Structure of a nonanucleotide duplex cross-linked by cisplatin at an ApG sequence

 The structure of the second major adduct formed by the antitumor drug cisplatin with DNA, the intrastand cis–Pt(NH₃)₂{d(ApG)N7–N7} chelate (A*G*), has been investigated using a double-stranded nonanucleotide, d(CTCA*G*CCTC)-d(GAGGCTGAG), by means of NMR and molecular modeling. The NMR data allow us to conclude that the oligonucleotide is kinked at the platinated site towards the major groove in a way similar to that observed elsewhere for the G*G*-crosslink in d(GCCG*G*ATCGC)-d(GCGATCCGGC). The main difference concerns the position of the thymine T(15) complementary to the platinated adenine A*(4). It remains stacked on its 5′-neighbor C(14), corresponding to the "model E" described previously, whereas in the G*G*-adduct, the cytosine facing the 5′-G* was found to oscillate between the 5′-branch ("model E") and the 3′-branch ("model C") of the complementary strand. Two "E-type" models are presented which account for the particular NOE connectivity and for two remarkable upfield NMR signals: those of the H2′ proton of the cytidine C(3) 5′ to the A*G* chelate, and of the H3 imino proton of T(15), the base complementary to A*(4). The former shift is attributed to shielding by the destacked A*(4) base, whereas the latter is accounted for by a swinging movement of the T(15) base between two positions where the imino Watson-Crick hydrogen bond with A*(4) remains intact and the amino hydrogen bond is disrupted, or vice versa. Possible implications of the structural difference between the AG and GG adducts of cisplatin in the mutagenic properties of the two adducts are discussed. Received: 19 August 1996 / Accepted: 4 November 1996     

Nuclear magnetic resonance studies on oligo-deoxyribonucleotides containing thedam methylation site GATC. Adenine methylation of d(GGATCC) does not change the helix geometry

We have studied the conformation of two hexanucleotides d(GGATCC) and d(GGm⁶ATCC) using proton nuclear magnetic resonance. Nuclear Overhauser effect measurements show that d(GGATCC) assumes a normal right handed B helix. The single and double strand resonances are in fast exchange on a proton nuclear magnetic resonance time scale. For d(GGm⁶ATCC), up to the Tm separate resonances are observed for each state, indicating slow exchange, though above the Tm it becomes more rapid. The orientation of the adenosine methyl-amino group, preferentiallycis to N¹, hinders base pair formation.The connectivities of the resonances of the two states were established by saturation transfer experiments. At 0°C irradiation of the m⁶ A-T imino proton gives an nuclear Overhauser effect to AH² showing that base pairing is Watson-Crick. Intra and interresidue nuclear Overhauser effects starting from the 3′ terminus show that the helix is right handed and in the B-form.The results on the two oligomers demonstrate that adenosine methylation induces little or no change in the conformation of the helix, but reduces the Tm from 45° to 32°C and slows the opening and closing of the m₆A.T base pair by a factor of about 100.     

A Theoretical Model for the Binding of Cis-Pt(NH3)2 +2 to DNA

Abstract

The binding of cis-Pt(NH₃)₂B₁B2 to the bases B₁ and B₂, i.e., guanine (G), cytosine (C), adenine (A), and thymine (T), of DNA is studied theoretically. The components of the binding are analyzed and a model structure is proposed for the intrastrand binding to the dB,pdB₂ sequence of a kinked double helical DNA. Quantum mechanical calculations of the ligand binding energy indicates that cw-Pt(NH₃)₂ ⁺² (cis-PDA) binds to N7(G), N3(C), 02(C), 06(G), N3(A), N7(A), 04(T) and 02(T) in order of decreasing binding energy. Conformational analysis provides structures of kinked DNA in which adjacent bases chelate to cis-PDA. Only bending toward the major groove allows the construction of acceptable square planar complexes. Examples are presented for kinks of ?70° and ?40° at the receptor site to orient the base pairs for ligand binding to B, and B₂ to form a nearly square planar complex. The energies for complex formation of cis-PDA to the various intra-strand base sites in double stranded DNA are estimated. At least 32 kcal/mole separates the energetically favorable dGpdG·cis-PDA chelate from the dCpdG·cis-PDA chelate. All other possible chelate structures are much higher in energy which correlates with their lack of observation in competition with the preferred dGpdG chelate.

