Influence of benzo[a]pyrene diol epoxide chirality on solution conformations of DNA covalent adducts: the (-)-trans-anti-[BP]G.C adduct structure and comparison with the (+)-trans-anti-[BP]G.C enantiomer.

Benzo[a]pyrene (BP) is an environmental genotoxin, which, following metabolic activation to 7,8-diol 9,10-epoxide (BPDE) derivatives, forms covalent adducts with cellular DNA. A major fraction of adducts are derived from the binding of N2 of guanine to the C10 position of BPDE. The mutagenic and carcinogenic potentials of these adducts are strongly dependent on the chirality at the four asymmetric benzylic carbon atoms. We report below on the combined NMR-energy minimization refinement characterization of the solution conformation of (-)-trans-anti-[BP]G positioned opposite C and flanked by G.C base pairs in the d(C1-C2-A3-T4-C5-[BP]G6-C7-T8-A9-C10-C11).d(G12-G13-T14++ +-A15-G16-C17- G18-A19-T20-G21-G22) duplex. Two-dimensional NMR techniques were applied to assign the exchangeable and non-exchangeable protons of the benzo[a]pyrenyl moiety and the nucleic acid in the modified duplex. These results establish Watson-Crick base pair alignment at the [BP]G6.C17 modification site, as well as the flanking C5.G18 and C7.G16 pairs within a regular right-handed helix. The solution structure of the (-)-trans-anti-[BP]G.C 11-mer duplex has been determined by incorporating intramolecular and intermolecular proton-proton distances defined by lower and upper bounds deduced from NOE buildup curves as constraints in energy minimization computations. The BP ring spans both strands of the duplex in the minor groove and is directed toward the 3'-end of the modified strand in the refined structure. One face of the BP ring of [BP]G6 stacks over the C17 residue across from it on the partner strand while the other face is exposed to solvent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solution structure of the nogalamycin-DNA complex

The nogalamycin-d(A-G-C-A-T-G-C-T) complex (two drugs per duplex) has been generated in aqueous solution and its structure characterized by a combined application of two-dimensional NMR experiments and molecular dynamics calculations. Two equivalents of nogalamycin binds to the self-complementary octanucleotide duplex with retention of 2-fold symmetry in solution. We have assigned the proton resonances of nogalamycin and the d(A1-G2-C3-A4-T5-G6-C7-T8) duplex in the complex and identified the intermolecular proton-proton NOEs that define the alignment of the antitumor agent at its binding site on duplex DNA. The analysis was greatly aided by a large number of intermolecular NOEs involving exchangeable protons on both the nogalamycin and the DNA in the complex. The molecular dynamics calculations were guided by 274 intramolecular nucleic acid distance constraints, 90 intramolecular nogalamycin distance constraints, and 104 intermolecular distance constraints between nogalamycin and the nucleic acid protons in the complex. The aglycon chromophore intercalates at (C-A).(T-G) steps with the long axis of the aglycon approximately perpendicular to the long axis of the flanking C3.G6 and A4.T5 base pairs. The aglycon selectively stacks over T5 and G6 on the T5-G6-containing strand with the aglycon edge containing OH-4 and OH-6 substituents directed toward the C3-A4-containing strand. The C3.G6 and A4.T5 base pairs are intact but buckled at the intercalation site with a wedge-shaped alignment of C3 and A4 on the C3-A4 strand compared to the parallel alignment of T5 and G6 on the T5-G6 strand in the complex. The nogalose sugar in a chair conformation, the aglycon ring A in a half-chair conformation, and the COOCH3-10 side chain form a continuous domain that is sandwiched within the walls of the minor groove and spans the three base pair (G2-C3-A4).(T5-G6-C7) segment. The nogalose ring is positioned in the minor groove such that its nonpolar face is directed toward the G6-C7 sugar-phosphate backbone while its polar face containing OCH3 groups is directed toward the G2-C3 sugar-phosphate backbone in the complex. The intermolecular contacts include a nonpolar patch of aglycon (CH3-9) and nogalose (CH3-3') methyl groups forming van der Waals contacts with the base-sugar residues in the minor groove and intermolecular hydrogen bonds involving the amino groups of G2 and G6 with the ether oxygens OCH3-3' and O7, respectively, on the nogalose sugar.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chromomycin dimer-DNA oligomer complexes. Sequence selectivity and divalent cation specificity

