Actinomycin D binding to unstructured, single-stranded DNA.

Actinomycin D is an anticancer antibiotic best know for inhibiting transcription by binding double-stranded DNA. Tight, sequence selective binding of actinomycin to single-stranded DNA is also known, however, and is implicated in biological activities including inhibition of (-) strand transfer by HIV reverse transcriptase. Oligonucleotide d(GTTAACCATAG) is one of the rare single-stranded DNAs that lack GC steps yet have high affinity for actinomycin. Oligonucleotide sequence and length requirements for drug binding were investigated by monitoring association of the fluorescent surrogate, 7-aminoactinomycin D, to d(GTTAACCATAG) and 31 related oligomers. The TAG-3' terminal sequence was essential for high-affinity binding, but was not sufficient. Five oligomers with TAG sequences on or near the 3'-end had high affinity [K(d) < or = 200 nM (oligomer)]. A sixth oligomer, d(GTAACCATATG), had moderately lower affinity (Kd = 370 nM), and other homologous oligomers had much lower affinity. The minimum length sequence for tight binding of 7-aminoactinomycin D was identified as only eight nucleotides, corresponding to d(AACCATAG). This octanucleotide is unstructured in the absence of actinomycin, and has the highest drug affinity of all oligomers examined (Kd = 125 nM). These studies show that high-affinity binding of 7-aminoactinomycin, and actinomycin D by extension, to single-stranded DNA does not require pre-existing secondary structure or any apparent propensity for secondary structure. It is proposed that actinomycin D binds to certain single-stranded DNA sequences by an induced-fit mechanism favored by participation of at least eight nucleotides, or the equivalent of four base pairs.

Analysis of oligonucleotides and unincorporated nucleotides from in vitro transcription by capillary electrophoresis in Pluronic F127 gels.

Small functional RNAs required for structure studies are often prepared by in vitro transcription. Capillary electrophoresis in liquid crystalline gels of Pluronic F127 was used to analyze unfractionated in vitro transcription reactions and anion-exchange high-performance liquid chromatography (HPLC) fractions from transcription reactions. Guanosine monophosphate (GMP), the four nucleoside triphosphates (NTPs), abortive transcripts, and transcripts with lengths near the desired product length were simultaneously resolved and quantified in a single run. Oligonucleotides up to at least 35 nucleotides were resolved to baseline within 10 min using a moderate field (185 V/cm) and short effective capillary length (7.6 cm) for electrophoresis in 20% Pluronic F127 at pH 8.3 in Tris-borate-EDTA (TBE) buffer (30 degrees C). Nucleotide migration times were 4-5 min, in the order UTP+CTP (unresolved)

Pluronic copolymer liquid crystals: unique, replaceable media for capillary gel electrophoresis.

Liquid crystalline solutions of Pluronic copolymers are versatile alternatives to solutions of entangled, random coil polymers as replaceable media for capillary gel electrophoresis (CGE). Pluronic copolymers are tri-block polymers of poly(ethylene oxide) [(EO)x] and poly(propylene oxide) [(PO)y] with the general formula (EO)x(PO)y(EO)x. Large micelles form in aqueous solutions in which central, hydrophobic cores of (PO)y segments are surrounded by "brushes" of hydrated (EO)x tails. Solutions of Pluronic F127 (BASF Performance Chemicals) in a concentration range of about 18-30% are liquids at refrigerator temperatures (< or = 5 degrees C) and are easily introduced into capillaries. A self-supporting, gel-like liquid crystalline phase is formed as the temperature is raised to > or = 20 degrees C. This liquid crystalline phase consists of spherical micelles with diameters of 17-18 nm which pack with local cubic symmetry. CGE in Pluronic F127 liquid crystals separates species within several chemical classes as varied as nucleoside monophosphates and organic dyes, oligonucleotides of 4-60 nucleotides, DNA fragments of 50-3000 base pairs (bp), and supercoiled plasmid DNAs of 2000-10,000 bp. Mechanisms of molecular sieving in polymer liquid crystals must differ in fundamental ways from separations in random polymer gels because molecules move around uncrosslinked obstacles that are larger than the smallest dimensions of typical analytes. Molecular sieving in Pluronic liquid crystals is envisioned to occur as molecules squeeze between hydrated (EO)x strands of micelle brushes, or through brushtips and interstitial spaces between micelles. Small molecules such as nucleotides appear to separate by a different mechanism involving partitioning between hydrophilic and hydrophobic environments. This process is termed "hydrophobic interaction electrophoresis". The unique structures of Pluronic copolymers and their liquid crystalline phases provide new challenges and opportunities in separations science.

