Structure and dynamics of a fluorescent DNA oligomer containing the EcoRI recognition sequence: fluorescence, molecular dynamics, and NMR studies

The self-complementary DNA decamer duplex d(CTGAATTCAG)2 and its modified counterpart d(CTGA[2AP]TTCAG)2, where the innermost adenine (6-aminopurine) has been replaced with the fluorescent analogue 2-aminopurine (2AP), have been studied by fluorescence and NMR spectroscopy and simulated by molecular dynamics. Both decamers are recognized and cleaved by the EcoRI restriction endonuclease. 2D NMR results show that both decamers have a standard B-type conformation below 20 degrees C, though a disturbance exists to the 5' side of the 2AP site which may originate from increased local mobility. The fluorescence and fluorescence anisotropy decays of both decamers, as well as the one containing 2AP in only one chain, were studied as a function of temperature. The data show that the 2AP base exists in a temperature-dependent distribution of states and shows rapid motions, suggesting interconversion among these states on a time scale of about 10(-10) s. The integrated fluorescence of the decamer with 2AP in both chains shows a large increase around the helix melting temperature whereas the decamer with one 2AP shows only a mild increase, showing that the mixed helix has a different structural transition as sensed by the 2AP base. The data suggest a model of conformational states which have distinct fluorescence decay times. The various states may differ in the degree of base stacking. Fluctuations in the degree of stacking of the A or 2AP base are supported by molecular dynamics simulations, which additionally show that the 2AP-T or A-T base pair hydrogen bonds remain intact during these large motions.     

Conformation and dynamics of abasic sites in DNA investigated by time-resolved fluorescence of 2-aminopurine

Abasic sites are highly mutagenic lesions in DNA that arise as intermediates in the excision repair of modified bases. These sites are generated by the action of damage-specific DNA glycosylases and are converted into downstream intermediates by the specific activity of apurinic/apyrimidinic endonucleases. Enzymes in both families have been observed in crystal structures to impose deformations on the abasic-site DNA, including DNA kinking and base flipping. On the basis of these apparent protein-induced deformations, we propose that altered conformation and dynamics of abasic sites may contribute to the specificity of these repair enzymes. Previously, measurements of the steady-state fluorescence of the adenine analogue 2-aminopurine (2AP) opposite an abasic site demonstrated that binding of divalent cations could induce a conformational change that increased the accessibility of 2AP to solute quenching [Stivers, J. T. (1998) Nucleic Acids Res. 26, 3837-44]. We have performed time-resolved fluorescence experiments to characterize the states involved in this conformational change. Interpretation of these studies is based on a recently developed model attributing the static and dynamic fluorescence quenching of 2AP in DNA to aromatic stacking and collisional interactions with neighboring bases, respectively (see the preceding paper in this issue). The time-resolved fluorescence results indicate that divalent cation binding shifts the equilibrium of the abasic site between two conformations: a "closed" state, characterized by short average fluorescence lifetime and complex decay kinetics, and an "open" state, characterized by monoexponential decay with lifetime approximately that of the free nucleoside. Because the lifetime and intensity decay kinetics of 2AP incorporated into DNA are sensitive primarily to collisional interactions with the neighboring bases, the absence of dynamic quenching in the open state strongly suggests that the fluorescent base is extrahelical in this conformation. Consistent with this interpretation, time-resolved quenching studies reveal that the open state is accessible to solute quenching by potassium iodide, but the closed state is not. Greater static quenching is observed in the abasic site when the fluorescent base is flanked by 5'- and 3'-thymines than in the context of 5'- and 3'-adenines, indicating that 2AP is more stacked with the neighboring bases in the former sequence. These results imply that the conformation of the abasic site varies in a sequence-dependent manner. Undamaged sequences in which the abasic site is replaced by thymine do not exhibit an open state and have different levels of both static and dynamic quenching than their damaged homologues. These differences in structure and dynamics may be significant determinants of the high specific affinity of repair enzymes for the abasic site.     

