Acylfulvenes (AFs) are a class of semisynthetic agents with high toxicity toward certain tumor cells, and for one analogue, hydroxymethylacylfulvene (HMAF), clinical trials are in progress. DNA alkylation by AFs, mediated by bioreductive activation, is believed to contribute to cytotoxicity, but the structures and chemical properties of corresponding DNA adducts are unknown. This study provides the first structural characterization of AF-specific DNA adducts. In the presence of a reductive enzyme, alkenal/one oxidoreductase (AOR), AF selectively alkylates dAdo and dGuo in reactions with a monomeric nucleoside, as well as in reactions with naked or cellular DNA, with 3-alkyl-dAdo as the apparently most abundant AF-DNA adduct. Characterization of this adduct was facilitated by independent chemical synthesis of the corresponding 3-alkyl-Ade adduct. In addition, in naked or cellular DNA, evidence was obtained for the formation of an additional type of adduct resulting from direct conjugate addition of Ade to AF followed by hydrolytic cyclopropane ring-opening, indicating the potential for a competing reaction pathway involving direct DNA alkylation. The major AF-dAdo and AF-dGuo adducts are unstable under physiologically relevant conditions and depurinate to release an alkylated nucleobase in a process that has a half-life of 8.5 h for 3-alkyladenine and less than approximately 2 h for dGuo adducts. DNA alkylation further leads to single-stranded DNA cleavage, occurring exclusively at dGuo and dAdo sites, in a nonsequence-specific manner. In AF-treated cells that were transfected with either AOR or control vectors, the DNA adducts identified match those from in vitro studies. Moreover, a positive correlation was observed between DNA adduct levels and cell sensitivity to AF. The potential contributing roles of AOR-mediated bioactivation and adduct stability to the cytotoxicity of AF are discussed.
Selective pairing of engineering nucleosides in DNA duplexes provides a potential means to probe structurally modified DNA bases (i.e., DNA adducts) and address challenges associated with correlating adduct chemical structure with biological impact. The current study provides the first example of a thermodynamically stable DNA base pair that is comprised of a biologically relevant carcinogen−DNA adduct and a synthetic nucleoside probe. O
6-Benzylguanine is a mutagenic DNA adduct; molecular modeling indicates that a novel diaminonaphthyl-derived nucleoside (dNap):O
6-benzylguanine base pair may be stabilized by a combination of hydrogen-bonding and hydrophobic interactions. The nucleoside dNap was synthetically incorporated into oligonucleotides, and a series of duplexes were evaluated by thermal denaturation studies. The bulky DNA adduct O
6-benzylguanine forms a highly stable and orthogonal base pair with dNap. Data indicate π-stacking potential, self-pairing capacity, isomeric selectivity, 1:1 duplex stoichiometry, and a B-form DNA structure. Further studies are required to understand the physical determinants of adduct:probe pair stability for the design of probes for diverse forms of DNA damage and for the development of adduct−probe-based molecular techniques.
Acylfulvenes comprise a family of semisynthetic natural product derivatives with potent antitumor activities. Previous studies indicated that acylfulvenes are bioactivated by NADPH-dependent alkenal/one reductase (AOR), presumably generating intermediates with the capacity to alkylate cellular targets, such as DNA, proteins, and glutathione. This process is thought to induce apoptosis, and the chemical and biochemical pathways involved are topics of current investigation. In this study, four acylfulvene analogues were synthesized: (-)-acylfulvene, (+)-acylfulvene, (-)-(hydroxymethyl)acylfulvene, and (+)-(hydroxymethyl)acylfulvene. These compounds were synthesized by a chiral-resolution method, described for the first time in this report, and by asymmetric synthesis using a method formally demonstrated previously. Cell toxicity studies indicate a positive correlation between AOR level and acylfulvene sensitivity. The absolute configuration of acylfulvene analogues has a significant influence on cytotoxicity. (-)-(Hydroxymethyl)acylfulvene is 25 times more potent than (+)-(hydroxymethyl)acylfulvene in cells transfected with an AOR overexpression vector. Based on kinetic parameters, the rates of AOR-mediated activation are more strongly dependent on acylfulvene substitution than on absolute stereochemistry. These data support the role of AOR-mediated metabolism and indicate the involvement of other stereochemically dictated pathways, such as transport and biomolecule binding, in contributing to the cytotoxicity of acylfulvenes.
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