This paper reports on a solution NMR characterization of the sequence selectivity and metal ion specificity in chromomycin-DNA oligomer complexes in the presence of divalent cations. The sequence selectivity studies have focused on chromomycin complexes with the self-complementary d(A1-A2-G3-G4-C5-C6-T7-T8) duplex containing a pair of adjacent (G3-G4).(C5-C6) steps and the self-complementary d(A1-G2-G3-A4-T5-C6-C7-T8) duplex containing a pair of separated (G2-G3).(C6-C7) steps in aqueous solution. The antitumor agent (chromomycin) and nucleic acid protons have been assigned following analysis of distance connectivities in NOESY spectra and coupling connectivities in DQF-COSY spectra for both complexes in H2O and D2O solution. The observed intermolecular NOEs establish that chromomycin binds as a Mg(II)-coordinated dimer [1 Mg(II) per complex] and contacts the minor-groove edge with retention of 2-fold symmetry centered about the (G3-G4-C5-C6).(G3-G4-C5-C6) segment of the d(A2G2C2T2) duplex. By contrast, complex formation is centered about the (G2-G3-A4-T5).(A4-T5-C6-C7) segment and results in removal of the two fold symmetry of the d(AG2ATC2T) duplex. Thus, the binding of one subunit of the chromomycin dimer at its preferred (G-G).(C-C) site assists in the binding of the second subunit to the less preferred adjacent (A-T).(A-T) site. These observations suggest a hierarchy of chromomycin binding sites, with a strong site detected at the (G-G) step due to the hydrogen-bonding potential of acceptor N3 and donor NH2 groups of guanosine that line the minor groove. The divalent cation specificity has been investigated by studies on the symmetric chromomycin-d(A2G2C2T2) complex in the presence of diamagnetic Mg(II), Zn(II), and Cd(II) cations and paramagnetic Ni(II) and Co(II) cations. A comparative NOESY study of the Mg(II) and Ni(II) symmetric complexes suggests that a single tightly bound divalent cation aligns the two chromomycins in the dimer through coordination to the C1 carbonyl and C9 enolate ions on the hydrophilic edge of each aglycon ring. Secondary divalent cation binding sites involve coordination to the major-groove N7 atoms on adjacent guanosines in G-G steps. This coordination is perturbed on lowering the pH below 6.0, presumably due to protonation of the N7 atoms. The midpoint of the thermal dissociation of the symmetric complex is dependent on the divalent cation with the stability for reversible transitions decreasing in the order Mg(II) greater than Zn(II) greater than Cd(II) complexes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification and assignment of base pairs in four helical segments of Bacillus megaterium ribosomal 5S RNA and its ribonuclease T1 cleavage fragments by means of 500-MHz proton homonuclear Overhauser enhancements.

Three different fragments of Bacillus megaterium ribosomal 5S RNA have been produced by enzymatic cleavage with ribonuclease T1. Fragment A consists of helices II and III, fragment B contains helix IV, and fragment C contains helix I of the universal 5S rRNA secondary structure. All (eight) imino proton resonances in the downfield region (9-15 ppm) of the 500-MHz proton FT NMR spectrum of fragment B have been identified and assigned as G80.C92-G81.C91-G82.C90-A83.++ +U89-C84.G88 and three unpaired U's (U85, U86, and U87) in helix IV by proton homonuclear Overhauser enhancement connectivities. The secondary structure in helix IV of the prokaryotic loop is completely demonstrated spectroscopically for the first time in any native or enzyme-cleaved 5S rRNA. In addition, G21.C58-A20.U59-G19.C60-A18.U61 in helix II, U32.A46-G31.C47-C30.G48-C29.G49 in helix III, and G4.C112-G5.C111-U6.G110 in the terminal stem (helix I) have been assigned by means of NOE experiments on intact 5S rRNA and its fragments A and C. Base pairs in helices I-IV of the universal secondary structure of B. megaterium 5S RNA are described.     

An approach to the structure determination of nucleic acid analogues hybridized to RNA. NMR studies of a duplex between 2'-OMe RNA and an oligonucleotide containing a single amide backbone modification.

The backbone modification amide-3, in which -CH2-NH-CO-CH2- replaces -C5'H2-O5'-PO2-O3'-, is studied in the duplex d(G1-C2-G3-T4.T5-G6-C7-G8)*mr(C9-G10-C11-A12-A13-C14-G15+ ++-C16) where . indicates the backbone modification and mr indicates the 2'-OMe RNA strand. The majority of the exchangeable and non-exchangeable resonances have been assigned. The assignment procedure differs from standard methods. The methyl substituent of the 2'-OMe position of the RNA strand can be used as a tool in the interpretation. The duplex structure is a right-handed double helix. The sugar conformations of the 2'-OMe RNA strand are predominantly N-type and the 2'-OMe is positioned at the surface of the minor groove. In the complementary strand, only the sugar of residue T4 is found exclusively in N-type conformation. The incorporation of the amide modification does not effect very strongly the duplex structure. All bases are involved in Watson-Crick base pairs.     

