Solution structure of the DNA decamer duplex containing a 3'-T x T basepair of the cis-syn cyclobutane pyrimidine dimer: implication for the mutagenic property of the cis-syn dimer

The effect of DNA backbone on the triplet mechanism of UV-induced thymine-thymine (6-4) dimer formation

Density functional theory calculations were carried out to investigate the formation mechanism of the thymine-thymine (6-4) dimer ((6-4)TT), which is one of the main DNA lesions induced by ultraviolet radiation and is closely related to skin cancers. The DNA backbone was found to have nonnegligible effects on the triplet reaction pathway, particularly the reaction steps involving substantial base rotations. The mechanism for the isomerization from (6-4)TT to its Dewar valence isomer (DewarTT) was also explored, confirming the necessity of absorbing a second photon. In addition, the solvation effects were examined and showed considerable influence on the potential energy surface. Graphical Abstract DFT calculations on the influence of DNA backbone on the mechanism of UV-induced thymine-thymine (6-4) dimer formation.

Both DNA global deformation and repair enzyme contacts mediate flipping of thymine dimer damage

The photo-induced cis-syn-cyclobutane pyrimidine (CPD) dimer is a frequent DNA lesion. In bacteria photolyases efficiently repair dimers employing a light-driven reaction after flipping out the CPD damage to the active site. How the repair enzyme identifies a damaged site and how the damage is flipped out without external energy is still unclear. Employing molecular dynamics free energy calculations, the CPD flipping process was systematically compared to flipping undamaged nucleotides in various DNA global states and bound to photolyase enzyme. The global DNA deformation alone (without protein) significantly reduces the flipping penalty and induces a partially looped out state of the damage but not undamaged nucleotides. Bound enzyme further lowers the penalty for CPD damage flipping with a lower free energy of the flipped nucleotides in the active site compared to intra-helical state (not for undamaged DNA). Both the reduced penalty and partial looping by global DNA deformation contribute to a significantly shorter mean first passage time for CPD flipping compared to regular nucleotides which increases the repair likelihood upon short time encounter between repair enzyme and DNA.

Influence of a cis,syn-cyclobutane pyrimidine dimer damage on DNA conformation studied by molecular dynamics simulations

The photo-induced formation of cis-syn-cyclobutane pyrimidine dimers (CPD) is a highly mutagenic and cancerogenic DNA lesion. In bacteria photolyases can efficiently reverse the dimer formation employing a light-driven reaction after looping out the CPD damaged bases into the enzyme active site. The exact mechanism how the repair enzyme identifies a damaged site within a large surplus of undamaged DNA is not fully understood. The CPD damage may alter the DNA structure and dynamics already in the absence of the repair enzyme which can facilitate the initial binding of a photolyase repair enzyme. To characterize the effect of a CPD damage, extensive comparative molecular dynamics (MD) simulations on duplex DNA with central regular or CPD damaged nucleotides were performed supplemented with simulations of the DNA-photolyase complex. Although no spontaneous flipping out transitions of the damaged bases were observed, the simulations showed significant differences in the conformational states of regular and CPD damage DNA. The isolated damaged DNA adopted transient conformations which resembled the global shape of the repair enzyme bound conformation more closely compared to regular B-DNA. In particular, these conformational changes were observed in most of helical and structural parameters where the protein bound DNA differs drastically from regular B-DNA. It is likely that the transient overlap of isolated DNA with the enzyme bound DNA conformation plays a decisive role for the specific and rapid initial recognition by the repair enzyme prior to the looping out process of the damaged DNA.

Molecular mechanisms of DNA damage recognition for mammalian nucleotide excision repair

For faithful DNA repair, it is crucial for cells to locate lesions precisely within the vast genome. In the mammalian global genomic nucleotide excision repair (NER) pathway, this difficult task is accomplished through multiple steps, in which the xeroderma pigmentosum group C (XPC) protein complex plays a central role. XPC senses the presence of oscillating 'normal' bases in the DNA duplex, and its binding properties contribute to the extremely broad substrate specificity of NER. Unlike XPC, which acts as a versatile sensor of DNA helical distortion, the UV-damaged DNA-binding protein (UV-DDB) is more specialized, recognizing UV-induced photolesions and facilitating recruitment of XPC. Recent single-molecule analyses and structural studies have advanced our understanding of how UV-DDB finds its targets, particularly in the context of chromatin. After XPC binds DNA, it is necessary to verify the presence of damage in order to avoid potentially deleterious incisions at damage-free sites. Accumulating evidence suggests that XPA and the helicase activity of transcription factor IIH (TFIIH) cooperate to verify abnormalities in DNA chemistry. This chapter reviews recent findings about the mechanisms underlying the efficiency, versatility, and accuracy of NER.

