Recognition of a guanine-cytosine base pair by 8-oxoadenine.

Two oligodeoxyribonucleotides, d-CTTCTTTTTTATTTT, I(A), and d-ATTATTTTTTATTTT, II(A), where C is 5-methylcytosine and A is 8-oxoadenine, were prepared and their interactions with the duplex d-GAAGAAAAAAYAAAA/d-TTTTZTTTTTTCTTC, III.IV(Y.Z), were studied. Oligomers I(A) and II(A) each form triplexes with III.IV(G.C) at temperatures below 20 degrees C as shown by continuous variation experiments, melting experiments, and circular dichroism (CD) spectroscopy. The CD spectra of these triplexes are almost identical to those formed by I(C) and II(C), oligomers which contain cytosine in place of 8-oxoadenine. This suggests that the 8-oxoadenine-containing triplexes have conformations which are very similar to those of the cytosine-containing triplexes. The melting temperature (Tm) for dissociation of the third strand of triplex II.III.IV(A.G.C) is 22 degrees C at pH 7.0 and 8.0, whereas the Tm of the corresponding transition in triplex II.III.IV(C.G.C) decreases from 28 degrees C at pH 7.0 to 17 degrees C at pH 8.0. The pH dependence of the Tm in the latter triplex reflects the necessity of protonating the N-3 of cytosine in order for it to form two hydrogen bonds with G of the G.C base pair. It appears that the keto form of 8-oxoadenine can potentially form two hydrogen bonds with the N-7 and O-6 atoms of G of the G.C base pair, when the 8-oxoadenine is in the syn conformation and in contrast to cytosine does not require protonation of the base. Oligomer I(A) does not form triplexes with III.IV(Y.Z) when Y.Z is A.T or T.A.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of the minor groove pyrimidine nucleobase functional groups on the stability of duplex DNA: the impact of uncompensated minor groove amino groups

DNA sequences containing four types of analog nucleosides are described. All four are pyridine derivatives constructed as C-nucleosides so that they mimic the pyrimidine derivatives 2'-deoxyuridine, thymidine or 2'-deoxycytidine, but in all cases the analogs lack the corresponding O2-carbonyls that in duplex DNA are located in the minor groove. In place of the O2-carbonyl is a hydrogen atom, a polar fluorine atom, or a nonpolar methyl group. The described C-nucleosides have native-like bidentate Watson-Crick hydrogen-bonding faces and can form essentially normal W-C base pairs of varying stability with A or G. In each modified base pair, two inter-residue hydrogen bonds should be present. In spite of a common number of interstrand hydrogen bonds, the thermodynamic stabilities of the prepared duplexes, each containing two analog base pairs, vary dramatically. Most notably, base pairs containing uncompensated purine amino groups (those lacking a hydrogen-bonding partner) in the minor groove exhibit the most dramatic reductions in thermodynamic stability. Removal of such uncompensated amino groups results in increased duplex stability. Base pairs containing fluorine in the minor groove positioned adjacent to an amino group seem to enhance duplex stability marginally (relative to --H or --CH(3)), but there is little evidence to suggest that fluorine is an effective hydrogen-bonding partner in these systems. The presence of minor groove methyl groups results in the least stable duplexes in each series of sequences.     

Structural Features and Hydration of d(C-G-C-G-A-A-T-T-A-G-C-G); a Double Helix Containing Two G.A Mispairs

Abstract

Single crystal X-ray diffraction techniques have been used to characterise the molecular structure of the title compound to 2.5Å resolution. The structure consists of ten standard Watson-Crick base pairs and two G.A mismatched base pairs. The purine-purine mismatches have guanine in the usual anti orientation with respect to the sugar and adenine in syn orientation. There are two hydrogen bonds formed between the mismatch bases, N-l and 0–6 of guanine with N-7 and N-6 of adenine respectively. The bulky purine-purine mismatches are accommodated with minor perturbation of the sugar-phosphate backbone. There is a slight improvement in base pair overlap at the mismatch sites. Details of the backbone conformation, base stacking interactions and hydration are presented and compared with those of the parent compound d(C-G-C-G-A-A-T-T-C-G-C-G).     

