A strategy for probing the autonomy of cross-domain stereochemical communication in glycoconjugates.

Glycoproteins contain carbohydrate and peptide sectors. As a model for studying whether there exists stereochemical "communication" between the two domains, we prepared two glycopeptides differing only in the absolute stereochemistry of the peptide domain (L-peptide vs D-peptide). High-field NMR spectroscopy revealed that there are distinct and measurable differences, indicating that the two domains are at some level interactive.

Mechanism of the bisphosphatase reaction of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase probed by (1)H-(15)N NMR spectroscopy.

The histidines in the bisphosphatase domain of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were labeled with (15)N, both specifically at N1' and globally, for use in heteronuclear single quantum correlation (HSQC) NMR spectroscopic analyses. The histidine-associated (15)N resonances were assigned by correlation to the C2' protons which had been assigned previously [Okar et al., Biochemistry 38, 1999, 4471-79]. Acquisition of the (1)H-(15)N HSQC from a phosphate-free sample demonstrated that the existence of His-258 in the rare N1' tautomeric state is dependent upon occupation of the phosphate binding site filled by the O2 phosphate of the substrate, fructose-2,6-bisphosphate, and subsequently, the phosphohistidine intermediate. The phosphohistidine intermediate is characterized by two hydrogen bonds involving the catalytic histidines, His-258 and His-392, which are directly observed at the N1' positions of the imidazole rings. The N1' of phospho-His-258 is protonated ((1)H chemical shift, 14.0 ppm) and hydrogen bonded to the backbone carbonyl of Gly-259. The N1' of cationic His-392 is hydrogen bonded ((1)H chemical shift, 13.5 ppm) to the phosphoryl moiety of the phosphohistidine. The existence of a protonated phospho-His-258 intermediate and the observation of a fairly strong hydrogen bond to the same phosphohistidine implies that hydrolysis of the covalent intermediate proceeds without any requirement for an "activated" water. Using the labeled histidines as probes of the catalytic site mutation of Glu-327 to alanine revealed that, in addition to its function as the proton donor to fructose-6-phosphate during formation of the transient phosphohistidine intermediate at the N3' of His-258, this residue has a significant role in maintaining the structural integrity of the catalytic site. The (1)H-(15)N HSQC data also provide clear evidence that despite being a surface residue, His-446 has a very acidic pK(a), much less than 6.0. On the basis of these observations a revised mechanism for fructose-2,6-bisphosphatase that is consistent with all of the previously published kinetic data and X-ray crystal structures is proposed. The revised mechanism accounts for the structural and kinetic consequences produced by mutation of the catalytic histidines and Glu-327. It also provides the basis for a hypothetical mechanism of bisphosphatase activation by cAMP-dependent phosphorylation of Ser-32, which is located in the N-terminal kinase domain.

Synthesis and characterization of nido-carborane-cobalamin conjugates.

Three vitamin B12 (cyanocobalamin) conjugates bearing one nido-carborane molecule or two nido-carborane molecules linked to the propionamide side chains via a four carbon linker have been synthesized. Reaction of o-carboranoylchloride with 1,4-diaminobutane in pyridine produced nido-carboranoyl(4-amidobutyl)amine, which was linked to the b- and d-monocarboxylic acids and the b,d-dicarboxylic acid of cyanocobalamin. Mass spectrometry analysis as well as 11B nuclear magnetic resonance demonstrated that during the reaction of o-carboranonylchloride with diaminobutane one of the boron atoms was eliminated. In vitro biological activity of the cyanocobalamin-nido-carborane conjugates was assessed by the unsaturated vitamin B12 binding capacity assay. When compared with 57Co cyanocobalamin, the biological activity of cyanocobalamin-b-nido-carborane, cyanocobalamin-d-nido-carborane, and cyanocobalamin-b-d-bis-nido-carborane conjugates were 92.93%, 35.75%, and 37.02%, respectively. These findings suggest that the 10B cobalamin conjugates might be useful agents in treating malignant tumors via neutron capture therapy.