Spectroscopic studies on ethidium bromide binding to intramolecular parallel and antiparallel triple helices containing T*A:T and G*G:C triplets

The interaction of ethidium bromide (EB), a DNA intercalator, with two intramolecular triplexes 5'd(G4A4G4-[T4]-C4T4C4-[T4]-G4T4G4), 5'd(G4T4G4-[T4]-G4A4G4-[T4]-C4T4C4) ([T4] represents a stretch of 4 thymine residues) and their precursor duplexes has been investigated by circular dichroism, fluorescence and UV absorption spectroscopy. Binding of EB induces a circular dichroism band in the region around 310 nm which is positive for the duplex forms but negative for the triplex forms. We observed that the binding of EB to the duplex form does not induce the formation of the triplex structures. Thermal denaturation experiments demonstrate that EB stabilizes more the parallel triple helix than the antiparallel one. Analysis of the binding process from fluorescence measurements shows that binding constants to the triple helical forms and to the hairpin reference duplex [T4]-G4A4G4-[T4]-C4T4C4) are close. However the binding site size is larger for the triplexes (4-6 base triplets) than for the duplex (2 base pairs).     

Effect of strand orientation on the interaction of berenil with DNA triple helices

Using circular dichroism spectroscopy the ability of berenil, a minor groove binding drug, to induce triple helix formation was investigated with two oligonucleotides designed to form two intramolecular triplexes containing T*A:T and G*G:C triplets, which differ only by the orientation of their third strand: 5'-d(G4A4G4-[T4]-C4T4C4-[T4]-G4T4G4), and 5'-d(G4T4G4-[T4]-G4A4G4-[T4]-C4T4C4), where [T4] represents a stretch of four thymine residues. We demonstrate that when added to the duplex form of these oligonucleotides, berenil induces triplex structure formation only if the orientation of third strand is anti-parallel to the purine strand.     

Solution conformation of the (+)-trans-anti-benzo[g]chrysene-dA adduct opposite dT in a DNA duplex.

The solution structure of the adduct derived from the covalent bonding of the fjord region (+)-(11S, 12R, 13R, 14S) stereoisomer of anti -11,12-dihydroxy-13,14-epoxy-11,12,13, 14-tetrahydrobenzo[g]chrysene, (+)- anti -B[g]CDE, to the exocyclic N(6)amino group of the adenine residue dA6, (designated (+)- trans-anti -(B[g]C)dA6), positioned opposite a thymine residue dT17 in the DNA sequence context d(C1-T2-C3-T4-C5-(B[g]C)A6-C7-T8-T9-C10-C11). d(G12-G13-A14-A15-G16-T17-G18-A19-G20++ +-A21-G22) (designated (B[g]C)dA. dT 11-mer duplex), has been studied using structural information derived from NMR data in combination with molecular dynamics (MD) calculations. The solution structure of the (+)- trans-anti -(B[g]C)dA.dT 11-mer duplex has been determined using an MD protocol where both interproton distance and dihedral angle restraints deduced from NOESY and COSY spectra are used during the refinement process, followed by additional relaxation matrix refinement to the observed NOESY intensities to account for spin diffusion effects. The results established that the covalently attached benzo[g]chrysene ring intercalates into the DNA helix directed towards the 5'-side of the modified strand and stacks predominantly with dT17 when intercalated between dC5.dG18 and (B[g]C)dA6.dT17 base-pairs. All base-pairs, including the modified (B[g]C)dA6.dT17 base-pair, are aligned through Watson-Crick pairing as in normal B -DNA. In addition, the potential strain associated with the highly sterically hindered fjord region of the aromatic portion of the benzo[g]chrysenyl ring is relieved through the adoption of a non-planar, propeller-like geometry within the chrysenyl ring system. This conformation shares common structural features with the related (+)- trans-anti -(B[c]Ph)dA adduct in the identical base sequence context, derived from the fjord region (+)-(1S,2R,3R,4S)-3, 4-dihydroxy-1,2-epoxy-1,2,3,4-tetrahydrobenzo[c]phenanthrene stereoisomer, in which intercalation is also observed towards the 5'-side of the modified dA6.dT17 base-pair.     

NMR studies of an exocyclic 1,N2-propanodeoxyguanosine adduct (X) located opposite deoxyadenosine (A) in DNA duplexes at basic pH: simultaneous partial intercalation of X and A between stacked bases