Electrophoresis in lyotropic polymer liquid crystals.

Excellent electrophoretic separations of a variety of biological molecules can be accomplished by using uncharged, triblock copolymers as the "gel" media. These copolymers form uncrosslinked, lyotropic liquid crystalline phases of large micelles between which molecules must travel. Unlike crosslinked hydrogels in common use, these alternative media have highly ordered internal structures. Pluronic F127, representative of the copolymer class, contains poly(ethylene oxide) (EO) and poly(propylene oxide) (PO) units with an approximate molecular formula (EO)106(PO)70(EO)106. Concentrated (18-30%) solutions of Pluronic F127 are freely flowing liquids at low temperature (0-5 degrees C) but form gel-like, cubic liquid crystals of large, spherical micelles when warmed. The utility of these media is illustrated by separations of linear, double-stranded DNA up to 3,000 bp long by conventional electrophoresis, and of single-stranded DNAs from 4 to 60 nt long by capillary electrophoresis. Extraordinary separations of supercoiled DNAs were also obtained by capillary electrophoresis. The versatility, availability, and ease of use of Pluronic polymers offer major advantages over conventional media for preparative and high performance analytical separations of nucleic acids and other biomolecules. Mechanisms of molecular transport and separation operating in polymer liquid crystals must differ in fundamental ways from those in crosslinked gels. Lyotropic polymer liquid crystals are unique systems for elucidating mechanisms of macromolecule migration in ordered, dense media, and provide opportunities in separations science.

Error analysis of chemically synthesized polynucleotides.

Two single-stranded polynucleotide constructs, 123 and 126 nucleotides in length, were chemically synthesized using standard phosphoramidite chemistry. Clonable, double-stranded DNA fragments about 100-bp long were prepared from the polynucleotides by primer extension with a DNA polymerase and end-trimming with two restriction endonucleases, then the fragments were ligated into separate plasmids. Errors in individual insert copies were determined by dideoxy sequencing after in vivo amplification of plasmids. Five of the ten inserts sequenced contained errors, including seven single-base-pair deletions, one four-base-pair deletion and one G-->C transversion. The origins of the latter two errors are unclear, but single-base deletions are inconsistent with errors of polymerases; thus, the most common sequence errors of chemical synthesis are deletion mutations. Deletions are most likely to result from incomplete capping or de-tritylation. The observed error rate can became a significant limiting factor in applications that depend on the correctness of a polynucleotide sequence in individual insert clones.

Templated pores in hydrogels for improved size selectivity in gel permeation chromatography.

The pore structures of cross-linked polyacrylamide gels can be altered by polymerizing in the presence of high concentrations of unreactive, micellar surfactant cosolutes which act as "templates". Removal of surfactant after polymerization is expected to leave pores with the approximate shape and dimensions of the surfactant micelles. A simple model was developed to simulate gel permeation chromatography (GPC) separations of globular proteins on templated gels. The model assumes that the partition coefficient for sieving of a protein is equal to the fraction of gel volume accessible to a sphere with a radius equal to the protein Stokes radius. The total gel volume is considered to include a fraction that is a conventional, random gel matrix and a remaining fraction contributed by templated pores. The pore size distribution of the conventional gel was estimated using the Ogston equation, which approximates the matrix as a random collection of long, thin, rigid fibers. Templated pores were assumed to have a Gaussian distribution of radii centered about some mean determined by the micelle radius. In comparison to conventional media, gels with templated pores are predicted to exhibit more sharply defined exclusion limits and improved resolution over a narrow size range centered on the mean templated pore size. Selectivity and resolution are expected to increase as the volume fraction of templated pores is increased and as the dispersion of templated pore radius is decreased. Small changes in template radius lead to large changes in the molecular weight range of optimal separation of globular proteins. It should be possible to create a series of GPC media that collectively offer high resolution over the molecular weight range of most globular proteins of interest.

DNA length and concentration dependencies of anisotropic phase transitions of DNA solutions.