The roles of Glu-327 and His-446 in the bisphosphatase reaction of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase probed by NMR spectroscopic and mutational analyses of the enzyme in the transient phosphohistidine intermediate complex.

The bisphosphatase domain derived from the rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase was studied by 1H-13C HMQC NMR spectroscopy of the histidine C2' and H2' nuclei. The bacterially expressed protein was specifically labeled with 13C at the ring C2' position of the histidines. Each of the seven histidine residues gave rise to a single cross-peak in the HMQC spectra, and these were assigned by use of a series of histidine-to-alanine point mutants. His-304, His-344, and His-469 exhibit 13C and 1H resonances that titrated with pH, while the remaining histidine-associated resonances did not. The 13C and 1H chemical shifts indicate that at neutral pH, His-304 and His-446 are deprotonated, while His-469 is protonated. The pKa of His-344 was determined to be 7.04. The 13C chemical shifts suggest that the deprotonated His-258 exists as the N1' tautomer, while His-392 and His-419 are protonated in the resting, wild-type enzyme. Mutation of the remaining member of the catalytic triad, Glu-327, to alanine in the resting enzyme caused an upfield shift of 1.58 and 1.30 ppm in the 1H and 13C dimensions, respectively, and significant narrowing of the His-258 cross-peak. Mutation of His-446 to alanine produced perturbations of the His-258 cross-peak that were similar to those detected in the E327A mutant. The His-392 resonances were also shifted by the E327A and H446A mutations. These observations strongly suggest that residues His-258, Glu-327, His-392, and His-446 exist within a network of interacting residues that encompasses the catalytic site of the bisphosphatase and includes specific contacts with the C-terminal regulatory region of the enzyme. The specifically 13C-labeled bisphosphatase was monitored during turnover by HMQC spectra acquired from the transient N3' phosphohistidine intermediate complex in the wild-type enzyme, the E327A mutant, and the H446A mutant. These complexes were formed during reaction with the physiological substrate fructose-2, 6-bisphosphate. Upon formation of the phosphohistidine at His-258, the 13C and 1H resonances of this residue were shifted downfield by 1.7 and 0.31 ppm, respectively, in the wild-type enzyme. The upfield shifts of the His-258 resonances in the E327A and H446A mutant resting enzymes were reversed when the phosphohistidine was formed, generating spectra very similar to that of the wild-type enzyme in the intermediate complex. In contrast, the binding of fructose-6-phosphate, the reaction product, to the resting enzyme did not promote significant changes in the histidine-associated resonances in either the wild-type or the mutant enzymes. The interpretation of these data within the context of the X-ray crystal structures of the enzyme is used to define the role of Glu-327 in the catalytic mechanism of the bisphosphatase and to identify His-446 as a putative link in the chain of molecular events that results in activation of the bisphosphatase site by cAMP-dependent phosphorylation of the hepatic bifunctional enzyme.

Probing cell-surface architecture through synthesis: an NMR-determined structural motif for tumor-associated mucins.

Cell-surface mucin glycoproteins are altered with the onset of oncogenesis. Knowledge of mucin structure could be used in vaccine strategies that target tumor-associated mucin motifs. Thus far, however, mucins have resisted detailed molecular analysis. Reported herein is the solution conformation of a highly complex segment of the mucin CD43. The elongated secondary structure of the isolated mucin strand approaches the stability of motifs found in folded proteins. The features required for the mucin motif to emerge are also described. Immunocharacterization of related constructs strongly suggests that the observed epitopes represent distinguishing features of tumor cell-surface architecture.

Conformational influences of glycosylation of a peptide: a possible model for the effect of glycosylation on the rate of protein folding.

Improved strategies for synthesis make it possible to expand the range of glycopeptides available for detailed conformational studies. The glycopeptide 1 was synthesized using a new solid phase synthesis of carbohydrates and a convergent coupling to peptide followed by deprotection. Its conformational properties were subjected to NMR analysis and compared with a control peptide 2 prepared by conventional solid phase methods. Whereas peptide 2 fails to manifest any appreciable secondary structure, the glycopeptide 1 does show considerable conformational bias suggestive of an equilibrium between an ordered and a random state. The implications of this ordering effect for the larger issue of protein folding are considered.