The second most favorable ligand energy occurs with N3(C). A novel binding site involving dC(N3)pdG(N7) is examined. Denaturation can result in an anti ? syn rotation of C about its glycosidic bond to place N3(C) in the major groove for intrastrand binding in duplex DNA. This novel intrastrand dCpdG complex and the most favored dGpdG structure are illustrated with stereographic projections.     

Chemical, structural and biological studies of cis-[Pt(3-Acpy)2Cl2]

Recent developments in the field of platinum anticancer drugs have revealed that compounds containing derivates of pyridine may exhibit highly cytotoxic activity against a variety of tumor cells, with AMD473 (cis-PtCl₂(NH₃)(2-methylpyridine)) as one of the most relevant examples. Following these advances, this paper describes the synthesis, characterization and X-ray structure of the square-planar compound cis-[Pt(3-Acpy)₂Cl₂] (1, Acpy stands for acetylpyridine), where the coordination of 3-acetylpyridine takes places through the pyridine nitrogen of the ligand. The structural arrangement of this compound is highly peculiar and it is the first example with two of these 3-acetylpyridine molecules in a cis disposition. In addition, the anticancer and antibacterial activities of this compound together with studies of DNA binding are also described in detail, with selective activity of compound 1 against A2780R cells. cis-[Pt(3-Acpy)₂Cl₂] apparently coordinates to the DNA double helix upon exchange of at least one of the Cl⁻ ions with the media and shows very interesting bacteriolytic and bacteriostatic activity against Escherichia coli and Streptomyces, respectively.     

Structural consequences of a 3′ → 3′ DNA interstrand cross-link by a trinuclear platinum complex: unique formation of two such cross-links in a 10-mer duplex

Combined multidimensional nuclear magnetic resonance spectroscopy and electrospray mass spectrometry was used to analyze the platinated DNA adduct of the phase II anticancer drug [{trans-PtCl(NH₃)₂}₂-μ-{trans-Pt(NH₃)₂(NH₂(CH₂)₆NH₂)₂}](NO₃)₄ (BBR3464) with [5′-d(ACG*TATACG*T)-3′]₂. Two 1,2-interstrand cross-links were formed by concomitant binding of two trinuclear moieties to the oligonucleotide. The four DNA-bound platinum atoms coordinated in the major groove at N7 positions of guanines in the 3′ → 3′ direction and the central platinum unit is expected to lie in the DNA minor groove. This is the first report of such a DNA lesion. The melting temperature of the adduct is 76 °C and is 42 °C higher than that of the unplatinated DNA. The sugar residues of the platinated bases are in the N-type conformation and the G9 nucleoside is in the syn orientation, while the G3 nucleoside appears to retain the anti configuration. The secondary structure of DNA was significantly changed upon cross-linking of the two BBR3464 molecules. Base destacking occurs between A1/C2 and C2/G3 and weakened stacking is seen for the C8/G9 and G9/T10 bases. The lack of Watson–Crick base pairing is also seen for A1–T10 and C2–G9 base pairs, whereas Watson–Crick base pairs in the central sequence of the DNA (T4 → A7) are well maintained. While DNA repair proteins may “see” different platinated adducts as bulky “lesions”, the subtle differences involved in base pairing and stacking, as summarized here, may extend to their role as a substrate for repair enzymes. Thus, differences in protein recognition and repair efficiency among the various interstrand cross-links are likely and a subject worthy of detailed exploration. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Crystal and Molecular Structure of the Sodium Salt of the Dinucleotide Duplex d(CpG)

