AbstractStructure activity relationships for tricyclic‐carboxamide topoisomerase II poisons indicate that cytotoxicity is enhanced by the presence of methyl, and other, groups in the position peri to the carboxamide. Linked dimers of phenazine‐1‐carboxamides are potent cytotoxins and one phenazine dimer, MLN944 (alternatively XR5944), has been in clinical trial. MLN944 is a template inhibitor of transcription, whereas corresponding monomers are not. Nevertheless, its cytotoxic potency is also diminished by removal of its peri methyl groups. Here, we describe NMR and molecular dynamic studies of the interaction of desmethyl MLN944 with d(ATGCAT)2, d(TATGCATA)2, and d(TACGCGTA)2 to investigate the influence of the nine‐methyl group on the structure of MLN944 complexes. As with MLN944, the carboxamide group hydrogen bonds to the phenazine ring nitrogen, the ligand sandwiches the central GC base pairs in the major groove, and the protonated linker amines hydrogen bond primarily to the O6 atom of the guanines. Molecular dynamics studies reveal that the linker exists in multiple conformations, none of which produce an ideal set of hydrogen bonds. In distinction, however, the carboxamide‐to‐phenazine ring nitrogen hydrogen bond is weaker, the overall helix winding is less and the NMR resonances are broader in the desmethyl complexes. Exchange between free and complexed DNA, quantified using two‐dimensional NOESY spectra, is faster for the desmethyl MLN944 complexes than for MLN944 complexes. Overall, the data suggest that desmethyl MLN944 DNA complexes are “looser” and more unwound at the binding site, leading to faster dissociation rates, which could account for the diminished efficacy of the desmethyl analog.