RNA folding topology and intermolecular contacts in the AMP-RNA aptamer complex.

We report below on the NMR structural characterization of the complex between AMP and a 40-mer RNA aptamer in aqueous solution. Resonance assignments are based on multinuclear multidimensional NMR studies on complexes uniformly 13C, 15N-labeled with either AMP or the RNA aptamer. AMP binds to an internal loop (labeled G7-G8-A9-A10-G11-A12-A13-A14-C15-U16-G17) and bulge (G34 positioned opposite the internal loop) segment in the RNA aptamer, and our NMR study provides insights into features of the RNA folding topology and the molecular recognition events in the AMP binding pocket on the RNA. Specifically, the helical stems are extended by G-G mismatch formation from either direction into the internal loop/bulge segment of the RNA aptamer on complex formation. The internal loop adopts a unique fold with the purine ring of AMP intercalated between A10 and G11 in the complex. The G8-A9-A10-AMP segment adopts certain stacking features in common with a GNRA turn and is closed by the G7.G11 mismatch pair. The purine rings of A12 and G34 (syn) are stacked on each other and participate in stablizing the AMP intercalation site. A large number of intermolecular NOEs have been identified between the AMP ligand and the G8, A10, G11, G17, U18, and G34 residues on the RNA aptamer in the complex. The Watson-Crick edge of the AMP is oriented toward the exocyclic amino group of G8, suggestive of a hydrogen-bonding alignment between G8 and AMP in the complex. The AMP sugar ring is positioned in the minor groove of the rightward helical stem centered about the G17.G34 mismatch and U18.A33 Watson-Crick pairs. The AMP binds to one face of the folded internal loop/bulge segment of the RNA aptamer while the opposite face is capped by a stacked alignment of the A13-A14-C15-U16 segment located toward the 3'-end of the internal loop segment. Globally, the two helical stems of the RNA aptamer are aligned approximately orthogonal to each other with tertiary interactions centered about the internal loop/bulge segment generating the AMP binding site on the RNA.

Molecular recognition in the FMN-RNA aptamer complex.

We report on a combined NMR-molecular dynamics calculation approach that has solved the solution structure of the complex of flavin mononucleotide (FMN) bound to the conserved internal loop segment of a 35 nucleotide RNA aptamer identified through in vitro selection. The FMN-RNA aptamer complex exhibits exceptionally well-resolved NMR spectra that have been assigned following application of two, three and four-dimensional heteronuclear NMR techniques on samples containing uniformly 13C, 15N-labeled RNA aptamer in the complex. The assignments were aided by a new through-bond NMR technique for assignment of guanine imino and adenine amino protons in RNA loop segments. The conserved internal loop zippers up through the formation of base-pair mismatches and a base-triple on complex formation with the isoalloxazine ring of FMN intercalating into the helix between a G.G mismatch and a G.U.A base-triple. The recognition specificity is associated with hydrogen bonding of the uracil like edge of the isoalloxazine ring of FMN to the Hoogsteen edge of an adenine at the intercalation site. There is significant overlap between the intercalated isoalloxazine ring and its adjacent base-triple platform in the complex. The remaining conserved residues in the internal loop participate in two G.A mismatches in the complex. The zippered-up internal loop and flanking stem regions form a continuous helix with a regular sugar-phosphate backbone except at a non-conserved adenine, which loops out of the helix to facilitate base-triple formation. Our solution structure of the FMN-RNA aptamer complex is to our knowledge the first structure of an RNA aptamer complex and outlines folding principles that are common to other RNA internal and hairpin loops, and molecular recognition principles common to model self-replication systems in chemical biology.

Influence of the glycosidic torsion angle on 13C and 15N shifts in guanosine nucleotides: investigations of G-tetrad models with alternating syn and anti bases.

