Crystal structure of the self-complementary 5''-purine start decamer d(GCGCGCGCGC) in the Z-DNA conformation. I.

Alternating self-complementary oligonucleotides starting with a 5'-pyrimidine usually form left-handed Z-DNA; however, with a 5'-purine start sequence they form the right-handed A-DNA. Here we report the crystal structure of the decamer d(GCGCGCGCGC) with a 5'-purine start in the Z-DNA form. The decamer crystallizes in the hexagonal space group P6(5)22, unit cell dimensions a = b = 18.08 and c = 43.10 A, with one of the following four dinucleotide diphosphates in the asymmetric unit: d(pGpC)/d(GpCp)/d(pCpG)/d(CpGp). The molecular replacement method, starting with d(pGpC) of the isomorphous Z-DNA hexamer d(araC-dG)3 without the 2'-OH group of arabinose, was used in the structure analysis. The method gave the solution only after the sugar-phosphate conformation of the GpC step was manipulated. The refinement converged to a final R value of 18.6% for 340 unique reflections in the resolution range 8.0-1.9 A. A result of the sequence alternation is the alternation in the nucleotide conformation; guanosine is C3'-endo, syn, and cytidine is C2'-endo, anti. The CpG step phosphodiester conformation is the same as ZI or ZII, whereas that of the GpC step phosphodiester is "intermediate" in the sense that zeta (O3'-P bond) is the same as ZII but alpha (P-O5' bond) is the same as ZI. The duplexes generated from the dinucleotide asymmetric unit are stacked one on top of the other in the crystal to form an infinite pseudocontinuous helix. This renders it a quasi-polymerlike structure that has assumed the Z-DNA conformation further strengthened by the long inner Z-forming stretch d(CG)4. An interesting feature of the structure is the presence of water strings in both the major and the minor grooves. In the minor groove the cytosine carbonyl oxygen atoms of the GpC and CpG steps are cross-bridged by water molecules that are not themselves hydrogen bonded but are enclosed by the water rings in the mouth of the minor groove. In the major groove three independent water molecules form a zigzagging continuous water string that runs throughout the duplex.     

Substrate specificity of T4 RNA-ligase. The effect of the nucleotide composition of substrates and the size of phosphate donor on the effectiveness of intermolecular ligation

Nucleoside 2' (3'),5'-diphosphates, dinucleotides pApA, pApC, pApU, pGpC, pCpC, pUpU (phosphate donors), and trinucleoside diphosphates, such as NpCpC, NpCpU, NpUpC, NpUpU and GpApN (N = U, C, A or G; phosphate acceptors) were used to study the substrate specificity of T4 RNA ligase. Relative efficiency of the mono- and dinucleotide donors depends on the 5'-terminal nucleoside moiety of the dinucleotide: upon ligation with the minimal phosphate acceptor GpUpC, dinucleotides pApA, pApC, and pApU are more effective than nucleotide diphosphate pAp; pGpC is more effective than pGp; efficiencies of pCpC and pCp are almost identical, and efficiency of pUpU is slightly lower than that of pUp. In relative efficiency, dinucleotide donors, varying only in 5'-terminal unit, do not correspond to mononucleotides: pApC greater than pCpC greater than pGpC and pCp greater than pUp approximately pAp much greater than pGp. The effects observed for homooligomeric substrates cannot be extra-polated on heterooligomers.     

Rate of B to Z structural transition of supercoiled DNA

The forward rate of the B to Z transition induced by negative supercoiling of plasmid DNA containing an alternating C-G sequence has been examined using the binding of Z-DNA-specific antibodies to follow the transition. DNA samples of a plasmid containing a d(pCpG)16 X d(pCpG)16 insert were supercoiled to different extents and appropriate amounts of ethidium were bound to the DNAs to relax them and to keep the alternating C-G sequence in the right-hand helical form. Following the rapid removal of ethidium by passage through a column of cation exchange resin, the DNA becomes negatively supercoiled, which induces the flipping of the helical hand of the C-G insert. The rate of the transition is strongly dependent on the degree of supercoiling. The transition is complete in less than 50 seconds for a DNA with a specific linking difference (superhelical density) sigma of -0.09. For the same DNA, the half-time of the transition is about two minutes at sigma = -0.07 and about a factor of 10 slower at sigma = -0.05.     

