Coralyne binds tightly to both T.A.T- and C.G.C(+)-containing DNA triplexes

Coralyne is a DNA-binding antitumor antibiotic whose structure contains four fused aromatic rings. The interaction of coralyne with the DNA triplexes poly(dT).poly(dA).poly(dT) and poly[d(TC)].poly[d(GA)].poly[d(C+T)] was investigated by using three techniques. First, Tm values were measured by thermal denaturation analysis. Upon binding coralyne, both triplexes showed Tm values that were increased more than those of the corresponding duplexes. A related drug, berberinium, in which one of the aromatic rings is partially saturated, gave much smaller changes in Tm. Second, the fluorescence of coralyne is quenched in the presence of DNA, allowing the measurement of binding parameters by Scatchard analysis. The binding isotherms were biphasic, which was interpreted in terms of strong intercalative binding and much weaker stacking interactions. In the presence of 2 mM Mg2+, the binding constants to poly(dT).poly-(dA).poly(dT) and poly[d(TC)].poly[d(GA)].poly[(C+T)] were 3.5 x 10(6) M-1 and 1.5 x 10(6) M-1, respectively, while the affinity to the parent duplexes was at least 2 orders of magnitude lower. In the absence of 2 mM Mg2+, the binding constants to poly[d(TC)].poly[d(GA)].poly[d(C+T)] and poly-[d(TC)].poly[d(GA)] were 40 x 10(6) M-1 and 15 x 10(6) M-1, respectively. Thus coralyne shows considerable preference for the triplex structure but little sequence specificity, unlike ethidium, which will only bind to poly(dT).poly(dA).poly(dT). Further evidence for intercalation of coralyne was provided by an increase in the relative fluorescence quantum yield at 260 nm upon binding of coralyne to triplexes as well as an absence of quenching of fluorescence in the presence of Fe[(CN)6]4-.(ABSTRACT TRUNCATED AT 250 WORDS)     

Coralyne has a preference for intercalation between TA.T triples in intramolecular DNA triple helices

Intercalating ligands may improve both the stability and sequence specificity of triple helices. Numerous intercalating drugs have been described, including coralyne, which preferentially binds triple helices, though its sequence specificity has been reported to be low [Lee,J.S., Latimer,L.J.P. and Hampel,K.J. (1993) Biochemistry , 32, 5591-5597]. In order to analyse the sequence preferences of coralyne we have used a combination of DNase I footprinting, UV melting, UV-visible spectrophotometry, circular dichroism and NMR spectroscopy to examine defined intermolecular triplexes and intramolecular triplexes linked either by hexaethylene glycol chains or by octandiol chains. DNase I footprinting demonstrated that coralyne has a moderate preference for triplexes over duplexes, but a substantial preference for TA.T triplets compared with CG. C+triplets. The drug was found to have essentially no effect on the melting temperatures of duplexes of the kind d(A)n.d(T)n or d(GA)n.d(TC)n. In contrast, it increased the T m for triplexes of the kind d(T)nd(A)n.dTn, but had little effect on the stability of d(TC)nd(GA).d(CT)n at either low or high pH. On binding to DNA triplexes, there is a large change in the absorption spectrum of coralyne and also a substantial fluorescence quenching that can be attributed to intercalation. The changes in the optical spectra have been used for direct titration with DNA. For triplexes d(T)6d(A)6.d(T)6, the Kd at 298 K was 0.5-0.8 microM. In contrast, the affinity for d(TC) nd(GA)n.d(CT)n triplexes was 6- to 10-fold lower and was characterized by smaller changes in the absorption and CD spectra. This indicates a preference for intercalation between TAT triples over CG.C+/TA.T triples. NMR studies confirmed interaction by intercalation. However, a single, secondary binding was observed at high concentrations of ligand to the triplex d(AGAAGA-L-TCTTCT-L-TCTTCT), presumably owing to the relatively low difference in affinity between the TA.T site and the competing, neighbouring sites.     

DNA "melting" proteins. I. Effects of bovine pancreatic ribonuclease binding on the conformation and stability of DNA

Bovine pancreatic ribonuclease is a DNA "melting" protein, since it binds with greater overall affinity to the single-stranded than to the double-stranded form of natural and synthetic deoxyribose-containing polynucleotides. As such, the DNA-RNase system provides a simple model for the more complex and biologically relevant melting protein-nucleic acid systems. Aspects of the DNA-RNase interactions which are related to the quantitative assessment of this system as a melting protein model are investigated here. A boundary sedimentation velocity technique is used to measure thermodynamic parameters of the interaction; association constants (Kh and Kc) and site sizes (nh and nc) are determined for the interaction of ribonuclease with native (double helical) and denatured (random coil) DNA. It is shown that log Kh and log Kc are linear functions of log [Na+], binding decreasing with increasing Na+ concentration, with Kh about 2 orders of magnitude smaller than Kc at the ionic strengths studied, nh and nc are approximately 8 and approximately 11 nucleotide residues, respectively, indicating that potential binding sites overlap. Binding to both forms of DNA is non-cooperative. It is shown by CD and ultraviolet spectroscopy that the binding of RNase to single- and double-stranded DNA perturbs the conformations of these polynucleotide conformations very little relative to the unliganded structures. Hydrodynamic methods are used to show that RNase binds to native DNA without altering the overall solution structure of the latter; however conditons which permit binding to, and stabilization of, transiently exposed single-stranded sequences result in a collapse of the stiff native DNA structure. We demonstrate by melting transition studies that ribonuclease does bring about an equilibrium destabilization of native DNA and poly [d(A-T)] and, by applying a ligand-perturbed helic in equilibrium coil theory developed by McGhee (McGhee, J.D. (1976) Biopolymers 15, 1345-1375), it is shown that the extent of the observed destabilization is in semiquantitative accord with expectations based on the measured affinity constants and site sizes for RNase binding to both DNA conformations. Spectral methods are used to show that the relative stability of native DNA sequences of varying base composition is the same in the presence and absence of ribonuclease, strongly arguing that this "melting" ligand "traps" single-stranded sequences transiently exposed by thermal fluctuations. RNase also undergoes an order in equilibrium disorder conformational transition as a function of temperature (the denatured form of RNase stabilizes native DNA, while native RNase destabilizes the native double helix), and the coupled equilibria involved in these interacting conformational changes are interpreted and discussed as possible models of genome regulatory interactions.     