The effect of the glycosidic torsion angle on 13C and 15N shifts of the sugar and base moieties of guanosine nucleotides was investigated by comparing the sites in two model G-tetrad oligodeoxynucleotides that contain guanosine residues alternately with syn and anti bases. The sugar puckering has been shown to be C2'-endo for both cases. It was observed that, for the instances with syn bases, the C1' through C4' carbons showed shifts that may be distinguished from those normally found in B-DNA-like structures. C1', C3' and C4' moved to lower field, while C2' moved to higher field. Effects of the change in glycosidic torsion angle were also seen in the shifts of base carbons and nitrogens in the five-membered ring portion of the base. Characterization of the shift variation associated with this conformational change may be useful in developing the use of 13C shifts as a tool in conformational analysis of oligonucleotides.

A siderophore from a marine bacterium with an exceptional ferric ion affinity constant.

Virtually all microorganisms require iron for growth. The paucity of iron in surface ocean water (approximately 0.02-1.0 nM (refs 1, 2)) has spurred a lively debate concerning iron limitation of primary productivity, yet little is known about the molecular mechanisms used by marine microorganisms to sequester iron. Terrestrial bacteria use a siderophore-mediated ferric uptake system. A siderophore is a low-molecular-mass compound with a high affinity for ferric ion which is secreted by microorganisms is response to low-iron environments; siderophore biosynthesis is regulated by iron levels, with repression by high iron. Although open-ocean marine microorganisms (such as phytoplankton and bacteria) produce siderophores, the nature of these siderophores has not been investigated. We report here the first structure determination, to our knowledge, of the siderophores from an open-ocean bacterium, alterobactin A and B from Alteromonas luteoviolacea. A. luteoviolacea is found in oligotrophic and coastal waters. Alterobactin A has an exceptionally high affinity constant for ferric ion. We suggest that at least some marine microorganisms may have developed higher-affinity iron chelators as part of an efficient iron-uptake mechanism which is more effective than that of their terrestrial counterparts.

Comparative NMR study of A(n)-bulge loops in DNA duplexes: intrahelical stacking of A, A-A, and A-A-A bulge loops.

We have prepared a series of deoxyoligonucleotide duplexes of the sequence d(G-C-A-T-C-G-X-G-C-T-A-C-G).d(C-G-T-A-G-C-C-G-A-T-G-C), in which X represents either one (A), two (A-A), or three (A-A-A) unpaired adenine basis. Using two-dimensional proton and phosphorus NMR spectroscopy, we have characterized conformational features of these bulge-loop duplexes in solution. We find that Watson-Crick hydrogen bonding is intact for all 12 base pairs, including the GC bases that flank the bulge loop. Observation of NOE connectivities in both H2O and D2O allows us to unambiguously localize all of the bulged adenine residues to intrahelical positions within the duplex. This is in contrast to an earlier model for multiple-base bulge loops in DNA [Bhattacharyya, A., & Lilley, D. M. J. (1989) Nucleic Acids Res. 17, 6821-6840], in which all but the most 5' bulged base are looped out into solution. We find that insertion of two or three bases into the duplex results in the disruption of specific sequential NOEs for the base step across from the bulge loop site on the opposite strand. This disruption is characterized by a partial shearing apart of these bases, such that certain sequential NOEs for this base step are preserved. We observe a downfield-shifted phosphorus resonance, which we assign in the A-A-A bulge duplex to the 3' side of the last bulged adenine residue. Proton and phosphorus chemical shift trends within the An-bulge duplex series indicate that there is an additive effect on the structural perturbations caused by additional unpaired bases within the bulge loop. This finding parallels previous observations [Bhattacharyya, A., & Lilley, D. M. J. (1989) Nucleic Acids Res. 17, 6821-6840; Hsieh, C.-H., & Griffith, J. D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 4833-4837] on the magnitude of the induced bending of DNA duplexes by multiple-base bulge loops.

Solution conformation of the major adduct between the carcinogen (+)-anti-benzo[a]pyrene diol epoxide and DNA.