Occurrence of bifurcated three-center hydrogen bonds in proteins

Analysis of 13 high-resolution protein X-ray crystal structures shows that 1204 (24%) of all the 4974 hydrogen bonds are of the bifurcated three-center type with the donor X-H opposing two acceptors A1, A2. They occur systematically in alpha-helices where 90% of the hydrogen bonds are of this type; the major component is (n + 4)N-H ... O = C(n) as expected for a 3.6(13) alpha-helix, and the minor component is (n + 4)N-H ... O = C(n + 1), as observed in 3(10) helices; distortions at the C-termini of alpha-helices are stabilized by three-center bonds. In beta-sheets 40% of the hydrogen bonds are three-centered. The frequent occurrence of three-center hydrogen bonds suggests that they should not be neglected in protein structural studies.     

Formation of purine-purine mispairs by Sulfolobus solfataricus DNA polymerase IV

DNA damage that stalls replicative polymerases can be bypassed with the Y-family polymerases. These polymerases have more open active sites that can accommodate modified nucleotides. The lack of protein-DNA interactions that select for Watson-Crick base pairs correlate with the lowered fidelity of replication. Interstrand hydrogen bonds appear to play a larger role in dNTP selectivity. The mechanism by which purine-purine mispairs are formed and extended was examined with Solfolobus solfataricus DNA polymerase IV, a member of the RAD30A subfamily of the Y-family polymerases, as is pol eta. The structures of the purine-purine mispairs were examined by comparing the kinetics of mispair formation with adenine versus 1-deaza- and 7-deazaadenine and guanine versus 7-deazaguanine at four positions in the DNA, the incoming dNTP, the template base, and both positions of the terminal base pair. The time course of insertion of a single dNTP was examined with a polymerase concentration of 50 nM and a DNA concentration of 25 nM with various concentrations of dNTP. The time courses were fitted to a first-order equation, and the first-order rate constants were plotted against the dNTP concentration to produce k pol and K d (dNTP) values. A decrease in k pol/ K d (dNTP) associated with the deazapurine substitution would indicate that the position is involved in a crucial hydrogen bond. During correct base pair formation, the adenine to 1-deazaadenine substitution in both the incoming dNTP and template base resulted in a >1000-fold decrease in k pol/ K d (dNTP), indicating that interstrand hydrogen bonds are important in correcting base pair formation. During formation of purine-purine mispairs, the k pol/ K d (dNTP) values for the insertion of dATP and dGTP opposite 7-deazaadenine and 7-deazaguanine were decreased >10-fold with respect to those of the unmodified nucleotides. In addition, the rate of incorporation of 1-deaza-dATP opposite guanine was decreased 5-fold. These results suggest that during mispair formation the newly forming base pair is in a Hoogsteen geometry with the incoming dNTP in the anti conformation and the template base in the syn conformation. These results indicate that Dpo4 holds the incoming dNTP in the normal anti conformation while allowing the template nucleotide to change conformations to allow reaction to occur. This result may be functionally relevant in the replication of damaged DNA in that the polymerase may allow the template to adopt multiple configurations.     

Structural features and hydration of d(C-G-C-G-A-A-T-T-A-G-C-G); a double helix containing two G.A mispairs

Single crystal X-ray diffraction techniques have been used to characterise the molecular structure of the title compound to 2.5A resolution. The structure consists of ten standard Watson-Crick base pairs and two G.A mismatched base pairs. The purine-purine mismatches have guanine in the usual anti orientation with respect to the sugar and adenine in syn orientation. There are two hydrogen bonds formed between the mismatch bases, N-1 and O-6 of guanine with N-7 and N-6 of adenine respectively. The bulky purine-purine mismatches are accommodated with minor perturbation of the sugar-phosphate backbone. There is a slight improvement in base pair overlap at the mismatch sites. Details of the backbone conformation, base stacking interactions and hydration are presented and compared with those of the parent compound d(C-G-C-G-A-A-T-T-C-G-C-G).     