Critical concentrations for the isotropic to cholesteric phase transitions of double-stranded DNA fragments in simple buffered saline (0.1 M NaCl) solutions were determined as a function of DNA contour length ranging from approximately 50 nm to 2700 nm, by solid-state 31P NMR spectroscopy and polarized light microscopy. As expected for semirigid chains, the critical concentrations decrease sharply with increasing DNA length near the persistence length in the range from 50 to 110 nm, and approach a plateau when the contour length exceeds 190 nm. The biphasic region is substantially wider than observed for xanthan, another semirigid polyelectrolyte approximately twice as stiff as DNA, primarily because of low critical concentrations for first appearance of the anisotropic phase, C(i)*, in DNA samples > or =110 nm (320 base pairs) long. The limiting C(i)* for DNA > or =490 nm long is exceptionally low (only 13 mg/ml) and is substantially lower than the C(i)* of approximately 40 mg/ml reported for the stiffer xanthan polyelectrolyte. The much higher values of the critical concentrations, C(a)*, for the disappearance of the isotropic DNA phase (> or =67 mg/ml) are modestly higher than those observed for xanthan and are predicted reasonably well by a theory that has been applied to other semirigid polymers, if a DNA persistence length in the consensus range of 50-100 nm is assumed. By contrast, the broad biphasic region and low C(i)* values of DNA fragments > or =190 nm long could only be reconciled with theory by assuming persistence lengths of 200-400 nm. The latter discrepancies are presumed to reflect some combination of deficiencies in current theory as applied to chiral, strong polyelectrolytes such as DNA, and sequence-dependent variations in DNA properties such as flexibility, curvature, or interaction potential. The propensity of DNA to spontaneously self-order at low concentrations well in the physiological range may have biological significance.

Synthetic polynucleotide templates for characterizing sequence-selective small molecule/nucleic acid interactions.

A synthetic polynucleotide sequence was developed and cloned to serve as a target in footprinting and other assays designed to characterize the sequence-selective binding of drugs and other small molecules to various forms of nucleic acids. The target sequence comprehensively represents all base quartet recognition sites in a minimal length sequence. Minimal length target sequences were found to be 144 nt long. One such target sequence was divided into two parts. One strand of each part was chemically synthesized and the complementary strands were generated using a DNA polymerase. Double-stranded sequences were then cloned into pGEM-3Zf(+/-) vectors (Promega, Inc.). The cloned target sequence can be used directly in double-stranded DNA form. Alternatively, features of the plasmid vector allow expression of the target sequences as single-stranded DNA or RNA or as RNA/DNA or RNA/RNA duplexes. These cloned target sequences designed for high information content overcome limitations to the use of natural DNA sequences for footprinting and related experiments arising from the unequal representation of base quartets and the potential for secondary structure formation in single-stranded forms.

Selective DNA binding of (N-alkylamine)-substituted naphthalene imides and diimides to G+C-rich DNA.

Alkylamine-substituted naphthalene imides and diimides bind DNA by intercalation and have applications as anticancer agents. The unique structures of these imides in which two adjacent carbonyl groups lie coplanar to an extended aromatic ring system allow the possibility of sequence-selective interactions between the intercalated chromophore and guanine amino groups situated in the DNA minor groove. The binding affinities of N-[3-(dimethylamino)propyl amine]-1,8-naphthalenedicarboxylic imide (N-DMPrNI) and N,N'-bis [3,3'-(dimethylamino)propylamine]-naphthalene-1,4,5,8-tetracarboxylic diimide (N-BDMPrNDI) for natural DNAs of differing base composition were determined spectroscopically and by equilibrium dialysis. In agreement with the above proposition, binding studies indicated that both the naphthalene imide and diimide strongly prefer to intercalate into steps containing at least one G:C base pair. The dependencies of association constants on DNA base composition are consistent with a requirement for one G:C pair in the binding site of the monomide, and two G:C pairs in binding sites of the diimide. These selectivities are comparable to or exceed that of actinomycin D, a classic G:C-selective drug. Protection footprinting with DNase I confirmed that the naphthalene monoiimide (N-DMPrNI) prefers to bind adjacent to G:C base pairs, with a most consistent preference for "mixed" steps containing both a G:C and an A:T pair, excepting GA:TC. Several 5'-CG-3' steps were also good binding sites as indicated by nuclease protection, but few GC:GC or GG:CC steps were protected. The naphthalene diimide inhibited DNase I digestion, but did not yield a footprint. The base recognition ability and versatile chemistry make naphthalene imides and diimides attractive building blocks for design of highly sequence-specific, DNA-directed drug candidates including conjugated oligonucleotides or oligopeptides.