We have synthesized, separated, and purified approximately 10 mg of a deoxyundecanucleotide duplex containing a single centrally positioned covalent adduct between (+)-anti-benzo[a]pyrene (BP) diol epoxide and the exocyclic amino group of guanosine. Excellent proton NMR spectra are observed for the (+)-trans-anti-BP diol epoxide-N2-dG adduct positioned opposite dC and flanked by G.C pairs in the d[C1-C2-A3-T4-C5-(BP)G6-C7-T8-A9-C10-C11].d[12- G13-T14-A15-G16-C17-G18-A19-T20-G 21-G22] duplex +ADdesignated (BP)G.C 11-mer+BD. We have determined the solution structure centered about the BP covalent adduct site in the (BP)G.C 11-mer duplex by incorporating intramolecular and intermolecular proton-proton distance bounds deduced from the NMR data sets as constraints in energy minimization computations. The BP ring is positioned in the minor groove and directed toward the 5' end of the modified strand. One face of the BP ring of (BP)G6 is stacked over the G18 and A19 sugar-phosphate backbone on the partner strand and the other face is exposed to solvent. A minimally perturbed B-DNA helix is observed for the d[T4-C5-(BP)G6-C7-T8].d[A15-G16-C17-G18-A19] segment centered about the adduct site with Watson-Crick alignment for both the (BP)G6.C17 pair and flanking G.C pairs. A widening of the minor groove at the adduct site is detected that accommodates the BP ring whose long axis makes an angle of approximately 45 degrees with the average direction of the DNA helix axis. Our study holds future promise for the characterization of other steroisomerically pure adducts of BP diol epoxides with DNA to elucidate the molecular basis of structure-activity relationships associated with the stereoisomer-dependent spectrum of mutational and carcinogenic activities.

Multinuclear nuclear magnetic resonance studies of Na cation-stabilized complex formed by d(G-G-T-T-T-T-C-G-G) in solution. Implications for G-tetrad structures.

There has been much recent interest in the self-association of short deoxyguanosine-rich motifs within single-stranded DNAs to generate monovalent cation modulated four-stranded helical segments called G-quadruplexes stabilized by hydrogen-bonded G-tetrad alignments. We have addressed structural aspects of this novel alignment and report on multinuclear 1H, 31P and 13C nuclear magnetic resonance studies on the d(G2T4CG2) deoxynonanucleotide with Na cation as counterion in aqueous solution at low temperature. This sequence forms stable structures even though it cannot align by Watson-Crick hydrogen bond formation (see the paper on d(G2T5G2) describing optical and calorimetric measurements by Jin, R., Breslauer, K. J., Jones, R. A. & Gaffney, B. L. (1990), Science, 250, 543-546). The four narrow exchangeable protons detected between 11.5 and 12.0 parts per million (p.p.m.), which are common to the d(G2T4CG2) deoxynonanucleotide and the d(G2TCG2) deoxyhexanucleotide sequences, are assigned to deoxyguanosine imino protons hydrogen-bonded to carbonyl acceptor groups. These narrow imino protons are not detected for d(IGN5IG) and d(I2N5G2), where two deoxyguanosine residues are replaced by two deoxyinosine residues in the deoxynonanucleotide sequences. This implies that the 2-amino protons of deoxyguanosine must also participate in hydrogen bond formation and stabilize the structured conformation of d(G2T4CG2) in Na cation-containing solution. We have completely assigned the base and sugar H1', H2',2'', H3', and H4' protons of the d(G2T4CG2) oligomer following analysis of two-dimensional nuclear Overhauser enhancement spectroscopy and two-dimensional correlated spectroscopy data sets in 0.1 M-NaCl, 10 mM-sodium phosphate, 2H2O solution at 0 degree C. The relative magnitude of the nuclear Overhauser enhancements (NOEs) between the base H8 and its own sugar H1' protons of individual deoxyguanosine residues establishes that G1 and G8 adopt syn orientations while G2 and G9 adopt anti orientations about the glycosidic bond in the d(G1-G2-T3-T4-T5-T6-C7-G8-G9) sequence in both Na and K cation-containing aqueous solution. Consequently, any structure proposed for the tetramolecular complex of d(G2T4CG2) must exhibit alternating G(syn) and G(anti) glycosidic torsion angles within each strand. The directionality and magnitude of the observed NOEs are consistent with the G(syn)-G(anti) steps adopting right-handed helical conformations in solution. We also note that the H8 protons of G1 and G8 (7.35 to 7.45 p.p.m.) in a syn alignment are shifted significantly upfield from the H8 protons of G2 and G9 (8.0 to 8.3 p.p.m.) in an anti alignment.(ABSTRACT TRUNCATED AT 400 WORDS)

NMR structural studies of intramolecular (Y+)n.(R+)n(Y-)nDNA triplexes in solution: imino and amino proton and nitrogen markers of G.TA base triple formation.