Abstract

The crystal and molecular structure of the sodium salt of deoxycytidylyl-{3′ ?5′)-deoxyguanosine has been determined from X-ray diffraction data. The crystals, obtained from an aqueous y- butyrolactone solution at pH = 5.3, are orthorhombic, P2₁2₁2₁, a= 10.640(2), b= 11.184(2) and c=44.618(4) A. The structure was refined to an R = 0.041. The d(CpG) structure is similar to the ammonium salt solved by Cruse et al.(1). Both structures form a parallel self base paired mini-double helix. In d(CpG).Na⁺, one of the two paired cytosines is protonated on N(3). The cytosines form 3 hydrogen bonds while the guanines form only 2. The Na⁺ ion is coordinated with five groups: two water molecules, 0(6) of guanine A, N(7) of guanine B and 0(5′) of cytosine B, forming a square pyramid. The hydration shell around the mini-helix is analysed and compared with that of the ammonium salt. d(CpG).Na⁺ is the second d(CpG) oligonucleotide found with a self base pairing arrangement despite of the fact that the crystallization conditions and counterion were different in both cases. The hypothesis that self base pairing is not only a crystallization artifact but may play a role under physiological conditions as a source of transversion mutations is discussed.     

Conformational preferences of modified nucleoside N(2)-methylguanosine (m(2)G) and its derivative N(2), N(2)-dimethylguanosine (m(2)(2)G) occur at 26th position (hinge region) in tRNA

Conformational preferences of the modified nucleosides N²-methylguanosine (m²G) and N², N²-dimethylguanosine (m₂²G) have been studied theoretically by using quantum chemical perturbative configuration interaction with localized orbitals (PCILO) method. Automated complete geometry optimization using semiempirical quantum chemical RM1, along with ab initio molecular orbital Hartree–Fock (HF-SCF), and density functional theory (DFT) calculations has also been made to compare the salient features. Single-point energy calculation studies have been made on various models of m²G26:C/A/U44 and m₂²G26:C/A/U44. The glycosyl torsion angle prefers “syn” (χ = 286°) conformation for m²G and m₂²G molecules. These conformations are stabilized by N(3)–HC2′ and N(3)–HC3′ by replacing weak interaction between O5′–HC(8). The N²-methyl substituent of (m²G26) prefers “proximal” or s-trans conformation. It may also prefer “distal” or s-cis conformation that allows base pairing with A/U44 instead of C at the hinge region. Thus, N²-methyl group of m²G may have energetically two stable s-trans m²G:C/A/U or s-cis m²G:A/U rotamers. This could be because of free rotations around C–N bond. Similarly, N², N²-dimethyl substituent of (m₂²G) prefers “distal” conformation that may allow base pairing with A/U instead of C at 44th position. Such orientations of m²G and m₂²G could play an important role in base-stacking interactions at the hinge region of tRNA during protein biosynthesis process.     

Parallel nucleic acid helices with hoogsteen base pairing: Symmetry and structure

Molecular structures for parallel DNA and RNA double helices with Hoogsteen pairing are proposed for the first time. The DNA helices have sugars in the C2′-endo region and the phosphodiester conformations are (trans, gauche^?), and the RNA helices have sugars in the C3′-endo region and the phosphodiester conformations are (gauche^?, gauche^?). A pseudorotational symmetry relates the two parallel strands of DNA helices and a screw symmetry relates the two strands of RNA helices, which have an associated tilt of the The conformational space of parallel helices with Hoogsteen base pairing, unlike the Watson-Crick duplex, is highly restricted due to the unique positioning of the symmetry axis in the former case. The features of the parallel double helix with Hoogsteen pairing are compared with the Watson-Crick duplex and the corresponding triple helix. © 1994 John Wiley & Sons, Inc.     