Protein electrophoresis in polyacrylamide gels with templated pores.

An approach is described for the synthesis of nanostructured hydrogels with defined size channels or pores for separations of biological macromolecules. Polyacrylamide gels (15-20% acrylamide) were cast in the presence of high concentrations (5%-28%) of hydrophilic, macromolecular cosolutes either semirigid, rod-like polyelectrolytes (short fragments of DNA or xanthan) or spherical micelles of sodium dodecyl sulfate (SDS). Polyanionic cosolutes were then removed by a combination of diffusion and electrophoresis. These processes are expected to yield gels with 'templated' channels having dimensions near those of the double helical polymers (diameters approximately 2-3 nm, lengths of 50-200 nm) or pores near the size of the spherical SDS micelles (approximately 4-5 nm). This hypothesis was tested by comparing the relative electrophoretic mobilities of proteins (3400 to 43,000 Da) complexed with SDS on templated and conventional gels. Differences in electrophoretic mobilities were observed between all templated gels and control normal gels, demonstrating that the templating process altered the polyacrylamide network. No evidence was found for phase separation of cosolutes from the polyacrylamide network during polymerization. Templated pores are expected to enhance the mobilities of molecules in a particular size range relative to smaller and larger molecules. Gels templated with DNA or xanthan (8-10% final concentration) exhibited little size selectivity, but selectivity was observed for gels templated with SDS varied with polyacrylamide concentration in a manner consistent with the creation of templated pores approximately the size of SDS micelles and larger than the average pore size in a surrounding polyacrylamide network.

N,N'-bis[3,3'-(dimethylamino)propylamine]-3,4,9, 10-perylenetetracarboxylic diimide, a dicationic perylene dye for rapid precipitation and quantitation of trace amounts of DNA.

A novel dicationic dye with a polycyclic aromatic perylene core and flexible cationic side chains- N,N'-bis[3, 3'-(dimethylamino)propylamine]-3,4,9,10-perylenetetracarboxylic diimide-termed "DAPER," was synthesized and characterized. The dye appears to exist in a highly stacked form in aqueous solution. DAPER precipitates extremely low concentrations of DNA very rapidly, efficiently, and with a stoichiometry of one tightly bound dye per DNA base pair, corresponding to a neutral complex. Precipitation may occur due to side-by-side association between the polyanionic DNA helix and polycationic dye stacks. DNA precipitation by DAPER is less sensitive to DNA concentration and length, and prevailing salt concentrations, than precipitation with ethanol or propanol. DAPER can be quantitatively extracted from DNA into a standard phenol:chloroform mixture under slightly alkaline conditions. The recovered DNA is suitable for treatment with enzymes typically used in DNA sequencing procedures. The amount of DNA precipitated is accurately determined by visible absorption or fluorescence spectroscopic analyses of the phenol:chloroform extracts. Several samples of DNA can be precipitated, recovered, and quantitated in about 1 h using standard microscale procedures and equipment. The unique qualities of DAPER provide the basis for a very sensitive, rapid, and versatile method for simultaneous precipitation and quantitation of microgram and submicrogram amounts of DNA.

Sequence-specific actinomycin D binding to single-stranded DNA inhibits HIV reverse transcriptase and other polymerases.

Primer extension assays using recombinant templates constructed to contain all 256 possible base quartets in a minimum length sequence were used to examine binding of the anticancer drug actinomycin D to single-stranded DNA. Single-stranded templates were generated by digestion of linearized plasmid with the double-strand-specific T7 gene 6 exonuclease. Actinomycin D formed high-affinity, kinetically stable complexes that paused primer elongation at specific sites by HIV-1 reverse transcriptase, Sequenase (modified T4 DNA polymerase), the Klenow fragment of Escherichia coli DNA polymerase, and Vent (exo-) DNA polymerase. Pauses occurred most commonly near G+C-rich nucleotide clusters, including GpC steps, the preferred sites of double-stranded DNA binding. Complexes were stable for several minutes at temperatures over 50 degrees C as determined by their abilities to pause Vent polymerase at elevated temperatures. Significant variations were noted in pause patterns of different polymerases, demonstrating differential responses of polymerases to a bound actinomycin. Covalent adducts formed on template DNA by a photoaffinity analog of actinomycin D completely stopped primer extension. These results support the possibility that actinomycin D inhibits transcription elongation by complexing single-stranded DNA in the open transcription complex. Single-stranded DNA binding by actinomycin D or analogs may also provide routes for combating HIV or other viruses which replicate through single-stranded intermediates.

