Effect of 60-Hz magnetic fields on ultraviolet light-induced mutation and mitotic recombination in Saccharomyces cerevisiae.

The purpose of this study was to examine the effect of extremely low frequency (ELF) magnetic fields on the induction of genetic damage. In general, mutational studies involving ELF magnetic fields have proven negative. However, studies examining sister-chromatid exchange and chromosome aberrations have yielded conflicting results. In this study, we have examined whether 60-Hz magnetic fields are capable of inducing mutation or mitotic recombination in the yeast Saccharomyces cerevisiae. In addition we determined whether magnetic fields were capable of altering the genetic response of S. cerevisiae to UV (254 nm). We measured the frequencies of induced mutation, gene conversion and reciprocal mitotic crossing-over for exposures to magnetic fields alone (1 mT) or in combination with various UV exposures (2-50 J/m2). These experiments were performed using a repair-proficient strain (RAD+), as well as a strain of yeast (rad3) which is incapable of excising UV-induced thymine dimers. Magnetic field exposures did not induce mutation, gene conversion or reciprocal mitotic crossing-over in either of these strains, nor did the fields influence the frequencies of UV-induced genetic events.

Human dUTP pyrophosphatase: cDNA sequence and potential biological importance of the enzyme.

Two functional human dUTP pyrophosphatase (dUTPase; EC 3.6.1.23) cDNAs were isolated from a cDNA expression library by genetic complementation in Escherichia coli. These cDNAs differed in size but exhibited a common overlapping DNA sequence. Contained within this sequence was a single long open reading frame sufficient to encode a polypeptide of 141 amino acids with a calculated molecular mass of 16.6 kDa. The amino acid sequence of this protein exhibits 35% identity with the E. coli dUTPase and 53% identity with the Saccharomyces cerevisiae enzyme. The human dUTPase was found to contain five characteristics amino acid sequence motifs that are common to the dUTPases of E. coli, yeast, and herpesviruses and to dUTPase-like sequences encoded by some retrovirus gag and pol genes. A high degree of amino acid sequence identity (greater than 60%) was also observed between the human dUTPase and the putative pseudoproteases of two poxviruses, indicating that these virus proteins are dUTPases. Northern hybridization analysis reveals that dUTPase is encoded by at least two species of poly(A)+ mRNA and possibly a third, smaller species. All of these mRNAs are present in a variety of human tissues but their relative levels vary between tissues. Southern analysis indicates that the dUTPase gene has been conserved to some extent throughout vertebrate evolution; however, the gene may be very large, or its organization somewhat complex in some systems. We suggest that dUTPase may generally perform an essential role in DNA replication and therefore could serve as a target enzyme for the development of chemotherapeutic compounds.

Analysis of restriction enzyme-induced DNA double-strand breaks in Chinese hamster ovary cells by pulsed-field gel electrophoresis: implications for chromosome damage.

Restriction enzymes can be electroporated into mammalian cells, and the induced DNA double-strand breaks can lead to aberrations in metaphase chromosomes. Chinese hamster ovary cells were electroporated with PstI, which generates 3' cohesive-end breaks, PvuII, which generates blunt-end breaks, or XbaI, which generates 5' cohesive-end breaks. Although all three restriction enzymes induced similar numbers of aberrant metaphase cells, PvuII was dramatically more effective at inducing both exchange-type and deletion-type chromosome aberrations. Our cytogenetic studies also indicated that enzymes are active within cells for only a short time. We used pulsed-field gel electrophoresis to investigate (i) how long it takes for enzymes to cleave DNA after electroporation into cells, (ii) how long enzymes are active in the cells, and (iii) how the DNA double-strand breaks induced are related to the aberrations observed in metaphase chromosomes. At the same concentrations used in the cytogenetic studies, all enzymes were active within 10 min of electroporation. PstI and PvuII showed a distinct peak in break formation at 20 min, whereas XbaI showed a gradual increase in break frequency over time. Another increase in the number of breaks observed with all three enzymes at 2 and 3 h after electroporation was probably due to nonspecific DNA degradation in a subpopulation of enzyme-damaged cells that lysed after enzyme exposure. Break frequency and chromosome aberration frequency were inversely related: The blunt-end cutter PvuII gave rise to the most aberrations but the fewest breaks, suggesting that it is the type of break rather than the break frequency that is important for chromosome aberration formation.

Analysis of interactions between mutagens, I. Heat and ultraviolet light in Saccharomyces cerevisiae.

