Sequence-Dependence of the Energetics of Opening of AT Basepairs in DNA

doi:10.1529/biophysj.104.045179

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Sequence-Dependence of the Energetics of Opening of AT Basepairs in DNA

Congju Chen and Irina M. Russu

Department of Chemistry and Molecular Biophysics Program, Wesleyan University, Middletown, Connecticut

Correspondence: Address reprint requests to Irina M. Russu, Tel.: 860-685-2428; Fax: 860-685-2211; Email: irussu{at}wesleyan.edu.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Proton exchange and nuclear magnetic resonance spectroscopyare being used to characterize the energetics of opening ofAT/TA basepairs in the DNA dodecamer 5'-d(GCTATAAAAGGG)-3'/5'-d(CCCTTTTATAGC)-3'.The dodecamer contains the TATA box of the adenovirus majorlate promoter. The equilibrium constants for opening of eachbasepair are measured from the dependence of the exchange ratesof imino protons on ammonia concentration. The enthalpy, entropy,and free energy changes in the opening reaction of each basepairare determined from the temperature dependence of the exchangerates. The results reveal that the opening enthalpy changesencompass a wide range of values, namely, from 17 to 29 kcal/mol.The largest values are observed for the AT basepairs in 7thand 8th positions. These values, and the exchange rates of thecorresponding imino protons, suggest that these two basepairsopen in a single concerted reaction. The enthalpy changes foropening of the central six basepairs are correlated to the openingentropy changes. This enthalpy-entropy compensation minimizesthe variations in the opening free energies among these centralbasepairs. Deviations from the enthalpy-entropy compensationpattern are observed for basepairs located close to the endsof the duplex structure, suggesting a different mode of openingfor these basepairs.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

The sequence of bases in DNA contains the chemical signaturenecessary for storing and expressing genetic information. Inturn, the base sequence induces specific structural, energetic,and dynamic features that enhance the identity of a DNA site.Proteins and other ligands sample these features and use themto select the site for their binding. The correlates betweenbase sequence and the flexibility of DNA have been the objectof investigations by a multitude of approaches, including structuralanalysis of DNA and DNA-protein complexes (Gorin et al., 1995;Olson et al., 1998), molecular dynamics simulations (Beveridgeand McConnell, 2000; Giudice and Lavery, 2002), and cyclizationkinetics (Kahn et al., 1994). This work addresses this questionby an investigation of the opening of DNA basepairs using protonexchange and nuclear magnetic resonance (NMR) spectroscopy.The opening of basepairs in DNA double helices is a prerequisitefor propagation and expression of genetic information. Moreover,DNA basepairs often open to allow their chemical modificationby enzymes, or to adjust to structural perturbations inducedby binding of proteins. The combined use of proton exchangeand NMR spectroscopy allows characterization of these processesat the level of individual basepairs (Gueron and Leroy, 1995;Russu, 2004).

The DNA molecule investigated is shown in Fig. 1. The sequenceof the central eight bases is the same as that of the TATA boxin the adenovirus major late promoter (Kim and Burley, 1994).The sequence contains a juxtaposition of two distinct tractsof adenines and thymines, namely, a (TATA) tract in the 5'-halfand a (AAAA) tract in the 3'-half. Thus, the dodecamer allowsexamination of opening of AT basepairs in various base-stepconfigurations, within the same DNA molecule.

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FIGURE 1 The DNA dodecamer investigated and the NMR resonances of its imino protons (N1-H in guanine and N3-H in thymine) in 0.1 M NaCl, with 2 mM EDTA and 2 mM triethanolamine, in 90%H₂O/10%D₂O at pH 8.3 and at 15°C.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