The NMR parameters for the 1,N2-propanodeoxyguanosine (X) opposite deoxyadenosine positioned in the center of the complementary d(C1-A2-T3-G4-X5-G6-T7-A8-C9).d(G10-T11-A12-C13-A14-C15-A 16-T17-G18) X.A 9-mer duplex are pH dependent. A previous paper established protonated X5(syn).A14(anti) pairing in the X.A 9-mer duplex at pH 5.8 [Kouchakdjian, M., Marinelli, E., Gao, X., Johnson, F., Grollman, A., & Patel, D. J. (1989) Biochemistry 28, 5647-5657]; this paper focuses on the pairing alignment at the lesion site at pH 8.9. The observed NOEs between specific exocyclic CH2 protons and both the imino proton of G6 and the sugar H1' protons of C13 and A14 establish that X5 is positioned toward the G6.C13 base pair with the exocyclic ring directed between C13 and A14 on the partner strand. The observed NOE between the H2 proton of A14 and the imino proton of G4, but not G6, establishes that A14 at the lesion site is directed toward the G4.C15 base pair. NOEs are detected between all exocyclic CH2 protons of X5 and the H2 proton of A14, confirming that both X5 and A14 are directed toward the interior of the helix. The X5(anti).A14(anti) alignment at pH 8.9 is accommodated within the helix with retention of Watson-Crick pairing at flanking G4.C15 and G6.C13 base pairs. The energy-minimized conformation of the (G4-X5-G6).(C13-A14-C15) segment at pH 8.9 establishes that X5 and A14 are directed into the helix, partially stack on each other, and are not stabilized by intermolecular hydrogen bonds. The X5 base is partially intercalated between C13 and A14 on the unmodified strand, while A14 is partially intercalated between G4 and X5 on the modified strand. This results in a larger separation between the G4.C15 and G6.C13 base pairs flanking the lesion site in the basic pH conformation of the X.A 9-mer duplex. The midpoint of the transition between the protonated X5(syn).A14(anti) and X5(anti).A14(anti) conformations occurs at pH 7.6, establishing an unusually high pKa for protonation of the A14 ring opposite the X5 exocyclic adduct site. Thus, the interplay between hydrophobic and hydrogen-bonding contributions modulated by pH defines the alignment of 1,N2-propanodeoxyguanosine opposite deoxyadenosine in the interior of DNA helices.     

Solution structures of aminofluorene [AF]-stacked conformers of the syn [AF]-C8-dG adduct positioned opposite dC or dA at a template-primer junction.

A solution structural study has been undertaken on the aminofluorene-C8-dG ([AF]dG) adduct located at a single-strand-double-strand d(A1-A2-C3-[AF]G4-C5-T6-A7-C8-C9-A10-T11-C12-C13). d(G14-G15-A16-T17-G18-G19-T20- A21-G22-N23) 13/10-mer junction (N = C or A) using proton-proton distance restraints derived from NMR data in combination with intensity-based relaxation matrix refinement computations. This single-strand-double-strand junction models one arm of a replication fork composed of a 13-mer template strand which contains the [AF]dG modification site and a 10-mer primer strand which has been elongated up to the modified guanine with either its complementary dC partner or a dA mismatch. The solution structures establish that the duplex segment retains a minimally perturbed B-DNA conformation with Watson-Crick hydrogen-bonding retained up to the dC5.dG22 base pair. The guanine ring of the [AF]dG4 adduct adopts a syn glycosidic torsion angle and is displaced into the major groove when positioned opposite dC or dA residues. This base displacement of the modified guanine is accompanied by stacking of one face of the aminofluorene ring of [AF]dG4 with the dC5.dG22 base pair, while the other face of the aminofluorene ring is stacked with the purine ring of the nonadjacent dA2 residue. By contrast, the dC and dA residues opposite the junctional [AF]dG4 adduct site adopt distinctly different alignments. The dC23 residue positioned opposite the adduct site is looped out into the minor groove by the aminofluorene ring. The syn displaced orientation of the modified dG with stacking of the aminofluorene and the looped out position of the partner dC could be envisioned to cause polymerase stalling associated with subsequent misalignment leading to frameshift mutations in appropriate sequences. The dA23 residue positioned opposite the adduct site is positioned in the major groove with its purine ring aligned face down over the van der Waals surface of the major groove and its amino group directed toward the T6.A21 base pair. The Hoogsteen edge of the modified guanine of [AF]dG4 and the Watson-Crick edge of dA23 positioned opposite it are approximately coplanar and directed toward each other but are separated by twice the hydrogen-bonding distance required for pairing. This structure of [AF]dG opposite dA at a model template-primer junctional site can be compared with a previous structure of [AF]dG opposite dA within a fully paired duplex [Norman, D., Abuaf, P., Hingerty, B. E., Live, D. , Grunberger, D., Broyde, S., and Patel, D. J. (1989) Biochemistry 28, 7462-7476]. The alignment of the Hoogsteen edge of [AF]dG (syn) positioned opposite the Watson-Crick edge of dA (anti) has been observed for both systems with the separation greater in the case of the junctional alignment in the model template-primer system. However, the aminofluorene ring is positioned in the minor groove in the fully paired duplex while it stacks over the junctional base pair in the template-primer system. This suggests that the syn [AF]dG opposite dA junctional alignment can be readily incorporated within a duplex by a translation of this entity toward the minor groove.     

Solution structure of the (+)-cis-anti-benzo[a]pyrene-dA ([BP]dA) adduct opposite dT in a DNA duplex.