Ultrafast fluorescence decay profiles reveal differential unstacking of 2-aminopurine from neighboring bases in single-stranded DNA-binding protein subsites

Gene 5 protein (g5p) is a dimeric single-stranded DNA-binding protein encoded by Ff strains of Escherichia coli bacteriophages. The 2-fold rotationally symmetric binding sites of a g5p dimer each bind to four nucleotides, and the dimers bind with high cooperativity to saturate antiparallel single-stranded DNA (ssDNA) strands. Ultrafast time-resolved fluorescence spectroscopies were used to investigate the conformational heterogeneity and dynamics of fluorescent 2-aminopurine (2AP) labels sequestered by bound g5p. The 2AP labels were positioned within the noncomplementary antiparallel tail sequences of d(AC)(8) or d(AC)(9) of hairpin constructs so that each fluorescent label could probe a different subsite location within the DNA-binding site of g5p. Circular dichroism and isothermal calorimetric titrations yielded binding stoichiometries of approximately six dimers per oligomer hairpin when tails were of these lengths. Mobility shift assays demonstrated the formation of a single type of g5p-saturated complex. Femtosecond time-resolved fluorescence spectroscopy showed that the 2AP in the free (non-protein-bound) DNAs had similar heterogeneous distributions of conformations. However, there were significant changes, dominated by a large increase in the population of unstacked bases from ~22 to 59-68%, depending on their subsite locations, when the oligomers were saturated with g5p. Anisotropy data indicated that 2AP in the bound state was less flexible than in the free oligomer. A control oligomer was labeled with 2AP in the loop of the hairpin and showed no significant change in its base stacking upon g5p binding. A proposed model summarizes the data.     

2-Aminopurine fluorescence studies of base stacking interactions at abasic sites in DNA: metal-ion and base sequence effects.

Metal-ion and sequence dependent changes in the stacking interactions of bases surrounding abasic (AB) sites in 10 different DNA duplexes were examined by incorporating the fluorescent nucleotide probe 2-aminopurine (2-AP), opposite to the site (AB-APopp) or adjacent to the site (AB-APadj) on either strand. A detailed study of the fluorescence emission and excitation spectra of these AB duplexes and their corresponding parent duplexes indicates that AB-APoppis significantly less stacked than 2-AP in the corresponding normal duplex. In general, AB-APadjon the AB strand is stacked, but AB-APadjon the opposite strand shows destabilized stacking interactions. The results also indicate that divalent cation binding to the AB duplexes contributes to destabilizaton of the base stacking interactions of AB-APopp, but has little or no effect on the stacking interactions of AB-APadj. Consistent with these results, the fluorescence of AB-APoppis 18-30-fold more sensitive to an externally added quenching agent than the parent normal duplex. When uracil DNA glycosylase binds to AB-APoppin the presence of 2.5 mM MgCl2, a 3-fold decrease in fluorescence is observed ( K d = 400 +/- 90 nM) indicating that the unstacked 2-APoppbecomes more stacked upon binding. On the basis of these fluorescence studies a model for the local base stacking interactions at these AB sites is proposed.     

Thermodynamic characterization of deoxyribooligonucleotide duplexes containing bulges

Ultraviolet absorption techniques were used to study the thermodynamics of duplex formation for a DNA decamer, d(GCGAAAAGCG).d(CGCTTTTCGC), and a series of related duplexes, each of which contains a bulged base centered in the A.T tract. Thermodynamic parameters were obtained from nonlinear least-squares fits of the melting curves and the concentration dependences of the melting temperatures. Duplexes containing a localized single-base bulge were found to be 3.5-4.6 kcal/mol less stable than the decamer at 37 degrees C. These results indicate that both the identity of the bulged base and the strand in which it is located may influence the amount by which the duplex is destabilized. Bulged bases located in the T-strand, d(CGCTTYTTCGC), in position Y, were observed to be slightly more destabilizing than those located in the A-strand, d(GCGAAXAAGCG), in position X. Bulged purines may be more destabilizing than bulged pyrimidines.     

A molecular dynamics simulation of a polyamine-induced conformational change of DNA. A possible mechanism for the B to Z transition.

