DNA-binding peptides searched from the solid-phase combinatorial library with the use of the magnetic beads attaching the target duplex DNA

We have exhibited successful and rapid screening of DNA-binding peptide ligands from solid-phase library beads with the use of the target DNA-conjugated magnetic beads. The target duplex DNA (3) has a polyether linker between two complementary sequences (T4A3G-ether linker-CT3A4) and is stable in the duplex form during the selection procedure. Finally, 71 pentapeptide sequences were identified from the solid-phase pentapeptide library. From an analysis of the peptide sequences identified in this study, it has been revealed that peptide ligands contain hydrophobic amino acids as the major component. The synthetic peptides with identified sequences and a combination of the major components have exhibited moderate to high binding affinity to the duplex DNA in competition experiments with ethidium-DNA complexes.     

Recognition of duplex DNA by RNA polynucleotides.

We are interested in creating artificial gene repressors based on duplex DNA recognition by nucleic acids. Homopyrimidine RNA oligonucleotides bind to duplex DNA at homopurine/homopyrimidine sequences under slightly acidic conditions. Recognition is sequence-specific, involving rU.dA.dT and rC+.dG.dC base triplets. Affinities were determined for folded polymeric RNAs (ca. 100-200 nt) containing 0, 1 or 3 copies of a 21 nt RNA sequence that binds duplex DNA by triple helix formation. When this recognition sequence was inserted into the larger folded RNAs, micromolar concentrations of the resulting RNA ligands bound a duplex DNA target at pH 5. However, these binding affinities were at least 20-fold lower than the affinity of an RNA oligonucleotide containing only the recognition sequence. Enzymatic probing of folded RNAs suggests that reduced affinity arises from unfavorable electrostatic, structural and topological considerations. The affinity of a polymeric RNA with three copies of the recognition sequence was greater than that of a polymeric RNA with a single copy of the sequence. This affinity difference ranged from 2.6- to 13-fold, depending on pH. Binding of duplex DNA by polymeric RNA might be improved by optimizing the RNA structure to efficiently present the recognition sequence.     

Novel DNA-binding ligands with sequence selectivity based on hydrophobic structure.

We have developed diamino-bistetrahydrofuran compounds (diamino-bisTHF) as new DNA binding molecules. Diamino-bisTHF (3:RR8) stabilized GC-rich duplex DNA with sequence specificity. DNA binding affinity increased as the alkyl chain was lengthened, indicating that the hydrophobic interaction is essential for DNA binding. It was also found that DNA binding affinity of the ligands depends on the stereochemistry of the amino group. In thermodynamic evaluation, diamino-bisTHF (3:RR8) showed a high affinity to the 12 bp duplex at a molar ratio of 1:1.     

Repertoire selection of variant single-chain Cro: toward directed DNA-binding specificity of helix-turn-helix proteins

A single-chain derivative of the lambda Cro repressor (scCro) has been randomly mutated in amino acid residues critical for specific DNA recognition to create libraries of protein variants. Utilizing phage display-afforded affinity selection, scCro variants have been isolated for binding to synthetic DNA ligands. Isolated scCro variants were analyzed functionally, both in fusion with phage particles and after expression of the corresponding free proteins. The binding properties with regard to specificity and affinity in binding to different DNA ligands were investigated by inhibition studies and determination of equilibrium dissociation constants for formed complexes. Variant proteins with altered DNA-sequence specificity were identified, which favored binding of targeted synthetic DNA sequences over a consensus operator sequence, bound with high affinity by wild-type Cro. The specificities were relatively modest (2-3-fold, as calculated from K(D) values), which can be attributed to the inherent properties in the design of the selection system; one half-site of the synthetic DNA sequences maintains the consensus operator sequence, and one "subunit" of the variant single-chain Cro dimers was conserved as wild-type sequence. The anticipated interaction between the wild-type subunit and the consensus DNA half-site of target DNA ligands is, hence, expected to contribute to the overlap in sequence discrimination. The binding affinity for the synthetic DNA sequences, however, was improved 10-30-fold in selected variant proteins as compared to "wild-type" scCro.     