Minor adducts, derived from the covalent binding of anti-benzo[a]pyrene-7,8-dihydroxy-9,10-epoxide to cellular DNA, may play an important role in generating mutations and initiating cancer. We have applied a combined NMR-computational approach including intensity based refinement to determine the solution structure of the minor (+)-cis-anti-[BP]dA adduct positioned opposite dT in the d(C1-T2-C3-T4-C5-[BP]A6-C7-T8-T9-C10-C11). (d(G12-G13-A14-A15-G16-T17-G18-A19-G20+ ++-A21-G22) 11-mer duplex. The BP ring system is intercalated toward the 5'-side of the [BP]dA6 lesion site without disrupting the flanking Watson-Crick dC5.dG18 and [BP]dA6.dT17 base pairs. This structure of the (+)-cis-anti-[BP]dA.dT 11-mer duplex, containing a bay region benzo[a]pyrenyl [BP]dA adduct, is compared with the corresponding structure of the (+)-trans-anti-[BPh]dA.dT 11-mer duplex (Cosman et al., Biochemistry 32, 12488-12497, 1993), which contains a fjord region benzo[c]phenanthrenyl [BPh]dA adduct with the same R stereochemistry at the linkage site. The carcinogen intercalates toward the 5'-direction of the modified strand in both duplexes (the adduct is embedded within the same sequence context) with the buckling of the Watson-Crick [BP]dA6.dT17 base pair more pronounced in the (+)-cis-anti-[BP]dA.dT 11-mer duplex compared to its Watson-Crick [BPh]dA.dT17 base pair in the (+)-trans-anti-[BPh]dA.dT 11-mer duplex. The available structural studies of covalent polycyclic aromatic hydrocarbon (PAH) carcinogen-DNA adducts point toward the emergence of a general theme where distinct alignments are adopted by PAH adducts covalently linked to the N(6) of adenine when compared to the N(2) of guanine in DNA duplexes. The [BPh]dA and [BP]dA N(6)-adenine adducts intercalate their polycyclic aromatic rings into the helix without disruption of their modified base pairs. This may reflect the potential flexibility associated with the positioning of the covalent tether and the benzylic ring of the carcinogen in the sterically spacious major groove. By contrast, such an intercalation without modified base pair disruption option appears not to be available to [BP]dG N(2)-guanine adducts where the covalent tether and the benzylic ring are positioned in the more sterically crowded minor groove. In the case of [BP]dG adducts, the benzopyrenyl ring is either positioned in the minor groove without base pair disruption, or if intercalated into the helix, requires disruption of the modified base pair and displacement of the bases out of the helix.     

Structural features of an exocyclic adduct positioned opposite an abasic site in a DNA duplex

Structural studies have been extended to dual lesions where an exocyclic adduct is positioned opposite an abasic site in the center of a DNA oligomer duplex. NMR and energy minimization studies were performed on the 1,N2-propanodeoxyguanosine exocyclic adduct (X) positioned opposite a tetrahydrofuran abasic site (F) with the dual lesions located in the center of the (C1-A2-T3-G4-X5-G6-T7-A8-C9).(G10-T11-A12-C-13-F14-C15 -A16-T17-G-18) X.F 9-mer duplex. Two-dimensional NMR experiments establish that the X.F 9-mer helix is right-handed with Watson-Crick A.T and G.C base pairing on either side of the lesion site. NOEs are detected from the methylene protons of the exocyclic ring of X5 to the imino protons of G4.C15 and G6.C13 which flank the lesion site, as well as to the H1' and H1" protons of the cross strand F14 tetrahydrofuran moiety. These NMR results establish that the exocyclic adduct X5 is positioned between flanking G4.C15 and G6.C13 base pairs and directed toward the abasic lesion F14 on the partner strand. These studies establish that the exocyclic ring of the 1,N2-propanodeoxyguanosine adduct fits into the cavity generated by the abasic site.     

Solution structure of the covalent sterigmatocystin-DNA adduct.

Sterigmatocystin and aflatoxin are potent mutagens that contaminate foodstuffs stored under conditions that permit fungal growth. These food mycotoxins can be metabolically activated to their epoxides, which subsequently form covalent adducts with DNA and can eventually induce tumor development. We have generated the sterigmatocystin-d(A1-A2-T3-G4-C5-A6-T7-T8) covalent adduct (two sterigmatocystins per duplex) by reacting sterigmatocystin-1,2-epoxide with the self-complementary d(A-A-T-G-C-A-T-T) duplex and determined its solution structure by the combined application of two-dimensional NMR experiments and molecular dynamics calculations. The self-complementary duplex retains its 2-fold symmetry following covalent adduct formation of sterigmatocystin at the N7 position of G4 residues on each strand of the duplex. The H8 proton of [ST]G4 exchanges rapidly with water and resonates at 9.58 ppm due to the presence of the positive charge on the guanine ring following adduct formation. We have assigned the exchangeable and nonexchangeable proton resonances of sterigmatocystin and the duplex in the covalent adduct and identified the intermolecular proton-proton NOEs that define the orientation and mode of binding of the mutagen to duplex DNA. The analysis was aided by intermolecular NOEs between the sterigmatocystin protons with both the major groove and minor groove protons of the DNA. The molecular dynamics calculations were aided by 180 intramolecular nucleic acid constraints, 16 intramolecular sterigmatocystin constraints, and 56 intermolecular distance constraints between sterigmatocystin and the nucleic acid protons in the adduct. The sterigmatocystin chromophore intercalates between the [ST]G4.C5 and T3.A6 base pairs and stacks predominantly over the modified guanine ring in the adduct duplex. The overall conformation of the DNA remains right-handed on adduct formation with unwinding of the helix, as well as widening of the minor groove. Parallel NMR studies on the sterigmatocystin-d(A1-A2-A3-G4-C5-T6-T7-T8) covalent adduct (two sterigmatocystins per duplex) provide supportive evidence that the mutagen covalently adducts the N7 position of G4 and its chromophore intercalates to the 5' side of the guanine and stacks over it. The present NMR-molecular dynamics studies that define a detailed structure for the sterigmatocystin-DNA adduct support key structural conclusions proposed previously on the basis of a qualitative analysis of NMR parameters for the adduct formed by the related food mutagen aflatoxin B1 and DNA [Gopalakrishnan, S., Harris, T. M., & Stone, M. P. (1990) Biochemistry 29, 10438-10448].     

