1. Guanine Holes Are Prominent Targets for Mutation in Cancer and Inherited Disease
- Author
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Robert M. Stephens, Karen M. Vasquez, David Neil Cooper, Regina Z. Cer, Aklank Jain, Uma Mudunuri, Jack R. Collins, Duncan E. Donohue, Brian T. Luke, Ming Yi, Edward V. Ball, Guliang Wang, Joseph Ivanic, Nuri A. Temiz, Natalia Volfovsky, and Albino Bacolla
- Subjects
Models, Molecular ,Cancer Research ,Guanine ,lcsh:QH426-470 ,Nonsense mutation ,Gene mutation ,Biology ,010402 general chemistry ,medicine.disease_cause ,01 natural sciences ,03 medical and health sciences ,Germline mutation ,Neoplasms ,Genetics ,medicine ,Humans ,Missense mutation ,Nucleotide Motifs ,Molecular Biology ,Germ-Line Mutation ,Genetics (clinical) ,Ecology, Evolution, Behavior and Systematics ,030304 developmental biology ,0303 health sciences ,Mutation ,Point mutation ,Mutagenesis ,Genetic Diseases, Inborn ,Nucleic acid sequence ,Computational Biology ,DNA, Neoplasm ,3. Good health ,0104 chemical sciences ,lcsh:Genetics ,Amino Acid Substitution ,Research Article - Abstract
Single base substitutions constitute the most frequent type of human gene mutation and are a leading cause of cancer and inherited disease. These alterations occur non-randomly in DNA, being strongly influenced by the local nucleotide sequence context. However, the molecular mechanisms underlying such sequence context-dependent mutagenesis are not fully understood. Using bioinformatics, computational and molecular modeling analyses, we have determined the frequencies of mutation at G•C bp in the context of all 64 5′-NGNN-3′ motifs that contain the mutation at the second position. Twenty-four datasets were employed, comprising >530,000 somatic single base substitutions from 21 cancer genomes, >77,000 germline single-base substitutions causing or associated with human inherited disease and 16.7 million benign germline single-nucleotide variants. In several cancer types, the number of mutated motifs correlated both with the free energies of base stacking and the energies required for abstracting an electron from the target guanines (ionization potentials). Similar correlations were also evident for the pathological missense and nonsense germline mutations, but only when the target guanines were located on the non-transcribed DNA strand. Likewise, pathogenic splicing mutations predominantly affected positions in which a purine was located on the non-transcribed DNA strand. Novel candidate driver mutations and tissue-specific mutational patterns were also identified in the cancer datasets. We conclude that electron transfer reactions within the DNA molecule contribute to sequence context-dependent mutagenesis, involving both somatic driver and passenger mutations in cancer, as well as germline alterations causing or associated with inherited disease., Author Summary A large number of DNA mutations identified in cells from patients with cancer or human inherited disease were analyzed to address a fundamental issue in human pathology, viz, the mutational mechanisms that cause irreversible changes to DNA. By using bioinformatics and computational methods, we found that mutations do not occur randomly, but instead affect specific bases, most often guanines flanked by other guanines or adenines. We attribute this effect to electron transfer, a chemical reaction known to underlie basic biological processes such as cellular respiration and photosynthesis. Certain types of carcinogens, oxidants or radiation can interact with DNA and abstract an electron. Our results imply that the ensuing sites of electron loss can migrate from their original position in the DNA to neighboring guanines where they become trapped, leading to further chemical modifications that may eventually result in mutations. Many of the mutations known to be important for tumor growth (driver mutations), as well as passenger mutations and mutations associated with inherited disease, appear to be caused by electron transfer. Beyond pathological mutations, electron transfer may represent a universal mechanism by which genetic changes occur in all life forms to drive population fitness over evolutionary time.
- Published
- 2013
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