A 75ps molecular dynamics simulation has been performed on a fully solvated complex of spermine with the B DNA decamer (dGdC)5.(dGdC)5. The simulation indicates a possible mechanism by which polyamines might induce the formation of a left-handed helix, the B to Z transition. Spermine was initially located in the major groove, hydrogen bonded to the helix. During the simulation the ligand migrates deeper into the DNA, maintaining strong hydrogen bonding to the central guanine bases and destroying the Watson-Crick base pairing with their respective cytosines. Significant rotation of these and other cytosine bases was observed, in part due to interactions of the helix with the aminopropyl chains of spermine. An intermediate BII conformation might be of importance in this process.     

Stacking-unstacking dynamics of oligodeoxynucleotide trimers

The structure and dynamics of DNA trimers are experimentally assessed using the fluorescent purine analogue 2-aminopurine (2AP), incorporating 2AP between purine and pyrimidine bases to form 5'dXp2APpY3' molecules. Circular dichroism and fluorescence quenching of the 2AP show that the bases are stacked; at the same time, fluorescence decay lifetimes are heterogeneous, indicative of conformational sampling. 2AP does not exhibit the long fluorescence decay time characteristic of the free nucleoside, suggesting that its motions in the trimers bring it into proximity of the neighboring bases, resulting in efficient charge transfer and average fluorescence lifetimes on the order of 1-2 ns.     

The binding of fluorescent 4,6,8(14)-triene-3-one steroids to cyclodextrins as a model for steroid-protein interactions

The 4,6,8(14)-triene-3-one steroids, highly fluorescent in aqueous solutions, lose their fluorescence power when binding occurs to hydrophobic regions of other molecules, such as the hydrophobic cavity in the ring system of cyclodextrins. The fluorescence intensity decreases almost completely when beta- and gamma-cyclodextrins are present in the solution. Scatchard plots derived from fluorescence titrations show that one or two molecules of steroid bind to one cyclodextrin molecule with KD,F-values of about 10(-4)-10(-5) mol/liter. Temperature-jump experiments show a single relaxation process, with rate constants for the decay of the beta-cyclodextrin-steroid complexes of about 10(4)-10(5) per s. For alpha- and gamma-cyclodextrins such relaxation processes are not observed.     

T.T pair intercalation and duplex interconversion within i-motif tetramers

The i-motif is a four-stranded structure built by intercalation in head-to-tail orientation of two parallel duplexes associated by hemi-protonated C.C(+) pairs. Using NMR methods, we investigated the structure, the base-pair opening kinetics and the internal motions of three i-motif tetramers: [d(5mCCTCnTCC)](4) (n=1, 2, 3). These tetramers cannot accommodate the intercalation of two T.T pairs in face-to-face orientation. They are built by intercalation of two symmetrical duplexes whose contacting T3/TM thymidine bases (M=5, 6, 7) are either base-paired or unstacked. The arrangement of the unstacked/paired thymidine bases of the two T/T groups results in the formation of two different conformations. One, fully symmetric, whose thymidine bases T3 and TM are unstacked and base-paired respectively. The other is the asymmetric assembly of two duplexes: one where both thymidine bases are unstacked and the other with two T.T pairs. The proportion of the symmetric conformer increases from a value beyond the detection threshold for n=1, to 19% for n=2 and up to more than 95% for n=3. The exchange cross-peaks connecting together the intercalated duplexes of [d(5mCCTCTCC)](4) and [d(5mCCTCCTCC)](4) reveal a structural interconversion induced by the simultaneous opening/closing of the contacting T3/TM thymidine bases. In [d(5mCCTCCTCC)](4) the motion of the T3/T6 groups triggers the interconversion of the symmetric and asymmetric conformations. In [d(5mCCTCTCC)](4) the intercalated duplexes exchange their structures in an apparently concerted motion, suggesting the simultaneous opening/closing of two distant T3/T5* and T5/T3* switching groups. The spectrum of [d(5mCCTCCCTCC)](4) is fully symmetric and, for this reason, its spectrum gives no indication for duplex interconversion. Nevertheless, the imino proton exchange kinetics argues for a switching motion of the T3/T7 group. Duplex interconversion is not detectable in that case, due to the tetramer symmetry. The origin of the structural conflict hindering the intercalation of two T.T pairs into the i-motif is discussed.     