NMR studies for identification of dI:dG mismatch base-pairing structure in DNA.

One- and two-dimensional NMR experiments have been undertaken to investigate deoxyinosine:deoxyguanosine (dI:dG) base pairing in a self-complementary dodecadeoxyribonucleotide, d(C1-G2-C3-I4-A5-A6-T7-T8-G9-G10-G11-G12) (designated IG-12), duplex. The NMR data indicate formation of a dI(syn):dG(anti) base pair in a B-DNA helix. This unusual base pairing results in altered NOE patterns between the base protons (H8 and H2) of the I4 residue and the sugar protons of its own and the 5'-flanking C3 residues. The dI(syn):dG(anti) base pair is accommodated in the B-DNA duplex with only a subtle distortion of the local conformation. Identification of the dI:dG base pairing in this study confirms that a hypoxanthine base can form hydrogen-bonded base pairs with all of the four normal bases, C, A, T, and G, in DNA.     

NMR structural studies of the ionizing radiation adduct 7-hydro-8-oxodeoxyguanosine (8-oxo-7H-dG) opposite deoxyadenosine in a DNA duplex. 8-Oxo-7H-dG(syn).dA(anti) alignment at lesion site

Proton NMR studies are reported on the complementary d(C1-C2-A3-C4-T5-A6-oxo-G7-T8-C9-A10-C11-C12).d(G13-G14-T15- G16-A17-A18-T19- A20-G21-T22-G23-G24) dodecanucleotide duplex (designated 8-oxo-7H-dG.dA 12-mer), which contains a centrally located 7-hydro-8-oxodeoxyguanosine (8-oxo-7H-dG) residue, a group commonly found in DNA that has been exposed to ionizing radiation or oxidizing free radicals. From the NMR spectra it can be deduced that this moiety exists as two tautomers, or gives rise to two DNA conformations, that are in equilibrium and that exchange slowly. The present study focuses on the major component of the equilibrium that originates in the 6,8-dioxo tautomer of 8-oxo-7H-dG. We have assigned the exchangeable NH1, NH7, and NH2-2 base protons located on the Watson-Crick and Hoogsteen edges of 8-oxo-7H-dG7 in the 8-oxo-7H-dG.dA 12-mer duplex, using an analysis of one- and two-dimensional nuclear Overhauser enhancement (NOE) data in H2O solution. The observed NOEs derived from the NH7 proton of 8-oxo-7H-dG7 to the H2 and NH2-6 protons of dA18 establish an 8-oxo-7H-dG7(syn).dA 18(anti) alignment at the lesion site in the 8-oxo-7H-dG.dA 12-mer duplex in solution. This alignment, which places the 8-oxo group in the minor groove, was further characterized by an analysis of the NOESY spectrum of the 8-oxo-7H-dG.dA 12-mer duplex in D2O solution. We were able to detect a set of intra- and interstrand NOEs between protons (exchangeable and nonexchangeable) on adjacent residues in the d(A6-oxo-G7-T8).d(A17-A18-T19) trinucleotide segment centered about the lesion site that establishes stacking of the oxo-dG7(syn).dA(anti) pair between stable Watson-Crick dA6.dT19 and dT8.dA17 base pairs with minimal perturbation of the helix. Thus, both strands of the 8-oxo-7H-dG.dA 12-mer duplex adopt right-handed conformations at and adjacent to the lesion site, the unmodified bases adopt anti glycosidic torsion angles, and the bases are stacked into the helix. The energy-minimized conformation of the central d(A6-oxo-G7-T8).d(A17-A18-T19) segment requires that the 8-oxo-7H-dG7(syn).dA18(anti) alignment be stabilized by two hydrogen bonds from NH7 and O6 of 8-oxo-7H-dG7(syn) to N1 and NH2-6 of dA18(anti), respectively, at the lesion site.(ABSTRACT TRUNCATED AT 400 WORDS)     

