NMR investigation of Hoogsteen base pairing in quinoxaline antibiotic--DNA complexes: comparison of 2:1 echinomycin, triostin A and [N-MeCys3,N-MeCys7] TANDEM complexes with DNA oligonucleotides.

Hoogsteen base pairs have been demonstrated to occur in base pairs adjacent to the CpG binding sites in complexes of triostin A and echinomycin with a variety of DNA oligonucleotides. To understand the relationship of these unusual base pairs to the sequence specificity of these quinoxaline antibiotics, the conformation of the base pairs flanking the YpR binding sites of the 2:1 drug-DNA complexes of triostin A with [d(ACGTACGT)]2 and of the TpA specific [N-MeCys3, N-MeCys7] TANDEM with [d(ATACGTAT)]2 have been studied by 1H NMR spectroscopy. In both the 2:1 triostin A-DNA complex and the 2:1 [N-MeCys3, N-MeCys7] TANDEM-DNA complex, the terminal A.T base pairs are Hoogsteen base paired with the 5' adenine in the syn conformation. This indicates that both TpA specific and CpG specific quinoxaline antibiotics are capable of inducing Hoogsteen base pairs in DNA. However, in both 2:1 complexes, Hoogsteen base pairing is limited to the terminal base pairs. In the 2:1 triostin A complex, the internal adenines are anti and in the 2:1 [N-MeCys3, N-MeCys7] TANDEM-DNA complex, the internal guanines are anti regardless of pH, which indicates that the central base pairs of both complexes form Watson-Crick base pairs. This indicates that the sequence dependent nature of Hoogsteen base pairing is the same in TpA specific and CpG specific quinoxaline antibiotic-DNA complexes. We have calculated a low resolution three-dimensional structure of the 2triostin A-[d(ACGTACGT)]2 complex and compared it with other CpG specific quinoxaline antibiotic-DNA complexes. The role of stacking in the formation of Hoogsteen base pairs in these complexes is discussed.     

Bifunctional intercalator [N-MeCys3,N-MeCys7]TANDEM binds to the dinucleotide TpA.

The binding of [N-MeCys3,N-MeCys7]TANDEM has been examined by DNase I footprinting and diethyl pyrocarbonate modification of several synthetic DNA fragments containing AT-rich regions. DNase I footprinting reveals that at low concentrations the ligand binds preferentially to the center of (AT)n regions. A fragment containing the tetranucleotide AATT was unaffected by the ligand. Diethyl pyrocarbonate modification of several fragments containing blocks of (AT)n revealed a pattern in which alternate adenines were rendered more reactive in the presence of the ligand. These reactive adenines were staggered across the two DNA strands in the 3'-direction, consistent with ligand binding to the dinucleotide TpA. In sequences of the type (TAA)n.(TTA)n, binding of [N-MeCys3,N-MeCys7]TANDEM resulted in strong modification of the second adenine in the sequence TAA, i.e., the base on the 3'-side of the ligand binding site. Data for binding to (AT)n are best explained by suggesting that the adenines sandwiched between the quinoxaline chromophores are rendered most reactive to diethyl pyrocarbonate.     

DNA sequence recognition by under-methylated analogues of triostin A.

Two new analogues of TANDEM (des-N-tetramethyl triostin A) have been synthesised in an effort to elucidate the molecular basis of DNA nucleotide sequence recognition in this series of compounds. Their binding preferences have been investigated by DNAase I footprinting and differential inhibition of restriction nuclease attack. The presence of a single N-methyl group on only one valine residue (in [N-MeVal4] TANDEM) abolishes the ability to recognise DNA, presumably because this antibiotic analogue has suffered an unfavourable conformational change in the depsipeptide ring. A bis-methylated analogue, [N-MeCys3, N-MeCys7]TANDEM, was found to interact quite strongly with DNA and afforded binding sites, rich in AT residues, identical to those of TANDEM. Footprinting with various DNA fragments of known sequence showed that this analogue recognises sequences containing the dinucleotide TpA, although we cannot exclude the possibility that it binds to ApT as well. [N-MeCys3, N-MeCys7]TANDEM inhibits cutting by RsaI, a restriction enzyme that recognises GTAC but not by Sau3AI which recognises GATC. This provides further supportive evidence that the ligand (and, by extension, TANDEM itself) prefers binding to sequences containing the dinucleotide step TpA.     