Molecular dynamics and mechanics calculations on a DNA duplex with A(+)-C,G-T and T-C mispairs

Despite major advances in characterizing purine(R)-purine(R), purine(R)-pyrimidine(Y) and pyrimidine(Y)-pyrimidine(Y) mismatches in DNA, there have not been any structural studies on a synthetic DNA duplex containing several different mispairs. Here, using NMR restrained molecular mechanics and dynamics simulations we have structurally characterized a 12 nucleotide long antiparallel DNA duplex with three different mispairs, namely A+-C, G-T and T-C. Our results show that the overall conformation of the antiparallel DNA duplex is B-DNA-like with slight structural distortions at or near the mispairs' sites. All these mispairs are properly stacked with their flanking base pairs. Each mispair is stabilized by two hydrogen bonds and the decreasing order of the hydrogen-bonding interactions is G-T>T-C>A+-C. G-T mispair has smaller configurational space while the structure is slightly bent at A+-C mispair's site. Overall, this study is the first ever structural characterization of a DNA duplex with three different mismatched base pairs and throws light upon the local conformations of the three mispairs present in the DNA duplex.     

Crystal structure of an RNA 16-mer duplex R(GCAGAGUUAAAUCUGC)2 with nonadjacent G(syn).A+(anti) mispairs

G.A mispairs are one of the most common noncanonical structural motifs of RNA. The 1.9 A resolution crystal structure of the RNA 16-mer r(GCAGAGUUAAAUCUGC)2 has been determined with two isolated or nonadjacent G.A mispairs. The molecule crystallizes with one duplex in the asymmetric unit in space group R3 and unit cell dimensions a = b = c = 49.24 A and alpha = beta = gamma = 51.2 degrees. It is the longest known oligonucleotide duplex at this resolution and isomorphous to the 16-mer duplex with the C.A+ mispairs [Pan, et al., (1998) J. Mol. Biol. 283, 977-984]. The C.A+ mispair behaves like a wobble pair while the G.A+ does not. The G.A mispairs are protonated at N1 of the adenines as in the C.A+ mispairs, and two hydrogen bonds in the G(syn).A+(anti) conformation are formed. The syn guanine is stabilized by an intranucleotide hydrogen bond between the 2-amino and the 5'-phosphate groups. The G(syn).A+(anti) conformation can provide a different surface for recognition in the grooves compared to other G.A hydrogen bonding schemes. The major groove is widened between the two mispairs allowing access to ligands. One of the 3-fold axes is occupied by a sodium ion and a water molecule, while a second is occupied by another water molecule.     

Structural features and hydration of a dodecamer duplex containing two C.A mispairs.

X-ray diffraction techniques have been used to characterise the crystal and molecular structure of the deoxyoligomer d(C-G-C-A-A-A-T-T-C-G-C-G) at 2.5A resolution. The final R factor is 0.19 with the location of 78 solvent molecules. The oligomer crystallises in a B-DNA type conformation with two strands coiled about each other to produce a duplex. This double helix consists of four A.T and six G.C Watson-Crick base pairs and two C.A mispairs. The mismatched base pairs adopt a "wobble" type structure with the cytosine displaced laterally into the major groove, the adenine into the minor groove. We have proposed that the two close contacts observed in the C.A pairing represent two hydrogen bonds one of which results from protonation of adenine. The mispairs are accommodated in the double helix with small adjustments in the conformation of the sugar-phosphate backbone. Details of the backbone conformation, base stacking interactions, thermal parameters and the hydration are now presented and compared with those of the native oligomer d(C-G-C-G-A-A-T-T-C-G-C-G) and with variations of this sequence containing G.T and G.A mispairs.     

