Rotational dynamics of adenine amino groups in a DNA double helix.

Exocyclic amino groups of the bases undergo conformational fluctuations that affect the recognition and reactivity of nucleic acid molecules. Among these fluctuations, rotation of amino groups around C-N bonds is of special interest. In the present paper, we report the first determination of the rates and energetic parameters for rotation of the N6-amino group of adenine in a DNA double helix. The DNA molecule studied is the dodecamer [d(CGCGAGCTCGCG)]2. The adenine in each A. T basepair of the dodecamer was labeled with 15N at the N6 position, and the NMR resonances of the two protons in the adenine amino group were selectively observed by 15N-editing methods. The rates of rotation of the amino group were obtained from experiments of transfer of magnetization between the two protons in the same group and from lineshape analysis of 15N-edited amino proton NMR resonances. The results show that, over the temperature range from 0 to 70 degrees C, the rates of rotation of adenine amino groups range from 60 to 24,000 s-1. Formation of the activated state during rotation has a standard enthalpy change of 15.3 +/- 0.2 kcal/mol and a standard entropy change of 6.0 +/- 0.7 cal/(mol. K). Analysis of the results suggests that rotation of the amino group occurs in the paired, closed state of the adenine in the A. T basepair of the double-helical DNA structure.

Multiple molecules of integration host factor (IHF) at a single DNA binding site, the bacteriophage lambda cos I1 site.

Integration host factor (IHF) is an E coli protein that binds DNA sequence-specifically and serves as a cofactor in many intracellular processes including lambda DNA packaging. In gel shift experiments, cos DNA, a DNA fragment containing the recognition signal for lambda DNA packaging, forms multiple protein-DNA complexes when combined with pure IHF. Copper(II)-1,10 orthophenanthroline footprinting of individual IHF-cos DNA complexes shows that multiple complex formation does not result from IHF binding to successive sites on the cos DNA fragment. Instead, the footprinting of DNA from two IHF-cos complexes shows protection at one site alone. DNA in the first complex is only partially protected from nucleolytic cleavage, while DNA in the second, slower-moving, complex is completely protected at the same binding site. Quantitative Western blotting experiments determined the relative stoichiometry of IHF to DNA in the two complexes. The results confirm that two molecules of IHF bind at a single site in the cos fragment. This site, cos I1, has two matches to the IHF consensus sequence, but the two matches overlap by eight of thirteen nucleotides. A search of the DNA sequence around cos, using an expanded IHF consensus sequence, has revealed additional, low-affinity consensus matches, contiguous to these. The extent of the copper(II)-1,10 orthophenanthroline footprint and the stoichiometry of the IHF-cos I1 complexes suggest that either two molecules of IHF bind to overlapping sites, or IHF binds to a site of low affinity contiguous to a strong site. Application of a thermodynamic model to the results of gel shift experiments with IHF and cos DNA suggests that multiple complex formation requires cooperative interaction between the two IHF binding sites.

Determination of distances involving exchangeable protons from NOESY spectra of two DNA dodecamers.

Two-dimensional proton nuclear Overhauser effect (NOESY) spectra were obtained as a function of mixing time for two DNA dodecamers, 5'-CGCGAATTCGCG-3' and 5'-CGCAAATTTGCG-3', in aqueous solutions. The time evolution of cross-peak volumes was quantitatively analyzed based on the approximate solution of the relaxation/exchange equation over a range of mixing times from 30 to 150 ms. Inter-proton distances, involving exchangeable protons in key locations of the structures, were calculated and compared to the distances predicted by the crystal structures. These NMR-derived distances enhance the number of constraints, and their accuracy, for determination of solution structures of the two DNA dodecamers.

Long-range effects and conformational flexibility of aldolase.

The conformational flexibility and long-range interactions in rabbit muscle aldolase induced by active-site ligand binding, cross-linking of the enzyme between Cys72 and Cys338, and removal of the C-terminal tyrosine residue were studied by following the changes in the microenvironments of Cys239 and Cys289 located outside the active site. It was found that substrates induced a conformational change in aldolase, which propagates from the active site to Cys239, which is located close to intersubunit contacts. The response of the enzyme is differential. Ligands having both C-1 and C-6 phosphates or C-1 phosphate only induce the enhancement of Cys239 reactivity, whereas those with C-6 phosphates only decrease Cys239 reactivity. This correlates well with a dramatic difference in kinetic parameters for a cleavage of fructose-1,6-P2 and fructose-1-P. Therefore, these changes can be interpreted as syncatalytic. Cross-linking of the aldolase subunit by an -S-S-bridge between Cys72 and Cys338 inactivates the enzyme, abolishes binding of active-site ligands, and induces a conformational change in the enzyme that can be detected far away (at Cys239 and Cys289) from the site of perturbation. Cys72 and Cys338 are not in the active site. This shows that the region of the active site and the environment of Cys72 and Cys338 are tightly coupled and that residues far away from the active site, through such coupling, can possess properties of active-site residues. Similar, although less dramatic changes are observed upon removal of the C-terminal tyrosine residue. In view of the results obtained in this paper, aldolase seems to be quite a flexible molecule, whose conformation is sensitive to the nature of a substrate bound to the enzyme and is able to transmit the information about a local perturbation over long distances within a molecule.