DNA binding by analogues of the bifunctional intercalator TANDEM

We have used DNase I footprinting to study the binding strength and DNA sequence selectivity of novel derivatives of the quinoxaline bis-intercalator TANDEM. Replacing the valine residues in the cyclic octadepsipeptide with lysines does not affect the selectivity for TpA but leads to a 50-fold increase in affinity. In contrast, replacing both of the quinoxaline chromophores with naphthalene rings abolishes binding, while changing a single ring decreases the affinity, and footprints are observed at only the best binding sites (especially TATATA). By using fragments with different lengths of [(AT) n ], we demonstrate that these ligands bind best to the center of the longer (AT) n tracts.     

The DNA sequence at echinomycin binding sites determines the structural changes induced by drug binding: NMR studies of echinomycin binding to [d(ACGTACGT)]2 and [d(TCGATCGA)]2

The complexes formed between the cyclic octadepsipeptide antibiotic echinomycin and the two DNA octamers [d(ACGTACGT)]2 and [d(TCGATCGA)]2 have been investigated by using one- and two-dimensional proton NMR spectroscopy techniques. The results obtained for the two complexes are compared to each other, to the crystal structures of related DNA-echinomycin complexes, and to enzymatic and chemical footprinting results. In the saturated complexes, two echinomycin molecules bind to each octamer by bisintercalation of the quinoxaline moieties on either side of each CpG step. Binding of echinomycin to the octamer [d(ACGTACGT)]2 is cooperative so that only the two-drug complex is observed at lower drug-DNA ratios, but binding to [d(TCGATCGA)]2 is not cooperative. At low temperatures, both the internal and terminal A.T base pairs adjacent to the binding site in the [d(ACGTACGT)]2-2 echinomycin complex are Hoogsteen base paired (Gilbert et al., 1989) as observed in related crystal structures. However, as the temperature is raised, the internal A.T Hoogsteen base pairs are destabilized and are observed to be exchanging between the Hoogsteen base-paired and an open (or Watson-Crick base-paired) state. In contrast, in the [d(TCGATCGA)]2-2 echinomycin complex, no A.T Hoogsteen base pairs are observed, the internal A.T base pairs appear to be stabilized by drug binding, and the structure of the complex does not change significantly from 0 to 45 degrees C. Thus, the structure and stability of the DNA in echinomycin-DNA complexes depends on the sequence at and adjacent to the binding site. While we conclude that no single structural change in the DNA can explain all of the footprinting results, unwinding of the DNA helix in the drug-DNA complexes appears to be an important factor while Hoogsteen base pair formation does not.     

Effect of geometric isomerism in dinuclear platinum antitumour complexes on the rate of formation and structure of intrastrand adducts with oligonucleotides.

The dinuclear platinum complexes [[trans -PtCl (NH3)2]2[mu]-[NH2(CH2) n NH2]](NO3)2[1,1/t,t ( n = 4,6)] and [[cis-PtCl(NH3)2]2[mu];-[NH2(CH2) n NH2](NO3) 2[1,1/c,c ( n = 4,6)] exhibit antitumour activity comparable with cisplatin. 1,1/c,c complexes do not form 1,2 GG intrastrand adducts, the major adduct of cisplatin, with double-stranded DNA. This 1H NMR spectroscopy study shows that, in the absence of a complementary strand, 1,1/c,c ( n = 4,6) form a 1,2 GG (N7, N7) intrastrand adduct with r(GpG), d(GpG) and d(TGGT). Initial binding to r(GpG) (and also reaction with GMP) at 37 degrees C was slower for 1,1/c,c compared with 1,1/t,t, whereas the second binding step (adduct closure) was faster for 1,1/c,c. However, the 1H NMR spectra of the 1,1/c,c adducts at 37 degrees C show two H8 signals, one of which is broad and becomes sharper on increasing the temperature, indicating restricted rotation around the Pt-N7 bond. For the d(GpG)-1,1/c,c ( n = 4) adduct, 2D NMR spectroscopy assigned the broad H8 signal to the 3' G, which has syn base orientation and 60% S-type/40% N-type sugar conformation. The 5' G has anti base orientation and S-type sugar conformation. Apart from the restricted rotation around the 3' G, the structure is similar to that of 1,2 GG intrastrand adducts of 1,1/t,t. This steric hindrance may explain the inability of 1,1/c,c complexes to form 1,2 GG intrastrand adducts with sterically more demanding double-stranded DNA.     