Structure of purine-purine mispairs during misincorporation and extension by Escherichia coli DNA polymerase I

The mechanism by which purine-purine mispairs are formed and extended was examined with the high-fidelity Klenow fragment of Escherichia coli DNA polymerase I with the proofreading exonuclease activity inactivated. The structures of the purine-purine mispairs were examined by comparing the kinetics of mispair formation with adenine versus 7-deazaadenine and guanine versus 7-deazaguanine at four positions in the DNA, the incoming dNTP, the template base, and both positions of the terminal base pair. A decrease in rate associated with a 7-deazapurine substitution would suggest that the nucleotide is in a syn conformation in a Hoogsteen base pair with the opposite base. During mispair formation, the k(pol)/K(d) values for the insertion of dATP opposite A (dATP/A) as well as dATP/G and dGTP/G were decreased greater than 10-fold with the deazapurine in the dNTP. These results suggest that during mispair formation the newly forming base pair is in a Hoogsteen geometry with the incoming dNTP in the syn conformation and the template base in the anti conformation. During mispair extension, the only decrease in k(pol)/K(d) was associated with the G/G base pair in which 7-deazaguanine was in the template strand. These results as well as previous results [McCain et al. (2005) Biochemistry 44, 5647-5659] in which a hydrogen bond was found between the 3-position of guanine at the primer terminus and Arg668 during G/A and G/G mispair extension indicate that the conformation of the purine at the primer terminus is in the anti conformation during mispair extension. These results suggest that purine-purine mispairs are formed via a Hoogsteen geometry in which the dNTP is in the syn conformation and the template is in the anti conformation. During extension, however, the conformation of the primer terminus changes to an anti configuration while the template base may be in either the syn or anti conformations.     

The conformational variability of an adenosine.inosine base-pair in a synthetic DNA dodecamer.

A crystal structure analysis of the synthetic deoxydodecamer d(CGCAAATTIGCG) which contains two adenosine.inosine (A.I) mispairs has revealed that, in this sequence, the A.I base-pairs adopt a A(anti).I(syn) configuration. The refinement converged at R = 0.158 for 2004 reflections with F greater than or equal to 2 sigma(F) in the range 7.0-2.5A for a model consisting of the DNA duplex and 71 water molecules. A notable feature of the structure is the presence of an almost complete spine of hydration spanning the minor groove of the whole of the (AAATTI)2 core region of the duplex. pH-dependent ultraviolet melting studies have suggested that the base-pair observed in the crystal structure is, in fact, a protonated AH+ (anti).I(syn) species and that the A.I base-pairs in the sequence studied display the same conformational variability as A.G mispairs in the sequence d(CGCAAATTGGCG). The AH+(anti).I(syn) base-pair predominates below pH 6.5 and an A(anti).I(anti) mispair is the major species present between pH 6.5 and 8.0. The protonated base-pairs are held together by two hydrogen bonds one between N6(A) and O6(I) and the other between N1(A) and N7(I). This second hydrogen bond is a direct result of the protonation of the N1 of adenosine. The ultraviolet melting studies indicate that the A(anti).I(anti) base-pair is more stable than the A(anti).G(anti) base-pair but that the AH+(anti).I(syn) base pair is less stable than its AH+(anti).G(syn) analogue. Possible reasons for this observation are discussed.     