Dinucleotides docking to scorpion polypeptide toxins: a molecular modeling method for protein functional site recognition

To understand the principles underlying protein folding, many molecular modeling methods are being developed for predicting functional positions. In this work, fully flexible dinucleotides d(pApA), d(pApC), d(pApG), d(pApT), d(pCpA), d(pCpC), d(pCpG), d(pCpT), d(pGpA), d(pGpC), d(pGpG), d(pGpT), d(pTpA), d(pTpC), d(pTpG), and d(pTpT) were first docked onto the surface of scorpion polypeptide toxins (LqhIT2, PDB ID:2I61) and homology modeled ANEPIII. Automated docking was able to identify sites on scorpion polypeptide toxins where favorable nucleotide interactions can occur, and those sites were in agreement with the mutation data of this protein published recently [I. Karbat, R. Kahn, L. Cohen, N. Ilan, N. Gilles, G. Corzo, O. Froy, M. Gur, G. Albrecht, S.H. Heinemann, D. Gordon, M. Gurevitz, The unique pharmacology of the scorpion alpha-like toxin Lqh3 is associated with its flexible C-tail, Febs J 274 (2007) 1918-1931]. Simulation results suggested that dinucleotides docking is a suitable molecular modeling method that could be developed for protein functional site recognition.     

Insertion of d(pCpG)n.d(pCpG)n into the lacZ gene of Escherichia coli inhibits expression of beta-galactosidase in vivo

Plasmids that contain a d(pCpG)13.d(pCpG)13 insert instead of a lac operator show a 34-fold decrease of beta-galactosidase synthesis. The same sequence causes a 24-fold decrease when inserted between codons 5 and 6 of the lacZ gene. In such constructs with d(pCpG)n.d(pCpG)n inserts, beta-galactosidase activity decreases approximately 1.6-fold per d(pCpG).d(pCpG) unit when n ranges from 5 to 16.     

Synthesis and proton-NMR studies of oligonucleotides containing an apurinic (AP) site

In order to elucidate the conformational properties of base-deleted oligodeoxyribonucleotides, the molecules d-CpS(pCpG)n (n = 1,2; S = sugar) were synthesized by the phosphotriester method and characterized by 1H-NMR spectroscopy. Complete assignment of all non-exchangeable proton resonances of both compounds was obtained by 1D- and 2D-NMR techniques. In combination with computer simulation, these spectra yielded proton-proton and proton-phosphorus coupling constants of high accuracy. These data provide valuable information about the sugar and the backbone conformation. It appears that d-Cp1Sp2Cp3G4 does not form a duplex under any of the conditions studied. On the contrary, the base-deleted hexamer d-Cp1Sp2Cp3Gp4Cp5G6 occurs as a right-handed' staggered' DNA duplex at 280 K: the core of this duplex is formed by the residues C(3)-G(6); two 'dangling' residues C(1) and S(2) are located at the two 5'-ends of the duplex. The assignment of the corresponding imino proton resonances for [d-CpS(pCpG)2]2 was based on their thermal behavior: the line broadening of these resonances was studied as a function of temperature. The chemical shift and the number of imino proton resonances accord well with the number and type of Watson-Crick base pairs which can be formed in the staggered duplex described above. Thermodynamic parameters of duplex formation were obtained from an analysis of the chemical shift versus temperature profiles of aromatic base and H-1' protons. It is suggested that the cytosine ring of C(1) stacks, at least part of the time, with the guanine ring on the nucleotide residue, G(6), situated in the complementary strand. The binding of Lys-Trp-Lys to [d-CpS(pCpG)2]2 as well as to [d-CpGpCpG]1 was investigated. It is concluded that the indole ring of the tryptophan residue probably stacks on top of the 3'-terminal guanine base of both duplexes, but not on the nucleic acid bases next to the apurinic (AP) site.     