Dynamics of mismatched base pairs in DNA

The structural dynamics of mismatched base pairs in duplex DNA have been studied by time-resolved fluorescence anisotropy decay measurements on a series of duplex oligodeoxynucleotides of the general type d[CGG(AP)GGC].d[GCCXCCG], where AP is the fluorescent adenine analogue 2-aminopurine and X = T, A, G, or C. The anisotropy decay is caused by internal rotations of AP within the duplex, which occur on the picosecond time scale, and by overall rotational diffusion of the duplex. The correlation time and angular range of internal rotation of AP vary among the series of AP.X mismatches, showing that the native DNA bases differ in their ability to influence the motion of AP. These differences are correlated with the strength of base-pairing interactions in the various AP.X mismatches. The interactions are strongest with X = T or C. The ability to discern differences in the strength of base-pairing interactions at a specific site in DNA by observing their effect on the dynamics of base motion is a novel aspect of the present study. The extent of AP stacking within the duplex is also determined in this study since it influences the excited-state quenching of AP. AP is thus shown to be extrahelical in the AP.G mismatch. The association state of the AP-containing oligodeoxynucleotide strand is determined from the temperature-dependent tumbling correlation time. An oligodeoxynucleotide triplex is formed with a particular base sequence in a pH-dependent manner.     

Sequence dependence of energy transfer in DNA oligonucleotides

The sequence, temperature, concentration, and solvent dependence of singlet energy transfer from normal DNA bases to the 2-aminopurine base in synthesized DNA oligomers were investigated by optical spectroscopy. Transfer was shown directly by a variable fluorescence excitation band at 260-280 nm. Adenine (A) is the most efficient energy donor by an order of magnitude. Stacks of A adjacent to 2AP act as an antenna for 2AP excitation. An interposed G, C, or T base between A and 2AP effectively blocks transfer from A to 2AP. Base stacking facilitates transfer, while base pairing reduces energy transfer slightly. The efficiency is differentially temperature dependent in single- and double-stranded oligomers and is highest below 0 degrees C in samples measured. An efficiency transition occurs well below the melting transition of a double-stranded decamer. The transfer efficiency in the duplex decamer d(CTGA[2AP]TTCAG)(2) is moderately dependent on the sample and salt concentration and is solvent dependent. Transfer at physiological temperature over more than a few bases is improbable, except along consecutive A's, indicating that singlet energy transfer is not a major factor in the localization of UV damage in DNA. These results have features in common with recently observed electron transfer from 2AP to G in oligonucleotides.     

Premelting thermal fluctuational base pair opening probability of poly(dA).poly(dT) as predicted by the modified self-consistent phonon theory.

We employ a mean field, modified, self-consistent phonon theory to evaluate the single base-pair opening rate and the probability of a base pair in the amino proton exchangeable state for the homopolymer poly(dA).poly(dT) at temperatures below the helix-coil transition region. Our calculated premelting single base-pair opening probabilities are in general agreement with several available experimental estimates from imino proton exchange and formaldehyde-induced DNA melting measurements. These calculated opening probabilities, however, are in disagreement with the prediction of the helix-coil transition theory. Possible reasons for the differences are discussed, especially the possible different definition of a meaningful open state in the premelting region. The premelting open state of the modified self-consistent phonon approximation theory seems to be appropriate to describe a solvent-accessible open configuration that is sufficient to facilitate important chemical reactions such as imino proton exchange and formaldehyde reaction with the bases. This can be compared with the completely unstacked open state of the helix-coil transition theory originally defined in the helix-coil transition region. We propose that the amino proton exchangeable state is different from the open state associated with melting and only involves the breaking of the amino interbase H bond. The agreement between the calculated and experimentally estimated probability of a base pair in the amino proton exchangeable state seems to support this hypothesis.     

A Molecular Dynamics Simulation of a Polyamine-Induced Conformational Change of DNA. A Possible Mechanism for the B to Z Transition

Abstract

A 75ps molecular dynamics simulation has been performed on a fully solvated complex of spermine with the B DNA decamer (dGdC)₅ · (dGdC)₅. The simulation indicates a possible mechanism by which polyamines might induce the formation of a left-handed helix, the B to Z transition. Spermine was initially located in the major groove, hydrogen bonded to the helix. During the simulation the ligand migrates deeper into the DNA, maintaining strong hydrogen bonding to the central guanine bases and destroying the Watson-Crick base pairing with their respective cytosines. Significant rotation of these and other cytosine bases was observed, in part due to interactions of the helix with the aminopropyl chains of spermine. An intermediate B_II conformation might be of importance in this process.     

