References
- Chakrabarti S, Kassis A I, Slayter H S, Bump E A, Sahu S K, Makrigiorgos G M. Continuous detection of radiation or metal generated hydroxyl radicals within core chromatin particles. International Journal of Radiation Biology 1998; 73: 53–63
- Chen K, Adelstein S J, Kassis A I. Molecular modeling of the interaction of iodinated Hoechst analogs with DNA: implications for new radiopharmaceutical design. Journal of Molecular Structure: (Theochem) 2004; 711: 49–56
- Coleman R S, Berg M A, Murphy C J. Coumarin base-pair replacement as a fluorescent probe of ultrafast DNA dynamics. Tetrahedron 2007; 63: 3450–3456
- Coussens L M, Tinkle C L, Hanahan D, Werb Z. MMP-9 supplied by bone marrow-derived cells contributes to skin carcinogenesis. Cell 2000; 103: 481–490
- Crosby D G, Berthold R V. Fluorescence spectra of some simple coumarins. Analytical Biochemistry 1962; 4: 349–57
- Drolet G, Dumbroff E B, Legge R L, Thompson J E. Radical scavenging properties of polyamines. Phytochemistry 1986; 25: 367–371
- Goodwin R H, Kavanagh F. Fluorescence of coumarin derivatives as a function of pH. Archives of Biochemistry 1950; 27: 152–173
- Goodwin R H, Kavanagh F. The fluorescence of coumarin derivatives as a function of pH. II. Archives of Biochemistry 1952; 36: 422–55
- Ha H C, Sirisoma N S, Kuppusamy P, Zweier J L, Woster P M, Casero R A, Jr. The natural polyamine spermine functions directly as a free radical scavenger. Proceedings of the National Academy of Science of the USA 1998; 95: 11140–11145
- Huang L, Kim P M, Nickoloff J A, Morgan W F. Targeted and nontargeted effects of low-dose ionizing radiation on delayed genomic instability in human cells. Cancer Research 2007; 67: 1099–1104
- Huang L, Snyder A R, Morgan W F. Radiation-induced genomic instability and its implications for radiation carcinogenesis. Oncogene 2003; 22: 5848–5854
- Kadhim M A, Lorimore S A, Townsend K MS, Goodhead D T, Buckle V J, Wright E G. Radiation-induced genomic instability: Delayed cytogenetic aberrations and apoptosis in primary human bone marrow cells. International Journal of Radiation Biology 1995; 67: 287–293
- Kaur H, Halliwell B. Detection of hydroxyl radicals by aromatic hydroxylation. Methods in Enzymology 1994; 233: 67–82
- Korolev N, Lyubartsev A P, Laaksonen A, Nordenskiöld L. On the competition between water, sodium ions, and spermine in binding to DNA: a molecular dynamics computer simulation study. Biophysical Journal 2002; 82: 2860–2875
- Makrigiorgos G M, Baranowska-Kortylewicz J, Bump E, Sahu S K, Berman R M, Kassis A I. A method for detection of hydroxyl radicals in the vicinity of biomolecules using radiation-induced fluorescence of coumarin. International Journal of Radiation Biology 1993; 63: 445–458
- Makrigiorgos G M, Folkard M, Huang C, Bump E, Baranowska-Kortylewicz J, Sahu S K, Michael B D, Kassis A I. Quantification of radiationinduced hydroxyl radicals within nucleohistones using a molecular fluorescent probe. Radiation Research 1994; 138: 177–185
- Mantaka A, Marketos D G, Stein G. Continuous g and pulse radiolysis of aqueous benzene solutions: some reactions of the hydroxycyclohexadienyl radical. Journal of Physical Chemistry 1971; 75: 3886–3889
- Mead J AR, Smith J N, Williams R T. Studies in detoxification. 72. The metabolism of coumarin and of o-coumaric acid. Biochemical Journal 1958; 68: 67–74
- Morgan W F. Non-targeted and delayed effects of exposure to ionizing radiation: II. Radiation-induced genomic instability and bystander effects in vivo, clastogenic factors and transgenerational effects. Radiation Research 2003; 159: 581–596
- Morgan W F, Sowa M B. Non-targeted bystander effects induced by ionizing radiation. Mutation Research 2007; 616: 159–164
- Morris G M, Goodsell D S, Halliday R S, Huey R, Hart W E, Belew R K, Olson A J. Automated docking using a Lamarckian genetic algorithm and an empirical binding free energy function. Journal of Computational Chemistry 1998; 19: 1639–1662
- Pryor W A. Why is the hydroxyl radical the only radical that commonly adds to DNA? Hypothesis: it has a rare combination of high electrophilicity, high thermochemical reactivity, and a mode of production that can occur near DNA. Free Radical Biology and Medicine 1988; 4: 219–223
- Raghavan N V, Steenken S. Electrophilic reaction of the OH radical with phenol. Determination of the distribution of isomeric dihydroxycyclohexadienyl radicals. Journal of the American Chemical Society 1980; 102: 3495–3499
- Roots R, Okada S. Estimation of life times and diffusion distances of radicals involved in X-ray-induced DNA strand breaks or killing of mammalian cells. Radiation Research 1975; 64: 306–320
- Schüttelkopf A W, van Aalten D MF. PRODRG: A tool for high-throughput crystallography of protein–ligand complexes. Acta Crystallographica 2004; D60: 1355–1363
- Singh A, Chen K, Adelstein S J, Kassis A I. Synthesis of coumarin–polyamine-based molecular probe for the detection of hydroxyl radicals generated by gamma radiation. Radiation Research 2007; 168: 233–242
- Smith L E, Nagar S, Kim G J, Morgan W F. Radiation-induced genomic instability: radiation quality and dose response. Health Physics 2003; 85: 23–29
- Sowa M, Arthurs B J, Estes B J, Morgan W F. Effects of ionizing radiation on cellular structures, induced instability and carcinogenesis. EXS 2006; 96: 293–301
- Tabor C W, Tabor H. Polyamines. Annual Review of Biochemistry 1984; 53: 749–790
- C von Sonntag, 1987. The chemical basis of radiation biology. London, Taylor & Francis
- Walling C, Johnson R A. Fenton's reagent. V. Hydroxylation and side-chain cleavage of aromatics. Journal of the American Chemical Society 1975; 97: 363–367
- Xue L Y, Butler N J, Makrigiorgos G M, Adelstein S J, Kassis A I. Bystander effect produced by radiolabeled tumor cells in vivo. Proceedings of the National Academy of Sciences of the USA 2002; 99: 13765–13770