Structural variation in d(CTCTAGAG). Implications for protein-DNA interactions

Single-crystal X-ray diffraction techniques have been used to characterize the structure of the self-complementary DNA oligomer d(CTCTAGAG). The structure was refined to an R factor of 14.7% using data to 2.15-A resolution. The tetragonal unit cell, space group P4(3)2(1)2, has dimensions a = 42.53 and c = 24.33 A. The asymmetric unit consists of a single strand or four base pairs. Two strands, related by a crystallographic dyad axis, coil about each other to form a right-handed duplex. This octamer duplex has a mean helix rotation of 32 degrees, 11.3 base pairs per turn, an average rise of 3.1 A, C3'-endo furanose conformations, a shallow minor groove, and a deep major groove. Such averaged parameters suggest classification of the octamer as a member of the A-DNA family. However, the global parameters tend to mask variations in conformational parameters observed at the level of the base pairs. In particular, the central TpA (= TpA) step displays extensive interstrand purine-purine overlap and an unusual sugar-phosphate backbone conformation. These structural features may be directly related to certain sequence-specific protein-DNA interactions involving nucleases and repressors.     

Conformational changes in d (TpG) and 5′GTP induced by monofunctional binding of [PtCl(NH3)3]Cl and [PtCl(dien)] are small

The binding of the monofunctioal cisplatin model compounds [PtCl(NH₃)Cl and [PtCl(dien)]Cl, to Guanosine-5′-triphosphate (5′GTP) is described. For comparison also the binding of [PtCl(NH₃)₃]Cl to d(TpG) has been studied. It is shown that in all cases the platinum triam(m)ine binds to guanine-N7. The conformations of the sugar rings have been determined using high-resolution NMR techniques. The relative amount of the N conformer of the sugar ring of 5′GTP increases upon platination. Only minor differences were observed between the 5′GTP adducts of [PtCl(NH₃)₃]Cl and [PtCl(dien)]Cl. The conformational equilibrium of the sugar rings of d(TpG), however, barely shows any change upon platination. For both cases the conformation is assumed to result from the interaction between the negatively charged (tri)phosphate group and the positively charged platinum group. This interaction causes a strain in the 5′GTP adducts resulting in the observed change in the conformational equilibrium of the sugar ring. In the case of d(TpG) such a strain is not found, which is ascribed to the lower charge on the phosphate group.     

Preferred binding sites for the bifunctional intercalator TANDEM determined using DNA fragments that contain every symmetrical hexanucleotide sequence

We have prepared novel DNA footprinting substrates that contain all 64 symmetrical hexanucleotide sequences. These were contained in two restriction fragments that were cloned into the pUC19 polylinker site; each fragment was also obtained in both orientations. These fragments were used to assess the sequence binding preferences of the synthetic quinoxaline antibiotic TANDEM. We found that, although the ligand binds to most TpA steps, the affinity is affected by the flanking sequences. The best binding sites contain the tetranucleotide sequence ATAT, although YATATR is a better site than RATATY. TTAA always is a poor binding site, especially TTTAAA. The binding to GTAC is strongly dependent on the flanking bases, with good binding to GGTACC but none at all to CGTACG.     

Conformational variations in d(TGACGTCA) and its reverse sequence d(ACTGCAGT): a joint circular dichroism and nuclear magnetic resonance study

Circular dichroism (CD) and nuclear magnetic resonance (NMR) techniques have been used to characterize the structural properties of the two self-complementary DNA octamers d(TGACGTCA) (I) and d(ACTGCAGT) (II). These display as distinctive features reverse sequences and central steps CpG and GpC, respectively. CD experiments lead to B-form DNA spectra characterized by larger magnitude signals in the case of octamer (I). NMR COSY spectra indicate that in the two octamers all the residues are predominantly south, S, (2'-endo) sugar conformation. NMR NOESY spectra show most of the glycosidic angles confined in the range predicted for B-form DNA although important heterogeneity is noticed along the chains, more pronounced in the case of octamer (I). Both the increase of north, N, (3'-endo) sugar conformation and P (pseudorotation phase angle) deviation from its standard B-form DNA value (162 degrees) express local sequence dependent structure distortions, remarkably visible in CpG step of octamer (I) and agreeing with NOESY cross-peaks intensities. Results interpreted according to Calladine's rules indicate higher cross-chain strains in octamer (I) than in octamer (II). All together, we find evidence to support for octamer (I) in solution local structures with A-DNA properties likely dictated by the central CpG step. Such structures could be involved in the DNA recognition by proteins and anticancerous drugs.     

