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ABSTRACT: The fluorescent adenosine analogue 4-amino-8-(2-deoxy-beta-d-ribofuranosyl)-5'-O-dimethoxytrityl-6-methyl-7(8H)-pteridone (6MAP) has been used to perform residue specific analyses of DNA A-tracts during the premelting transition. DNA A-tracts, which exhibit sequence-induced curvature, adopt a B-DNA conformation as a function of increasing temperature. Fluorescence melting curves indicate that 6MAP is a more sensitive reporter of the premelting transition than UV absorption spectroscopy. Further, residue specific fluorescence analyses of A-tract and control duplexes reveal that some of the conformational changes associated with the premelting transition occur within A-tract regions. Analyses of the energetics of the premelting transition indicate that ApA steps make a larger enthalpic contribution to the premelting transition than ApT steps. To explore the effect of cations on the premelting transition, fluorescence melts were performed in the presence of NH(4)(+), Mg(2+), and low (0.05 M) and high (0.5 M) concentrations of Na(+). These studies show that the fluorescence intensity changes associated with the premelting transition are sensitive to cation type and concentration and are larger and more pronounced in the presence of 0.5 M Na(+), NH(4)(+), and Mg(2+). Incorporation of 6MAP into longer duplexes containing phased A-tracts shows that the local environment of adenosines in phased A-tracts is similar to that of individual A-tracts. Fluorescence quenching results indicate that ApA and ApT steps within A-tracts are less solvent exposed than their counterparts in control sequence isomers, possibly because of the narrowed minor groove of A-tract sequences.
Biochemistry 05/2006; 45(15):5039-47. · 3.42 Impact Factor
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ABSTRACT: The Escherichia coli protein HU functions as an architectural DNA-binding protein by facilitating DNA looping or bending to form multiprotein complexes. Although HU does not recognize a specific DNA sequence, site-specific binding to a number of discontinuous, looped, or bent DNA substrates has been observed. In this study UV resonance Raman (UVRR) spectroscopy is used to identify structural elements associated with low- and high-affinity binding by examining three different HU-DNA complexes. UVRR spectra obtained with an excitation wavelength of 210 nm, which preferentially enhances protein backbone amide vibrations, indicate that HU secondary structure content increases and the protein structure becomes more rigid upon binding to DNA. The increase in alpha-helical content is attributed to the C-terminal helix, which interacts with the DNA and may play a role in binding affinity and specificity. UVRR spectra obtained with a 215 nm excitation wavelength demonstrate that Pro mode intensity at 1455 cm(-1) decreases upon complex formation. This intensity decrease is attributed to the intercalation of Pro residues between DNA base pairs to induce a bend in the DNA, as has been observed previously in the IHF-DNA and HU-DNA cocrystal structures. DNA vibrational modes are also indicative of significant base unstacking and opening of the minor groove upon protein binding, consistent with bending and distortion of the DNA. In all three complexes, A-DNA conformational features are indicated by deoxyribose-phosphate backbone modes. These and other results suggest that protein-induced bending plays an important role in HU site-specific binding and supports a model of a mutually induced fit.
Protein Science 10/2004; 13(9):2416-28. · 2.80 Impact Factor
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ABSTRACT: The effects of HU, the histone-like protein from Escherichia coli, on the equilibrium cyclization of duplex DNAs have been observed as a function of protein concentration and DNA sequence. The results indicate that the presence of HU significantly enhances the extent of cyclization and increases the melting temperature, T(m), of the cyclized form of the DNA by >10 K. The stabilization of equilibrium cyclization by HU binding is at least -1.2 kcal/mol. The results are consistent with two HU homotypic dimers binding to each of the three 29-mer duplexes studied. One of the 29-mer duplexes contains a central dA tract, one contains mismatched sites, and one a conventional sequence. Stepwise or microscopic association constants, determined from the fluorescence data, range from 1.5 to 0.6 micro M(-1). The binding affinity of the HU dimer is strongest for the mismatched duplex and lowest for the dA tract, consistent with HU dimers having a preference for flexible DNA substrates. These results demonstrate the utility of the equilibrium cyclization approach to monitor DNA-protein interactions. These results have been considered along with those previously obtained to refine a model for the interaction of HU with duplex DNA.
Biophysical Journal 03/2004; 86(3):1625-31. · 3.65 Impact Factor
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ABSTRACT: HU, an architectural DNA-binding protein, either stabilizes DNA in a bent conformation or induces a bend upon binding to give other proteins access to the DNA. In this study, HU binding affinity for a bent DNA sequence relative to a linear sequence was investigated using fluorescence anisotropy measurements. A static bend was achieved by the introduction of two phased A4T4 tracts in a 20 bp duplex. Binding affinity for 20 bp duplexes containing two phased A-tracts in either a 5'-3' or 3'-5' orientation was found to be almost 10-fold higher than HU binding to a random sequence 20 bp duplex (6.1 vs 0.68 microM(-1)). The fluorescence technique of resonance energy transfer was used to quantitatively determine the static bend of the DNA duplexes and the HU-induced bend. DNA molecules were 5'-end labeled with fluorescein as the donor or rhodamine as the acceptor. From the efficiency of energy transfer, the end-to-end distance of the DNA duplexes was calculated. The end-to-end distance relative to DNA contour length (R/R(C)) yields a bend angle for the A-tract duplex of 45 +/- 7 degrees in the absence of HU and 70 +/- 3 degrees in the presence of HU. The bend angle calculated for the T4A4 tract duplex was 62 +/- 4 degrees after binding two HU dimers. Fluorescence anisotropy measurements reveal that HU binds in a 1:1 stoichiometry to the A4T4 tract duplex but a 2:1 stoichiometry to the T4A4 tract and random sequence duplex. These findings suggest that HU binding and recognition of DNA may be governed by a structural mechanism.
Biochemistry 04/2003; 42(10):3096-104. · 3.42 Impact Factor
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ABSTRACT: Abstract UV resonance Raman (UVRR) spectroscopy has been used to investigate the three purine bases, adenine, guanine and inosine, as a function of pH. Excitation wavelengths of 260 and 210 nm were used to probe the in-plane ring stretching frequencies and the exocyclic functional groups, respectively. These studies are suggestive that tautomeric forms can be stabilized at low and high pH values and these forms can be identified using UVRR spectroscopy. At pH values ≤5.0, a band at 1693 cm (-1) is observed in the UVRR spectra of dAMP, which is suggestive of the imino protonated tautomer. At pH values of 10.0 and above both dGMP and IMP show evidence for forming the enolate tautomer, by the loss in intensity of the C=O stretching mode at 1686 cm(-1). The protonated forms of dGMP and dAMP exhibit distinct Raman bands at approximately 1460 and 1561 cm(-1) and we suggest that these protonated states can be identified using UVRR spectroscopy. Most distinctively, the -NH(2) scissors mode of dGMP and dAMP shifts up in frequency and increases in intensity as the pH is decreased. Interestingly, these features are also observed in a comparison of an A-tract containing dodecamer with a non A-tract dodecamer. In particular, a frequency upshift of the -NH(2) scissors mode and a mode at 1466 cm(-1) is observed. Because of the resonance enhancement and the similarities to the protonated dAMP spectrum, these features are attributed to the dA residues in the A-tract. It is suggested that these spectral features may be characteristic of 'bent' DNA.
Journal of biomolecular structure & dynamics 01/2000; 17(sup1):327-334. · 4.99 Impact Factor
