Louise H. Lutze

Unique DNA repair properties of a xeroderma pigmentosum revertant.

A group A xeroderma pigmentosum revertant with normal sensitivity was created by chemical mutagenesis. It repaired (6-4) photoproducts normally but not pyrimidine dimers and had near normal levels of repair replication, sister chromatid exchange, and mutagenesis from UV light. The rate of UV-induced mutation in a shuttle vector, however, was as high as the rate in the parental xeroderma pigmentosum cell line.

Radiation-induced point mutations, deletions and micronuclei in lacI transgenic mice.

Ionizing radiation induces gene mutations (point mutations, deletions and insertions) as well as chromosome damage in mammalian cells. Although these effects have been studied extensively in cells in culture, until recently it has not been possible to analyze the mutagenic potential of ionizing radiation in vivo, especially at the molecular level. The development of transgenic mutagenesis systems has now made it possible to study the effects of ionizing radiation at both the molecular and chromosomal levels in the same animal. In this report we present preliminary data on the response of Big Blue lacI transgenic mice to ionizing radiation as measured by lacI mutations and micronuclei. C57Bl/6 transgenic mice were irradiated with 137Cs gamma-rays at doses ranging from 0.1 to 14 Gy, and expression times ranging from 2 to 14 days. Dose-related increases in the mutant frequency were observed after irradiations with longer expression times. Mutant plaques were analyzed by restriction enzyme digestion to detect large structural changes in the target sequence. Of 34 gamma-ray-induced mutations analyzed, 4 were large-scale rearrangements. 3 of these rearrangements were deletions within the lacI gene characterized by the presence of short regions of homology at the breakpoint junctions. The fourth rearrangement was a deletion that extended from within the alpha lacZ gene into downstream sequences and that had 43 bp of homology at the junction. These data indicate that the Big Blue lacI transgenic mouse system in sensitive to the types of mutations induced by ionizing radiation. To determine whether the presence of the transgene affects micronucleus induction we compared the response of nontransgenic to hemizygous transgenic B6C3F1 mice and the response of nontransgenic to hemizygous and homozygous transgenic C57Bl/6 mice. The presence or absence of the lacI transgene had no effect on spontaneous micronucleus frequencies for either strain. However, radiation-induced micronucleus frequencies were significantly higher in hemizygous lacI B6C3F1 mice than in nontransgenic litter mates; the converse was true in C57Bl/6 mice. These data suggest that the lacI transgene does not cause chromosome instability as measured by spontaneous micronucleus levels. However, the response of these transgenic mice to a variety of clastogenic agents needs to be investigated before they are integrated into standard in vivo assays for chromosome damage.

THE RELATIVE BIOLOGICAL IMPORTANCE OF CYCLOBUTANE AND(6–4) PYRIMIDINE‐PYRIMIDONE DIMER PHOTOPRODUCTS IN HUMAN CELLS: EVIDENCE FROM A XERODERMA PIGMENTOSUM REVERTANT

Abstract— The relative biological importance of(5–5,6–6) cyclobutane and(6–4) pyrimidine‐pyrimidone dimers in mammalian cells has been determined in a xeroderma pigmentosum (XP) revertant that repairs only the(6–4) photoproduct. Surprisingly, the majority of biological effects of UV light, including cell killing, sister chromatid exchange, mutagenesis, and inhibition and recovery of DNA and RNA synthesis, appear to be due to the(6–4) photoproduct and not to the cyclobutane dimer. Although the XP revertant repairs its own genomic DNA, it fails to repair damage in shuttle vectors, including the pZ189 mutational and chloramphenicol acetyl transferase transcriptional assay systems. The revertant is therefore a cell line for which shuttle vectors are inappropriate as models for genomic DNA repair, and may highlight a general weakness of shuttle vectors for the study of infrequent DNA lesions.

