Inhibition of 5'-UTR RNA conformational switching in HIV-1 using antisense PNAs.

BACKGROUND: The genome of retroviruses, including HIV-1, is packaged as two homologous (+) strand RNA molecules, noncovalently associated close to their 5'-end in a region called dimer linkage structure (DLS). Retroviral HIV-1 genomic RNAs dimerize through complex interactions between dimerization initiation sites (DIS) within the (5'-UTR). Dimer formation is prevented by so calledLong Distance Interaction (LDI) conformation, whereas Branched Multiple Hairpin (BMH) conformation leads to spontaneous dimerization. METHODS AND RESULTS: We evaluated the role of SL1 (DIS), PolyA Hairpin signal and a long distance U5-AUG interaction by in-vitro dimerization, conformer assay and coupled dimerization and template-switching assays using antisense PNAs. Our data suggests evidence that PNAs targeted against SL1 produced severe inhibitory effect on dimerization and template-switching processes while PNAs targeted against U5 region do not show significant effect on dimerization and template switching, while PNAs targeted against AUG region showed strong inhibition of dimerization and template switching processes. CONCLUSIONS: Our results demonstrate that PNA can be used successfully as an antisense to inhibit dimerization and template switching process in HIV -1 and both of the processes are closely linked to each other. Different PNA oligomers have ability of switching between two thermodynamically stable forms. PNA targeted against DIS and SL1 switch, LDI conformer to more dimerization friendly BMH form. PNAs targeted against PolyA haipin configuration did not show a significant change in dimerization and template switching process. The PNA oligomer directed against the AUG strand of U5-AUG duplex structure also showed a significant reduction in RNA dimerization as well as template- switching efficiency.The antisense PNA oligomers can be used to regulate the shift in the LDI/BMH equilibrium.

The crucial role of divalent metal ions in the DNA-acting efficacy and inhibition of the transcription of dimeric chromomycin A3.

Chromomycin A3 (Chro) is capable of forming a stable dimeric complex via chelation with Ni(II), Fe(II) and Co(II). According to the circular dichroism study, the dimer conformations are significantly different among the Fe(II)-, Co(II)-, and Ni(II)-containing dimeric Chro complexes; however, the dimer conformations were preserved at high temperatures. Furthermore, we conducted a systematic study to determine the effects of these divalent metal ions on the DNA-acting efficacy of dimeric Chro, including its DNA-binding affinity, DNA stabilization capacity, DNA cleavage activity, and the inhibition of transcription both in vitro and within cells. Kinetic analyses using surface plasmon resonance (SPR) showed that Ni(II)(Chro)(2) exhibited the highest K(a) with a value of 1.26 × 10(7) M(-1), which is approximately 1.6- and 3.7-fold higher than the K(a) values obtained for Co(II)(Chro)(2) and Fe(II)(Chro)(2), respectively. The T(m) and ΔG values for the DNA duplex increased after the addition of drug complexes in the following order: Ni(II)(Chro)(2)>Co(II)(Chro)(2)>Fe(II)(Chro)(2). In the DNA integrity assays, the DNA cleavage rate of Co(II)(Chro)(2) (1.2 × 10(-3) s(-1)) is higher than those of Fe(II)(Chro)(2) and Ni(II)(Chro)(2), which were calculated to be 1 × 10(-4) and 3.1 × 10(-4) s(-1), respectively. Consistent with the SPR and UV melting results, Ni(II)(Chro)(2) possesses the highest inhibitory effect on in vitro transcription and c-myc transcription within cells compared to Co(II)(Chro)(2) and Fe(II)(Chro)(2). By comparing the cytotoxicity among Co(II)(Chro)(2), Fe(II)(Chro)(2), and Ni(II)(Chro)(2) to several cancer cell lines, our studies concluded that Ni(II)(Chro)(2) displayed more potential antitumor activities than Co(II)(Chro)(2) and Fe(II)(Chro)(2) did due to its higher DNA-acting efficacy. Changes to the divalent metal ions in the dimeric Chro complexes have been correlated with improved anticancer profiles. The availability of new metal derivatives of Chro may introduce new possibilities for exploiting the unique properties of this class of compounds for therapeutic applications.

