Crystal structure of an inhibitor and a model for inhibition of replicative DNA synthesis

6-(p-Hydroxyphenylhydrazino)-uracil is an antimicrobial agent that selectively blocks replicative DNA synthesis in Bacillus subtilis by inhibiting DNA polymerase III. The drug crystallizes as a monoclinic monohydrate, space group $\text{C2}\text{c}$, with $\text{a = 23.920(6)}\text{A}\text{̊}\text{, b = 5.587(3)}\text{A}\text{̊}\text{, c = 17.466(5)}\text{A}\text{̊}\text{, β = 101.45(8) °}$, and eight hydrated molecules per cell. Three-dimensional X-ray diffraction data were collected. The structure was solved by Patterson methods and refined to an R value of 6.8% for the 1651 data. The geometry of the uracil ring is unusual. The bond distances suggest that a resonance form involving a positively charged hydrazino nitrogen and a negatively charged carbonyl oxygen, O(4), makes a large contribution to the valence bond structure of this compound. The exocyclic C(6)N bond is short (1.335 Å), the C(6)C(5) bond distance is 1.371 Å, which is longer than in uracil, and the C(5)C(4) distance (1.396 Å) is short. The uracil ring, the linked hydrazino nitrogen, and the hydrogen on this nitrogen are in the same plane. Each uracil group is hydrogen bonded to a nearly coplanar uracil across a center of symmetry. The water molecule is also near the plane of these paired bases and forms a hydrogen bond with the uracil-linked hydrazino NH group. This paired base arrangement and the restricted rotation about the exocyclic C(6)N link that constrains the hydrazino NH group to lie near the uracil plane suggest a model for the interaction of the drug with template-primer DNA. The drug acts when cytosine is the base to be copied in the template strand, and the drug is competitive with dGTP. Both cytosine and guanine can be accommodated with little distortion of the crystal structure geometry in a manner compatible with the known geometry of DNA. The structural and biochemical aspects of the model for drug action are discussed.