We reported previously on NMR studies of (Y+)n.(R+)n(Y-)n DNA triple helices containing one oligopurine strand (R)n and two oligopyrimidine strands (Y)n stabilized by T.AT and C+.GC base triples [de los Santos, C., Rosen, M., & Patel, D. J. (1989) Biochemistry 28, 7282-7289]. Recently, it has been established that guanosine can recognize a thymidine.adenosine base pair to form a G.TA triple in an otherwise (Y+)n.(R+)n(Y-)n triple-helix motif. [Griffin, L. C., & Dervan, P. B. (1989) Science 245, 967-971]. The present study extends the NMR research to the characterization of structural features of a 31-mer deoxyoligonucleotide that folds intramolecularly into a 7-mer (Y+)n.(R+)n(Y-)n triplex with the strands linked through two T5 loops and that contains a central G.TA triple flanked by T.AT triples. The G.TA triplex exhibits an unusually well resolved and narrow imino and amino exchangeable proton and nonexchangeable proton spectrum in H2O solution, pH 4.85, at 5 degrees C. We have assigned the imino protons of thymidine and amino protons of adenosine involved in Watson-Crick and Hoogsteen pairing in T.AT triples, as well as the guanosine imino and cytidine amino protons involved in Watson-Crick pairing and the protonated cytidine imino and amino protons involved in Hoogsteen pairing in C+.GC triples in the NOESY spectrum of the G.TA triplex. The NMR data are consistent with the proposed pairing alignment for the G.TA triple where the guanosine in an anti orientation pairs through a single hydrogen bond from one of its 2-amino protons to the 4-carbonyl group of thymidine in the Watson-Crick TA pair.(ABSTRACT TRUNCATED AT 250 WORDS)

Heteronuclear two-dimensional 15N- and 13C-NMR studies of DNA oligomers and their netropsin complexes using indirect proton detection.

Heteronuclear multispin coherence proton-detected two-dimensional nmr spectroscopic experiments were used to obtain information on protonated carbons and nitrogens of the self-complementary d(G-G-T-A-T-A-C-C) and d(G-G-A-A-T-T-C-C) duplexes, with and without the drug netropsin dissolved in aqueous solution. Many correlations of protons coupled to 13C nuclei on the base and sugar rings of the octanucleotides were detected, allowing the carbon resonances to be assigned based on previous homonuclear proton two-dimensional nmr studies. Imino nitrogen assignments can also be made using the proton assignments from previous one-dimensional nuclear overhauser effect experiments. Imino nitrogen shifts may be useful indicators of changes in local hydrogen-bonding interactions to base-pair edges.

NMR studies of an oligonucleotide with an unusual structure induced by platinum anti-cancer drugs.