Mechanisms involved in rejoining DNA double-strand breaks induced by ionizing radiation and restriction enzymes

DNA double-strand breaks are considered to be the most deleterious lesion induced by ionizing radiation. However, the mechanism of rejoining of these lesions has not been extensively studied at the molecular level. We have used a shuttle vector, pHAZE, to analyze the mechanism of rejoining of DNA double-strand breaks in human cells. The advantage of this vector system is that, unlike many previously described shuttle vectors, it has a large target gene for the detection of deletions and it is maintained as a freely replicating episome with chromatin conformation in the nucleus of human cells. In this study we compare data obtained on the spectrum of mutations induced in pHAZE by ionizing radiation (alpha-particles) and restriction enzymes (PvuII, ClaI, and PvuI). Unlike ionizing radiation, restriction enzymes induce double-strand breaks in DNA with known end structures at defined locations and therefore provide a model system for analyzing cellular responses to DNA double-strand breaks. Exposure of human cells containing the vector to alpha-particle irradiation produced both point mutations and large deletions in pHAZE. When the junction regions of the deletions were sequenced it was found that 65% were rejoined with up to 6 bp of homology at the junction region. Analysis of restriction-enzyme-induced mutations suggests that double-strand break ends are modified to facilitate rejoining and that the type of modification is characteristic for different end structures. Double-strand breaks with cohesive ends appear to have fewer modifications introduced at the break points before rejoining than breaks with blunt ends. When considered in relation to the data obtained with ionizing radiation this suggests that the presence of cohesive sequences either at, or in proximity to, the ends enhances rejoining of DNA double-strand breaks.

pHAZE: A shuttle vector system for the detection and analysis of ionizing radiation-induced mutations

We have designed and constructed a shuttle vector system, pHAZE, that is maintained as an episome in normal human fibroblasts, has a low background mutation frequency, and is capable of detecting a spectrum of mutations, including deletions up to 8.3 kb. The efficacy of this system was demonstrated by using it to analyze mutations produced by X-rays, which induced both point mutations and large deletions in pHAZE.

Chromosome aberration induction in Chinese hamster ovary cells by restriction enzymes with different methylation sensitivity

The isoschizomer pair MspI and HpaII were used to investigate whether the putative specificity of restriction endonucleases would be maintained when they were introduced into mammalian cells. Although both enzymes recognize the sequence CCGG, HpaII will cut only if the internal cytosine is unmethylated, whereas MspI will cut regardless of the methylation status. Cleavage results in a cohesive-end DNA double-strand break, which can lead to the formation of chromosome aberrations. Since mammalian DNA is heavily methylated, one would expect MspI to be much more effective than HpaII at inducing chromosome aberrations in Chinese hamster ovary cells. In fact, during G1, MspI induced a >90-fold higher number of aberrations than did HpaII. Cell cycle studies indicated that during early S there was a 30-fold increase in HpaII-induced aberrations. This increase may be due to increased accessibility of replicating hypomethylated DNA. Cells that were treated with the demethylating agent 5-aza-2′-deoxycytidine (AzdC) displayed only a moderate increase in HpaII-induced aberrations during G1. This observation, together with the results of restriction enzyme analysis of genomic DNA, indicated that demethylation was incomplete. The effects of AzdC on the induction of aberrations by MspI suggested that AzdC increases chromatin accessibility. Our results were consistent with the expected specificity of MspI and HpaII. Thus, it appears that restriction endonucleases can play a useful role in determining the biological consequences of DNA double-strand breaks.

EXCISION OF CYCLOBUTANE DIMERS IN GENOMIC AND EPISOMAL DNA IN HUMAN CELLS

Abstract Direct determination has been made of cyclobutyl pyrimidine dimer induction and excision repair in an episomal SV40 DNA population in vivo. Maintaining SV40‐transformed human (GM637) cells in confluent culture results in amplification of a mutant SV40 episome to high copy number. T4 endonuclease V was used to quantify the induction and repair of cyclobutane dimers in the SV40 episome and genomic DNA of the same cells. Differences in both parameters were observed cyclobutane dimers were induced at 1.5–2‐fold greater frequency in episomal DNA and excised at a reduced rate compared to genomic DNA in the host cells.