NMR and computational characterization of the N-(deoxyguanosin-8-yl)aminofluorene adduct [(AF)G] opposite adenosine in DNA: (AF)G[syn].A[anti] pair formation and its pH dependence

This paper reports on a combined two-dimensional NMR and energy minimization computational characterization of the conformation of the N-(deoxyguanosyl-8-yl)aminofluorene adduct [(AF)G] positioned across adenosine in a DNA oligomer duplex as a function of pH in aqueous solution. This study was undertaken on the d[C1-C2-A3-T4-C5-(AF)G6-C7-T8-A9-C10-C11].[G12-G13-T14 -A15-G16-A17-G18- A19-T20-G21-G22] complementary undecamer [(AF)G 11-mer duplex]. The modification of the single G6 on the pyrimidine-rich strand was accomplished by reaction of the oligonucleotide with N-acetoxy-2-(acetylamino)fluorene and subsequent deacetylation under alkaline conditions. The HPLC-purified modified strand was annealed with the unmodified purine-rich strand to generate the (AF)G 11-mer duplex. The exchangeable and nonexchangeable protons are well resolved and narrow in the NMR spectra of the (AF)G 11-mer duplex so that the base and the majority of sugar nucleic acid protons, as well as several aminofluorene ring protons, have been assigned following analysis of two-dimensional NOESY and COSY data sets at pH 6.9, 30 degrees C in H2O and D2O solution. The NOE distance constraints establish that the glycosidic torsion angle is syn at (AF)G6 and anti at A17, which results in the aminofluorene ring being positioned in the minor groove. A very large downfield shift is detected at the H2' sugar proton of (AF)G6 associated with the (AF)G6[syn].A17[anti] alignment in the (AF)G 11-mer duplex. The NMR parameters demonstrate formation of Watson-Crick C5.G18 and C7.G16 base pairs on either side of the (AF)G6[syn].A17[anti] modification site with the imino proton of G18 more stable to exchange than the imino proton of G16. Several nonexchangeable aminofluorene protons undergo large downfield shifts as do the imino and H8 protons of G16 on lowering of the pH from neutrality to acidic values for the (AF)G 11-mer duplex. Both the neutral and acidic pH conformations have been defined by assigning the NOE constraints in the [C5-(AF)G6-C7].[G16-A17-G18] segment centered about the modification site and incorporating them in distance constrained minimized potential energy calculations in torsion angle space with the DUPLEX program. A series of NOEs between the aminofluorene protons and the DNA sugar protons in the neutral pH conformation establish that the aminofluorene ring spans the minor groove and is directed toward the G16-A17-G18 sugar-phosphate backbone on the partner strand.(ABSTRACT TRUNCATED AT 400 WORDS)     

荷斯坦牛BoLA-DRA基因SNPs筛选及生物信息学分析

为了探讨BoLA-DRA基因多态性,本研究利用DNA混合池扩增产物直接测序的方法对荷斯坦牛BoLA-DRA基因编码区SNPs进行筛选,并利用生物信息学软件预测该基因m RNA二级结构。结果表明:荷斯坦牛BoLA-DRA基因编码区共有4个SNPs (exon2-A82T,exon2-G116A,exon2-C197T,exon2-C233A)。生物信息学预测结果显示,exon2-A82T、exon2-G116A和exon2-C233A增大了m RNA二级结构的稳定性,而exon2-C197T降低了mRNA二级结构的稳定性。本研究结果可为荷斯坦牛抗病和抗逆性能研究积累更多的分子遗传学数据,并为经济性状相关基因筛选提供理论依据。     

The precursor tRNA 3'-CCA interaction with Escherichia coli RNase P RNA is essential for catalysis by RNase P in vivo

The L15 region of Escherichia coli RNase P RNA forms two Watson-Crick base pairs with precursor tRNA 3'-CCA termini (G292-C75 and G293-C74). Here, we analyzed the phenotypes associated with disruption of the G292-C75 or G293-C74 pair in vivo. Mutant RNase P RNA alleles (rnpBC292 and rnpBC293) caused severe growth defects in the E. coli rnpB mutant strain DW2 and abolished growth in the newly constructed mutant strain BW, in which chromosomal rnpB expression strictly depended on the presence of arabinose. An isosteric C293-G74 base pair, but not a C292-G75 pair, fully restored catalytic performance in vivo, as shown for processing of precursor 4.5S RNA. This demonstrates that the base identity of G292, but not G293, contributes to the catalytic process in vivo. Activity assays with mutant RNase P holoenzymes assembled in vivo or in vitro revealed that the C292/293 mutations cause a severe functional defect at low Mg2+ concentrations (2 mM), which we infer to be on the level of catalytically important Mg2+ recruitment. At 4.5 mM Mg2+, activity of mutant relative to the wild-type holoenzyme, was decreased only about twofold, but 13- to 24-fold at 2 mM Mg2+. Moreover, our findings make it unlikely that the C292/293 phenotypes include significant contributions from defects in protein binding, substrate affinity, or RNA degradation. However, native PAGE experiments revealed nonidentical RNA folding equilibria for the wild-type versus mutant RNase P RNAs, in a buffer- and preincubation-dependent manner. Thus, we cannot exclude that altered folding of the mutant RNAs may have also contributed to their in vivo defect.     

