DNA-XPA interactions: a (31)P NMR and molecular modeling study of dCCAATAACC association with the minimal DNA-binding domain (M98-F219) of the nucleotide excision repair protein XPA.

Recent NMR-based, chemical shift mapping experiments with the minimal DNA-binding domain of XPA (XPA-MBD: M98-F219) suggest that a basic cleft located in the loop-rich subdomain plays a role in DNA-binding. Here, XPA-DNA interactions are further characterized by NMR spectroscopy from the vantage point of the DNA using a single-stranded DNA nonamer, dCCAATAACC (d9). Up to 2.5 molar equivalents of XPA-MBD was titrated into a solution of d9. A subset of (31)P resonances of d9 were observed to broaden and/or shift providing direct evidence that XPA-MBD binds d9 by a mechanism that perturbs the phosphodiester backbone of d9. The interior five residues of d9 broadened and/or shifted before (31)P resonances of phosphate groups at the termini, suggesting that when d9 is bound to XPA-MBD the internal residues assume a correlation time that is characteristic of the molecular weight of the complex while the residues at the termini undergo a fraying motion away from the surface of the protein on a timescale such that the line widths are more characteristic of the molecular weight of ssDNA. A molecular model of the XPA-MBD complex with d9 was calculated based on the (15)N (XPA-MBD) and (31)P (d9) chemical shift mapping studies and on the assumption that electrostatic interactions drive the complex formation. The model shows that a nine residue DNA oligomer fully covers the DNA-binding surface of XPA and that there may be an energetic advantage to binding DNA in the 3'-->5' direction rather than in the 5'-->3' direction (relative to XPA-MBD alpha-helix-3).

Solution-state structure of a DNA dodecamer duplex containing a Cis-syn thymine cyclobutane dimer, the major UV photoproduct of DNA.

The solution structures of a duplex DNA dodecamer containing a cis-syn cyclobutane thymine dimer d(GCACGAAT[cs]TAAG).d(CTTAATTCG TGC) and its native parent sequence were determined using NMR data collected at 750 MHz. The dodecamer sequence corresponds to the section of a site-specific cis-syn dimer containing 49-mer that was found to be the binding site for the dimer-specific T4 denV endonuclease V repair enzyme by chemical and enzymatic footprinting experiments. Structures of both sequences were derived from NOE restrained molecular dynamics/simulated annealing calculations using a fixed outer layer of water and an inner dynamic layer of water with sodium counterions. The resulting structures reveal a subtle distortion to the phosphodiester backbone in the dimer-containing sequence which includes a BII phosphate at the T9pA10 junction immediately 3' to the dimer. The BII phosphate, established experimentally by analysis of the 31P chemical shifts and interpretation of the 3JP-H3' values using an optimized Karplus relationship, enables the DNA helix to accommodate the dimer by destacking the base 3' to the dimer. Furthermore, the structures provide explanations for the unusually shifted T8-N3H imino, A16-H2 and T8-Me proton resonances and T9pA10 (31)P NMR resonance and are consistent with bending, unwinding, and thermodynamic data. The implications of the structural data for the mechanism by which cis-syn dimers are recognized by repair enzymes and bypassed by DNA polymerases are also discussed.

A comprehensive approach for accurate measurement of proton-proton coupling constants in the sugar ring of DNA.

Stereo-selectivedeuteration has been explored as an approach for improving the accuracy of NMR-derived, three-bond vicinal proton-proton coupling constants in the 12-base-pair DNA Dickerson sequence [d(CGCGAATTCGCG)(2)]. The coupling constants are useful for DNA structure determination in restrained molecular dynamics calculations. Specifically, the A5 and A6 residues were prepared with the H2" proton stereo-selectively replaced with a deuteron. Deuteration of the H2" leads to a 42-fold reduction in the transverse cross-relaxation rate of the H2' spin, effectively negating the contribution of transverse cross relaxation to the cross peak frequencies and phases. Calculated linewidth and polarization transfer functions indicated that the reduced dipolar interaction is also expected to result in a significant increase in intensity for all cross peaks involving the H1', H2', or H3' spin. The spectral complexity is also reduced by selective deuteration. Time-shared homonuclear decoupling of passive spins during acquisition was implemented, reducing the spin system, in some cases, to an effectively isolated two-spin system. This enables the use of a 90 degrees mixing pulse instead of the 35 degrees pulse commonly used in standard P.E.COSY experiments, leading to an additional 75% increase in signal intensity. Selective excitation pulses were used to reduce the number of increments required in the indirect dimension by as much as a factor of 4. The cumulative improvement in sensitivity is striking, approaching three orders of magnitude per unit time. Separate experiments, referred to as Stripe-COSY and Superstripe-COSY, were optimized for each coupling constant measured. Finally, J-doubling was used to obtain the most accurate peak separations. This comprehensive approach shows promise as an effective method for extracting highly accurate homonuclear vicinal coupling constants in DNA.