The solution structure of the Sac7d/DNA complex: a small-angle X-ray scattering study.

Small-angle X-ray scattering has been used to study the structure of the multimeric complexes that form between double-stranded DNA and the archaeal chromatin protein Sac7d from Sulfolobus acidocaldarius. Scattering data from complexes of Sac7d with a defined 32-mer oligonucleotide, with poly[d(GC)], and with E. coli DNA indicate that the protein binds along the surface of an extended DNA structure. Molecular models of fully saturated Sac7d/DNA complexes were constructed using constraints from crystal structure and solution binding data. Conformational space was searched systematically by varying the parameters of the models within the constrained set to find the best fits between the X-ray scattering data and simulated scattering curves. The best fits were obtained for models composed of repeating segments of B-DNA with sharp kinks at contiguous protein binding sites. The results are consistent with extrapolation of the X-ray crystal structure of a 1:1 Sac7d/octanucleotide complex [Robinson, H., et al. (1998) Nature 392, 202-205] to polymeric DNA. The DNA conformation in our multimeric Sac7d/DNA model has the base pairs tilted by about 35 degrees and displaced 3 A from the helix axis. There is a large roll between two base pairs at the protein-induced kink site, resulting in an overall bending angle of about 70 degrees for Sac7d binding. Regularly repeating bends in the fully saturated complex result in a zigzag structure with negligible compaction of DNA. The Sac7d molecules in the model form a unique structure with two left-handed helical ribbons winding around the outside of the right-handed duplex DNA.     

Detection of Z DNA binding proteins in tissue culture cells.

A gel electrophoresis DNA binding assay to detect Z DNA binding proteins has been developed utilising [32P] labelled poly [d(G-C)] which was converted to the Z form by incubation in 100 microM Co(NH3)6Cl3. The parameters of the assay were established using a Z DNA antibody as a model system and then applied to extracts of Hela and BHK21 cells. Using an anti-Z DNA antibody conditions were established which allowed resolution of antibody-DNA complexes and free DNA in the presence of 100 microM Co(NH3)6Cl3. The inclusion of unlabelled complementary homopolymers eliminated non-specific binding to the labelled Z-DNA probe. Competition experiments demonstrated that the assay was highly specific for double stranded non-B DNA. Application of the technique to extracts of mammalian cells demonstrated that human and hamster cells contain Z-DNA binding proteins; further characterisation by a blotting technique indicated that a 56,000 molecular weight cell protein preferentially binds Z-DNA.     

Investigation of DNA binding modes for a symmetrical cyanine dye trication: effect of DNA sequence and structure.

The DNA binding behavior of a tricationic cyanine dye (DiSC3+(5)) was studied using the [Poly(dA-dT)]2, [Poly(dI-dC)]2 and Poly(dA) x Poly(dT) duplex sequences and the Poly(dA) x 2Poly(dT) triplex. Optical spectroscopy and viscometry results indicate that the dye binds to the triplex structure by intercalation, to the nonalternating Poly(dA) x Poly(dT) duplex through minor groove binding and to the alternating [Poly(dA-dT)]2 duplex by a combination of two binding modes: intercalation at low concentration and dimerization within the minor groove at higher concentration. Dimerization occurs at lower dye concentrations for the [Poly(dI-dC)]2 sequence, consistent with our previous investigations on an analogous monocationic cyanine dye. [Seifert, J.L., et al. (1999) J. Am. Chem. Soc. 121, 2987-2995] These studies illustrate the diversity of DNA binding modes that are available to a given ligand structure.     

Molecular structure of antitumor drug steffimycin and modelling of its binding to DNA.

