Acetaldehyde induces NER repairable mutagenic DNA lesions.

Nucleotide excision repair (NER) is a repair mechanism that removes DNA lesions induced by UV radiation, environmental mutagens and carcinogens. There exists sufficient evidence against acetaldehyde suggesting it to cause a variety of DNA lesions and be carcinogenic to humans. Previously, we found that acetaldehyde induces reversible intra-strand GG crosslinks in DNA similar to those induced by cis-diammineplatinum(II) that is subsequently repaired by NER. In this study, we analysed the repairability by NER mechanism and the mutagenesis of acetaldehyde. In an in vitro reaction setup with NER-proficient and NER-deficient xeroderma pigmentosum group A (XPA) cell extracts, NER reactions were observed in the presence of XPA recombinant proteins in acetaldehyde-treated plasmids. Using an in vivo assay with living XPA cells and XPA-correcting XPA cells, the repair reactions were also observed. Additionally, it was observed that DNA polymerase eta inserted dATP opposite guanine in acetaldehyde-treated oligonucleotides, suggesting that acetaldehyde-induced GG-to-TT transversions. These findings show that acetaldehyde induces NER repairable mutagenic DNA lesions.

Acetaldehyde forms covalent GG intrastrand crosslinks in DNA.

Carcinogens often generate mutable DNA lesions that contribute to cancer and aging. However, the chemical structure of tumorigenic DNA lesions formed by acetaldehyde remains unknown, although it has long been considered an environmental mutagen in alcohol, tobacco, and food. Here, we identify an aldehyde-induced DNA lesion, forming an intrastrand crosslink between adjacent guanine bases, but not in single guanine bases or in other combinations of nucleotides. The GG intrastrand crosslink exists in equilibrium in the presence of aldehyde, and therefore it has not been detected or analyzed in the previous investigations. The newly identified GG intrastrand crosslinks might explain the toxicity and mutagenicity of acetaldehyde in DNA metabolism.

Fluorescence detection of DNA mismatch repair in human cells.

Mismatched base pairs, produced by nucleotide misincorporation by DNA polymerase, are repaired by the mismatch repair (MMR) pathway to maintain genetic integrity. We have developed a method for the fluorescence detection of the cellular MMR ability. A mismatch, which would generate a stop codon in the mRNA transcript unless it was repaired, was introduced into the gene encoding the enhanced green fluorescent protein (EGFP) in an expression plasmid. When MMR-proficient HeLa cells were transformed with this plasmid, the production of active EGFP was observed by fluorescence microscopy. It was assumed that the nick required to initiate the MMR pathway was produced non-specifically in the cells. In contrast, fluorescence was not detected for three types of MMR-deficient cells, LoVo, HCT116, and DLD-1, transformed with the same plasmid. In addition, the expression of a red fluorescent protein gene was utilized to avoid false-negative results. This simple fluorescence method may improve the detection of repair defects, as a biomarker for cancer diagnosis and therapy.

An assay to detect DNA-damaging agents that induce nucleotide excision-repairable DNA lesions in living human cells.

Biochemical risk assessment studies of chemicals that induce DNA lesions are important, because lesions in genomic DNA frequently result in cancer, neurodegeneration, and aging in humans. Many classes of DNA lesions induced by chemical agents are eliminated via DNA repair mechanisms, such as nucleotide excision repair (NER) and base excision repair (BER), for the maintenance of genomic integrity. Individuals with NER-defective xeroderma pigmentosum (XP), in which bulky DNA lesions are not efficiently removed, are cancer-prone and suffer neurodegeneration. For research into cancer and neurological diseases, therefore, it might be important to identify DNA damage from agents that induce NER-repairable bulky DNA lesions. However, simple and quick assays to detect such damaging agents have not been developed using human cells. Here, we report a simple, non-isotopic assay for determining DNA damaging agents that induce NER-repairable DNA lesions by visualizing gene expression from treated fluorescent protein vectors in a mammalian cell system. This assay is based on a comparison of fluorescent protein expression in NER-proficient and NER-deficient cells. When we tested UV-irradiated fluorescent protein vectors, the fluorescent protein was observed in NER-proficient cells, but not in NER-deficient cells. Similar results were obtained for vectors treated with the anticancer drug, cisplatin. In contrast, when treated with the DNA alkylating agent methyl methanesulfonate, believed to cause BER-repairable damage, no difference in gene expression between NER-proficient and NER-deficient cells was observed. These results suggest that our assay can specifically detect DNA-damaging agents that induce NER-repairable DNA lesions, and could be used to analyze chemicals with the potential to cause cancer and neurological diseases. With further validation, the assay might be also applicable to XP diagnosis.