Possible conformations of double-helical polynucleotides containing incorrect base pairs

Theoretical conformational analysis using classical potential functions has shown the possibility of incorporation of nucleotide mispairs with the bases in normal tautomeric forms into the DNA double helix. Incorrect purine-pyrimidine, purine-purine and pyrimidine-pyrimidine pairs can be incorporated into the double helix existing both in A- and B-conformations. The most energy favourable conformations of fragments containing a mispair have all the dihedral angles of the sugar-phosphate backbone within the limits characteristic of double helices consisting of Watson-Crick nucleotide pairs. Incorporation of mispairs is possible practically without the appearance of reduced interatomic contacts. Mutual position of bases in the incorporated mispair does not differ much from their position at the energy minimum of the corresponding isolated base pairs. Conformational parameters of irregular regions of double-stranded polynucleotides containing G:U, I:A, I:A* (syn) and U:C pairs are presented. Distortion of the sugar-phosphate backbone is the least upon incorporation of the G:U pair. Formation of mispairs in the processes of nucleic acid biosynthesis and spontaneous mutagenesis is discussed.     

Interactions between an anthracycline antibiotic and DNA: molecular structure of daunomycin complexed to d(CpGpTpApCpG) at 1.2-A resolution

The crystal structure of a daunomycin-d(CGTACG) complex has been solved by X-ray diffraction analysis and refined to a final R factor of 0.175 at 1.2-A resolution. The crystals are in a tetragonal crystal system with space group P4(1)2(1)2 and cell dimensions of a = b = 27.86 A and c = 52.72 A. The self-complementary DNA forms a six base pair right-handed double helix with two daunomycin molecules intercalated in the d(CpG) sequences at either end of the helix. Daunomycin in the complex has a conformation different from that of daunomycin alone. The daunomycin aglycon chromophore is oriented at right angles to the long dimension of the DNA base pairs, and the cyclohexene ring A rests in the minor groove of the double helix. Substituents on this ring have hydrogen-bonding interactions to the base pairs above and below the intercalation site. O9 hydroxyl group of the daunomycin forms two hydrogen bonds with N3 and N2 of an adjacent guanine base. Two bridging water molecules between the drug and DNA stabilize the complex in the minor groove. In the major groove, a hydrated sodium ion is coordinated to N7 of the terminal guanine and the O4 and O5 of daunomycin with a distorted octahedral geometry. The amino sugar lies in the minor groove without bonding to the DNA. The DNA double helix is distorted with an asymmetrical rearrangement of the backbone conformation surrounding the intercalator drug. The sugar puckers are C1,C2'-endo, G2,C1'-endo, C11,C1'-endo, and G12,C3'-exo. Only the C1 residue has a normal anti-glycosyl torsion angle (chi = -154 degrees), while the other three residues are all in the high anti range (average chi = -86 degrees). This structure allows us to identify three principal functional components of anthracycline antibiotics: the intercalator (rings B-D), the anchoring functions associated with ring A, and the amino sugar. The structure-function relationships of daunomycin binding to DNA as well as other related anticancer drugs are discussed.     

Structural and thermodynamic studies on the adenine.guanine mismatch in B-DNA.

The structure of the synthetic dodecamer d(CGCAAATTGGCG) has been shown by single crystal X-ray diffraction methods to be that of a B-DNA helix containing two A(anti).G(syn) base pairs. The refinement, based on data to a resolution of 2.25 A shows that the mismatch base pairs are held together by two hydrogen bonds. The syn-conformation of the guanine base of the mismatch is stabilised by hydrogen bonding to a network of solvent molecules in both the major and minor grooves. A pH-dependent ultraviolet melting study indicates that the duplex is stabilised by protonation, suggesting that the bases of the A.G mispair are present in their most common tautomeric forms and that the N(1)-atom of adenine is protonated. The structure refinement shows that there is some disorder in the sugar-phosphate backbone.     

MSH2 and MSH6 are required for removal of adenine misincorporated opposite 8-oxo-guanine in S. cerevisiae.