The effect of intercalating drugs on the kinetics of the B to Z transition of poly(dG-dC)

We have measured the ability of the intercalating drugs proflavine, ethidium bromide, actinomycin D, and bismethidiumspermine to inhibit the salt induced transition of poly(dG-dC) from the B to the Z form. While all of the drugs studied slowed the B to Z transition, the effectiveness of the drugs correlates much better with their DNA binding kinetics than their DNA binding constants. In studies where the binding densities of ethidium and actinomycin were varied we have found that high levels of ethidium, more than 1 per 20 base pairs, were required to inhibit the B to Z transition while low levels of actinomycin, less than 1 per 450 base pairs, reduced the transition rate. Studies of the B to Z transition in the presence of both actinomycin and ethidium suggest that the drugs inhibit the transition by different mechanisms. The results are interpreted in terms of a modification of the kinetic model proposed by Pohl and Jovin in which, depending on the DNA binding kinetics of the drug, the drug may inhibit nucleation and/or propagation of the B to Z transition.     

Formation of DNA complexes with actinomycins in aqueous solutions and films

The mechanisms of DNA interaction with actinomycin D (AMD), 7-amino-actinomycin D (7-AAMD), and ethidium bromide (EtBr) were studied in aqueous solutions and in condensed state (films coating plates). The use of the methods of absorption (UV, IR, and visible spectral ranges) and fluorescence (steady-state, polarization, and phase-modulation) spectroscopy revealed that (1) the formation of DNA complexes with 7-AAMD in solution was not accompanied by energy transfer from photoexcited nucleotides to phenoxazone chromophore and (2) the mechanism of ligand incorporation was distinct from stacking. In the film of the DNA-7-AAMD complex, which simulated the native state in a biological cell, the efficiency of the energy transfer was high. This indicates that a stacking-type mechanism underlies actinomycin intercalation into DNA. In the presence of high concentrations of 7-AAMD in the film, DNA denatured and its double-helical structure, degraded. In the DNA-AMD complex, the native B-form of DNA molecule was conserved both in films and in solution.     

Carcinogen-nucleic acid interactions: equilibrium binding studies of aflatoxin B1 with the oligodeoxynucleotide d(ATGCAT)2 and with plasmid pBR322 support intercalative association with the B-DNA helix

Equilibrium binding of aflatoxin B1 (AFB1) to the oligodeoxynucleotide d(ATGCAT)2 was examined by using 1H NMR. AFB1 binds to double-stranded d(ATGCAT)2 with an apparent binding constant of 3.7 x 10(3) M-1. The equilibrium is rapid on the NMR time scale; the observed 1H NMR spectrum represents the population-weighted average of the chemical shifts arising from the free and bound states of the oligodeoxynucleotide and the AFB1. The spectrum of d(ATGCAT)2 exhibits exchange broadening in the presence of AFB1, manifested as decreases in apparent T2 relaxation times for the d(ATGCAT)2 base protons. Upon binding to d(ATGCAT)2, the AFB1 signals are shifted upfield, indicative of increased shielding. The adenine H2 protons are also shifted upfield in the presence of the carcinogen. Small changes in chemical shift are observed for other d(ATGCAT)2 protons. A substantial decrease in the nonselective T1 relaxation time is observed for the adenine H2 protons in the presence of AFB1. Competition binding experiments in which the competing ligands actinomycin D, ethidium bromide, and spermidine were individually added to an AFB1-d(ATGCAT)2 equilibrium mixture showed that addition of 1 equiv of actinomycin D or 4 equiv of ethidium bromide was sufficient to displace bound AFB1 from d(ATGCAT)2. In contrast, the addition of spermidine did not result in the displacement of bound AFB1 molecules and may have slightly enhanced binding, presumably due to stabilization of the DNA duplex. 1H NOESY experiments confirmed that the overall conformation for the d(ATGCAT)2 duplex was right-handed both in the absence and in the presence of AFB1. Equilibrium binding of AFB1 to d(ATGCAT)2 is greatly diminished at higher temperatures at which the oligodeoxynucleotide is single-stranded.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of poly[d(pGpT).d(pApC)] and poly[d(pCpG).d(pCpG)] repeats on homologous recombination in somatic cells.