DNA samples
The two strands of the DNA dodecamer were synthesized separatelyon a DNA synthesizer (Applied Biosystems, Foster City, CA) usingsolid-support phosphoramidite chemistry. They were purifiedby reverse-phase HPLC on a PRP-1 column (Hamilton, Reno, NV)in 50 mM triethylamine acetate buffer at pH 7 (with a gradientof 5–30% acetonitrile in 44 min). The counterions werereplaced with Na⁺ ions by repeated centrifugation through CentriconYM-3 tubes (Amicon, Bedford, MA) using 0.5 M NaCl. This wasfollowed by repeated centrifugation in the solvent used in NMRexperiments, namely, 0.1 M NaCl with 2 mM EDTA at pH 8.0 (at25°C). The DNA duplex was annealed by equilibrating thetwo oligonucleotides in a water bath at 80°C for 30 min,followed by slow cooling down. The DNA concentration in thesample used for NMR was 1.5 mM (duplex). The sample also contained2 mM triethanolamine, which was used to determine the pH ofthe sample directly inside the NMR tube. This was done by measuringfirst the difference between the chemical shifts of the resonancesof the two methylene groups of triethanolamine as a functionof pH for a sample of 2 mM triethanolamine in 0.1 M NaCl with2 mM EDTA. The measurements were carried out at each temperatureof interest. These chemical shift versus pH calibration curveswere then used to measure the pH of the DNA sample in each NMRexperiment. For proton exchange measurements, increasing concentrationsof ammonia were obtained by adding to the DNA sample small aliquotsof stock ammonia solutions (0.5–5 M) in 0.1 M NaCl with2 mM EDTA at pH 8.0. The final concentration of ammonia in thesample was measured by ¹⁴N NMR using a Varian VXR-400 NMR spectrometeroperating at 9.4 T. The intensity of the ¹⁴N NMR resonance ofammonia was calibrated separately for a range of ammonia concentrationsfrom 0.175 to 3 M (the highest ammonia concentration used inthe NMR experiments). The concentration of the acceptor in iminoproton exchange (i.e., ammonia base) was calculated at eachtemperature from the total ammonia concentration (C₀) and thepH as:

(1)
where the pK value of ammoniaat each temperature was used (Weast, 1987).

NMR experiments
The NMR experiments were performed on a Varian INOVA 500 spectrometeroperating at 11.75 T. One-dimensional (1-D) NMR spectra wereobtained using the Jump-and-Return pulse sequence (Plateau andGueron, 1982). ¹H-¹H NOESY spectra were obtained at a mixingtime of 100 ms using the WATERGATE-NOESY pulse sequence (Lippenset al., 1995). The proton exchange rates were measured by transferof magnetization from water. The water proton resonance wasselectively inverted using a Gaussian 180° pulse (5.8–8.1ms). This was followed by a variable delay in which the transferof magnetization occurs from water protons to DNA imino protons.To prevent the effects of radiation damping upon the recoveryof water magnetization to equilibrium a weak gradient (0.21G/cm) was applied during this exchange delay. At the end ofthe exchange delay, a second Gaussian pulse (1.7–2.7 ms)was applied to bring the water magnetization back to the oZaxis. The observation was with the Jump-and-Return pulse sequence.Twenty-five values of the exchange delay in the range from 2to 900 ms were used in each experiment. The exchange rates werecalculated from the dependence of the intensity of the iminoproton resonance of interest on the exchange delay as we havedescribed (Mihailescu and Russu, 2001; Powell et al., 2001).

Imino proton exchange in DNA
The exchange of DNA imino protons with solvent protons occursvia a structural opening reaction that brings the imino protoninto an open state. In this state, the hydrogen bond holdingthe imino proton is transiently broken such that the protoncan be transferred to proton acceptors present in solution (Englanderand Kallenbach, 1984; Gueron et al., 1990). The exchange rateobserved experimentally depends upon the kinetic parametersof the opening reaction as (Englander and Kallenbach, 1984):

(2)
where k_op and k_cl are the opening and the closingrate, respectively, and k_ex,open is the rate of exchange fromthe open state. The rate of exchange from the open state isproportional to the concentration of proton acceptor B (namely,ammonia base in this work):

(3)
wherek_B is the rate constant for proton transfer in isolated nucleotides,and ${alpha}$ is a factor that accounts for differences in the rate ofproton transfer between isolated nucleotides and open DNA basepairs,e. g., restricted accessibility of the proton acceptor to theimino proton in the open base. Previous investigations haveshown that ${alpha}$ is generally close to unity (Gueron et al., 1990).The rate constants k_B for ammonia have been calculated previouslyand, for the temperatures studied in this work, they range from3.9 x 10⁸ to 4.2 x 10⁸ M^–1 s^–1 for thymine, andfrom 9.6 x 10⁸ to 1.1 x 10⁹ M^–1 s^–1 for guanine(Moe and Russu, 1992).