NMR structure of stem-loop SL2 of the HIV-1 psi RNA packaging signal reveals a novel A-U-A base-triple platform

The genome of the human immunodeficiency virus type-1 (HIV-1) contains a stretch of approximately 120 nucleotides known as the psi-site that is essential for RNA packaging during virus assembly. These nucleotides have been proposed to form four stem-loops (SL1-SL4) that have both independent and overlapping functions. Stem-loop SL2 is important for efficient recognition and packaging of the full-length, unspliced viral genome, and also contains the major splice-donor site (SD) for mRNA splicing. We have determined the structure of the 19-residue SL2 oligoribonucleotide by heteronuclear NMR methods. The structure is generally consistent with the most recent of two earlier secondary structure predictions, with residues G1-G2-C3-G4 and C6-U7 forming standard Watson Crick base-pairs with self-complementary residues C16-G17-C18-C19 and A12-G13, respectively. However, residue A15, which is located near the center of the stem, does not form a predicted bulge, and residues A5 and U14 do not form an expected Watson-Crick base-pair. Instead, these residues form a novel A5-U14-A15 base-triple that appears to be stabilized by hydrogen bonds from A15-H61 and -H62 to A5-N1 and U14-O2, respectively; from A5-H61 to U14-O2, and from C16-H42 to U14-O2'. A kink in the backbone allows the aromatic rings of the sequential U14-A15 residues to be approximately co-planar, adopting a stable "platform motif" that is structurally similar to the A-A (adenosine) platforms observed in the P4-P6 ribozyme domain of the Tetrahymena group I intron. Platform motifs generally function in RNA by mediating long-range interactions, and it is therefore possible that the A-U-A base-triple platform mediates long-range interactions that either stabilize the psi-RNA or facilitate splicing and/or packaging. Residue G8 of the G8-G9-U10-G11 tetraloop is stacked above the U7-A12 base-pair, and the remaining tetraloop residues are disordered and available for potential interactions with either other RNA or protein components.     

Deoxyguanosine-deoxyadenosine pairing in the d(C-G-A-G-A-A-T-T-C-G-C-G) duplex: conformation and dynamics at and adjacent to the dG X dA mismatch site

Nuclear magnetic resonance (NMR) has been used to monitor the conformation and dynamics of the d-(C1-G2-A3-G4-A5-A6-T6-T5-C4-G3-C2-G1) self-complementary dodecanucleotide (henceforth called 12-mer GA) that contains a dG X dA purine-purine mismatch at position 3 in the sequence. These results are compared with the corresponding d(C-G-C-G-A-A-T-T-C-G-C-G) dodecamer duplex (henceforth called 12-mer) containing standard Watson-Crick base pairs at position 3 [Patel, D.J., Kozlowski, S.A., Marky, L.A., Broka, C., Rice, J.A., Itakura, K., & Breslauer, K.J. (1982) Biochemistry 21, 428-436]. The dG X dA interaction at position 3 was monitored at the guanosine exchangeable H-1 and nonexchangeable H-8 protons and the nonexchangeable adenosine H-2 proton. We demonstrate base-pair formation between anti orientations of the guanosine and adenosine rings on the basis of nuclear Overhauser effects (NOE) observed between the H-2 proton of adenosine 3 and the imino protons of guanosine 3 (intra base pair) and guanosines 2 and 4 (inter base pair). The dG(anti) X dA(anti) pairing should result in hydrogen-bond formation between the guanosine imino H-1 and carbonyl O-6 groups and the adenosine N-1 and NH2-6 groups, respectively. The base pairing on either side of the dG X dA pair remains intact at low temperature, but these dG X dC pairs at positions 2 and 4 are kinetically destabilized in the 12-mer GA compared to the 12-mer duplex. We have estimated the hydrogen exchange kinetics at positions 4-6 from saturation-recovery measurements on the imino protons of the 12-mer GA duplex between 5 and 40 degrees C. The measured activation energies for imino proton exchange in the 12-mer GA are larger by a factor of approximately 2 compared to the corresponding values in the 12-mer duplex. This implies that hydrogen exchange in the 12-mer GA duplex results from a cooperative transition involving exchange of several base pairs as was previously reported for the 12-mer containing a G X T wobble pair at position 3 [Pardi, A., Morden, K.M., Patel, D.J., & Tinoco, I., Jr. (1982) Biochemistry 21, 6567-6574]. We have assigned the nonexchangeable base protons by intra and inter base pair NOE experiments and monitored these assigned markers through the 12-mer GA duplex to strand transition.(ABSTRACT TRUNCATED AT 400 WORDS)