Sequencing studies have shown that in somatic cells alternating runs of purines and pyrimidines are frequently associated with recombination crossover points. To test whether such sequences actually promote recombination, we have examined the effects of poly[d(pGpT).d(pApC)] and poly[d(pCpG).d(pCpG)] repeats on a homologous recombination event. The parental molecule used in this study, pSVLD, is capable of generating wild-type simian virus 40 DNA via recombination across two 751-base-pair regions of homology and has been described previously (Miller et al., Proc. Natl. Acad. Sci. USA 81:7534-7538, 1984). Single inserts of either a poly[d(pGpT).d(pApC)] repeat or a poly[d(pCpG).d(pCpG)] repeat were positioned adjacent to one region of homology in such a way that the recombination product, wild-type simian virus 40 DNA, could be formed only by recombination within the homologies and not by recombination across the alternating purine-pyrimidine repeats. We have found that upon transfection of test DNAs into simian cells, a poly[d(pCpG).d(pCpG)] repeat enhanced homologous recombination 10- to 15-fold, whereas a poly[d(pGpT).d(pApC)] repeat had less effect. These results are discussed in terms of the features of these repeats that might be responsible for promoting homologous recombination.     

Selective binding of actinomycin D induces a reversible conformational transition of nucleosomes

Equilibrium and hydrodynamic studies on the complex of actinomycin D with H1-H5 depleted, 175 basepair nucleosomes are reported. By spectral titration the intrinsic affinities of actinomycin D for nucleosomes and for DNA are found strictly comparable. Sedimentation analysis shows that actinomycin can apparently unfold the nucleosome, like ethidium bromide and daunomycin, but it does so at a much lower bound drug to DNA molar ratio (about 1 drug molecule to 45 basepairs). Since about four bound actinomycin molecules are able to induce the reversible conformational transition of a nucleosome, it is suggested that the sites of interaction may correspond to the kinked DNA sites evidenced by Klug and collaborators (Richmond, T.J., Finch, J.T., Rushton, B., Rhodes, D. and Klug, A. (1984) Nature 311, 532-537) in the structure of the nucleosome. A relevance of these findings to the interaction of actinomycin with "active chromatin" is also suggested.     

N-acetoxy-2-acetylaminofluorene modification of a deoxyoligonucleotide duplex.

The carcinogen N-acetoxy-2-acetylaminofluorene was reacted with d (CCACGCACC) to form a covalent adduct with attachment at the single guanine. The sample was purified, mixed 1:1 with d (GGTGCGTGG) and studied by thermal denaturation experiments. The Tm for the mixture was 35 +/- 3 degrees C, consistent with duplex formation. The method of continuous variation shows that the modified oligomer, d (CCACGAAFCACC), forms a 1:1 duplex with d (GGTGCGTGG). Circular dichroism spectra also indicate the formation of a duplex and suggest that the modified duplex has a left-handed conformation. Addition of the intercalating drug ethidium alters the CD spectrum of the modified duplex, resulting in a CD spectrum similar to that of ethidium bound to right-handed DNA.     

Photoaffinity approaches to determining the sequence selectivities of DNA-small molecule interactions: actinomycin D and ethidium.

The DNA photoaffinity ligands, 7-azidoactinomycin D and 8-azidoethidium, form DNA adducts that cause chain cleavage upon treatment with piperidine. Chemical DNA sequencing techniques were used to detect covalent binding. The relative preferences for modifications of all possible sites defined by a base pair step (e.g. GC) were determined within all quartet contexts such as (IGCJ). These preferences are described in terms of 'effective site occupations', which express the ability of a ligand to covalently modify some base in the binding site. Ideally, the effective site occupations measured for photoaffinity agents can also be related to site-specific, non-covalent association constants of the ligand. The sites most reactive with 7-azidoactinomycin D were those preferred for non-covalent binding of unsubstituted actinomycin D. GC sites were most reactive, but next-nearest neighbors exerted significant influences on reactivity. GC sites in 5'-(pyrimidine)GC(purine)-3' contexts, particularly TGCA, were most reactive, while reactivity was strongly suppressed for GC sites with a 5'-flanking G, or a 3'-flanking C. High reactivities were also observed for bases in the first (5') GG steps in TGGT, TGGG and TGGGT sequences recently shown to bind actinomycin D with high affinity. Pyrimidine-3',5'-purine steps and GG steps flanked by a T were most preferred by 8-azidoethidium, in agreement with the behavior of unsubstituted ethidium. The good correspondence between expected and observed covalent binding preferences of these two azide analogs demonstrates that photoaffinity labeling can identify highly preferred sites of non-covalent DNA binding by small molecules.     