Design, synthesis, and evaluation of phenanthridine derivatives targeting the telomerase RNA/DNA heteroduplex.

We are targeting molecules to the RNA/DNA heteroduplex that forms during the enzyme telomerase's catalytic cycle. Telomerase is a potential universal anti-cancer target that we have previously shown can be inhibited by molecules that target this heteroduplex. The aim of this work was to make derivatives of our lead, ethidium, that would allow its straightforward incorporation into molecules in both solid and solution phase. The heteroduplex targeting intercalator will act as a scaffold to allow the incorporation of new functionalities that will interact with specific protein surfaces of telomerase, thereby potentially increasing affinity and specificity. In examining multiple new derivatives of ethidium, with literature precedent or novel, we have identified one, a 5-benzylic acid ethidium derivative that is synthesized in three steps as a single isomer, and completely retains the inhibition efficacy of the parent compound. Furthermore, we have demonstrated that it can be effectively incorporated into resin bound amines on the solid phase. As such it represents an ideal monomer for the exploration of telomerase inhibition or for other applications which would benefit from hybrid molecules that can target duplexes.

Silver (I) cation specifically stabilizes heteroduplex with C:C mismatch base pair: toward the efficient detection of single nucleotide polymorphism (2).

We examined the effect of silver (I) cation on the thermal stability of heteroduplex and homoduplex. Addition of silver (I) cation increased the melting temperature of heteroduplex containing C:C mismatch base pair by about 3-4 degrees C. The thermal stability of homoduplex and heteroduplexes containing other kinds of mismatch base pairs was not significantly changed by the addition of silver (I) cation. We conclude that silver (I) cation specifically stabilizes heteroduplex containing C:C mismatch base pair. Our results certainly support the idea that the addition of silver (I) cation to C:C mismatch base pair in heteroduplex could be a convenient strategy for heteroduplex analysis and may eventually lead to progress in single nucleotide polymorphism genotyping.

Thermodynamic analyses of the specific interaction between T:T mismatch base pair and mercury (II) cation: toward the efficient detection of single nucleotide polymorphism (1).

We examined the effect of mercury (II) cation on the thermal stability of heteroduplex and homoduplex. Addition of mercury (II) cation increased the melting temperature of heteroduplex containing T:T mismatch base pair by about 4 degrees C. The thermal stability of homoduplex and heteroduplexes containing other kinds of mismatch base pairs was not significantly changed by the addition of mercury (II) cation. Isothermal titration calorimetric study demonstrated that mercury (II) cation directly bound to T:T mismatch base pair in hcteroduplex at a molar ratio of 1:1. The binding constant and the enthalpy change for the binding of mercury (II) cation to T:T mismatch base pair was approximately 10(6) M(-1) and -6 kcal mol(-1), respectively. We conclude that mercury (II) cation directly binds to T:T mismatch base pair in heteroduplex with high affinity and specificity. Our results certainly support the idea that the addition of mercury (II) cation to T:T mismatch base pair in heteroduplex could be a convenient strategy for heteroduplex analysis and may eventually lead to progress in single nucleotide polymorphism genotyping.

Drug-induced stabilisation of a mismatched C-T base pair in a DNA hairpin.

We have shown that a key feature of drug binding, namely specific G-C base pair recognition at a 5'-TG step, can induce a number of novel structural features when an extrahelical base is inserted in close proximity to the drug binding site; we have clearly demonstrated the formation of a stabilised C-T mismatched base pair at a non-terminal site.

Photo-oxidation of duplex DNA with the stable trioxatriangulenium ion.

We show that 5'-Gs in 5'-GG-3' duplex DNA dinucleotide steps are preferentially oxidized by the trioxatriangulenium ion (TOTA( plus sign in circle )) upon photo-activation, an oxidation pattern characteristic of guanine radical cation formation. Some photo-oxidation of the 3'G in 5'GG3' steps and of isolated guanines is also observed but reactions carried out in D(2)O reveal only a minor increase in oxidation damage at these sites, indicating that electron transfer is the primary mechanism of guanine oxidation.

Mechanistic aspects of CoII(HAPP)(TFA)2 in DNA bulge-specific recognition.