Interaction of DNA with the Klenow fragment of DNA polymerase I studied by time-resolved fluorescence spectroscopy

The interaction of a fluorescent duplex DNA oligomer with the Klenow fragment of DNA polymerase I from Escherichia coli has been studied in solution by using time-resolved fluorescence spectroscopy. An aminonaphthalenesulfonate (dansyl) fluorescent probe was linked by a propyl chain to a C5-modified uridine base located at a specific site in the primer strand of the DNA oligomer. The fluorescent oligomer bound tightly to the Klenow fragment (KD = 7.9 nM), and the probe's position within the DNA-protein complex was varied by stepwise elongation of the primer strand upon addition of the appropriate deoxynucleoside triphosphates. The decay of the total fluorescence intensity and the polarization anisotropy were measured with a picosecond laser and a time-correlated single photon counting system. The fluorescence lifetimes, the correlation time for internal rotation, and the angular range of internal rotation varied according to the probe's position within the DNA-protein complex. These results showed that five or six bases of the primer strand upstream of the 3' terminus were in contact with the protein and that within this contact region there were differences in the degree of solvent accessibility and the closeness of contact. Further, a minor binding mode of the DNA-protein complex was identified, on the basis of heterogeneity of the probe environment observed when the probe was positioned seven bases upstream from the primer 3' terminus, which resulted in a distinctive "dip and rise" in the anisotropy decay. Experiments with an epoxy-terminated DNA oligomer and a site-directed mutant protein established that the labeled DNA was binding at the polymerase active site (major form) and at the spatially distinct 3'----5' exonuclease active site (minor form). The abundance of each of these distinct binding modes of the DNA-protein complex was estimated under solution conditions by analyzing the anisotropy decay of the dansyl probe. About 12% of the labeled DNA was bound at the 3'----5' exonuclease site. This method should be useful for investigating the editing mechanism of this important enzyme.     

Binding of EcoP15I DNA methyltransferase to DNA reveals a large structural distortion within the recognition sequence

EcoP15I DNA methyltransferase, a member of the type III restriction-modification system, binds to the sequence 5'-CAGCAG-3' transferring a methyl group from S-adenosyl-l-methionine to the second adenine base. We have investigated protein-DNA interactions in the methylase-DNA complex by three methods. Determination of equilibrium dissociation constants indicated that the enzyme had higher affinity for DNA containing mismatches at the target base within the recognition sequence. Potassium permanganate footprinting studies revealed that there was a hyper-reactive permanganate cleavage site coincident with adenine that is the target base for methylation. More importantly, to detect DNA conformational alterations within the enzyme-DNA complexes, we have used a fluorescence-based assay. When EcoP15I DNA methyltransferase bound to DNA containing 2-aminopurine substitutions within the cognate sequence, an eight to tenfold fluorescent enhancement resulting from enzymatic flipping of the target adenine base was observed. Furthermore, fluorescence spectroscopy analysis showed that the changes attributable to structural distortion were specific for only the bases within the recognition sequence. More importantly, we observed that both the adenine bases in the recognition site appear to be structurally distorted to the same extent. While the target adenine base is probably flipped out of the DNA duplex, our results also suggest that fluorescent enhancements could be derived from protein-DNA interactions other than base flipping. Taken together, our results support the proposed base flipping mechanism for adenine methyltransferases.     

Cy3-DNA stacking interactions strongly depend on the identity of the terminal basepair

We characterized the effect of the first basepair on the conformational dynamics of the fluorescent dye Cy3 attached to the 5′ end of double-stranded DNA using Gaussian-mixture adaptive umbrella sampling simulations. In the simulations, the sampling of all five dihedral angles along the linker was enhanced, so that both stacked and unstacked states were sampled. The affinity of Cy3 for a T·A basepair (with the dye attached to T) was found to be significantly less than for the other basepairs. This was verified experimentally by measuring the activation energies for cis-trans isomerization of the dye. The simulation and experimental results indicate the existence of partially unstacked conformations amenable to photoisomerization. The simulations also showed that stacking of Cy3 straightens the DNA while stabilizing the first basepair. Our findings indicate that fluorescence is modulated by Cy3-DNA interactions in a sequence-dependent manner.     

