An NMR and molecular modelling analysis of d(CTACTGCTTTAG). d(CTAAAGCAGTAG) reveals that the particular behaviour of TpA steps is related to edge-to-edge contacts of their base-pairs in the major groove.

In a previous NMR study we detected the presence of particular motions and hydration properties within the DNA fragment d(CTACTGCTTTAG).d(CTAAAGCAGTAG). Now, we report on an NMR and molecular modelling analysis of this sequence focusing our attention on the biologically important TpA steps. NOe and coupling constant restraints were introduced in three different modelling protocols: X-PLOR and JUMNA used with Flex and AMBER94 as force-fields. Despite their differences the protocols produce similar mean B-DNA structures (r.m.s.d. <1 A). The new information confirms our previous experimental results on the narrowing of the minor groove along the T8T9T10/A17A16A15 run and the sudden widening at the T10pA11 step ending this run. It is further shown that this step displays a large positive roll with its T10:A15 and A11:T14 base-pairs likely stabilised by amino-amino and amino-carbonyl interactions in the major groove. A relationship between roll values and amino-amino and amino-carbonyl distances strongly suggests that electrostatics or bifurcated hydrogen-bonds could be responsible for induction of positive rolls in TpA steps. Such edge-to-edge interactions could explain the slower motions shown by the adenine A15. The influence of these interactions on the stabilisation of particular DNA conformers is discussed using our data and those provided by the recent literature.

An NMR study of d(CTACTGCTTTAG).d(CTAAAGCAGTAG) showing hydration water molecules in the minor groove of a TpA step.

The hydration properties of the non-palindromic duplex d(CTACTGCTTTAG). d(CTAAAGCAGTAG) were investigated by NMR spectroscopy. The oligonucleotide possesses a heterogeneous B-DNA structure. The H2(n)-H1'(m+1) distances reflect a minor groove narrowing within the TTT/AAA segment (approximately 3.9A) and a sudden widening at the T10:A15 base-pair (approximately 5.3A), the standard B-DNA distance being approximately 5A. The facing T10pA11 and T14pA15 steps at the end of the TTTA/AAAT segment have completely different behaviors. Only A15 ending the AAA run displays NMR features comparable to those shown by adenines of TpA steps occupying the central position of TnAn (n> or =2) segments. These involve particular chemical shifts and line broadening of the H2 and H8 protons. Positive NOESY cross-peaks were measured between the water protons and the H2 protons of A15, A16 and A17 reflecting the occurrence of hydration water molecules with residence times longer than 500 picoseconds along the minor groove of the TTT/AAA segment. In contrast no water molecules with long residence times were observed neither for A3, A20 and A23 nor for A11 ending the 5'TTTA run. We confirm thus that the binding of water molecules with long residence time to adenine residues correlates with the minor groove narrowing. In contrast, the widening of the minor groove at the A11:T14 base-pair ending the TTTA/TAAA segment, likely associated to a high negative propeller twist value at this base-pair, prevents the binding of a water molecule with long residence time to A11 but not to A15 of the preceding T10:A15 base-pair. Thus, in our non-palindromic oligonucleotide the water molecules bind differently to A11 and A15 although both adenines are part of a TpA step. The slower motions occurring at A15 compared to A11 are also well explained by the present results.