The molecular and crystal structure of steffimycin have been determined by single crystal X-ray diffraction to 0.9 angstrom resolution. The triclinic crystals are in the space group P1, with the unit cell dimensions of a = 8.606(3) angstrom, b = 22.168(7) angstrom, c = 8.448(2) angstrom, alpha = 97.56(3) degrees, beta = 95.97(2) degrees, gamma = 87.94(3) degrees, Z = 2. The structure was solved by direct methods and refined by the full-matrix least-squares method to a final R value of 0.065 with 3405 (Inet greater than 2.0 sigma (Inet] observed reflections using the NRCVAX software package. The crystal lattice includes 2 independent steffimycin, 3 water and one 2-methyl-2,4-pentanediol molecules. The conformation of steffimycin is grossly similar to other anthracycline antibiotics including daunorubicin. The crystal packing interactions of steffimycin suggest a preferred stacking of the aglycone chromophore of the antibiotic which resembles the intercalative interactions seen in the daunorubicin-d(CGTACG) (Wang et al., Biochemistry 26, 1152 (1987] and nogalamycin-d(CGT(pS)ACG) (Liaw et al., Biochemistry 28, 9913 (1989] complexes. The atomic coordinates data from these complexes were used to model the intercalative binding of steffimycin to DNA. The models were then stereochemically idealized by the constraint refinement program NUCLSQ. Subsequently XPLOR software package was used for energy minimization of these models in vacuo. The model building studies suggest that steffimycin has a higher CpG base sequence specificity over the TpA step, similar to that of daunorubicin and nogalamycin.     

Studies of the binding activity of phage G13 to synthetic trisaccharides analogous to binding structures in Salmonella typhimurium and Escherichia coli C core saccharide. Correlation between conformation and binding activity.

Phage G13 binds to the carbohydrate part of lipopolysaccharides from rough mutants of Salmonella and Escherichia coli as the first event of infection. Equilibrium dialysis inhibition studies with native and synthetic trisaccharides as inhibitors suggested that phage G13 recognizes branched oligosaccharides having 6-O-alpha- or 7-O-alpha-glycosyl groups with alpha-Man(1----3) [alpha-Man(1----6)]Man (Man[Man]Man) and alpha-Glc(1----3)-[alpha-Hep(1----7)] alpha-Hep(1----3) alpha-Hep(1----5)Kdo as the smallest saccharides with inhibitory activity (Wollin et al., 1989). Of four synthetic analogues to Man[Man]Man only Man(1----3)[alpha-Gal(1----6)]alpha-Man-OMe (Man[Gal]-Man) and alpha-Glc(1----3)[alpha-Hep(1----7)]alpha-Hep-OMe (Glc[Hep]Hep) inhibited the binding of labelled E. coli C core nonasaccharide ligand to G13 with activities which were 10- and 15-fold lower than Man[Man]Man. The trisaccharides alpha-Man(1----3)[alpha-Glc(1----6)[alpha-Man-OMe (Man[Glc]Mann) and alpha-Man(1---3)[alpha-Tal(1----6)]alpha-Man-OMe (Man[Tal]Man) showed no inhibition at concentrations 75-fold higher than Man[Man]Man. Minimum energy conformation calculations of the saccharides using the GESA method showed that the 6-O-alpha-Man group in Man[Man]Man and the 7-O-alpha-Hep group SL805 pentasaccharide expose their OH-2 and OH-3 groups in a similar way and these are postulated to be key structural features for binding activity. The importance of hydroxy groups at certain positions is implied from the fact that both manno- and galacto-isomers are active. We also conclude that the O6-C6-C5-O5-C1 region of the 3-O-alpha-glycosyl group in the Man[Man]Man trisaccharide, or part of it, is important for the G13 binding activity.     