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.

Binding of actinomycin D to the T(G)nT motif of double-stranded DNA: determination of the guanine requirement in nonclassical, non-GpC binding sites.

Strong binding of the antitumor antibiotic actinomycin D to the sequence 5'-TGGGT-3' in double-stranded DNA was recently established by equilibrium binding studies (Bailey et al., 1993). Actinomycin D binding to this -TGGGT- containing sequence was shown to be comparable to that of an -XGCY- containing oligonucleotide (Ka approximately 10(6) M-1). Investigation of -TGGGT- as a high-affinity binding site for actinomycin D follows from our 1989 sequencing study (Rill et al., 1989) in which the photoaffinity analog of actinomycin D (7-azidoactinomycin D) was used to determine DNA base sequence specificities and neighboring base effects. The studies presented here examine the guanine requirements for actinomycin D binding to such nonclassical (non-dGpC) sites by varying the number of central guanine residues in a series of selected duplex oligonucleotides. The central -T(G)nT- motif varies from n equals 1 to 4. Actinomycin D binding to each of these undecamers is characterized and correlated with binding to oligonucleotides of identical length and similar sequences that contain classical dGpC binding sites. Binding affinities of actinomycin D to this series of oligonucleotide duplexes (10 degrees C) can be summarized as -TGGGT- > -TGGT- > TGGGGT- > -TGT. The kinetics of SDS-induced dissociation of actinomycin D from these oligonucleotides reveal single-exponential decays with duration dependent on the sequence at the binding site. With the exception of the -TGGGT- containing oligomer, dissociation times for the T(G)nT duplexes were drastically different and much shorter than times obtained for the dissociation of actinomycin D from oligonucleotides having classical dGpC sites.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of DNA base sequence on the binding energetics of actinomycin D.

The influences of base sequence on the thermodynamic properties associated with the interaction of actinomycin D with DNA are examined. It has been previously established that GpC steps of double-helical DNAs are highly preferred binding sites for actinomycin D. In this study, a series of oligonucleotides was designed and synthesized to probe the effects of flanking base sequence (adjacent to the GpC step) and novel non-GpC binding sites on the binding of actinomycin D. The use of these oligonucleotides provides a direct method for quantitating sequence specificities and actinomycin D binding energetics. Effects of different 5' and 3' flanking nucleotides on the interactions of actinomycin with the core GpC binding sites were examined using UV-visible spectrophotometric methods, and changes in binding energetics were quantitated. These studies demonstrate strong actinomycin D binding affinities to both classical GpC and an atypical non-GpC site. Enthalpy and entropy components of the DNA binding energetics for the GpC binding sites are compared and correlated with those determined for actinomycin D binding to the high-affinity non-GpC site of an 11-mer containing TGGGT as the central sequence. This TGGGT site, first suggested to be a high-affinity sequence in our earlier photoaffinity labeling studies, exhibits binding of actinomycin D comparable in strength to that of traditional actinomycin D binding sites (i.e., GpC steps). From these studies, the overall affinity and specific thermodynamic contributions (delta H degree, delta S degree) to binding of actinomycin D are demonstrated to be highly influenced both by the sequence at the intercalation site and by neighboring bases which flank the intercalation site.

The influence of reducing agent and 1,10-phenanthroline concentration on DNA cleavage by phenanthroline + copper.

Copper in the presence of excess 1,10-phenanthroline, a reducing agent, and molecular oxygen causes cleavage of DNA with a preference for T-3',5'-A-steps, particularly in TAT triplets. The active molecular species is commonly thought to be the bis-(1,10-phenanthroline)Cu(I) complex, (Phen)2Cu(I), regardless of the reducing agent type. We have found that (Phen)2Cu(I) is not the predominant copper complex when 3-mercaptopropionic acid (MPA) or 2-mercaptoethanol are used as the reducing agents, but (Phen)2Cu(I) predominates when ascorbate is used as the reducing agent. Substitution of ascorbate for thiol significantly enhances the rate of DNA cleavage by 1,10-phenanthroline + copper, without altering the sequence selectivity. We show that (Phen)2Cu(I) is the complex responsible for DNA cleavage, regardless of reducing agent, and that 1,10-phenanthroline and MPA compete for copper coordination sites. DNA cleavage in the presence of ascorbate also occurs under conditions where the mono-(1,10-phenanthroline)Cu(I) complex predominates (1:1 phenanthroline:copper ratio), but preferential cleavage was observed at a CCGG sequence and not at TAT sequences. The second phenanthroline ring of the (Phen)2Cu(I) complex appears essential for determining the T-3',5'-A sequence preferences of phenanthroline + copper when phenanthroline is in excess.

