Loss of DNA-protein crosslinks from formaldehyde-exposed cells occurs through spontaneous hydrolysis and an active repair process linked to proteosome function.

DNA-protein crosslinks (DPC) involving all major histones are the dominant form of DNA damage in formaldehyde-exposed cells. In order to understand the repair mechanisms for these lesions we conducted detailed analysis of the stability of formaldehyde-induced DPC in vitro and in human cells. DNA-histone linkages were found to be hydrolytically unstable, with t(1/2) = 18.3 h at 37 degrees C. When histones were allowed to remain bound to DNA after crosslink breakage, the half-life of DPC increased to 26.3 h. This suggests that approximately 30% of spontaneously broken DPC could be re-established under physiological conditions. The half-lives of DPC in three human cell lines (HF/SV fibroblasts, kidney Ad293 and lung A549 cells) were similar and averaged 12.5 h (range 11.6-13.0 h). After adjustment for spontaneous loss, an active repair process was calculated to eliminate DPC from these cells with an average t(1/2) = 23.3 h. Removal of DPC from peripheral human lymphocytes was slower (t(1/2) = 18.1 h), due to inefficient active repair (t(1/2) = 66.6 h). This indicates that the major portion of DPC is lost from lymphocytes through spontaneous hydrolysis rather than being actively repaired. Depletion of intracellular glutathione from A549 cells had no significant effect on the initial levels of DPC, the rate of their repair or cell survival. Nucleotide excision repair does not appear to be involved in the removal of DPC, since the kinetics of DPC elimination in XP-A and XP-F fibroblasts were very similar to normal cells. Incubation of normal or XP-A cells with lactacystin, a specific inhibitor of proteosomes, caused inhibition of DPC repair, suggesting that the active removal of DPC in cells may involve proteolytic degradation of crosslinked proteins. XP-F cells showed somewhat higher sensitivity to formaldehyde, possibly signaling participation of XPF protein in the removal of residual peptide-DNA adducts.

[1]  W. Thilly,et al.  Formaldehyde is mutagenic for cultured human cells. , 1983, Mutation research.

[2]  V. Bohr DNA repair fine structure and its relations to genomic instability. , 1995, Carcinogenesis.

[3]  T. Starr,et al.  Formaldehyde toxicity--new understanding. , 1990, Critical reviews in toxicology.

[4]  A. Rivett Proteasomes: multicatalytic proteinase complexes. , 1993, The Biochemical journal.

[5]  J. Barret,et al.  Deficient nucleotide excision repair activity in protein extracts from normal human lymphocytes. , 1995, Carcinogenesis.

[6]  W. Peters,et al.  Age and gender dependent levels of glutathione and glutathione S-transferases in human lymphocytes. , 1998, Carcinogenesis.

[7]  Kevin T. Morgan,et al.  Covalent Binding of Inhaled Formaldehyde to DNA in the Respiratory Tract of Rhesus Monkeys: Pharmacokinetics, Rat-to-Monkey Interspecies Scaling, and Extrapolation to Man , 1991 .

[8]  C. Nathan,et al.  Glutathione depletion sensitizes tumor cells to oxidative cytolysis. , 1982, The Journal of biological chemistry.

[9]  A. Zhitkovich,et al.  A simple, sensitive assay to detect DNA-protein crosslinks in intact cells and in vivo. , 1992, Carcinogenesis.

[10]  L. Pluta,et al.  p53 mutations in formaldehyde-induced nasal squamous cell carcinomas in rats. , 1992, Cancer research.

[11]  V. Feron,et al.  Aldehydes: occurrence, carcinogenic potential, mechanism of action and risk assessment. , 1991, Mutation research.

[12]  A. Natarajan,et al.  Evaluation of the mutagenicity of formaldehyde in mammalian cytogenetic assays in vivo and vitro. , 1983, Mutation research.

[13]  G. Newton,et al.  Determination of biothiols by bromobimane labeling and high-performance liquid chromatography. , 1995, Methods in enzymology.

[14]  P. D'Arpa,et al.  Ubiquitin-dependent Destruction of Topoisomerase I Is Stimulated by the Antitumor Drug Camptothecin* , 1997, The Journal of Biological Chemistry.

[15]  Y. Morimitsu,et al.  Reaction of formaldehyde with calf-thymus nucleohistone. , 1979, European journal of biochemistry.

[16]  H. Heck,et al.  Covalent binding of inhaled formaldehyde to DNA in the nasal mucosa of Fischer 344 rats: analysis of formaldehyde and DNA by high-performance liquid chromatography and provisional pharmacokinetic interpretation. , 1989, Fundamental and applied toxicology : official journal of the Society of Toxicology.

[17]  J. Paramio,et al.  Changes in proteasome localization during the cell cycle. , 1994, European journal of cell biology.

[18]  T. Skopek,et al.  Formaldehyde mutagenesis and formation of DNA-protein crosslinks in human lymphoblasts in vitro. , 1987, Mutation research.

[19]  S. Biswal,et al.  Acrolein Causes Inhibitor κB-independent Decreases in Nuclear Factor κB Activation in Human Lung Adenocarcinoma (A549) Cells* , 1999, The Journal of Biological Chemistry.

