X-ray and solution studies of DNA oligomers and implications for the structural basis of A-tract-dependent curvature.

DNA containing short periodic stretches of adenine residues (known as A-tracts), which are aligned with the helical repeat, exhibit a pronounced macroscopic curvature. This property is thought to arise from the cumulative effects of a distinctive structure of the A-tract. It has also been observed by gel electrophoresis that macroscopic curvature is largely retained when inosine bases are introduced singly into A-tracts but decreases abruptly for pure I-tracts. The structural basis of this effect is unknown. Here we describe X-ray and gel electrophoretic analyses of several oligomers incorporating adenine or inosine bases or both. We find that macroscopic curvature is correlated with a distinctive base-stacking geometry characterized by propeller twisting of the base-pairs. Regions of alternating adenine and inosine bases display large propeller twisting comparable to that of pure A-tracts, whereas the values observed for pure I-tracts are significantly smaller. We also observe in the crystal structures that propeller twist leads to close cross-strand contacts between amino groups from adenine and cytosine bases, indicating an attractive NH-N interaction, which is analogous to the NH-O interaction proposed for A-tracts. This interaction also occurs between adenine bases across an A-T step and may explain in part the different behavior of A-T versus T-A steps in the context of A-tract-induced curvature. We also note that hydration patterns may contribute to propeller-twisted conformation. Based on the present data and other structural and biophysical studies, we propose that DNA macroscopic curvature is related to the structural invariance of A-tract and A-tract-like regions conferred by high propeller twist, cross-strand interactions and characteristic hydration. The implications of these findings to the mechanism of DNA bending are discussed.

A recipe for specificity.

Water molecules and DNA conformation are now recognized as ingredients which can influence both the affinity and specificity of protein/DNA complexes.

Effects of antioestrogens on the DNA binding activity of oestrogen receptors in vitro.

We have investigated the effect of a series of steroidal oestrogen antagonists, related to ICI 164,384, on the DNA binding activity of mouse oestrogen receptors expressed in insect cells. The analogues possess different side chains at the 7-position of the B ring in the steroid. Inhibition was observed when the length of the side-chain was 15-16 carbon atoms but not 10 or 20 carbon atoms and only when the 7 alpha isomer was used. The DNA binding activity of receptors expressed in COS-1 cells was also inhibited after extended periods of incubation with antioestrogens but not that of the human receptor in breast cancer cell-extracts. We have proposed that ICI 164,384 might disrupt receptor dimerisation, and therefore the variation in its ability to inhibit DNA binding activity may reflect differences in dimer stability. Since the DNA binding activity of in vitro translated receptors was inhibited when they were translated in the presence of the antioestrogen we suggest that ICI 164,384 might prevent the formation of receptor dimers without necessarily being able to disrupt preformed dimers.