Two kinetic regimes can be distinguished depending on how therate of exchange from the open state compares with the rateof closing. The EX2 regime occurs when k_ex,open << k_cl.In this case, the observed rate of exchange is proportionalto the concentration of proton acceptor B:

(4)
whereK_op = k_op/k_cl is the equilibrium constant for opening of thebase that contains the imino proton. When k_ex,open >>k_cl (EX1 regime), the exchange occurs in each opening eventand

(5)

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

The resonances of imino protons (N1-H in guanine and N3-H inthymine) of the DNA dodecamer investigated are shown in Fig. 1.The assignments of the resonances to individual protons inthe structure were obtained by ¹H-¹H NOESY experiments, as illustratedin Fig. 2.

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FIGURE 2 Expanded region of the ¹H-¹H NOESY spectrum of the DNA dodecamer showing connectivities between imino protons. The experimental conditions are the same as in Figure 1.

To characterize the processes of base-pair opening in the DNAdodecamer we have measured the exchange rate of each imino protonas a function of the concentration of ammonia base. The resultsare illustrated in Figs. 3 and 4. For several imino protons,such as that in T₈ (Fig. 3), the dependence of the exchangerate on ammonia base concentration exhibits the hyperbolic formpredicted by Eqs. 2 and 3 and, at high ammonia concentrations,the exchange approaches the EX1 regime. For other imino protons,the EX1 regime of exchange could not be reached for two reasons.First, for several imino protons the exchange rates increaserapidly with ammonia concentration. An example is the iminoproton in T₃ (Fig. 3). Due to the high exchange rate, the resonanceof this proton is greatly broadened even at relatively low ammoniaconcentrations (e.g., 20 mM; Fig. 4), thus preventing exchangemeasurements in the EX1 regime. Second, several imino protonresonances shift slightly and overlap other resonances uponincreasing ammonia concentration. Examples of these resonancesare those from T₄ and T₆ in Fig. 4.

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FIGURE 3 Dependence of the exchange rate of imino protons in T₈ and T₃ on ammonia base concentration, [B], at 15°C. The exchange rates for T₈ were fitted to Eq. 2 (with k_ex,open expressed as in Eq. 3) and those for T₃ to Eq. 4. For most of the experimental points shown the errors are smaller than the symbols.

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FIGURE 4 Imino proton resonances of the DNA dodecamer at various ammonia concentrations at 15°C. The concentration of ammonia base for each spectrum is indicated on the left.

The exchange rate measurements were carried out at five temperaturesin the range from 10 to 30°C. An illustration of the dependenceof the exchange curves on temperature is shown in Fig. 5 A forthe imino proton in T₇.

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FIGURE 5 Illustration of the dependence of the exchange rates and opening equilibrium constants on temperature. (A) The exchange rate of T₇ imino proton as a function of ammonia base concentration at all temperatures investigated. The curves represent nonlinear least-squares fits to Eq. 2 (with k_ex,open expressed as in Eq. 3). (B) Temperature dependence of the equilibrium constant for opening of AT₇ basepair. The line represents a fit to Eq. 6.

The equilibrium constant for the opening reaction of each basepair,K_op, was obtained by fitting the exchange rate as a functionof ammonia base concentration to Eq. 2 (with k_ex,open expressedas in Eq. 3) or to Eq. 4. The rate constant k_B for transferof the imino proton from thymine or guanine to ammonia baseat each temperature was used (Moe and Russu, 1992

), and thefactor ${alpha}$ was assumed to be independent of temperature ( ${alpha}$ = 1).Representative K_op values are shown in Fig. 6 A. Only the centraleight basepairs of the dodecamer are included in the figure.For the other four basepairs, the exchange of imino protonsis very fast due to fraying at the ends of the structure, andthe K_op values could not be measured accurately.

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FIGURE 6 Opening equilibrium constants at 15°C (panel A) and opening enthalpy changes (panel B) for the central basepairs in the DNA dodecamer.

The energetic parameters of the opening reaction for each basepairwere obtained from the dependence of the equilibrium constanton temperature using the M-linear regression algorithm introducedby Krug and co-workers (Krug et al., 1976

). The experimentaldata were fitted to the following modified van't Hoff equation(Fig. 5 B):

(6)
where T_hm is the harmonicmean of the experimental temperatures (293 K), ${Delta}$ H_op and ${Delta}$ G_op arethe enthalpy and free energy changes in the opening reaction,and R is the universal gas constant. The use of this equationensures that the obtained values of the thermodynamic parameters ${Delta}$ H_op and ${Delta}$ G_op (T_hm) are free of statistical compensation effects(Krug et al., 1976). The values of the opening enthalpy changesfor the central eight basepairs in the dodecamer are summarizedin Fig. 6 B and are compared to the values of the free energychanges in Fig. 8.