A novel octahedral complex CoII(HAPP)(TFA)2 [hexaazaphenantholine-cyclophane (HAPP), trifluoroacetate (TFA)] is a DNA bulge-specific probe with single-strand DNA cleavage activity in the presence of H2O2. This complex exhibits low affinity towards double-stranded DNA and low reactivity toward single-stranded DNA. Metal-HAPP complexes with different coordination number and ring size were synthesized and their selectivity and reactivity for DNA bulges were compared. The DNA sequence at the bulge site influences the intensity of cleavage at the bulge and the flanking sites after piperidine treatment. Cleavage specificity of CoII(HAPP)(TFA)2 was characterized extensively using scavenger reagents to quench the cleavage reaction and high-resolution polyacrylamide gel electrophoresis. In addition, 3'-phosphoglycolate cleavage products were trapped and analyzed by matrix-assisted laser desorption ionization time-of-flight mass spectrometry. These data were used to deduce that the DNA cleavage pathway for CoIIHAPP2+ in the presence of H2O2 involves 4'-H abstraction of the deoxyribose moiety.

Antitumor polycyclic acridines. Part 12. Physical and biological properties of 8,13-diethyl-6-methylquino[4,3,2-kl]acridinium iodide: a lead compound in anticancer drug design.

The biophysical and biological characterization of 8,13-diethyl-6-methylquino[4,3,2-k]lacridinium iodide (6) is reported. The compound binds to DNA, as measured by UV, fluorescence, and circular dichroism studies, and stabilizes the double helix and higher order DNA structures (DNA triplexes and quadruplexes) against thermal denaturation. Unlike many DNA ligands, (6) shows no specificity for binding to specific base pair combinations and does not inhibit topoisomerase I (topo I) or topo II activity. Furthermore, the biological fingerprint elicited by (6) in in vitro evaluations does not compare with clinical agents of the topo II inhibition class. The compound provokes cell cycle arrest in response to DNA damage and the biological sequelae are dependent on the p53 status of the cell line. DNA damage by (6) upregulates p53 and p21(CIP/WAF1) proteins. The unusual structure of (6) and its ease of synthesis in a "one-pot" reaction are features that are being exploited in the design and development of a new series of G-quadruplex stabilizing telomerase inhibitors. However, although the second-generation compounds that resulted from (6) present strong telomerase inhibition, (6) in itself presents yet a different mode of action, with a strong preference for triplex DNA, sequences often found in a number of genes.

Evidence that a burst of DNA depurination in SENCAR mouse skin induces error-prone repair and forms mutations in the H-ras gene.

Treatment of SENCAR mouse skin with dibenzo[a,l]pyrene results in abundant formation of abasic sites that undergo error-prone excision repair, forming oncogenic H-ras mutations in the early preneoplastic period. To examine whether the abundance of abasic sites causes repair infidelity, we treated SENCAR mouse skin with estradiol-3,4-quinone (E(2)-3,4-Q) and determined adduct levels 1 h after treatment, as well as mutation spectra in the H-ras gene between 6 h and 3 days after treatment. E(2)-3,4-Q formed predominantly (> or =99%) the rapidly-depurinating 4-hydroxy estradiol (4-OHE(2))-1-N3Ade adduct and the slower-depurinating 4-OHE(2)-1-N7Gua adduct. Between 6 h and 3 days, E(2)-3,4-Q induced abundant A to G mutations in H-ras DNA, frequently in the context of a 3'-G residue. Using a T.G-DNA glycosylase (TDG)-PCR assay, we determined that the early A to G mutations (6 and 12 h) were in the form of G.T heteroduplexes, suggesting misrepair at A-specific depurination sites. Since G-specific mutations were infrequent in the spectra, it appears that the slow rate of depurination of the N7Gua adducts during active repair may not generate a threshold level of G-specific abasic sites to affect repair fidelity. These results also suggest that E(2)-3,4-Q, a suspected endogenous carcinogen, is a genotoxic compound and could cause mutations.

Induction of duplex to G-quadruplex transition in the c-myc promoter region by a small molecule.