Oxidation of G in DNA yields 8-oxo-G (GO), a mutagenic lesion that leads to misincorporation of A opposite GO. In E. coli, GO in GO:C base pairs is removed by MutM, and A in GO:A mispairs is removed by MutY. In S. cerevisiae, mutations in MSH2 or MSH6 caused a synergistic increase in mutation rate in combination with mutations in OGG1, which encodes a MutM homolog, resulting in a 140- to 218-fold increase in the G:C-to-T:A transversion rate. Consistent with this, MSH2-MSH6 complex bound to GO:A mispairs and GO:C base pairs with high affinity and specificity. These data indicate that in S. cerevisiae, MSH2-MSH6-dependent mismatch repair is the major mechanism by which misincorporation of A opposite GO is corrected.     

Fidelity of mispair formation and mispair extension is dependent on the interaction between the minor groove of the primer terminus and Arg668 of DNA polymerase I of Escherichia coli

The hydrogen bonding interactions between the Klenow fragment of Escherichia coli DNA polymerase I with the proofreading exonuclease inactivated (KF(-)) and the minor groove of DNA were examined with modified oligodeoxynucleotides in which 3-deazaguanine (3DG) replaced guanine. This substitution would prevent a hydrogen bond from forming between the polymerase and that one site on the DNA. If the hydrogen bonding interaction were important, then we should observe a decrease in the rate of reaction. The steady-state and pre-steady-state kinetics of DNA replication were measured with 10 different oligodeoxynucleotide duplexes in which 3DG was placed at different positions. The largest decrease in the rate of replication was observed when 3DG replaced guanine at the 3'-terminus of the primer. The effect of this substitution on mispair extension and formation was then probed. The G to 3DG substitution at the primer terminus decreased the k(pol) for the extension past G/C, G/A, and G/G base pairs but not the G/T base pair. The G to 3DG substitution at the primer terminus also decreased the formation of correct base pairs as well as incorrect base pairs. However, in all but two mispairs, the effect on correct base pairs was much greater than that of mispairs. These results indicate that the hydrogen bond between Arg668 and the minor groove of the primer terminus is important in the fidelity of both formation and extension of mispairs. These experiments support a mechanism in which Arg668 forms a hydrogen bonding fork between the minor groove of the primer terminus and the ring oxygen of the deoxyribose moiety of the incoming dNTP to align the 3'-hydroxyl group with the alpha-phosphate of the dNTP. This is one mechanism by which the polymerase can use the geometry of the base pairs to modulate the rate of formation and extension of mispairs.     

The crystal structure of the octamer [r(guauaca)dC]2 with six Watson-Crick base-pairs and two 3' overhang residues

The crystal structure of an alternating RNA octamer, r(guauaca)dC (RNA bases are in lower case while the only DNA base is in upper case), with two 3' overhang residues one of them a terminal deoxycytosine and the other a ribose adenine, has been determined at 2.2 A resolution. The refined structure has an Rwork 18.6% and Rfree 26.8%. There are two independent duplexes (molecules I and II) in the asymmetric unit cell, a = 24.95, b = 45.25 and c = 73.67 A, with space group P2(1)2(1)2(1). Instead of forming a blunt end duplex with two a+.c mispairs and six Watson-Crick base-pairs, the strands in the duplex slide towards the 3' direction forming a two-base overhang (radC) and a six Watson-Crick base-paired duplex. The duplexes are bent (molecule I, 20 degrees; molecule II, 25 degrees) and stack head-to-head to form a right-handed superhelix. The overhang residues are looped out and the penultimate adenines of the two residues at the top end (A15) are anti and at the bottom (A7) end are syn. The syn adenine bases form minor groove A*(G.C) base triples with C8-H...N2 hydrogen bonds. The anti adenine in molecule II also forms a triple and a different C2-H...N3 hydrogen bond, while the other anti adenine in molecule I does not, it stacks on the looped out overhang base dC. The 3' terminal deoxycytosines form two stacked hemiprotonated trans d(C.C)+ base-pairs and the pseudo dyad related molecules form four consecutive deoxyribose and ribose zipper hydrogen bonds in the minor groove.     