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FIGURE 8 (A) Correlation between enthalpy and entropy changes for opening of the central basepairs in the DNA dodecamer. The slope of the fitted line corresponds to a compensation temperature T_c = (306 ± 4) K. (B) Correlation between opening free energy changes at T_hm (20°C) and opening enthalpy changes. The fitted line corresponds to the equation ${Delta}$ H_op= –(100 ± 34) + (18 ± 5) x ${Delta}$ G_op with a correlation coefficient of 0.87.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

The results obtained in this work reveal that the energeticparameters of the opening reaction vary among different AT/TAbasepairs in the dodecamer. For the opening equilibrium constantsthe largest value is observed for TA₃, e.g., K_op = (2.4 ±0.1) x 10^–5 at 15°C (Fig. 6 A). This large value explainsthe high exchange rates observed for the T₃ imino proton (Fig. 3).For the other basepairs in the TATA half of the dodecamerthe opening equilibrium constants are $~$ 5-fold smaller, e.g.,(4.4 ± 0.2) x 10^–6 for TA₅. A further decrease(two- to threefold) is observed for the remaining basepairs(AT₇ through GC₁₀).

Insight into the energetic origin of these differences is providedby the opening enthalpy changes measured for each basepair.As shown in Fig. 6 B, the ${Delta}$ H_op values vary by more than 10 kcal/molamong different AT/TA basepairs. For the basepairs in the centerof the TATA box, AT₄ and TA₅, the values are the lowest, i.e.,17 ± 2 and 17.5 ± 0.9 kcal/mol, respectively.The highest enthalpy changes for opening are observed for AT₇and AT₈, i.e., 29 ± 2 and 28 ± 1 kcal/mol, respectively.For comparison, the enthalpy changes for opening of AT/TA basepairsin various DNA duplexes, which have been reported to date, rangefrom 14 to 21 kcal/mol (Moe and Russu, 1992; Folta-Stogniewand Russu, 1994; Moe et al., 1995). These previous determinationsencompass a variety of sequence contexts for AT/TA basepairssuch as those in the duplexes d(CGCGAATTCGCG)₂, d(CGCAGATCTGCG)₂,d(CGCAAATTTGCG)₂, and d(CGCACATGTGCG)₂. Hence, compared to theseand previous results, the enthalpy changes for opening of AT₇and AT₈ basepairs are anomalously high.

An explanation for the increased ${Delta}$ H_op values of AT₇ and AT₈ issuggested by the observation that the exchange rate of the iminoproton in T₇ is the same as that of the proton in T₈. This observationis presented in Fig. 7 A which includes the exchange rates ofthe two protons measured in this work at all ammonia concentrationsand at all temperatures. It is clear that, under these wideranges of experimental conditions, the exchange rates of thetwo protons remain the same. This observation differs from thegeneral observation that, in double-helical DNA, the exchangeof imino protons in adjacent basepairs occurs at different rates(Leroy et al., 1988; Gueron et al., 1990; Moe and Russu, 1990;Folta-Stogniew and Russu, 1994; Moe et al., 1995). Differentexchange rates have been observed even when the 5'- and 3'-neighborsof each base are the same. This fact is illustrated in Fig.7 B by a comparison of the exchange rates of the imino protonsin T₄ and T₅. One notes that, although the 5'- and 3'-neighborsof T₄ are the same as those of T₅, the exchange rates of thetwo protons are different over the entire range of experimentalconditions investigated.

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FIGURE 7 Comparison of the exchange rates of imino protons in AT₇ and AT₈ (panel A), and in AT₄ and TA₅ (panel B), at all ammonia concentrations and all temperatures investigated. In panel A, the slope of the fitted line is 1.004 ± 0.005, and the correlation coefficient of the linear fit is 0.99. In panel B, the slope of the fitted line is 0.78 ± 0.01 and correlation coefficient of the linear fit is 0.99.