[20]  P. O'Connor,et al.  Isolation and characterization of proteins cross-linked to DNA by the antitumor agent methylene dimethanesulfonate and its hydrolytic product formaldehyde. , 1989, The Journal of biological chemistry.

[21]  J A Swenberg,et al.  Carcinogenicity of formaldehyde in rats and mice after long-term inhalation exposure. , 1983, Cancer research.

[22]  D. Paustenbach,et al.  DNA-protein cross-links produced by various chemicals in cultured human lymphoma cells. , 1997, Journal of toxicology and environmental health.

[23]  Aaron Ciechanover,et al.  The ubiquitin–proteasome pathway: on protein death and cell life , 1998, The EMBO journal.

[24]  M. Solomon,et al.  Formaldehyde-mediated DNA-protein crosslinking: a probe for in vivo chromatin structures. , 1985, Proceedings of the National Academy of Sciences of the United States of America.

[25]  M. Koivusalo,et al.  Formaldehyde dehydrogenase from human liver. Purification, properties, and evidence for the formation of glutathione thiol esters by the enzyme. , 1974, The Journal of biological chemistry.

[26]  A. Kumatori,et al.  Direct evidence for nuclear and cytoplasmic colocalization of proteasomes (Multiprotease complexes) in liver , 1989, Journal of cellular physiology.

[27]  R. Jamasbi,et al.  Growth inhibition and DNA damage induced by benzo[a]pyrene and formaldehyde in primary cultures of rat tracheal epithelial cells. , 1988, Mutation research.

[28]  R F Standaert,et al.  Inhibition of proteasome activities and subunit-specific amino-terminal threonine modification by lactacystin , 1995, Science.

[29]  Richard D. Wood,et al.  Nucleotide Excision Repair in Mammalian Cells* , 1997, The Journal of Biological Chemistry.

[30]  E. Eder,et al.  Structures of acrolein-guanine adducts: a semi-empirical self-consistent field and nuclear magnetic resonance spectral study. , 1998, Chemical research in toxicology.

[31]  Kent D. Sugden,et al.  Hypervalent chromium mimics reactive oxygen species as measured by the oxidant-sensitive dyes 2',7'-dichlorofluorescin and dihydrorhodamine. , 1998, Chemical research in toxicology.

[32]  T. Ma,et al.  Review of the genotoxicity of formaldehyde. , 1988, Mutation research.

[33]  R. Mason,et al.  Formaldehyde adducts of glutathione. Structure elucidation by two-dimensional n.m.r. spectroscopy and fast-atom-bombardment tandem mass spectrometry. , 1988, The Biochemical journal.

[34]  J. Pouliot,et al.  Yeast gene for a Tyr-DNA phosphodiesterase that repairs topoisomerase I complexes. , 1999, Science.

[35]  T. Skopek,et al.  Formaldehyde-induced and spontaneous alterations in human hprt DNA sequence and mRNA expression. , 1989, Mutation research.

[36]  R B Conolly,et al.  Comparison of inhaled formaldehyde dosimetry predictions with DNA-protein cross-link measurements in the rat nasal passages. , 1997, Toxicology and applied pharmacology.

[37]  P. van Bladeren,et al.  Glutathione-dependent biotransformation of the alkylating drug thiotepa and transport of its metabolite monoglutathionylthiotepa in human MCF-7 breast cancer cells. , 1998, Cancer research.

[38]  M. Flyvholm,et al.  Identification of formaldehyde releasers and occurrence of formaldehyde and formaldehyde releasers in registered chemical products. , 1993, American journal of industrial medicine.

[39]  A. Zhitkovich,et al.  Analysis of DNA-protein crosslinking activity of malondialdehyde in vitro. , 1999, Mutation research.

[40]  O Merk,et al.  Significance of formaldehyde‐induced DNA–protein crosslinks for mutagenesis , 1998, Environmental and molecular mutagenesis.

[41]  E. Niki,et al.  Protein-bound acrolein: potential markers for oxidative stress. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[42]  N. Oleinick,et al.  Inhibition of radiation-induced DNA-protein cross-link repair by glutathione depletion with L-buthionine sulfoximine. , 1988, NCI monographs : a publication of the National Cancer Institute.

[43]  C. Harris,et al.  Repair of DNA damage caused by formaldehyde in human cells. , 1984, Cancer research.

[44]  V. Jackson Studies on histone organization in the nucleosome using formaldehyde as a reversible cross-linking agent , 1978, Cell.

[45]  A. Zhitkovich,et al.  Glutathione and free amino acids form stable complexes with DNA following exposure of intact mammalian cells to chromate. , 1995, Carcinogenesis.

[46]  Howard Hughes Lactacystin, Proteasome Function, and Cell Fate* , 1998, The Journal of Biological Chemistry.

[47]  T. Skopek,et al.  Molecular analysis of formaldehyde-induced mutations in human lymphoblasts and E. coli. , 1988, Environmental and molecular mutagenesis.

[48]  M. Casanova,et al.  Further studies of the metabolic incorporation and covalent binding of inhaled [3H]- and [14C]formaldehyde in Fischer-344 rats: effects of glutathione depletion. , 1987, Toxicology and applied pharmacology.