A major control element of the human c-myc oncogene is the nuclease-hypersensitive purine/pyrimidine-rich sequence. This double-stranded DNA fragment, corresponding to the 27-base pair segment in the nuclease-hypersensitive element of the c-myc promoter region, forms a stable Watson-Crick double helix under physiological conditions. However, this duplex DNA can be effectively converted to G-quadruplex DNA by a small molecular weight ligand. Both intermolecular and intramolecular G-quadruplex forms can be induced by this ligand. Similar transitional changes are also observed with the duplex telomeric sequence from the Oxytricha species. These results provide additional support to the idea that G-quadruplex structures may play structural roles in vivo and also provide insight into novel methodologies for rational drug design. These structurally altered DNA elements might serve as regulatory signals in gene expression or in telomere dynamics and hence are promising targets for drug action.

Sequence specificity of Hprt lymphocyte mutation in rats fed the hepatocarcinogen 2-acetylaminofluorene.

Rats fed the hepatocarcinogen 2-acetylaminofluorene (2-AAF) have a low, but significantly increased, frequency of lymphocyte Hprt mutants. In this study, mutants from 2-AAF-fed and control F344 rats were examined for mutations in the Hprt gene in order to determine if the 2-AAF treatment resulted in an agent-specific mutation profile. The most common mutation from 2-AAF-treated rats was G:C-->T:A transversion (32% of all mutations) followed by 1-basepair (bp) deletion (19%); there were very few (5%) G:C-->A:T transitions. Among mutations from control rats, G:C-->A:T transition was the most common (43%), and there were very few G:C-->T:A transversions (5%) and no 1-bp deletions. The profile of mutations from 2-AAF-fed rats was significantly different from control rats (P = 0.003) and was consistent with the types of mutations produced by 2-AAF in vitro. The results of this study indicate that even weak mutational responses in the lymphocyte Hprt assay are capable of producing mutation profiles that reflect the DNA damage inducing them.

Modified (PNA, 2'-O-methyl and phosphoramidate) anti-TAR antisense oligonucleotides as strong and specific inhibitors of in vitro HIV-1 reverse transcription.

Natural beta-phosphodiester 16mer and 15mer antisense oligonucleotides targeted against the HIV-1 and HIV-2 TAR RNAs respectively were previously described as sequence-specific inhibitors of in vitro retroviral reverse transcription. In this work, we tested chemically modified oligonucleotide analogues: alpha-phosphodiester, phosphorothioate, methylphosphonate, peptide nucleic acid or PNA, 2'- o -methyl and (N3'-P5') phosphoramidate versions of the 16mer anti-TAR oligonucleotide. PNA, 2'- O -methyl and (N3'-P5') phosphoramidate oligomers showed a strong inhibitory effect compared with the unmodified 16mer, with reverse transcription inhibition (IC50) values in the nanomolar range. The inhibition was sequence-specific, as scrambled and mismatched control oligonucleotides were not able to inhibit cDNA synthesis. No direct binding of the 2'- O -methyl, PNA or (N3'-P5') phosphoramidate anti-TAR oligonucleotides to the HIV-1 reverse transcriptase was observed. The higher T m obtained with 2'- O -methyl, (N3'-P5') phosphoramidate and PNA molecules concerning the annealing with the stem-loop structure of the TAR RNA, in comparison with the beta-phosphodiester oligonucleotides, is correlated with their high inhibitory effect on reverse transcription.

The impact of an exocyclic cytosine adduct on DNA duplex properties: significant thermodynamic consequences despite modest lesion-induced structural alterations.