The 31P NMR spectra of Pt(en)[d(T1A2T3G4G5G6T7A8C9C10C11A12T13A14)] (14-mer) and Pt(en)[d(A2T3G4G5G6T7A8C9C10C11A12T13)] (12-mer) (en = ethylenediamine) each contain two signals far downfield (ca. -2.9 and -2.6 ppm from trimethylphosphate standard), two signals slightly downfield, and at least one signal slightly upfield of the normal range (ca -4.0 to -4.4 ppm). This pattern suggested a distorted structure. The unusual 31P signals of the 12-mer were assigned by analogy to signals of the 14-mer previously assigned by 17O-labeling methods. A combination of heteronuclear multiple-quantum coherence, one-dimensional and two-dimensional nuclear Overhauser effect (1D and 2D-NOE) and homonuclear shift correlation spectroscopy (COSY) experiments assigned all aromatic 1H signals of the 12-mer except H8 of G5 or G6. One of these H8 signals is missing from the spectrum and the nucleotide is labeled Gm. The other H8 is the most downfield signal and has a strong NOE to its H1'. Since this strong NOE indicates that this nucleoside exists in a syn conformation, it is labeled Gs. A strong NOE was observed between the Gs and A8 H8 signals. Several lines of evidence suggested a hairpin-like structure with a loop region (G6T7A8C9) and a stem region involving A2T3G4G5 and C10C11A12T13. The 31P signals for the stem region are within or slightly outside the normal range. 3JH3'-P values (3-6 Hz), measured by a 2D-J experiment, of stem nucleotides were characteristic for a DNA duplex. Imino signals for base pairs A2T13, T3A12, G4C11, and probably G5C10, and the observation of internucleotide NOE connectivities for these nucleotides (e.g. between an H8 signal and the H1' signal of the 5' nucleotide) suggested a right-handed helical structure. For the loop region, a distorted sugar-phosphate backbone is indicated by far downfield positions of the G5pG6 and A8pC9 31P signals, the 3JH3'-P values for C9p (8.0 Hz) and A8p (6.8 Hz), and the absence of H3'-P coupling for G5p. In the loop region, no imino signals or internucleotide NOEs characteristic of a right-handed duplex were observed. However, A8H8, C9H6, and C10H6 each exhibited unusual internucleotide NOEs to the H4' signal of the 5' residue. NOE crosspeaks between T7 1H signals and signals attributed to sugars of the Gs and Gm suggested that the T7 moiety is located within the space encircled by the loop. The few NOE crosspeaks, pH dependence, and Cu2+ broadening of C9 1H signals indicate an isolated location accessible to solvent.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

NMR and computational characterization of mitomycin cross-linked to adjacent deoxyguanosines in the minor groove of the d(T-A-C-G-T-A).d(T-A-C-G-T-A) duplex.

Two-dimensional homonuclear and heteronuclear NMR and minimized potential energy calculations have been combined to define the structure of the antitumor agent mitomycin C (MC) cross-linked to deoxyguanosines on adjacent base pairs in the d(T1-A2-C3-G4-T5-A6).d(T7-A8-C9-G10-T11-A12) duplex. The majority of the mitomycin and nucleic acid protons in the MC-X 6-mer complex have been assigned from through-bond and through-space two-dimensional proton NMR studies in aqueous solution at 5 and 20 degrees C. The C3.G10 and G4.C9 base pairs are intact at the cross-link site and stack on each other in the complex. The amino protons of G4 and G10 resonate at 9.36 and 8.87 ppm and exhibit slow exchange with solvent H2O. The NMR experimental data establish that the mitomycin is cross-linked to the DNA through the amino groups of G4 and G10 and is positioned in the minor groove. The conformation of the cross-link site is defined by a set of NOEs between the mitomycin H1" and H2" protons and the nucleic acid imino and amino protons of G4 and the H2 proton of A8 and another set of NOEs between the mitomycin geminal H10" protons and the nucleic acid imino and amino protons of G10 and the H2 proton of A2. Several phosphorus resonances of the d(T-A-C-G-T-A) duplex shift dramatically on mitomycin cross-link formation and have been assigned from proton-detected phosphorus-proton two-dimensional correlation experiments. The proton chemical shifts and NOEs establish fraying at the ends of the d(T-A-C-G-T-A) duplex, and this feature is retained on mitomycin cross-link formation. The base-base and base-sugar NOEs exhibit similar patterns for symmetry-related steps on the two nucleic acid strands in the MC-X 6-mer complex, while the proton and phosphorus chemical shifts are dramatically perturbed at the G10-T11 step on cross-link formation. The NMR distance constraints have been included in minimized potential energy computations on the MC-X 6-mer complex. These computations were undertaken with the nonplanar five-membered ring of mitomycin in each of two pucker orientations. The resulting low-energy structures MX1 and MX2 have the mitomycin cross-linked in a widened minor groove with the chromophore ring system in the vicinity of the G10-T11 step on one of the two strands in the duplex.(ABSTRACT TRUNCATED AT 400 WORDS)