Surviving the sun: repair and bypass of DNA UV lesions

Structural studies of UV-induced lesions and their complexes with repair proteins reveal an intrinsic flexibility of DNA at lesion sites. Reduced DNA rigidity stems primarily from the loss of base stacking, which may manifest as bending, unwinding, base unstacking, or flipping out. The intrinsic flexibility at UV lesions allows efficient initial lesion recognition within a pool of millions to billions of normal DNA base pairs. To bypass the damaged site by translesion synthesis, the specialized DNA polymerase η acts like a molecular "splint" and reinforces B-form DNA by numerous protein-phosphate interactions. Photolyases and glycosylases that specifically repair UV lesions interact directly with UV lesions in bent DNA via surface complementation. UvrA and UvrB, which recognize a variety of lesions in the bacterial nucleotide excision repair pathway, appear to exploit hysteresis exhibited by DNA lesions and conduct an ATP-dependent stress test to distort and separate DNA strands. Similar stress tests are likely conducted in eukaryotic nucleotide excision repair.

Thermodynamics and kinetics for base pair opening in the DNA decamer duplexes containing cyclobutane pyrimidine dimer

The cyclobutane pyrimidine dimer (CPD) is one of the major classes of cytotoxic and carcinogenic DNA photoproducts induced by UV light. Hydrogen exchange rates of the imino protons were measured for various CPD-containing DNA duplexes to better understand the mechanism for CPD recognition by XPC-hHR23B. The results here revealed that double T.G mismatches in a CPD lesion significantly destabilized six consecutive base pairs compared to other DNA duplexes. This flexibility in a DNA duplex caused at the CPD lesions with double T.G mismatches might be the key factor for damage recognition by XPC-hHR23B.

Structures and energetics of base flipping of the thymine dimer depend on DNA sequence

The cis,syn-cyclobutane pyrimidine dimer (CPD) is a photoinduced DNA lesion leading to a significant distortion of the DNA structure. Its repair by DNA photolyase requires a flip of the damaged base into an extrahelical position. This base flip is expected to be sequence-dependent, but the structures and energetics as a function of the bases 3' and 5' to the CPD lesion are unknown. Eight-nanosecond MD simulations of four different hexadecamer duplexes with the CPD were performed for the flipped-in and flipped-out structures. Analysis of these results indicates clear sequence-dependent differences. Significant disruptions of the base pairs to the 3' side of the CPD are observed for the flipped-out structures with adjacent A-T pairs, whereas those with G-C pairs adjacent show no such distortions. The conformational spaces occupied by these two duplexes are significantly different. The structural differences correlate well with the free energy differences for base flipping calculated using the previously established 2D potential of mean force (PMF) method. The energy differences for base flipping in duplexes containing A, T, G, and C pairs adjacent to the CPD were found to be 6.25-6.5, 5.25-5.5, 7.25-7.5, and 6.5-6.75 kcal/mol, respectively. These energy differences of up to 2 kcal/mol should be large enough to be detected experimentally using sensitive probes.

Kinking the double helix by bending deformation

DNA bending and torsional deformations that often occur during its functioning inside the cell can cause local disruptions of the regular helical structure. The disruptions created by negative torsional stress have been studied in detail, but those caused by bending stress have only been analyzed theoretically. By probing the structure of very small DNA circles, we determined that bending stress disrupts the regular helical structure when the radius of DNA curvature is smaller than 3.5 nm. First, we developed an efficient method to obtain covalently closed DNA minicircles. To detect structural disruptions in the minicircles we treated them by single-strand-specific endonucleases. The data showed that the regular DNA structure is disrupted by bending deformation in the 64-65-bp minicircles, but not in the 85-86-bp minicircles. Our results suggest that strong DNA bending initiates kink formation while preserving base pairing.

Functional insights gained from structural analyses of DNA duplexes that contain UV-damaged photoproducts

Ultraviolet photolesions endow DNA with distinct structural and dynamic properties. Biophysical studies of photoproduct-containing DNA have shown that these lesions affect the mutagenic properties of DNA and damage recognition by DNA repair systems. Recently obtained high-resolution cocrystal structures of damaged DNA bound to either DNA polymerase or DNA repair enzymes have enriched our understanding of the mechanisms by which DNA lesions are bypassed or recognized by DNA metabolizing proteins. Here, we summarize the results of these structural studies and discuss their implications for DNA metabolism.