The exocyclic base adduct 3,N4-deoxyethenocytosine (epsilonC) is a common DNA lesion that can arise from carcinogen exposure and/or as a biproduct of cellular processes. We have examined the thermal and thermodynamic impact of this lesion on DNA duplex properties, as well as the structural alterations imparted by the lesion. For these studies, we used calorimetric and spectroscopic techniques to investigate a family of 13-mer DNA duplexes of the form (5'CGCATGNGTACGC3')x(3'GCGTACNCATGCG5'), where the central NxN base pair represents the four standard Watson-Crick base pairs (corresponding to four control duplexes), and where either one of the N bases has been replaced by epsilonC, yielding eight test duplexes. Studies on these 12 duplexes permit us to assess the impact of the epsilonC lesion as a function of sequence context. Our spectroscopic and calorimetric data allow us to reach the following conclusions: (i) The epsilonC lesion imparts a large penalty on duplex stability, with sequence context only modestly modulating the extent of this lesion-induced destabilization. This result contrasts with our recent studies of duplexes with abasic sites, where sequence context was found to be the predominant determinant of thermodynamic damage. (ii) For the epsilonC-containing duplexes, sequence context effects are most often observed in the enthalpic contribution to lesion-induced duplex destabilization. However, due to compensating entropies, the free energy changes associated with this lesion-induced duplex destablization are nearly independent of sequence context. (iii) Despite significant lesion-induced changes in duplex energetics, our spectroscopic probes detect only modest lesion-induced changes in duplex structure. In fact, the overall duplex maintains a global B-form conformation, in agreement with NMR structural data. We discuss possible interpretations of the apparent disparity between the severe thermodynamic and relatively mild structural impacts of the epsilonC lesion on duplex properties. We also note and discuss the implications of empirical correlations between biophysical and biological properties of lesion-containing duplexes.

Differential effects of camptothecin derivatives on topoisomerase I-mediated DNA structure modification.

The effects of eleven camptothecin derivatives on calf thymus topoisomerase I-mediated cleavage of synthetic DNA duplex have revealed that the A ring of camptothecin is very important for its biochemical activity. Depending on the type, number, and location of substituents, highly active or inactive analogues were obtained. The persistence of CPT-induced topoisomerase I-DNA covalent binary complexes was investigated by using as substrates DNA containing several good topoisomerase I cleavage sites, or else a synthetic DNA duplex of defined structure with a single high-efficiency cleavage site. The ligation kinetics at a given topoisomerase I cleavage site were sometimes quite different in the presence of CPT derivatives whose structures were closely related. Even in the presence of a single CPT analogue, topoisomerase I-DNA covalent binary complexes underwent ligation with different kinetics, presumably reflecting a dependence on DNA sequences flanking the individual topoisomerase I cleavage sites. Individual camptothecin derivatives also exhibited a spectrum of inhibitory potentials in blocking the topoisomerase I-mediated rearrangement of branched, nicked, and gapped DNA duplex substrates; in some cases the potencies of inhibition observed in these assays for individual camptothecin analogues were quite different than those determined for stabilization of the unmodified DNA-topoisomerase I binary complex.

Effect of mismatched complementary strands and 5'-change in sequence context on the thermodynamics and structure of benzo[a]pyrene-modified oligonucleotides.

Benzo[a]pyrene (B[a]P) is a well-studied environmental carcinogen that when activated can react with DNA to form four major adducts: (+)-trans-, (-)-trans-, (+)-cis-, and (-)-cis-anti-B[a]P-dG. In this study, two oligonucleotides (5'-dCCATT-GB[a]P-CTACC-3' and 5'-dCCATC-GB[a]P-CTACC-3') were prepared, each containing the four isomeric adducts, and these were hybridized to either complementary sequences or to sequences containing an A, G, or T opposite the adducted guanine. Thermal melting curves, CD, and UV spectra of each duplex were measured and compared with the unmodified counterpart. The raw and relative thermodynamic measurements were then compared which indicated that differences occur that are both adduct and sequence dependent. These differences were next compared with the in vitro DNA polymerase incorporation data and were found to be strikingly correlated. Most significantly, for all four B[a]P isomers a mismatch of an A across from the adduct resulted in the least amount of relative destabilization, while the Watson-Crick complement C showed the most; in vitro studies showed that A is the preferred base incorporated across from each isomer, while C was incorporated least often. This observed correlation suggests that one factor contributing to misincorporation at an adduct site is the thermodynamic stability of the incorporated base. Structurally, the effect of sequence context and mismatched complementary strands were also compared, suggesting that all adducts tend to intercalate within the helix when they are complemented with a mismatched complementary strand. In addition, the level of this intercalation seems to be both sequence and stereoisomer dependent.

Selectivity of F8-actinomycin D for RNA:DNA hybrids and its anti-leukemia activity.

