Mikhail F. Denissenko

Slow repair of bulky DNA adducts along the nontranscribed strand of the human p53 gene may explain the strand bias of transversion mutations in cancers

Using UvrABC incision in combination with ligation-mediated PCR (LMPCR) we have previously shown that benzo(a)pyrene diol epoxide (BPDE) adduct formation along the nontranscribed strand of the human p53 gene is highly selective; the preferential binding sites coincide with the major mutation hotspots found in human lung cancers. Both sequence-dependent adduct formation and repair may contribute to these mutation hotspots in tumor tissues. To test this possibility, we have extended our previous studies by mapping the BPDE adduct distribution in the transcribed strand of the p53 gene and quantifying the rates of repair for individual damaged bases in exons 5, 7, and 8 for both DNA strands of this gene in normal human fibroblasts. We found that: (i) on both strands, BPDE adducts preferentially form at CpG sequences, and (ii) repair of BPDE adducts in the transcribed DNA strand is consistently faster than repair of adducts in the nontranscribed strand, while repair at the major damage hotspots (guanines at codons 157, 248 and 273) in the nontranscribed strand is two to four times slower than repair at other damage sites. These results strongly suggest that both preferential adduct formation and slow repair lead to hotspots for mutations at codons 157, 248 and 273, and that the strand bias of bulky adduct repair is primarily responsible for the strand bias of G to T transversion mutations observed in the p53 gene in human cancers.

The p53 codon 249 mutational hotspot in hepatocellular carcinoma is not related to selective formation or persistence of aflatoxin B1 adducts.

Sequence-dependent formation and lack of repair of polycyclic aromatic hydrocarbon-induced DNA adducts correlates well with the positions of p53 mutational hotspots in smoking-related lung cancers (, ). The mycotoxin aflatoxin B1 (AFB1) is considered to be a major causative agent in hepatocellular carcinoma (HCC) in regions with presumed high food contamination by AFB1. A unique mutational hotspot, a G to T transversion at the third base of codon 249 of the p53 gene is observed in these tumors. To test whether a selectivity of AFB1 adduct formation is related to this peculiar mutational spectrum, we have mapped AFB1-DNA adducts at nucleotide resolution using ligation-mediated PCR and terminal transferase-dependent PCR. Human HepG2 cells were exposed to AFB1 metabolically activated in the presence of rat liver microsomes. Significant adduct formation was seen at the third base of codon 249. However, this was not the major site of AFB1 adducts and strong adduction was also observed at codons 226, 243, 244, 245 and 248 in exon 7 of the p53 gene and at several codons in exon 8. The damage at codon 249 does not consist of a unique abasic site or ring-opened aflatoxin B1 adduct but rather is consistent with the principal N7-guanine adduct of AFB1. Time course experiments indicate that, under the conditions used, AFB1 adducts are not removed in a strand-selective manner and adduct removal from the third base of codon 249 proceeds at a relatively fast rate (50% in 7u2009h). The incomplete correspondence between sites of persistent AFB1 damage and the specific codon 249 mutation suggests that AFB1 may not be involved in mutation of this site or that additional mechanisms such as parallel infection with hepatitis B virus may be required for selection of codon 249 mutants in HCC.

Formation and repair of DNA lesions in the p53 gene: Relation to cancer mutations?

The number and diversity of mutations in the p53 mutation data base provides indirect evidence that implicates environmental mutagens in human carcinogenesis. The p53 gene has a large mutational target size; more than 280 out of 393 amino acids are found mutated in tumors. We argue that there is possibly a limited involvement of selection for specific mutations in the central domain of the protein, and that the distribution of DNA damage along the p53 gene caused by environmental carcinogens can be correlated with the mutational spectra, i.e., hotspots and types of mutations, of certain cancers. This concept has been validated by experiments with sunlight and the cigarette smoke component benzo[a]pyrene representing the polycyclic aromatic hydrocarbon class of carcinogens. The damage/repair data obtained for these mutagens can predict certain parameters of the mutational spectra including the distribution of hotspots in human nonmelanoma skin cancers and lung cancers from smokers. Future studies with suspected mutagens may help to implicate causative agents involved in other cancers, such as colon and breast cancer, where the exact carcinogen has not yet been identified but an environmental factor is suspected. Environ. Mol. Mutagen. 31:197–205, 1998

Promoter structure and cell cycle dependent expression of the human methylpurine-DNA glycosylase gene.