The structure of guanosine-thymidine mismatches in B-DNA at 2.5-A resolution

The structure of the deoxyoligomer d(C-G-C-G-A-A-T-T-T-G-C-G) was determined at 2.5-A resolution by single crystal x-ray diffraction techniques. The final R factor is 18% with the location of 71 water molecules. The oligomer crystallizes in a B-DNA-type conformation, with two strands interacting to form a dodecamer duplex. The double helix consists of four A X T and six G X C Watson-Crick base pairs and two G X T mismatches. The G X T pairs adopt a "wobble" structure with the thymine projecting into the major groove and the guanine into the minor groove. The mispairs are accommodated in the normal double helix by small adjustments in the conformation of the sugar phosphate backbone. A comparison with the isomorphous parent compound containing only Watson-Crick base pairs shows that any changes in the structure induced by the presence of G X T mispairs are highly localized. The global conformation of the duplex is conserved. The G X T mismatch has already been studied by x-ray techniques in A and Z helices where similar results were found. The geometry of the mispair is essentially identical in all structures so far examined, irrespective of the DNA conformation. The hydration is also similar with solvent molecules bridging the functional groups of the bases via hydrogen bonds. Hydration may be an important factor in stabilizing G X T mismatches. A characteristic of Watson-Crick paired A X T and G X C bases is the pseudo 2-fold symmetry axis in the plane of the base pairs. The G X T wobble base pair is pronouncedly asymmetric. This asymmetry, coupled with the disposition of functional groups in the major and minor grooves, provides a number of features which may contribute to the recognition of the mismatch by repair enzymes.     

Structure, stability, and thermodynamics of a short intermolecular purine-purine-pyrimidine triple helix

We have investigated the structure and physical chemistry of the d(C3T4C3).2[d(G3A4G3)] triple helix by polyacrylamide gel electrophoresis (PAGE), 1H NMR, and ultraviolet (UV) absorption spectroscopy. The triplex was stabilized with MgCl2 at neutral pH. PAGE studies verify the stoichiometry of the strands comprising the triplex and indicate that the orientation of the third strand in purine-purine-pyrimidine (pur-pur-pyr) triplexes is antiparallel with respect to the purine strand of the underlying duplex. Imino proton NMR spectra provide evidence for the existence of new purine-purine (pur.pur) hydrogen bonds, in addition to those of the Watson-Crick (W-C) base pairs, in the triplex structure. These new hydrogen bonds are likely to correspond to the interaction between third-strand guanine NH1 imino protons and the N7 atoms of guanine residues on the purine strand of the underlying duplex. Thermal denaturation of the triplex proceeds to single strands in one step, under the conditions used in this study. Binding of the third strand appears to enhance the thermal stability of the duplex by 1-3 degrees C, depending on the DNA concentration. The free energy of triplex formation (-26.0 +/- 0.5 kcal/mol) is approximately twice that of duplex formation (-12.6 +/- 0.7 kcal/mol), suggesting that the overall stability of the pur.pur base pairs is similar to that of the W-C base pairs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Refined crystal structure of an octanucleotide duplex with I.T. mismatched base pairs.

The structure of the synthetic deoxyoctamer d(GGIGCTCC) has been determined by single crystal X-ray diffraction techniques to a resolution of 1.7A. The sequence crystallises in space group P6(1), with unit cell dimensions a = b = 45.07, c = 45.49A. The refinement converged with a crystallographic residual R = 0.14 and the location of 81 solvent molecules. The octamer forms an A-DNA duplex with 6 Watson-Crick (G.C) base pairs and 2 inosine-thymine (I.T) pairs. Refinement of the structure shows it to be essentially isomorphous with that reported for d(GGGGCTCC) with the mispairs adopting a "wobble" conformation. Conformational parameters and base stacking interactions are compared to those for the native duplex d(GGGGCCCC) and other similar sequences. A rationale for the apparent increased crystal packing efficiency and lattice stability of the I.T octamer is given.