Formaldehyde-activated WEHI-150 induces DNA interstrand crosslinks with unique structural features.

Mitoxantrone is an anticancer anthracenedione that can be activated by formaldehyde to generate covalent drug-DNA adducts. Despite their covalent nature, these DNA lesions are relatively labile. It was recently established that analogues of mitoxantrone featuring extended side-chains terminating in primary amino groups typically yielded high levels of stable DNA adducts following their activation by formaldehyde.

Pharmacogenomics in Papua New Guineans: unique profiles and implications for enhancing drug efficacy while improving drug safety.

Papua New Guinea (PNG) can be roughly divided into highland, coastal and island peoples with significant mitochondrial DNA differentiation reflecting early and recent distinct migrations from Africa and East Asia, respectively. Infectious diseases such as tuberculosis, malaria and HIV severely impact on the health of its peoples for which drug therapy is the major treatment and pharmacogenetics has clinical relevance for many of these drugs. Although there is generally little information about known single nucleotide polymorphisms in the population, in some instances, their frequencies have been shown to be higher than anywhere worldwide.

Reversible and formaldehyde-mediated covalent binding of a bis-amino mitoxantrone analogue to DNA.

The ability of a bis-amino mitoxantrone anticancer drug (named WEHI-150) to form covalent adducts with DNA, after activation by formaldehyde, has been studied by electrospray ionisation mass spectrometry and HPLC. Mass spectrometry results showed that WEHI-150 could form covalent adducts with d(ACGCGCGT)2 that contained one, two or three covalent links to the octanucleotide, whereas the control drugs (daunorubicin and the anthracenediones mitoxantrone and pixantrone) only formed adducts with one covalent link to the octanucleotide. HPLC was used to examine the extent of covalent bond formation of WEHI-150 with d(CGCGCG)2 and d(CG(5Me)CGCG)2.

M2, a novel anthracenedione, elicits a potent DNA damage response that can be subverted through checkpoint kinase inhibition to generate mitotic catastrophe.

Pixantrone is a promising anti-cancer aza-anthracenedione that has prompted the development of new anthracenediones incorporating symmetrical side-chains of increasing length varying from two to five methylene units in each pair of drug side-chains. A striking relationship has emerged in which anthracenedione-induced growth inhibition and apoptosis was inversely associated with side-chain length, a relationship that was attributable to a differential ability to stabilise the topoisomerase II (TOP2) cleavage complex. Processing of the complex to a DNA double strand break (DSB) flanked by γH2AX in nuclear foci is likely to occur, as the generation of the primary lesion was antecedent to γH2AX induction.