The methylpurine-DNA glycosylase (MPG) gene coding for human 3-methyladenine (3-meAde)-DNA glycosylase functions in the first step of base excision repair (BER) to remove numerous damaged bases including 3-meGua, ethenoadenine, and hypoxanthine (Hx) in addition to 3-meAde. In this report, we identify the length of the minimal MPG promoter region, demonstrate the involvement of several transcription factors in expression of the MPG gene, and determine the point at which transcription initiates. We also demonstrate that control of MPG expression is linked to MPG activity. To initiate studies on how the MPG functions with the ensemble of BER genes to effect repair, we have investigated the cell cycle control of MPG and other BER genes in normal human cells. Steady-state mRNA levels of MPG, human Nth homologue (NTH), and uracil-DNA glycosylase (UDG), DNA glycosylases, and human AP site-specific endonuclease (APE), an endonuclease incising DNA at abasic sites, are cell cycle dependent. In contrast, expression levels of genes coding for human 8-oxoguanine-DNA glycosylase (OGG1) and TDG DNA glycosylases, and omicron 6-methylguanine-DNA methyltransferase (MGMT) gene, and the RPA4 subunit gene do not vary with cell cycle. These observed cell cycle dependent differences might reflect distinct roles of individual BER proteins in mutation avoidance.

PCR-based approaches to adduct analysis

Ligation-mediated polymerase chain reaction (LMPCR) is a PCR-based method for the detection of DNA adducts at individual nucleotide positions in mammalian genes. Adduct-specific enzymes, such as T4 endonuclease V, various base excision repair enzymes, UvrABC nuclease, and chemical cleavage techniques can be used to convert the adducts into DNA strand breaks. The positions of these breaks are then detected by LMPCR. This method has been used primarily to map the distribution of UV-induced DNA lesions and adducts of polycyclic aromatic hydrocarbons. The number and diversity of mutations in the p53 mutation database provides indirect evidence that environmental mutagens may be involved in human carcinogenesis. We hypothesize that there is a limited involvement of selection for specific mutations in the central domain of the p53 protein, and that the distribution of DNA damage along the p53 gene caused by environmental carcinogens can be correlated with the mutational spectra, i.e. hotspots and types of mutations, of certain cancers. This concept has been validated by experiments with sunlight and the cigarette smoke component benzo[a]pyrene representing the polycyclic aromatic hydrocarbon class of carcinogens. The damage and repair data obtained for these mutagens can predict certain parameters of the mutational spectra of human non-melanoma skin cancers and lung cancers from smokers. Future studies with suspected mutagens may help to implicate causative agents involved in other cancers, where the exact carcinogen has not yet been identified but an environmental factor is suspected.

Mapping polycyclic aromatic hydrocarbon and aromatic amine-induced DNA damage in cancer-related genes at the sequence level.

Genomic injury induced by environmental carcinogens, such as polycyclic aromatic hydrocarbons and aromatic amines, is the initial step that can trigger mutagenesis and carcinogenesis. In addition to the physico-chemical property of DNA damaging agents, several important factors such as primary sequence, chromatin structure, methylation, protein association, and transcriptional activity can affect not only the initial level and distribution of DNA damage but also the efficiency of repair. Therefore, mapping the DNA damage induced by environmental agents in cancer-related genes such as p53 and ras at the sequence level provides essential information for assessing their carcinogenic potential. Recently, using the E. coli nucleotide excision enzyme complex, UvrABC nucleases in combination with ligation-mediated polymerase chain reaction, we developed a method to map DNA damage in the p53 and ras genes. These studies led us to conclude that targeted DNA damage, in combination with growth selection, contributes greatly in shaping the mutation spectrum in these genes in human cancer. Here we present the rationale and details of this approach, typical experimental results and necessary precautions.