Noncovalent DNA binding of bis(1,10-phenanthroline)copper(I) and related compounds.

The noncovalent DNA binding of the bis(1,10-phenanthroline)copper(I) complex [(Phen)2CuI] was examined under anaerobic conditions by absorption and circular dichroism spectroscopy, and viscometry, as a function of phenanthroline concentration. Analyses according to the McGhee-von Hippel method indicated that binding exhibited both neighbor-exclusion and positive cooperativity effects, with a neighbor-exclusion parameter n approximately 2 and a cooperativity parameter omega approximately 4. The association constant for (Phen)2CuI binding decreased with increasing concentration of phenanthroline in excess over that required to stoichiometrically generate (Phen)2CuI, indicating that free phenanthroline was a weak competitive inhibitor of (Phen)2CuI binding. The maximal association constant for DNA binding of (Phen)2CuI in 0.2 M NaCl and 9.8% ethanol, extrapolated to zero concentration of excess phenanthroline, was 4.7 x 10(4) M-1 (DNA base pairs). The magnitude of the neighbor-exclusion parameter, the changes in spectral properties of (Phen)2CuI induced by DNA binding, and the increase in DNA solution viscosity upon (Phen)2CuI addition are consistent with a model for DNA binding by (Phen)2CuI involving partial intercalation of one phenanthroline ring of the complex between DNA base pairs in the minor groove as suggested previously [Veal & Rill (1989) Biochemistry 28, 3243-3250]. Viscosity measurements indicated that the mono(phenanthroline)copper(I) complex also binds to DNA by intercalation; however, no spectroscopic or viscometric evidence was found for DNA binding of free phenanthroline or the bis(2,9-dimethyl-1,10-phenanthroline)copper(I) complex. DNA binding of free phenanthroline may be cooperative and induced by prior binding of (Phen)2CuI.

Electrochemical deposition of molecular adsorbates for in situ scanning probe microscopy.

We have studied gold and graphite electrodes in an electrochemistry cell under various solutions using the scanning tunneling microscope (STM). The gold (111) surface yields quite reproducible images and cyclic voltammograms. In situ voltammograms show that, under certain conditions, nanomolar quantities of DNA fragments can suppress the adsorption of a buffer salt of millimolar concentration. When the DNA concentration is reduced below that required for a monolayer coverage, the salt adsorption is restored. We show images of bare gold, gold covered with an adsorbate produced by the buffer salt, and gold prepared with a concentration of DNA fragments close to that required for monolayer coverage added to the buffer. Under these conditions, the surface is found to be uniformly covered with a characteristic structure.

Sequence preferences of covalent DNA binding by anti-(+)- and anti-(-)-benzo[a]pyrene diol epoxides.

The sequence preferences of formation of piperidine-labile adducts of guanine by individual (+)- and (-)-isomers of trans-7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10- tetrahydrobenzo[a]pyrene [anti-(+)- and anti-(-)-BPDE] were examined by techniques analogous to chemical DNA sequencing. Data were obtained on over 1200 bases with anti-(-)-BPDE and 1000 bases with anti-(+)-BPDE. Guanines on average yielded more labile adducts than other bases, and the reactivities of guanines with both anti-(+)- and anti-(-)-BPDE isomers were found to be distinctly nonrandom with respect to DNA sequence. The most and least reactive guanines, defined in terms of the upper and lower 10 percentiles of reactivity, differed on average by a factor of 17. This range of guanine reactivities was correlated with distinct sequence preferences, which differed in part for the two isomers. The strongest determinant for preferred reaction of anti-(-)-BPDE to form a labile adduct at a guanine was the presence of a 3'-flanking guanine, but a thymine 5'-flanking a guanine also generally enhanced reactivity. The triplets containing central guanines most preferred by anti-(-)-BPDE were AGG, CGG, and TG(G greater than T greater than C,A). anti-(+)-BPDE also formed labile adducts preferentially at AGG and CGG triplets, but not at TGN triplets. Significant effects of next-nearest-neighbor bases on guanine reactivities were also noted.