Although many compounds have been found that bind to DNA in various ways and exhibit various biological activities, few compounds that specifically bind to RNA or RNA:DNA hybrids are known, even though such compounds are expected to have important biological properties. For example, one characteristic function of the retroviruses, which is generally not found in eukaryotic cells, is the production of an RNA:DNA hybrid in the viral replication phase. If an agent is designed to bind only to an RNA:DNA hybrid, and not to DNA or to RNA, such an agent might be able to inhibit specifically the RNase H activity of retroviral reverse transcriptase, and therefore suppress viral replication. Actinomycin D is known to bind to double-stranded DNA, but not to RNA, because steric hindrance between the 2-amino group of the phenoxazone ring and the 2'-hydroxyl group of RNA prevents intercalation of the compound. However, if the > C-H moiety at the 8-position of the phenoxazone ring is replaced by a > C-F, a possible hydrogen-bond acceptor, this analogue (8-fluoro-actinomycin D, F8AMD) might be able to bind intercalatively to an RNA:DNA hybrid by forming an additional hydrogen bond between F8 and the 2'-hydroxyl group of the guanosine ribose. To test this hypothesis, the crystal structure of d(GAAGCTTC)2-F8AMD has been determined at 3.0 A resolution. Based on this crystal structure, a model in which F8AMD binds into the hybrid r(GAAGCUUC):d(GAAGCTTC) has been built using molecular mechanics and dynamic methods. These structural studies indicate that F8AMD binds intercalatively to a B-form double-stranded DNA whereas the drug intercalates into an RNA:DNA hybrid taking an A-form conformation. In the RNA:DNA hybrid complex, the F8 atom is located so as to be able to interact to an O2' hydroxyl group with either an O-H...F hydrogen bond or H+...F- electrostatic interaction. This interaction might stabilize the F8AMD molecule in the RNA:DNA hybrid. A binding study indicates that both actinomycin D (AMD) and F8AMD bind intercalatively not only to double-stranded DNAs, but also to RNA:DNA hybrids. Although the overall binding capacity of F8AMD (k = 4.5 x 10(5) M-1) is reduced slightly in comparison with AMD itself (k = 1.8 x 10(6) M-1), F8AMD tends to bind relatively more favorably than AMD to the RNA:DNA hybrids. The drugs' effects on RNA synthesis in HeLa cells indicates that the binding capacities of AMD and F8AMD correlates strongly to their RNA synthesis inhibitory activities. F8AMD required a concentration of 78 nM to inhibit RNA polymerase activity in HeLa cells by 50%, whereas AMD reached the same inhibitory level at 30 nM. Surprisingly, F8AMD exhibits unique selectivity against leukemia cells as does another C8-derivatized AMD analogue, N8AMD. F8AMD inhibits 50% of leukemia cell growth at less than 1.0 nM whereas 10- to 130-fold-higher drug concentrations are required to inhibit the growth of other tumor cell lines by 50%. The GI50 value of F8AMD for leukemia cells is the lowest among the GI50 values for all other AMD derivatives tested. By contrast, AMD is quite potent and kills most cells at less than 50 nM concentration, but it does not show any selectivity for certain cell lines. This indicates that AMD should have very limited use as an antitumor agent. It is difficult to rationalize why F8AMD and N8AMD show such strong selectivity against leukemia cells. However, this study and our previous study (J. Am. Chem. Soc. 1994, 116, 7971) indicated that F8AMD and N8AMD tended to bind more favorably to RNA:DNA hybrids. Thus, the unique antileukemia selectivity shown by F8AMD and N8AMD might be used by the agents binding to RNA:DNA hybrids rather than to double-stranded DNA.

Structural transitions of a GG-platinated DNA duplex induced by pH, temperature and box A of high-mobility-group protein 1.

