aromatic amines constitutes an alternative mechanism for the transformation of aromatic amines into proximate mutagens/carcinogens.

1-Nitropyrene: a mutagenic product induced by the action of near ultraviolet light on 1-aminopyrene

A solution of 1-aminopyrene in dimethyl sulfoxide exposed to an artificial source of near ultraviolet light (600 kJ/m2) induced significant direct-acting mutagenicity in the Ames/Salmonella plating assay utilizing strain TA98. High-performance liquid chromatography of this solution resulted in a fraction that was mutagenic on TA98 but inactive on a nitroreductase-deficient strain of Salmonella (TA98NR). This observation suggested the presence of a nitro-containing compound. Mass spectral analysis confirmed that 1-nitropyrene was the active photoproduct in this fraction. These data implicate photochemical transformation of primary aromatic amines as an alternative mechanism by which nitroaromatic compounds can be formed in the environment.

Genotoxicity induced in cultured chinese hamster cells exposed to natural or synthetic crude oils and near ultraviolet light

Cultured Chinese hamster ovary (CHO) cells were incubated with dilutions of natural or synthetic crude oils and subsequently exposed to near ultraviolet light (NUV). Although the magnitude of photo-induced cytotoxicity in CHO was essentially independent of the source of the oil (within a factor of two), two shale oils were exceptionally high in photo-induced mutagenic activity eliciting a response 10-12 times the observed natural background mutation frequency. Other shale oils, natural crude oils and a solvent refined coal medium distillate blend were weaker or negative in photo-induced mutagenic activity. Hydrotreatment of a photoactive shale oil, although eliminating the mutagenic potential, did not reduce the oils cytotoxic potential.

Reactions induced in vitro between model DNA and benzo[A]pyrene by near-ultraviolet radiation

Near-ultraviolet (300--480 nm wavelength) irradiation of the single-strand polydeoxynucleotide poly[d(A,C,G,T)] and carbon-14 labeled benzo[alpha]-pyrene (B[alpha] P) in aqueous dimethylsulfoxide (DMSO) solution led to appreciable binding of labeled hydrocarbon to the polynucleotide. Nuclease digests of polydeoxynucleotide-B[alpha]P complexes were examined by chromatography on Sephadex LH-20; at high fluences of near-ultraviolet light deoxyguanosine (dG) residues of the polymer were largely destroyed when the hydrocarbon was present. Approximately 85% of the B[alpha] P of the digests were recovered as hydrophilic derivatives not adsorbed by Sephadex LH-20. Elution of the columns with an aqueous-methanol gradient indicated that substances similar to the covalent deoxynucleoside-B[alpha] P adducts formed between microsomally-oxidized B[alpha] P and DNA were likewise present in the digests. When the deoxyadenosine (dA), deoxycytidine (dC) or dG moieties of the polymer were tritium-labeled, substances doubly-labeled with tritium and carbon-14 were found; ratios of the two radioactivities indicated that equimolar amounts of deoxynucleoside and hydrocarbon were present.