13C- and 1H-nmr evidence for all-cis peptide bonds in cyclic tetrapeptide cyclo(L-Pro-Sar)2

Conformations of the cyclic tetrapeptide cyclo(L -Pro-Sar)₂ in solution were studied by ¹H- and ¹³C-nmr spectrometry and model building. The nmr data provide definite evidence that this cyclic peptide exists chiefly in two conformations, namely, a C₂-symmetric conformation and an asymmetric structure. The former was demonstrated to be predominant in polar solvents (100% in Me₂SO-d₆). This structure contains all cis-peptide bond linkages and all trans′ Pro C^α?CO bonds. It represents the first cyclic tetrapeptide in which all four peptide bonds have been found in the cis-conformation. As the polarity of the solvent decreases, the population of C₂-symmetric conformers decreases (88% in CD₃CN and 65% in CDCl₃). At the same time, a minor asymmetric conformer, characterized by cis-cis-cis-trans peptide bond sequences (two cis Sar-Pro bonds, one cis Pro-Sar bond, and one trans Pro-Sar bond), is seen to increase (9% in CD₃CN and 30% in CDCl₃). A proposed predominant conformation in solution for cyclo(L -Pro-Sar)₂ was compared with a crystal structure, as reported in an accompanying paper. Both structures show striking overall similarities.     

Author index to volume 175

500 MHz ¹H-NMR and NOE measurements of d(GGATCC) and d(GGm⁶ATCC) show that both oligo-nucleotides assume a B-DNA conformation at low temperature. Around the melting temperature, however, the single and double strands of the N-methylated form are in slow exchange on the NMR time scale. The preferred conformation of the adenine methyl group, cis to N¹, retards base pairing and also destabilizes the double helix.     

Characterisation of cisplatin coordination sites in cellular <Emphasis Type="Italic">Escherichia coli</Emphasis> DNA-binding proteins by combined biphasic liquid chromatography and ESI tandem mass spectrometry

Combined multidimensional liquid chromatography and electrospray ionisation tandem mass spectrometry was employed to analyse platinated tryptic peptides from Escherichia coli cells treated with the anticancer drug cis-[PtCl₂(NH₃)₂] at pH 7.0. Prerequisites for the LC/LC/MS/MS analysis of protein targets that are fulfilled by cisplatin are (a) that the original protein binding sites have a high kinetic stability over the range 2.3 < pH < 8.5, and (b) that the metal fragment remains coordinated to a significant number of b⁺ and y⁺ peptide ions under MS/MS fragmentation conditions. Matching the MS/MS spectra of the platinated tryptic peptides to sequences of proteins in the E. coli database enabled the identification of 31 protein targets for cisplatin. Whereas six of these are high-abundance enzymes and ribosomal proteins in E. coli cells, five low-abundance DNA-binding proteins were also identified as specific targets. These include the DNA mismatch repair protein mutS, the DNA helicase II (uvrD) and topoisomerase I (top1). Two efflux proteins (acrD, mdtA), the redox regulator thioredoxin 1 (thiO) and the external filament-like type-1 fimbrial protein A chain (fimA1) were also characterised as specific cisplatin-binding proteins. Kinetically favoured carboxylate (D, E) and hydroxy (S, T, Y) O atoms were identified as the Pt coordination sites in 18 proteins and methionyl S atoms in 9 proteins.     

A Kinked Model for the Solution Structure of DNA Tridecamers with Inserted Adenosines: Energy Minimization and Molecular Dynamics

Abstract

Structural modelling techniques using energy minimization and molecular dynamics have been employed to generate kinked models for the solution structure of two DNA tridecamer sequences containing inserted adenosines: d(CGCAGAATTCGCG)₂ and d(CGCAGAGCTCGCG)₂. These models are consistent with NMR studies of these sequences in solution. The overall shapes of the two models are similar, consisting of three B-DNA sections: two outer segments on the same side of the central portion, with the additional adenosines acting as wedges to kink the structure. An alternative scheme for the hydrogen bond pairing at the kink site is suggested as a way for the additional adenosines to be stabilized in the duplex.     