Structural changes of an abasic site in duplex DNA affect noncovalent binding of the spin label ç

The influence of structural changes of an abasic site in duplex DNA on noncovalent and site-directed spin labeling (NC-SDSL) of the spin label ç were examined with electron paramagnetic resonance (EPR) spectroscopy. The binding affinities of ç to sixteen different DNA duplexes containing all possible sequences immediately flanking the abasic site were determined and the results showed that the binding of ç is highly flanking-sequence dependent. In general, a 5′-dG nucleotide favors the binding of the spin label. In particular, 5′-d(G__T) was the best binding sequence whereas 5′-d(C__T) showed the lowest affinity. Changing the structure of the abasic site linker from a tetrahydrofuran analog (F) to the anucleosidic C₃-spacer (C₃) does not appreciably affect the binding of ç to the abasic site. For efficient binding of ç, the abasic site needs to be located at least four base pairs away from the duplex end. Introducing a methyl substituent at N3 of ç did not change the binding affinity, but a decreased binding was observed for both N3-ethyl and -propyl groups. These results will guide the design of abasic site receptors and spin label ligands for NC-SDSL of nucleic acids.     

Novel class of DNA binding motifs based on bistetrahydrofuran and bisfuran skeleton with long alkyl chains

Small molecules with DNA-binding affinity within the minor groove have become of great interest. In this paper, new DNA binding molecules; diamino-bistetrahydrofuran (bisTHF) and diamino-bisfuran are reported. The bisTHF ligand with RR configuration at the amino groups and C8 alkyl chains (RR8) stabilized GC-rich duplex. In contrast, bisfuran compounds stabilized AT-rich duplex. The binding affinity of RR8 with 12 mer duplex DNA was determined by isothermal titration calorimetry to be 3.3 x 10(8) M-1.     

A CT promoter element binding protein: definition of a double-strand and a novel single-strand DNA binding motif.

Numerous genes contain promoter elements that are nuclease hypersensitive. These elements frequently possess polypurine/polypyrimidine stretches and are usually associated with altered chromatin structure. We have previously isolated a clone that binds a class of CT-rich promoter elements. We have further characterized this clone, termed the nuclease-sensitive element protein-1, or NSEP-1. NSEP-1 binds both duplex CT elements and the CT-rich strand of these elements in a 'generic' sequence specific manner and has overlapping but distinct single-and double-strand DNA binding domains. The minimal peptide region sufficient for both duplex and single-strand DNA binding includes two regions rich in basic amino acids flanking an RNP-CS-1 like octapeptide motif. Deletion analysis shows that the single-strand DNA binding activity is mediated by the RNP-CS-1 like octapeptide motif and is the key peptide region necessary for single-strand binding. NSEP-1's affinity for CT rich promoter elements with strand asymmetry in addition to its double- and single-strand DNA binding properties suggests that it may be a member of a class of DNA binding proteins that modulate gene expression by their ability to recognize DNA with unusual secondary structure.     

NOVEL CLASS OF DNA BINDING MOTIFS BASED ON BISTETRAHYDROFURAN AND BISFURAN SKELETON WITH LONG ALKYL CHAINS

Small molecules with DNA-binding affinity within the minor groove have become of great interest. In this paper, new DNA binding molecules; diamino-bistetrahydrofuran (bisTHF) and diamino-bisfuran are reported. The bisTHF ligand with RR configuration at the amino groups and C8 alkyl chains (RR8) stabilized GC-rich duplex. In contrast, bisfuran compounds stabilized AT-rich duplex. The binding affinity of RR8 with 12 mer duplex DNA was determined by isothermal titration calorimetry to be 3.3 × 10⁸ M^?1.     

Targeting Telomeres: Molecular Dynamics and Free Energy Simulation of Gold-Carbene Binding to DNA

DNA sequences in regulatory regions and in telomers at the ends of chromosomes frequently contain tandem repeats of guanine nucleotides that can form stacked structures stabilized by Hoogsten pairing and centrally bound monovalent cations. The replication and elongation of telomeres requires the disruption of these G-quadruplex structures. Hence, drug molecules such as gold (Au)-carbene that stabilize G-quadruplexes may also interfere with the elongation of telomeres and, in turn, could be used to control cell replication and growth. To better understand the molecular mechanism of Au-carbene binding to G-quadruplexes, we employed molecular dynamics simulations and free energy simulations. Whereas very restricted mobility of two Au-carbene ligands was found upon binding as a doublet to one side of the G-quadruplex, much larger translational and orientational mobility was observed for a single Au-carbene binding at the second G-quadruplex surface. Comparative simulations on duplex DNA in the presence of Au-carbene ligands indicates a preference for the minor groove and weaker unspecific and more salt-dependent binding than to the G-quadruplex surface. Analysis of energetic contributions reveals a dominance of nonpolar and van der Waals interactions to drive binding. The simulations can also be helpful for proposing possible modifications that could improve Au-carbene affinity and specificity for G-quadruplex binding.     