[1H, 15N] and 1H NMR, and CD spectroscopy are used to show that the duplex d(A-T-A-C-A-T-Pt 7G-Pt7G-T-A-C-A-T-A).d(T-A-T-G-T-A-C-C-A-T-G-T-A-T), where Pt7G is platinated guanine, containing the cis-[Pt(NH3)2]2+ adduct, undergoes reversible temperature-induced (T0.5 310 K) and pH-induced (pKa approximately 4.8) transitions between kinked-duplex and distorted forms, with the latter forms predominating at high temperature and low pH. A related pH-induced structural change was observed for the unplatinated duplex (pKa 4.69, Hill coefficient n = 1.4) but was less cooperative than for the platinated duplex (n = 2). The pH-induced transition is attributed to protonation of cytosine residues and has wider implications, since many reported NMR studies of DNA are carried out near pH 5 to minimize NH-exchange rates. The [Pt(en)]2+ (where en is 1,2-ethanediamine) GG chelate of the same duplex is shown to exist in kinked and distorted forms, and the [1H,15N]-NMR shifts for the kinked form are indicative of the presence of highly stereospecific interactions with the Pt-NH protons. On binding of the duplex platinated with [Pt(NH3)2]2+ to high-mobility-group protein 1 (HMG1) box A, similar changes in shifts of the Pt-NH3 resonances to those induced by raising the temperature or lowering the pH were observed. The specific changes in 1H-NMR chemical shifts of HMG1 box A are consistent with binding of the platinated duplex (intermediate exchange rate on the 1H-NMR time-scale) to the concave face of the protein via helices I and II and the intervening loop.

NMR data show that the carcinogen N-2-acetylaminofluorene stabilises an intermediate of -2 frameshift mutagenesis in a region of high mutation frequency.

The heteroduplex, D(ACCGGCGCCACA) . d(TGTGG-CCGGT), containing two bulged bases, a cytosine and the guanine G7, either unmodified or modified with the carcinogen N-2-acetylaminofluorene, have been studied by NMR as models of slipped-mutagenic intermediates (SMI). The melting temperature of the modified heteroduplex is strongly increased compared with that of the unmodified heteroduplex. NMR studies have shown that all the bases of the unmodified heteroduplex are stacked within the helix, without any disruption of the sequential connectivities. The two strands are in a B-like conformation. Nevertheless, exchangeable-proton studies have revealed that base pairing is very weak, or even lacking, over two base pairs apart from the bulge. Concerning the modified heteroduplex, no B-like connectivity is observed in the G5-C9 segment. Moreover, the cytosine C8 is rejected outside the helix, whereas the N-2-acetylaminofluorene moiety is inserted within the helix. The G5.C18, C6.G17 and C9.G16 bases are remarkably stable when the temperature is increased, in agreement with the high melting temperature. Some small unassigned peaks reveal the presence of the minor conformation in equilibrium. The strong stabilisation of the N-2-acetylaminofluorene-modified heteroduplex compared with the unmodified duplex is in agreement with the high N-2-acetylaminofluorene-induced mutation frequency compared with the spontaneous frequency and with the hypothesis of mutagenesis occurring during replication.

Base sequence-dependent bends in site-specific benzo[a]pyrene diol epoxide-modified oligonucleotide duplexes.

The site specifically modified oligonucleotides 5'-d(TCCTCCTG1G2CCTCTC) (I) and 5'-d(CTATG1G2G3TATC) (II) were synthesized with single modified guanine residues at positions G1, G2, or G3, derived from the covalent binding reaction of 7R,8S-dihydroxy-9S,10R-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene ((+)-anti-BPDE) with the exocyclic amino groups of the guanine residues. In denaturing 20% polyacrylamide gels, the electrophoretic mobilities of the (+)-anti-BPDE-modified oligonucleotides I and II are slower than the mobilities of the respective unmodified oligonucleotides and independent of the positions of the BPDE-modified guanines. However, in the double-stranded forms in native 8% polyacrylamide gels, the electrophoretic mobilities of the duplexes with lesions at G2 or G3 are remarkably slower (reductions in mobilities up to approximately 40%) than to duplexes with lesions at G1 and are attributed to physical bends or flexible hinge joints at the sites of the BPDE lesions. These sequence-dependent mobility effects occur whenever the BPDE-modified guanine residues with (+)-trans-stereochemistry are flanked by unmodified G's on the 5'-side. These retarded electrophoretic mobilities are attributed to bending induced by steric hindrance effects involving the bulky 5'-flanking guanines and the pyrenyl residues that are known to point into the 5'-direction relative to the modified G [Cosman, M., et al. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 1914-1918]. These anomalous electrophoretic mobility effects are not observed in the case of (-)-anti-BPDE-modified sequences I with trans-(-)-anti-BPDE-N2-dG adduct stereochemistry.