A triple-helical model for (Gly-Pro-Hyp)n with cis peptide units

Synthetic regular polytripeptides of the type (Gly-R₂-R₃) where R₂, R₃, or both, are imino acids have been widely studied as model compounds for collagen. One such polytripeptide is poly(Gly-Pro-Hyp), since triplets with this sequence constitute about 10% of collagen. Recently, a new model has been proposed for this polytripeptide in which one of the three peptide bonds in the tripeptide unit is in the cis conformation, and the γ-hydroxyl group of hydroxyproline forms a direct interchain hydrogen bond within the triple helix. We have confirmed this structure by model building using computer techniques, and the helical parameters obtained by us are close to the experimentally observed values. The model is also found to be comparable in stability with other models from energy considerations.     

A high melting cis-[Pt(NH3)2[d(GpG)]]adduct of a decanucleotide duplex

The [cis-Pt(NH3)2(d(GCCGGATCGC)-N7(4), N7(5))]-d(GCGATCCGGC) duplex has been prepared with Tm = 49 degrees C (vs 58 degrees C for the unplatinated form). NMR of the ten observable imino protons supports a kinked structure with intact base pairing of the duplex on the 3'-side of the d(GpG).cis-Pt chelate (relative to the platinated strand) The modification of the B-DNA type CD spectrum, due to the platinum chelate, is comparable to that observed for the platination (at a 0.05 Pt:base ratio) of the Micrococcus Lysodeikticus DNA (72% GC).     

Cis-diamminedichloroplatinum(II) Induced Distortion of a Single and Double Stranded Deoxydecanucleosidenona-phosphate Studied by Nuclear Magnetic Resonance

Abstract

The structural distortion of a single- and a double-stranded decadeoxynucleotide upon binding of cis-PtCI₂(NH₃)₂ was studied by ¹H-NMR. After selective platination of d(T-C-T- C-G-G-T-C-T-C) (I) at the central d(-GpG-) site (resulting in I-Pt), several non-exchangeable base protons as well as H1′, H2′ H2″ and H3′ protons could be assigned by means of conventional NMR double-resonance techniques. Addition of the complementary decamer strand to I and I-Pt yielded the double-stranded III and III-Pt, respectively. All non-exchangeable base, H1′, and most of the H2′ and H2″ protons in the two double stranded compounds could be assigned using 2D-chemical shift correlation (COSY) and nuclear Overhauser enhancement (NOESY) techniques. The double stranded compound III appears to adopt a B-DNA like structure. Comparison of NOEs and proton-proton coupling constants in the d(-GpG-)·cisPt part in I-Pt and III-Pt reveals that their structure displays large similarity. Significant chemical shift changes (i.e, larger than 0.1 ppm) between III and III-Pt are restricted to the central four base pairs. It follows that the outer three base pairs, located on either side of the central four base pairs in III-Pt are likely to adopt a regular B-DNA type helix. The observed large upfield and downfield chemical shifts in the d(-CpGpG-) part of III with respect to III-Pt can be rationalized by describing the distortion of the double helix as a kink. A discussion of the observed physical effects upon platination of a double-stranded oligonucleotide is presented.     

Rapid binding and release of Hfq from ternary complexes during RNA annealing

The Sm protein Hfq binds small non-coding RNA (sRNAs) in bacteria and facilitates their base pairing with mRNA targets. Molecular beacons and a 16 nt RNA derived from the Hfq binding site in DsrA sRNA were used to investigate how Hfq accelerates base pairing between complementary strands of RNA. Stopped-flow fluorescence experiments showed that annealing became faster with Hfq concentration but was impaired by mutations in RNA binding sites on either face of the Hfq ring or by competition with excess RNA substrate. A fast bimolecular Hfq binding step (∼10⁸ M⁻¹s⁻¹) observed with Cy3-Hfq was followed by a slow transition (0.5 s⁻¹) to a stable Hfq–RNA complex that exchanges RNA ligands more slowly. Release of Hfq upon addition of complementary RNA was faster than duplex formation, suggesting that the nucleic acid strands dissociate from Hfq before base pairing is complete. A working model is presented in which rapid co-binding and release of two RNA strands from the Hfq ternary complex accelerates helix initiation 10 000 times above the Hfq-independent rate. Thus, Hfq acts to overcome barriers to helix initiation, but the net reaction flux depends on how tightly Hfq binds the reactants and products and the potential for unproductive binding interactions.     