DNA binding of iron(II) mixed-ligand complexes containing 1,10-phenanthroline and 4,7-diphenyl-1,10-phenanthroline

Absorption spectroscopy and circular dichroism (CD) have been used to characterize the DNA binding of [Fe(phen)3]2+, [Fe(phen)2(DIP)]2+ and [Fe(phen)(DIP)2]2+ where phen and DIP stand for 1,10-phenanthroline and 4,7-diphenyl-1,10-phenanthroline, respectively. Both [Fe(phen)3]2+ and [Fe(phen)2(DIP)]2+ bind weakly to calf thymus DNA (CT-DNA) in an electrostatic mode, while [Fe(phen)(DIP)2]2+ binds more strongly to CT-DNA, possibly in an intercalation mode. The hypochromicity, red shift and Kb increase in the order [Fe(phen)3]2+ < [Fe(phen)2(DIP)]2+ < [Fe(phen)(DIP)2]2+ in accordance with the increase in size and hydrophobicity of the iron(II) complexes. The thermodynamic parameters obtained suggest that the DNA binding of both [Fe(phen)3]2+ and [Fe(phen)2(DIP)]2+ is entropically driven, while that of [Fe(phen)(DIP)2]2+ is enthalpically driven. A strong CD spectrum in the UV and visible region develops upon addition of CT-DNA into the racemate solution of each iron(II) complex (Pfeiffer effect). This has revealed that a shift in diastereomeric inversion equilibrium takes place in the solution to yield an excess of one of the DNA-complex diastereomers. The striking resemblance of the CD spectral profiles to those of the pure delta-enantiomer indicates that the delta-enantiomer of the iron(II) complexes is preferentially bound to CT-DNA. The mechanism of the development of Pfeiffer CD is proposed on the basis of kinetic studies on the DNA binding of the racemic iron(II) complexes.     

Influence of counter-ions on the crystal structures of DNA decamers: binding of [Co(NH3)6]3+ and Ba2+ to A-DNA.

A-DNA is a stable alternative right-handed double helix that is favored by certain sequences (e.g., (dG)n.(dC)n) or under low humidity conditions. Earlier A-DNA structures of several DNA oligonucleotides and RNA.DNA chimeras have revealed some conformational variation that may be the result of sequence-dependent effects or crystal packing forces. In this study, four crystal structures of three decamer oligonucleotides, d(ACCGGCCGGT), d(ACCCGCGGGT), and r(GC)d(GTATACGC) in two crystal forms (either the P6(1)22 or the P2(1)2(1)2(1) space group) have been analyzed at high resolution to provide the molecular basis of the structural difference in an experimentally consistent manner. The study reveals that molecules crystallized in the same space group have a more similar A-DNA conformation, whereas the same molecule crystallized in different space groups has different (local) conformations. This suggests that even though the local structure is influenced by the crystal packing environments, the DNA molecule adjusts to adopt an overall conformation close to canonical A-DNA. For example, the six independent CpG steps in these four structures have different base-base stacking patterns, with their helical twist angles (omega) ranging from 28 degrees to 37 degrees. Our study further reveals the structural impact of different counter-ions on the A-DNA conformers. [Co(NH3)6]3+ has three unique A-DNA binding modes. One binds at the major groove side of a GpG step at the O6/N7 sites of guanine bases via hydrogen bonds. The other two modes involve the binding of ions to phosphates, either bridging across the narrow major groove or binding between two intra-strand adjacent phosphates. Those interactions may explain the recent spectroscopic and NMR observations that [Co(NH3)6]3+ is effective in inducing the B- to A-DNA transition for DNA with (G)n sequence. Interestingly, Ba2+ binds to the same O6/N7 sites on guanine by direct coordinations.     

Similar binding of the carcinostatic drugs cis-[Pt(NH3)2Cl2] and [Ru(NH3)5Cl] Cl2 to tRNAphe and a comparison with the binding of the inactive trans-[Pt(NH3)2Cl2] complex - reluctance in binding to Watson-Crick base pairs within double helix.

A comparative study of the binding of square planar cis- and trans-[Pt(NH3)2Cl2] complexes and the octahedral [Ru(NH3)5(H2O)]3+ complex to tRNAphe from yeast was carried out by X-ray crystallography. Both of the carcinostatic compounds, cis-[Pt(NH3)2Cl2] and [Ru(NH3)5(H2O)]3+ show similarities in their mode of binding to tRNA. These complexes bind specifically to the N(7) positions of guanines G15 and G18 in the dihydrouridine loop. [Ru(NH3)5(H2O)]3+ has an additional binding site at N(7) of residue G1 after extensive soaking times (58 days). A noncovalent binding site for ruthenium is also observed in the deep groove of the acceptor stem helix with shorter (25 days) soaking time. The major binding site for the inactive trans-[Pt(NH3)Cl2] complex is at the N(1) position of residue A73, with minor trans-Pt binding sites at the N(7) positions of residues Gm34, G18 and G43. The similarities in the binding modes of cis-[Pt(NH3)2Cl2] and [Ru(NH3)5(H2O)]3+ are expected to be related to their carcinostatic properties.     