Cofactor-induced orientation of the DNA bases in single-stranded DNA complexed with RecA protein. A fluorescence anisotropy and time-decay study

The structure of the RecA-single-stranded DNA complex was investigated by studying the fluorescence emission of poly(deoxy-1,N6-ethenoadenylic acid (poly(d epsilon A)), a fluorescent derivative of poly(dA), under various viscosity conditions. The fluorescence intensity and average lifetime of poly(d epsilon A) are much smaller than those of nonpolymerized monoethenonucleotides (1,N6-ethenoadenosine 5'-triphosphate and 1,N6-ethenoadenine deoxyribose 5'-monophosphate) at low viscosity and reflect intramolecular base-base collisions in the polymer. They considerably increased upon RecA binding, both in the presence and absence of cofactor ATP or adenosine 5'-O-(3-thiotriphosphate). This increase, as well as the increase in fluorescence anisotropy upon RecA binding, was very similar to that which resulted from sucrose addition to free poly(d epsilon A). These observations point to a decrease in the mobility of DNA bases upon RecA binding. In the presence of cofactor, the fluorescence features became independent of viscosity. This strongly suggests the absence of base motion of significant amplitude on the time scale of the fluorescence lifetime (about 10 ns). In the absence of cofactor, however, these features remained sensitive to viscosity, implying residual local motions of the bases. Such cofactor-dependent rigid attachment of DNA bases to stiff phosphate backbone could facilitate the search for homology between two DNA molecules during recombination.     

Influence of base stacking and hydrogen bonding on the fluorescence of 2-aminopurine and pyrrolocytosine in nucleic acids

Fluorescent nucleobase analogues are used extensively to probe the structure and dynamics of nucleic acids. The fluorescence of the adenine analogue 2-aminopurine and the cytosine analogue pyrrolocytosine is significantly quenched when the bases are located in regions of double-stranded nucleic acids. To allow more detailed structural information to be obtained from fluorescence studies using these bases, we have studied the excited-state properties of the bases at the CIS and TDB3LYP level in hydrogen-bonded and base-stacked complexes. The results reveal that the first excited state (the fluorescent state) of a hydrogen-bonded complex containing 2-aminopurine and thymine is just the first excited state of 2-aminopurine alone. However, the same cannot be said for structures in which 2-aminopurine is base stacked with other nucleobases. Stacking causes the molecular orbitals involved in the fluorescence transition to spread over more than one base. The predicted rate for the fluorescence transition is reduced, thus reducing the fluorescence quantum yield. The decrease in radiative rate varies with the stacking arrangement (e.g., A- or B-form DNA) and with the identity of the nucleobase with which 2-aminopurine is stacked. Stacking 2-aminopurine between two guanine moieties is shown to significantly decrease the energy gap between the first and second excited states. We do not find reliable evidence for a low-energy charge-transfer state in any of the systems that were studied. In the case of pyrrolocytosine, base stacking was found to reduce the oscillator strength for the fluorescence transition, but very little spreading of molecular orbitals across more than one base was observed.     

Intrinsic fluorescence from DNA can be enhanced by metallic particles

High sensitivity detection of DNA is essential for genomics. The intrinsic fluorescence from DNA is very weak and almost all methods for detecting DNA rely on the use of extrinsic fluorescent probes. We show that the intrinsic emission from DNA can be enhanced many-fold by spatial proximity to silver island films. Silver islands are subwavelength size patches of metallic silver on an inert substrate. Time-resolved measurements show a decreased lifetime for the intrinsic DNA emission near the silver islands. These results of increased intensity and decreased lifetime indicate a metal-induced increase in the radiative rate decay of the DNA bases. The possibility of increased radiative decay rates for DNA bases and other fluorophores suggest a wide variety of DNA measurements and other biomedical assays based on metal-induced increases in the fluorescence quantum yield of weakly fluorescent substances.