The Telomeric dG(GT)4G Sequence Can Adopt a Parallel-Stranded Double Helical Conformation

Abstract

Oligonucleotides 3′-d(GTGTGTGTGG)-L-d(GGTGTGTGTG)-3′ (hp-GT) and 3′- d(G^4STG^4STG^4STG^4STGG)-L-d(GGTGTGTGTG)-3′ (hp-SGT), (L=(CH₂CH₂O)₃), were shown by use of several optical techniques to form a novel parallel-stranded (ps) intramolecular double helix with purine-purine and pyrimidine-pyrimidine base pairing. The rotational relaxation time of hp-GT was similar to that of a 10-bp reference duplex, and the fraction of unpaired bases was determined to be ～ 7%, testifying to the formation of an intramolecular double helical hairpin by the sequence under the given experimental conditions. A quasi-two- state mode of ps-double helix formation was validated, yielding a helix-coil transition enthalpy of ?135±5 kJ/mol. The G-G and T·T (or ^4ST·T) base pair configurations and conformational parameters of the double helix were derived with molecular modeling by force field techniques. Repetitive d(GT) sequences are abundant in telomers of different genomes and in the regulatory regions of genes. Thus, the observed conformational potential of the repetitive d(GT) sequence may be of importance in the regulation of cell processes.     

Kinked structures of isolated nicotinic receptor M2 helices: A molecular dynamics study

The pore-lining M2 helix of the nicotinic acetylcholine receptor exhibits a pronounced kink when the corresponding ion channel is in a closed conformation [N. Unwin (1993) Journal of Molecular Biology, Vol. 229, pp. 1101–1124]. We have performed molecular dynamics simulations of isolated 22-residue M2 helices in order to identify a possible molecular origin of this kink. In order to sample a wide range of conformational space, a simulated annealing protocol was used to generate five initial M2 helix structures, each of which was subsequently used as the basis of 300 ps MD simulations. Two helix sequences (M2α and M2δ) were studied in this manner, resulting in a total often 300 ps trajectories. Kinked helices present in the trajectories were identified and energy minimized to yield a total of five different stable kinked structures. For comparison, a similar molecular dynamics simulation of a Leu₂₃ helix yielded no stable kinked structures. In four of the five kinked helices, the kink was stabilized by H bonds between the helix backbone and polar side-chain atoms. Comparison with data from the literature on site-directed mutagenesis of M2 residues suggests that such polar side-chain to main-chain H bonds may also contribute to kinking of M2 helices in the intact channel protein. © 1994 John Wiley & Sons, Inc.     

Identification of platination sites on human serum transferrin using 13C and 15N NMR spectroscopy

 Reactions between various apo and metal-bound forms of human serum transferrin (80 kDa) and the recombinant N-lobe (40 kDa) with [Pt(en)Cl₂] or cis-[PtCl₂(NH₃)₂] have been investigated in solution via observation of [¹H,¹⁵N] NMR resonances of the Pt complexes, [¹H,¹³C] resonances of the eCH₃ groups of the protein methionine residues, and by chromatographic analysis of single-site methionine mutants. For the whole protein, the preferred Pt binding site appears to be Met256. Additional binding occurs at the other surface-exposed methionine (Met499), which is platinated at a slower rate than Met256. In contrast, binding of similar Pt compounds to the N-lobe of the protein occurs at Met313, rather than Met256. Met313 is buried in the interlobe contact region of intact transferrin. After loss of one chloride ligand from Pt and binding to methionine sulfur of the N-lobe, chelate-ring closure appears to occur with binding to a deprotonated backbone amide nitrogen, and the loss of the other chloride ligand. Such chelate-ring closure was not observed during reactions of the whole protein, even after several days. Received: 5 May 1999 / Accepted: 26 July 1999