A new mathematical approach to the description of interaction data (Ager and Haynes, 1987) is applied here to the interaction between heat and ultraviolet light (UV) in Saccharomyces cerevisiae. A strong synergism for cell killing is found to be associated with large increases in gene conversion (of up to 8-fold), and mutation (of up to 14-fold). Analysis of the interaction data for both wild-type and repair-deficient strains indicates that the heat-UV synergism arises via the inhibition of two different repair pathways. Unambiguous conclusions regarding the molecular mechanisms by which these repair processes are inhibited cannot be drawn on the basis of dose-response data alone. However, this approach does enable one to make well defined, empirical comparisons of the nature and kinetics of such interactions.

Analysis of interactions between mutagens, II. Ethyl methanesulfonate and ultraviolet light in Saccharomyces cerevisiae.

The results of this study indicate the existence of a strong interaction between ethyl methanesulfonate (EMS) and ultraviolet light (UV) for cell killing in the yeast Saccharomyces cerevisiae. Conversely, mutation and gene conversion frequencies observed for the combined treatment of EMS and UV do not deviate significantly from that expected on the basis of simple additivity. Studies involving repair-deficient mutants (rad mutants) reveal that the synergistic interaction for cell killing depends on RAD52 function (recombinational repair), but not on RAD3 function (excision repair). On the basis of this analysis, the interaction between EMS and UV in S. cerevisiae might arise from the inhibition of double-strand break repair by one, or both agents.

Calibration of pulsed field gel electrophoresis for measurement of DNA double-strand breaks.

The pulsed field gel electrophoresis (PFGE) assay was calibrated for the measurement of X-ray-induced DNA double-strand breaks in Chinese hamster ovary (CHO) cells. Calibration was conducted by incorporating [125I]deoxyuridine into DNA, which induces one double-strand break for every disintegration that occurs in frozen cells. Based on the percentage of the DNA migrating into the gel, the number of breaks/dalton/Gy was estimated to be (9.3 +/- 1.0) x 10(-12). This value is close to (10 to 12) x 10(-12) determined by neutral filter elution using similar cell lysis procedures at 24 degrees C and at pH 8.0. Also, the estimate is in good agreement with the value of (11.7 +/- 2) x 10(-12) breaks/dalton/Gy as measured in Ehrlich ascites tumour cells using the neutral sucrose gradient method (Blöcher 1988), and (6 to 9) x 10(-12) breaks/dalton/Gy as measured in mouse L and Chinese hamster V79 cells using neutral filter elution (Radford and Hodgson 1985).

Measurement of radiation-induced DNA double-strand breaks by pulsed-field gel electrophoresis.

We have examined the use of pulsed-field gel electrophoresis (PFGE) to measure DNA double-strand breaks induced in CHO cells by ionizing radiation. The PFGE assay provides a simple method for the measurement of DNA double-strand breaks for doses as low as 3-4 Gy ionizing radiation, and appears applicable for the measurement of damage produced by any agent producing double-strand breaks. The conditions of transverse alternating field electrophoresis determined both the sensitivity of the assay and the ability to resolve DNA fragments with different sizes. For example, with 0.8% agarose and a 1-min pulse time at 250 V for 18 h of electrophoresis, 0.39% of the DNA per gray migrated into the gel, and only molecules less than 1500 kb could be resolved. With 0.56% agarose and a 60-min pulse time at 40 V for 6 days of electrophoresis, 0.55-0.90% of the DNA per gray migrated into the gel, and molecules between 1500 and 7000 kb could be resolved.

Quantitative aspects of the interactive killing effects between X rays and other mutagens in microorganisms.

Recently we presented a mathematical description of the synergistic interaction which occurs when Escherichia coli B/r is exposed to both X rays and 254 nm ultraviolet light (D. D. Ager and R. H. Haynes, Radiat. Res. 110, 129-141 (1987]. Here we extend this approach to other bacteria and describe a graphical technique which can be used to determine the nature and relative importance of second and third degree terms in the function h(x, y), which describes the dose dependence of such effects. In most cases, interaction functions appear to be dominated, in the biologically interesting dose range, by a second degree term in the product, xy, of the doses of the two agents. We find that the magnitudes of these interactions vary among the organisms examined and can be surprisingly large. Finally, we show that the simple xy dependence observed for most interactions does not carry any unambiguous implications with respect to previous speculations on the mechanisms of these effects.

Mathematical description of the interactions between cellular inactivating agents.

A mathematical technique for characterizing the interactive effects that may occur when cells are treated with two or more toxic agents is developed. This technique is used to account for the previously unexplained properties of the dose-response relations for the uv-X-ray interaction in Escherichia coli B/r.