The current model for imino proton exchange in DNA duplexespostulates that basepairs open one at a time, independentlyof the opening of their neighbors (Gueron and Leroy, 1995

).This postulate has been made on the basis of the general observationthat imino protons in adjacent basepairs exchange with differentrates. The identity of the exchange rates observed here forAT₇ and AT₈ suggests that, in this case, the exchange occursin a single opening event, possibly by the concerted openingof the two basepairs. Such concerted opening should have a higherenthalpic cost, thus explaining the high enthalpy values observedfor AT₇ and AT₈. This suggestion is supported by recent moleculardynamics simulations in which energetic coupling between openingof neighboring basepairs has been observed (Giudice et al.,2003

). The molecular basis for this special behavior of AT₇and AT₈ basepairs is not clear. In the dodecamer investigatedthe two basepairs belong to a tract of four AT basepairs (henceforthlabeled A₄). Previous investigations have shown that the ratesof opening of AT basepairs in A_n and A_nT_m tracts are slow whenn or n + m $≥$ 4 (Leroy et al., 1988

; Moe and Russu, 1990

). However,different rates of exchange have been observed for imino protonsof neighboring AT basepairs within the tract, at ammonia concentrationscomparable to those investigated here. Moreover, the ${Delta}$ H_op valuesfor opening of basepairs within the tract are in the range observedfor other base sequence contexts in DNA. For example, in theDNA duplex d(CGCAAATTTGCG)₂, which contains a A₃T₃ tract, the ${Delta}$ H_op values for opening of the AT basepairs are all around 20kcal/mol (Moe et al., 1995

). These observations suggest thatthe unique exchange properties and opening enthalpy changesthat we observed for AT₇ and AT₈ in the dodecamer investigateddo not result from the participation of these basepairs in theA₄ tract. Instead, they probably represent a special dynamicfeature, which is induced in the tract by the juxtapositionof the TATA sequence next to it. The influence of the TATA sequenceon the A₄ tract has been observed in molecular dynamics simulationsof TATA-box DNA (Flatters et al., 1997

; Pastor et al., 1997

).The simulations show that the tract assumes a structure similarto that of canonical A-form. The first adenines in the tractexhibit an enhanced tendency toward C3'-endo sugar puckering,and the helix axis is strongly bent. Such conformational changesmay alter the opening pathways of basepairs in the tract, assuggested here for AT₇ and AT₈.

Another interesting aspect of our results is the relationshipbetween the equilibrium constants for base-pair opening andthe enthalpic costs in the opening reactions. The opening enthalpychanges vary among different basepairs by more than 10 kcal/mol(Fig. 6 B). In contrast, the equilibrium constants for opening(Fig. 6 A) are distributed within a much narrower range of values;their variations are <15-fold, corresponding to variationsin the free energy of opening of <1.5 kcal/mol (at 15°C).Such behavior is indicative of the presence of enthalpy-entropycompensation in these opening processes (Lumry and Rajender,1970).

Enthalpy-entropy compensation is generally expressed by thelinear relationship between entropy and enthalpy changes (Lumryand Rajender, 1970). We have calculated the entropy changesin the opening of each basepair as:

(7)
wherethe ${Delta}$ H_op and ${Delta}$ G_op(T_hm) values were obtained as described above(Eq. 6). The plot of the ${Delta}$ H_op values versus the obtained ${Delta}$ S_opvalues (Fig. 8 A) is linear with a slope corresponding to acompensation temperature T_c = (306 ± 4) K (Lumry andRajender, 1970). An alternative way to express enthalpy-entropycompensation is the relationship between ${Delta}$ H_op and ${Delta}$ G_op(T_hm) (Fig.8 B). As demonstrated by other groups, this kind of analysisis free of statistical effects and provides strong evidencefor the existence of chemical/structural compensation effects(Krug et al., 1976; Sharp, 2001). The linear correlation between ${Delta}$ H_op and ${Delta}$ G_op(T_hm) is observed for the majority of the basepairsin the dodecamer (Fig. 8 B). The two points that deviate fromthe predicted linear dependence correspond to basepairs TA₃and GC₁₀. Both basepairs are situated two positions away fromthe ends of the structure. In these locations, fraying at theends of the duplex may influence the exchange of the T₃ andG₁₀ imino protons. As shown by other laboratories, fraying affectsthe parameters of the opening reactions, e.g., the accessibilityfactor ${alpha}$ in Eq. 3 (Nonin et al., 1995). The results in Fig. 8 Bsupport these previous findings, and suggest that the pathwaysand/or the energetics of opening of the TA₃ and GC₁₀ basepairsdiffer from those of the central basepairs in the dodecamer.