NMR structure of the DNA decamer duplex containing double T*G mismatches of cis-syn cyclobutane pyrimidine dimer: implications for DNA damage recognition by the XPC-hHR23B complex

The cis-syn cyclobutane pyrimidine dimer (CPD) is a cytotoxic, mutagenic and carcinogenic DNA photoproduct and is repaired by the nucleotide excision repair (NER) pathway in mammalian cells. The XPC-hHR23B complex as the initiator of global genomic NER binds to sites of certain kinds of DNA damage. Although CPDs are rarely recognized by the XPC-hHR23B complex, the presence of mismatched bases opposite a CPD significantly increased the binding affinity of the XPC-hHR23B complex to the CPD. In order to decipher the properties of the DNA structures that determine the binding affinity for XPC-hHR23B to DNA, we carried out structural analyses of the various types of CPDs by NMR spectroscopy. The DNA duplex which contains a single 3' T*G wobble pair in a CPD (CPD/GA duplex) induces little conformational distortion. However, severe distortion of the helical conformation occurs when a CPD contains double T*G wobble pairs (CPD/GG duplex) even though the T residues of the CPD form stable hydrogen bonds with the opposite G residues. The helical bending angle of the CPD/GG duplex was larger than those of the CPD/GA duplex and properly matched CPD/AA duplex. The fluctuation of the backbone conformation and significant changes in the widths of the major and minor grooves at the double T*G wobble paired site were also observed in the CPD/GG duplex. These structural features were also found in a duplex that contains the (6-4) adduct, which is efficiently recognized by the XPC-hHR23B complex. Thus, we suggest that the unique structural features of the DNA double helix (that is, helical bending, flexible backbone conformation, and significant changes of the major and/or minor grooves) might be important factors in determining the binding affinity of the XPC-hHR23B complex to DNA.

NMR study on the interaction between RPA and DNA decamer containing cis-syn cyclobutane pyrimidine dimer in the presence of XPA: implication for damage verification and strand-specific dual incision in nucleotide excision repair

In mammalian cells, nucleotide excision repair (NER) is the major pathway for the removal of bulky DNA adducts. Many of the key NER proteins are members of the XP family (XPA, XPB, etc.), which was named on the basis of its association with the disorder xerodoma pigmentosum. Human replication protein A (RPA), the ubiquitous single-stranded DNA-binding protein, is another of the essential proteins for NER. RPA stimulates the interaction of XPA with damaged DNA by forming an RPA-XPA complex on damaged DNA sites. Binding of RPA to the undamaged DNA strand is most important during NER, because XPA, which directs the excision nucleases XPG and XPF, must bind to the damaged strand. In this study, nuclear magnetic resonance (NMR) spectroscopy was used to assess the binding of the tandem high affinity DNA-binding domains, RPA-AB, and of the isolated domain RPA-A, to normal DNA and damaged DNA containing the cyclobutane pyrimidine dimer (CPD) lesion. Both RPA-A and RPA-AB were found to bind non- specifically to both strands of normal and CPD- containing DNA duplexes. There were no differences observed when binding to normal DNA duplex was examined in the presence of the minimal DNA-binding domain of XPA (XPA-MBD). However, there is a drastic difference for CPD-damaged DNA duplex as both RPA-A and RPA-AB bind specifically to the undamaged strand. The strand-specific binding of RPA and XPA to the damaged duplex DNA shows that RPA and XPA play crucial roles in damage verification and guiding cleavage of damaged DNA during NER.

H-NMR studies of duplex DNA decamer containing a uracil cyclobutane dimer: implications regarding the high UV mutagenecity of CC photolesions

To determine the origin of the UV-specific CC to TT tandem mutation at the CC site, we made a duplex DNA decamer containing a uracil cis-syn cyclobutane dimer (CBD) as the deaminated model of a cytosine dimer. Two-dimensional 1H-NMR spectroscopy studies were performed on this sequence where two adenines (Ade) were opposite to the uracil dimer. Two imino protons of the uracil dimer were found to retain Watson-Crick hydrogen bonding with the opposite Ade, although the 5'-U(NH) of the dimer site showed unusual upfield shift like that of the 5'-T(NH) of the TT dimer, which seemed to be associated with deshielding by the flanking base rather than with reduced hydrogen bonding. (McAteer et al. 1998, J. Mol. Biol. 282:1013-1032). Hydrogen bondings at the dimer site were also supported by detecting typical strong nuclear Overhauser effects (NOE) between two imino protons and the opposite Ade H2 or NH2. But sequential NOE interactions of base protons with sugar protons were absent at the two flanking nucleotides of the 5' side of the uracil dimer and at the intradimer site, contrasting with its thymine analog where sequential NOE was absent only at the A4-T5 step. In addition, NOE cross peak for U5(NH) <--> A4(H2) was detected, although the NOE interactions of U6(NH) with A7(H2) and A17(H2) were not observed in contrast to the thymine dimer duplex. This different local structural alteration may be affected by the induced right-hand twisted puckering mode of cis-syn cyclobutane ring of the uracil dimer in the B-DNA duplex, even though the isolated uracil dimer had left-hand twisted puckering rigidly. In parallel, these observations may be correlated with observed differences in mutagenic properties between cis-syn UU dimer and cis-syn TT dimer.