Z* DNA, the left-handed helical form of poly[d(G-C)] in MgCl2-ethanol, is biologically active.

The interconversion between the right (R) and left (L) helical forms of poly[d(G-C)] occurs at low concentrations of MgCl2 and EtOH, acting together in a highly synergistic manner. Thus, the cooperative R---L transition is induced by only 0.4 mM and 4 MM MgCl2 in combination with 20% and 10% EtOH, respectively. The L form of poly[d(G-C)] formed under these conditions has the spectroscopic properties (absorption, circular dichroism) previously demonstrated under high salt conditions (Pohl and Jovin, 1972) and thought to correspond to the left-handed Z DNA structures recently established by X-ray crystallography (Wang et al., 1979; Drew et al., 1980). However, L DNA formed in Mg2+-EtOH (which we designate as Z* DNA) has unique properties: a) it can be sedimented readily out of solution at low speed, indicative of condensation and intermolecular aggregation; b) it supports the binding of several intercalating (ethidium bromide, actinomycin D) and non-intercalating (mithramycin) drugs, although these interact preferentially with the R (i.e., B) form of DNA; and c) it functions as a template for Escherichia coli RNA polymerase. B and Z* DNAs can be generated under identical ionic conditions and compared in a number of biochemical systems. Our results suggest that left-handed DNA may form under physiological conditions and serve a biological function.     

Interaction of intercalating and non-intercalating agents with DNA: use of hydroxyapatite chromatography and S1 nuclease

We have used hydroxyapatite (HA) chromatography and S1 nuclease hydrolysis to study the modification in the secondary structure of DNA caused by certain intercalating and non-intercalating ligands. The principal conclusions of HA experiments were as follows: (1) when native DNA, complexed with drugs believed to bind to DNA by intercalation (ethidium bromide, acridine orange, actinomycin D and acriflavin), is chromatographed on HA a lower affinity of DNA for HA is observed; also, the DNA elutes from HA columns as a drug-DNA complex; (ii) ligands that are known to interact with DNA by surface interactions do not show these effects; (iii) it may be possible to quantitate the binding of the intercalating drug to DNA and to determine its degree of binding by HA chromatography. Possibly, intercalation causes a change in the configuration of the sugarphosphate backbone of DNA, resulting in an altered steric orientation or 'burial' of phosphate groups with reduced availability for surface interactions with HA. S1 nuclease was used to determine the thermal melting profiles of DNA complexed with ethidium bromide and acridine orange. The melting profile in both cases was found to be biphasic with considerably reduced denaturation even at 95 degrees C. This is accounted for by the property of intercalating agents of stabilizing the secondary structure of DNA and the reported preference in binding to G-C base pairs.     

Crystal structure of the Tyr45Trp mutant of ribonuclease T1 in a complex with 2'-adenylic acid