Stopped-flow kinetic studies of actinomycin binding to DNAs.

Stopped-flow kinetic studies of the association of actinomycins with narural and synthetic DNA duplexes are presented. The actinomycins examined were D (C1), D lactam (in which the pentapeptide rings are closed by lactam instead of lactone linkages), X2, XObeta, and actinomine. The DNAs used included claf-thymus DNA, PM2, DNA, and two synthetic d(A-T)-lide copolymers containing 2,6-diaminopurine (DAP) in place of adenine residues, poly[d(DAP-T)]-poly[d(DAP-T)] and poly[d(DAP-A-T]-poly[d(DAP-A-T)]. Apparent equilibrium constants indicate that the DAP-containing polynucleotides bind actinomycin strongly. Comples formation of actinomycins D, D lactam, X2 and XObeta with these DNAs can be deconvoluted into five rate processes. These steps do not necessarily proceed to completion. The rates of two of these steps display a firstorder dependence on DNA concentration. The large negative entropies of activation of these steps suggest a high degree of restriction to freedom of motion on the respective transition states. The rates of the remaining three steps are independent of DNA concentration. Kinetic parameters of actinimycin binding to DNAs are presented and suggestions are made about some of the molecular evente believed to be responsible for the appearance of the five rate processes. For example, for DNA, poly[d(DAP-A-T)], and poly[d(DAP-T)], the observed order of apparent second-order rate constants, normalized to the concentration of actinomycin binding sites, suggests that binding of the antibiotic occurs most rapidly at binding sites (G-C of d DAT-T) near d(A-T) base pairs, where weakening of the double-helical conformation requires the least energy. Results obtained from studies of actinomycin D binding to heat-denatured poly[d(DAP-A-T)] and of actinomine and actinomycin D lactam binding to DNA suggest that the slow rate processes are related to an actinomycyl-pentapeptide-induced unwinding of the sugar-phosphate backbone of DNA accompanying insertion of the cyclic peptides into DNA.     

Conformational heterogeneity of quinoxaline peptides in solution.

The conformational heterogeneity of several quinoxaline antibiotics, a class of naturally occurring quinoxaline peptides with antitumor properties, and their synthetic analogues was investigated in polar and nonpolar solvents by high performance liquid chromatography (HPLC) with uv photodiode array detection, uv-absorbance, low-temperature phosphorescence, and nmr techniques. Multiple peak formation and interconversion in the HPLC and 1H-nmr analysis of triostin A, its under-N-methylated synthetic analogues (des-N-tetramethyltriostin A [TANDEM] and [N-MeCys3, N-MeCys7]-TANDEM [MCTAN-DEM]), and echinomycin were examined as a function of temperature, solvent polarity, and residence time in solution prior to analysis. Slow interconversion between HPLC peaks, ascribed to the presence of multiple solution conformers, was exhibited by these peptides although at very different interconversion rates. Among the triostins, the rate of interconversion appeared to vary with the degree of N-methylation of the residues in the cyclic depsipeptide chain. Interconversion of the n and p conformers of triostin A in chloroform occurred on a chromatographic timescale (a few minutes with kn----p calculated to be 0.02 s-1 at 25 degrees C) while the solution conformers of TANDEM in methanol equilibrated very slowly to one preferred conformer over a period of several weeks at ambient temperature. MCTANDEM, a synthetic analogue of triostin A with an intermediate degree of N-methylation of the residues in the peptide ring, consisted of an equilibrium mixture of n and p conformers in methanol that interconverted on a chromatographic time scale. Two additional conformers of MCTANDEM developed within a few weeks' residence time in methanol at ambient temperature. Echinomycin was found to exist in methanol as an interconverting mixture of at least four minor conformers in addition to the major isoform (95% by peak area) of the peptide. The solution conformers of the quinoxaline peptides investigated in this report are most likely a consequence of hindered rotation about the N-methylated peptide bonds in the depsipeptide ring and/or intramolecular hydrogen bonding.