The structure of the interstrand cross-linked adduct formed between a C8-C8'-linked pyrrolobenzodiazepine (PBD) dimer (DSB-120; 1,1'-(propane-1,3-diyldioxy)bis[(11aS)-7-methoxy-1,2,3,11a-t etrahydro-5H- pyrrolo[2,1-c][1,4]benzodiazepin-5-one]) and a self-complementary d(CICGATCICG)2 duplex has been determined from high-field 1D- and 2D-NMR data using a simulated annealing procedure. The refined structure supports earlier observations from solution NMR experiments and indicates that the covalently bound molecule spans six DNA base pairs in the minor groove, forming a symmetric cross-link between the spatially separated internal guanines and with active recognition of an embedded 5'-GATC bonding site. This result confirms that template-directed approaches are useful for the design of linked DNA-interactive PBD dimers with viable DNA cross-linking potential. Further, head-to-head connection of the PBD moieties results in an overall retention of 5'-GA bonding site preference for each alkylating PBD subunit. Structural analysis indicates that cross-link formation results in a localized perturbation of the DNA duplex, attributable in part to a mutual reduction in dynamic mobility or "covalent clamping" within the Gua4-Cyt7 base tract. However, ligand-induced distortion is confined to the Cyt7 and Ino8 residues on each strand. The Gua(N2)-Gua(N2) cross-link is stabilized by two directed H-bonds from the formed animal residues to N3 acceptor atoms of adenine bases on the 3'-side of each covalently modified guanine. Evidence for sequence-specific cross-linking with DSB-120 is provided by extended modeling studies which suggest that recognition of the favored d(.GATC.) motif is dominated by van der Waals steric factors, although electrostatic and H-bonded interaction terms also play a key role. This conclusion supports recent covalent footprinting studies revealing that this PBD dimer shows a selectivity for embedded base sequences of the type 5'-(pu/py)GATC(py/pu).