A DNA Spiegelmer to staphylococcal enterotoxin B

Bacterial staphylococcal enterotoxin B is involved in several severe disease patterns and it was therefore used as a target for the generation of biologically stable mirror-image oligonucleotide ligands, so called Spiegelmers. The toxin is a 28 kDa protein consisting of 239 amino acids. Since the full-length protein is not accessible to chemical peptide synthesis, a stable domain of 25 amino acids was identified as a suitable selection target. DNA in vitro selection experiments were carried out against the equivalent mirror-image D-peptide domain resulting in high affinity D-DNA aptamers. As expected, the corresponding enantiomeric L-DNA Spiegelmer showed comparable binding characteristics to the L-peptide domain. Moreover, the Spiegelmer bound the whole protein target with only slightly reduced affinity. Dissociation constants of both peptide-oligonucleotide complexes were measured in the range of 200 nM, whereas the Spiegelmer binding to the full-length protein was determined at approximately 420 nM. These data demonstrate the possibility to identify Spiegelmers against large protein targets by a domain approach.     

Targeting pyrimidine single strands by triplex formation: structural optimization of binding.

Recent reports describe a new strategy for the binding of single-stranded pyrimidine sequences by triple helix formation. In this approach, a double-length purine-rich oligonucleotide binds a target strand, folding back to form an antiparallel pur.pur.pyr triple helix. We now describe a series of studies in which sequence and structural variations are made in such purine-rich ligands, in an effort to optimize binding properties. Comparison is made between the use of two separate strands and the use of single two-domain ligands; the latter are found to bind more tightly and to aggregate less in media containing Na+ or K+. Placement of mismatched bases in the target shows that sequence selectivity of binding is as high as that for Watson-Crick duplex formation. Variation of the lengths and sequences of loops bridging the binding domains demonstrates that dinucleotide loops composed of pyrimidines give the highest stability. Oligoethylene glycol-derived loop replacements are shown to give good binding affinity as well. The binding of an RNA target is shown to occur with the same affinity as the binding of DNA. In general, it is found that circular variants bind more tightly than do either separate strands or singly-linked ligands and unlike linear oligomers, the circular compounds do not aggregate to a large extent even in buffers containing 100 mM K+. Such structurally optimized ligands are useful in expanding the number of possible naturally-occurring sequences which can be targeted by triplex formation.     

Benzofuroquinoline Derivatives Had Remarkable Improvement of their Selectivity for Telomeric G-Quadruplex DNA over Duplex DNA upon Introduction of Peptidyl Group

In order to improve the selectivity of 5-N-methyl quindoline (cryptolepine) derivatives as telomeric quadruplex binding ligands versus duplex DNA, a series of peptidyl-benzofuroquinoline (P-BFQ) conjugates (2a-2n) were designed and synthesized. Their interactions with telomeric quadruplex and duplex DNA were examined by using the fluorescence resonance energy transfer (FRET) melting assay, surface plasmon resonance (SPR), circular dichroism spectroscopy (CD), and molecular modeling studies. Introduction of a peptidyl group at 11-position of the aromatic benzofuroquinoline scaffold not only effectively increased its binding affinity, but also significantly improved its selectivity toward telomeric quadruplex versus duplex DNA. Combined with the data for their inhibitory effects on telomerase activity, their structure-activity relationships (SARs) studies showed that the types of amino acid residues and the length of the peptidyl side chains were important for the improvement of their interactions with the telomeric G-quadruplex. Long-term exposure of human cancer cells to 2c showed a remarkable cessation in population growth and cellular senescence phenotype, and accompanied by a shortening of the telomere length.     

Transposon Tn7 protein TnsD binding to Escherichia coli attTn7 DNA and its eukaryotic orthologs

Transposon Tn7 inserts itself into the attTn7 target DNA sequence at the 3' end of the Escherichia coli glmS gene with high specificity and efficiency. This site in the E. coli genome displays amino acid conservation and nucleotide similarity with orthologous sequences in Archaebacteria and eukaryotes. On the basis of the high degree of nucleotide similarity, particularly with eukaryotes, we examined the interactions of a set of 20-bp duplex DNA sequences with the Tn7 protein TnsD. The protein was overexpressed in the IPTG-inducible vector pET14b-TnsD in E. coli BL21(DE3)-RIL-Codon-Plus, and purified by nickel chelation and ion exchange chromatography. Changes in the conformation of DNA duplexes upon interaction with TnsD were monitored by circular dichroism (CD) spectroscopy. TnsD binding to and dissociation from immobilized DNA duplexes were monitored by total internal reflectance (TIR). CD and TIR results were analyzed to calculate k(on), k(off), and K(D) values. The 20-bp DNA duplex corresponding to attTn7 at the 3' end of E. coli glmS displayed strong affinity for TnsD protein, with K(D) approximately 20 nM. Eukaryotic orthologs of attTn7 from yeast and mammalian GFPT1 displayed lower affinity, with K(D) approximately 500 nM. Mutant DNA sequences with a single central mismatch did not display any detectable interaction with TnsD. The physical studies validate our biological observation of Tn7 transposition into a plasmid containing the mammalian attTn7 ortholog sequence [Cleaver, S. H., and Wickstrom, E. (2000) Gene 254, 37-44], and suggest that 1-2 amino acid substitutions in TnsD might be sufficient to permit binding to mammalian orthologs that is as strong as wild-type TnsD binding to attTn7.     

