SEQUENCE EFFECTS ON LOCAL DNA TOPOLOGY

Nuclear Overhauser effect-derived distances between adenine H2 protons and anomeric H1' protons on the same strand or on the complementary strand are presented for several different DNA duplexes. The cross-strand (n)AH2 to (m + 1)H1' distances [designated as x, where (n) and (m) are complementary residues] vary by up to 1 angstrom depending on the sequence. In all possible A-containing pyrimidine-purine steps (CA, TG, and TA), x is > 4.5 angstrom. In GA steps, x varies within rather wide limits in the range 3.8-4.5 angstrom, whereas in AA steps the lower limit is 3.7 angstrom and the upper limit is almost-equal-to 4.2 angstrom. In purine-purine steps, x is affected by at least three factors: (i) adjacent pyrimidine-purine steps at the 5' end [e.g., YRA sequences (where Y = T or C and R = G or A)], or a pyrimidine-purine step at the 3' end of the pyrimidine-pyrimidine step on the complementary strand, cause x to increase, (ii) an AT step at the 3' end of a purine-purine step (e.g., RAT) causes x to decrease, and (iii) substitution of bases at the next-nearest neighbor position leads to changes in x at GA and AA steps. The latter factor seems to be due to a cooperative effect arising from formation of the "anomalous" B' structure when the substitution produces an A(n)T(m) tract (which always produces a decrease in x). The data indicate that (n)AH2-(n + 1)H1' distances on the same strand (designated as s) are also sequence dependent. Thus on AA steps, neighboring substitutions produce the same effect on s as on the cross-strand x distances. The results lead to the ability to predict changes in AH2-H1' distances depending on the DNA sequence. By using high-resolution x-ray B-type structures as a set of allowable B conformations, a very good correlation was found between x and the minor groove width parameters P-P or H1'-H1'. Thus, the x distances are a direct probe of the minor groove width in B-type DNA, and changes in this distance therefore reflect changes in the minor groove width. Since many of the sequences studied are sites of protein recognition, the observed sequence-structure dependence in DNA probably plays an important role in the process of recognition by proteins and minor groove ligands such as drugs.