NMR evidence for base dynamics at all TpA steps in DNA.

NMR evidence is presented indicating that the exceptional conformational dynamics found at TpA steps in DNA is general to all immediate sequence contexts. One easily tractable NMR parameter that is sensitive to TpA base dynamics is the resonance linewidth of the TpA adenine H2 proton. This resonance experiences a temperature-dependent broadening due to conformational dynamics. Unusual dynamics at TpA steps were originally observed in the sequence context (T)pTpTpApAp(A). We have since shown that the evidence for TpA dynamics persists when either the thymine preceding the TpA step or the adenine following the TpA step is preserved [McAteer et al., Nucleic Acids Res. 23, 3962-3966 (1995)]. Here, in order establish whether or not exceptional TpA dynamics occurs in all DNA sequence contexts, we investigated a series of DNA sequences of the form GCNaTANbNbTANaGC, where N=A,T,C,G. In this family of sequences, all 16 possible immediate sequence context environments of the form NaTANb were examined using 10 DNA sequences. Our NMR results show that the TpA adenine H2 resonance contains a temperature dependent excess linewidth indicative of dynamics in all 16 sequence context environments. By studying a complete set of sequence contexts, it was possible to recognize trends relating resonance parameters and sequence environment. For example, the magnitude of the maximum linewidth is largely determined by the identity of the nucleotide following the TpA step and the magnitude of the linewidth maximum is moderately correlated (r=0.56) with the temperature of the linewidth maximum. The physical basis for these correlations is discussed.

The effects of sequence context on base dynamics at TpA steps in DNA studied by NMR.

Base dynamics, heretofore observed only at TpA steps in DNA, were investigated as a function of sequence context by NMR spectroscopy. The large amplitude conformational dynamics have been previously observed in TnAn segments where n > or = 2. In order to determine whether the dynamic characteristics occur in more general sequence contexts, we examined four self-complementary DNA sequences, [d(CTTTA-NATNTAAAG)2] (where N = A, C, T, G and N = complement of N). The anomalous broadening of the TpA adenine H2 resonance which is indicative of large amplitude base motion was observed in all nine unique four nucleotide contexts. Furthermore, all the adenine H2 resonances experienced a linewidth maximum as a function of temperature, which is a characteristic of the dynamic process. Interestingly, the temperature of the linewidth maximum varied with sequence indicating that the thermodynamics of TpA base dynamics are also sequence dependent. In one example, neither a T preceding nor an A trailing the TpA step was required for base dynamics. These results show that base dynamics, heretofore observed in only a few isolated sequences, occurs at all TpA steps which are either preceded or followed by a thymine or adenine, respectively, and may be characteristic of all TpA steps in DNA notwithstanding sequence context.

A multiphase 113Cd NMR investigation of metalloporphyrin reorientation in cadmium-substituted myoglobin.

113Cd NMR spectroscopy in both the solution and solid state has been used to investigate the role of the metal ion and the proximal histidine on metalloporphyrin reorientation in myoglobin. Heme disorder has been known to exist for many years but understanding its mechanism has proved difficult due to the short-lived nature of the minor porphyrin isomer in native myoglobin. Cadmium-substituted myoglobin can be generated in one form which contains different insertion isomers or in another form which contains predominantly only one of these species. This allows for direct investigation of heme disorder in metal-substituted myoglobin.