Enthalpy-entropy compensation in nucleic acids has been previouslyobserved in the melting of double- and single-helical structures(Searle and Williams, 1993; Petruska and Goodman, 1995) andin the binding of drugs to DNA (Marky and Breslauer, 1987; Quet al., 2003). Our results show that the same compensation existsin the conformational fluctuations of each basepair that yieldthe open state responsible for imino proton exchange. The compensationcould reflect the involvement of water in the opening reactions(Marky and Kupke, 2000). Recent molecular dynamics simulations(Giudice et al., 2003) support participation of water in base-pairopening. The simulations show that the conformational rearrangementsof the DNA that occur in the opening reaction perturb the hydrationwater and several new water-binding sites form between the openbases. The observed enthalpy-entropy compensation could alsoresult from properties that are intrinsic to the structure andstructural stability of DNA double helices. For example, moleculardynamics simulations reveal that, upon opening of a basepair,the conformational freedom of the phosphate-sugar backbone increases(Giudice et al., 2003). The entropy changes associated withthis increase could be compensated by the endothermic cost ofremoving a base from its helical stack. A similar mechanismhas been proposed for the compensation observed in the meltingof DNA and RNA helices (Searle and Williams, 1993). Regardlessof its exact origins, the enthalpy-entropy compensation in base-pairopening has an important consequence for the structural integrityof the DNA molecule. As a result of the compensation, the variationsof the free energies of opening among different basepairs areminimized. This ensures that no basepair in the DNA double helix,regardless of its sequence context, acquires a very high thermodynamicpropensity for opening.

The DNA dodecamer investigated contains the TATA box of theadenovirus major late promoter (i.e., 5'-TATAAAAG-3'). The structureof this DNA in complex with TATA-box binding protein (TBP) fromArabidopsis thaliana has been solved at 1.9 Å resolutionby Burley and co-workers (Kim and Burley, 1994). The proteinconsists of two pseudosymmetrical domains of nearly identicalamino acid sequence and structure. In spite of the high similaritiesbetween the domains, the binding of the protein to DNA is directional,namely, the C-terminal domain binds to the 5'-half of the TATAbox and the N-terminal domain to the other half. Binding ofthe protein induces large conformational changes in DNA. Twokinks (45°) are introduced by insertion of pairs of phenylalanineresidues at the first TpA step and at the ApG step. Throughoutthe box, the DNA unwinds by a total of 105°. The reducedtwist is coupled with base-pair roll at each step yielding anoverall 80° bend of the helix axis. Due to these large protein-induceddeformations in the DNA, the TBP protein has been a paradigmfor the indirect read-out mechanism in protein-DNA recognition(Kim and Burley, 1994; Juo et al., 1996).

The TBP-induced deformations of the DNA are clearly much morecomplex than the base-pair opening reactions investigated here.Nevertheless, one expects the enthalpy changes for base-pairopening to be related to the enthalpic costs of those protein-inducedconformational changes that involve perturbations of inter-basehydrogen bonds and/or helical base-stacking interactions. Alongthese lines, our results show that the TATA box DNA has an intrinsicenergetic asymmetry: the enthalpy changes for opening basepairsin the TATA half of the box are much lower than those in theother half (Fig. 6 B). This asymmetry may contribute to thebinding directionality of TBP by making the C-terminal domainof the protein interact first with the TATA sequence (Kim andBurley, 1994).

In summary, the results presented in this work demonstrate thatthe opening reactions of AT/TA basepairs in TATA-box DNA stronglydepend on the location and the sequence context of each basepair.This dependence affects the enthalpy and entropy changes thatoccur in base-pair opening, while maintaining the opening freeenergy changes at fairly constant values. The location of theAT/TA basepair in the structure may also affect the nature ofthe molecular fluctuations that yield the open state. A completedescription of these sequence- and position-induced dependenciesawaits future investigations of AT/TA basepairs in other DNAmolecules, alone or in complexes with ligands. These investigationsare in progress in our laboratory.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

This work was supported by a grant from the National Institutesof Health (GM65159).

Submitted on April 29, 2004; accepted for publication June 28, 2004.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

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				A. Krueger, E. Protozanova, and M. D. Frank-Kamenetskii Sequence-Dependent Basepair Opening in DNA Double Helix Biophys. J., May 1, 2006; 90(9): 3091 - 3099. [Abstract] [Full Text] [PDF]