Bisaryldiketene derivatives: A new class of selective ligands for c-myc G-quadruplex DNA

A series of bisaryldiketene derivatives were designed and synthesized as a new class of specific G-quadruplex ligands. The ligand-quadruplex interactions were further evaluated by FRET, ITC, and PCR stop assay. In contrast to most of the G-quadruplex ligands reported so far, which comprise an extended aromatic ring, these compounds are neither polycyclic nor macrocyclic, but have a non-aromatic and relative flexible linker between two quinoline moieties enabling the conformation of compounds to be flexible. Our results showed that these bisaryldiketene derivatives could selectively recognize G-quadruplex DNA rather than binding to duplex DNA. Moreover, they showed promising discrimination between different G-quadruplex DNA. The primary binding affinity of ligand M2 for c-myc G-quadruplex DNA was over 200 times larger than that for telomere G-quadruplex DNA.     

Alternative heterocycles for DNA recognition: a 3-pyrazole/pyrrole pair specifies for G.C base pairs

Synthetic ligands comprising three aromatic amino acids, pyrrole (Py), imidazole (Im), and hydroxypyrrole (Hp), specifically recognize predetermined sequences as side-by-side pairs in the minor groove of DNA. To expand the repertoire of aromatic rings that may be utilized for minor groove recognition, three five-membered heterocyclic rings, 3-pyrazolecarboxylic acid (3-Pz), 4-pyrazolecarboxylic acid (4-Pz), and furan-2-carboxylic acid (Fr), were examined at the N-terminus of eight-ring hairpin polyamide ligands. The DNA binding properties of 3-Pz, 4-Pz, and Fr each paired with Py were studied by quantitative DNase I footprinting titrations on a 283 bp DNA restriction fragment containing four 6-bp binding sites 5'-ATNCCTAA-3' (N = G, C, A, or T; 6-bp polyamide binding site is underlined). The pair 3-Pz/Py has increased binding affinity and sequence specificity for G.C bp compared with Im/Py.     

Combinatorial determination of sequence specificity for nanomolar DNA-binding hairpin polyamides

Development of sequence-specific DNA-binding drugs is an important pharmacological goal, given the fact that numerous existing DNA-directed chemotherapeutic drugs rely on the strength and selectivity of their DNA interactions for therapeutic activity. Among the DNA-binding antibiotics, hairpin polyamides represent the only class of small molecules that can practically bind any predetermined DNA sequence. DNA recognition by these ligands depends on their side-by-side amino acid pairings in the DNA minor groove. Extensive studies have revealed that these molecules show extremely high affinity for sequence-directed, minor groove interaction. However, the specificity of such interactions in the presence of a large selection of sequences such as the human genome is not known. We used the combinatorial selection method restriction endonuclease protection, selection, and amplification (REPSA) to determine the DNA binding specificity of two hairpin polyamides, ImPyPyPy-gamma-PyPyPyPy-beta-Dp and ImPyPyPy-gamma-ImPyPyPy-beta-Dp, in the presence of more than 134 million different sequences. These were verified by restriction endonuclease protection assays and DNase I footprinting analysis. Our data showed that both hairpin polyamides preferentially selected DNA sequences having consensus recognition sites as defined by the Dervan pairing rules. These consensus sequences were rather degenerate, as expected, given that the stacked pyrrole-pyrrole amino acid pairs present in both polyamides are unable to discriminate between A.T and T.A base pairs. However, no individual sequence within these degenerate consensus sequences was preferentially selected by REPSA, indicating that these hairpin polyamides are truly consensus-specific DNA-binding ligands. We also discovered a preference for overlapping consensus binding sites among the sequences selected by the hairpin polyamide ImPyPyPy-gamma-PyPyPyPy-beta-Dp, and confirmed by DNase I footprinting that these complex sites provide higher binding affinity. These data suggest that multiple hairpin polyamides can cooperatively bind to their highest-affinity sites.