The recombinant Tyr45Trp mutant of Lys25-ribonuclease T1 was overexpressed and purified from an Escherichia coli strain. The mutant enzyme, which shows reduced activity towards GpA and increased activity towards pGpC, pApC and pUpC compared with wild-type RNase T1, was co-crystallized with 2'-adenylic acid by microdialysis. The space group is P212121 with unit cell dimenions a = 4.932(2), b = 4.661(2), c = 4.092(1) nm. The crystal structure was solved using the coordinates of the isomorphous complex of wild-type RNase T1 with 2'-AMP. The refinement was based on Fhkl of 7726 reflexions with Fo greater than or equal to 1 sigma (Fo) in the resolution range of 2.0-0.19 nm and converged with an R factor of 0.179. The adenosine of 2'-AMP is not bound to the guanosine binding site, as could be expected from the mutation of Tyr45Trp, but is stacked on the Gly74 carbonyl group and the His92 imidazole group which form a subsite for substrate binding, as already observed in the wild-type 2'-AMP complex. The point mutation of Tyr45Trp does not perturb the backbone conformation and the Trp-indole side chain is in a comparable position to the phenolic Tyr45 of the wild-type enzyme.     

Antiestrogen action: Differential nuclear retention and extractability of the estrogen receptor

Since there is a much longer uterine nuclear retention of the U-11,100A (antiestrogen) receptor complex (UARC) than of the estradiol receptor complex (ERC) at 4–12 hrs after injection, experiments were designed to determine if there is a difference between the relative nuclear affinities for the two RCs as determined by extraction with various ionic strength mediums. Although the UARC was retained longer in the nuclear fraction $\text{in}$$\text{vivo}$, the UARC was completely extractable with 0.3M KC1 or 50mM spermine, whereas the ERC demonstrates a saltresistant form. This suggests that the ERC is more tightly bound to nuclear components through this salt-resistant form of the receptor. In addition, various intercalating agents were used to distinguish the different nuclear chromatin DNA sites where the UARC and ERC may be binding. With actinomycin D (50 uM) more ERC than UARC was retained in the nuclear fraction. However, with ethidium bromide (100uM) less ERC than UARC was retained. Also, the ERC selectively released by ethidium bromide is precisely that fraction not released by salt. These results indicate that the UARC and ERC bind to different chromatin loci.     

DNA structural variations produced by actinomycin and distamycin as revealed by DNAase I footprinting.

The technique of DNAase I footprinting has been used to investigate preferred binding sites for actinomycin D and distamycin on a 160-base-pair DNA fragment from E. coli containing the tyr T promoter sequence. Only sites containing the dinucleotide step GpC are protected by binding of actinomycin, and all such sites are protected. Distamycin recognizes four major regions rich in A + T residues. Both antibiotics induce enhanced rates of cleavage at certain regions flanking their binding sites. These effects are not restricted to any particular base sequence since they are produced in runs of A and T by actinomycin and in GC-rich sequences by distamycin. The observed increases in susceptibility to nuclease attack are attributed to DNA structural variations induced in the vicinity of the ligand binding site, most probably involving changes in the width of the helical minor groove.     

The effect of several nucleic acid binding drugs on the cleavage of d(GGAATTCC) and pBR 322 by the Eco RI restriction endonuclease

The endonucleolytic action of the EcoRI restriction enzyme on the double-stranded oligonucleotide d(GGAATTCC) and the supercoiled plasmid DNA pBR 233 is inhibited by actinomycin D, ethidium bromide, proflavin, distamycin A and netropsin. Half-maximal inhibition is observed at around 100 microM concentrations for the intercalating drugs, and around 0.1 to 1 microM concentrations for netropsin and distamycin A. The inhibitory activity of these drugs can be correlated with their affinity to the oligonucleotide and the plasmid DNA. Since at high concentrations of the drugs a complete inhibition is observed, it is concluded that the effect of the drugs on the stereochemistry of the EcoRI site is such that recognition is excluded.     

DNA supercoiling in vivo

DNA topoisomerase mutants of Escherichia coli and Saccharomyces cerevisiae were used to study the topological state of intracellular DNA. In E. coli, it is shown that switching off the gene topA encoding DNA topoisomerase I leads to an increase in the degree of negative supercoiling of intracellular DNA and inhibition of the growth of the cells: a d(pCpG)16.d(pCpG)16 sequence on a plasmid is also shown to flip from a right-handed B-helical structure to a left-handed Z-helical structure in vivo when topA is switched off. In S. cerevisiae, the topological state of intracellular DNA is little affected by the cellular levels of the topoisomerases.