Small ligands that neither bind to nor alter the structure of d(GA x TC)n sequences in DNA

Three minor-groove binding ligands have been used to study the characteristics of two d(GA x CT)n DNAs embedded in longer DNA fragments. The binding of mithramycin, netropsin or Thia-Net to these sequences has been studied using DNAse I footprinting. None of these ligands appeared to bind to d(GA x CT)5 nor to d(GA x CT)22 extensively, although with mithramycin some protected bonds were detected at the very edge of these sequences. In general, these small ligands did not enhance the DNAse I cleavage patterns at the alternating d(GA x CT)n flanking sequences located near DNA regions where the drug was bound. The d(GA x CT)n sequences could act as a rigid block in which it is not easy to propagate structural changes, whereas other sequences flanking the binding sites showed cleavage enhancements.     

The Zalpha domain from human ADAR1 binds to the Z-DNA conformer of many different sequences

Z-DNA, the left-handed conformer of DNA, is stabilized by the negative supercoiling generated during the movement of an RNA polymerase through a gene. Recently, we have shown that the editing enzyme ADAR1 (double-stranded RNA adenosine deaminase, type 1) has two Z-DNA binding motifs, Zalpha and Zbeta, the function of which is currently unknown. Here we show that a peptide containing the Zalpha motif binds with high affinity to Z-DNA as a dimer, that the binding site is no larger than 6 bp and that the Zalpha domain can flip a range of sequences, including d(TA)3, into the Z-DNAconformation. Evidence is also presented to show that Zalpha and Zbeta interact to form a functional DNA binding site. Studies with atomic force microscopy reveal that binding of Zalpha to supercoiled plasmids is associated with relaxation of the plasmid. Pronounced kinking of DNA is observed, and appears to be induced by binding of Zalpha. The results reported here support a model where the Z-DNA binding motifs target ADAR1 to regions of negative supercoiling in actively transcribing genes. In this situation, binding by Zalpha would be dependent upon the local level of negative superhelicity rather than the presence of any particular sequence.     

Recognition of DNA by single-chain derivatives of the phage 434 repressor: high affinity binding depends on both the contacted and non-contacted base pairs

Single-chain derivatives of the phage 434 repressor, termed single-chain repressors, contain covalently dimerized DNA-binding domains (DBD) which are connected with a peptide linker in a head-to-tail arrangement. The prototype RR69 contains two wild-type DBDs, while RR*69 contains a wild-type and an engineered DBD. In this latter domain, the DNA- contacting amino acids of thealpha3 helix of the 434 repressor are replaced by the corresponding residues of the related P22 repressor. We have used binding site selection, targeted mutagenesis and binding affinity studies to define the optimum DNA recognition sequence for these single-chain proteins. It is shown that RR69 recognizes DNA sequences containing the consensus boxes of the 434 operators in a palindromic arrangement, and that RR*69 optimally binds to non-palindromic sequences containing a 434 operator box and a TTAA box of which the latter is present in most P22 operators. The spacing of these boxes, as in the 434 operators, is 6 bp. The DNA-binding of both single-chain repressors, similar to that of the 434 repressor, is influenced indirectly by the sequence of the non-contacted, spacer region. Thus, high affinity binding is dependent on both direct and indirect recognition. Nonetheless, the single-chain framework can accommodate certain substitutions to obtain altered DNA-binding specificity and RR*69 represents an example for the combination of altered direct and unchanged indirect readout mechanisms.     

Isolation and characterization of a monoclonal anti-quadruplex DNA antibody from autoimmune "viable motheaten" mice

A cell line that produces an autoantibody specific for DNA quadruplex structures has been isolated and cloned from a hybridoma library derived from 3-month-old nonimmunized autoimmune, immunodeficient "viable motheaten" mice. This antibody has been tested extensively in vitro and found to bind specifically to DNA quadruplex structures formed by two biologically relevant sequence motifs. Scatchard and nonlinear regression analyses using both one- and two-site models were used to derive association constants for the antibody-DNA binding reactions. In both cases, quadruplexes had higher association constants than triplex and duplex molecules. The anti-quadruplex antibody binds to the quadruplex formed by the promoter-region-derived oligonucleotide d(CGCG4GCG) (Ka = 3.3 x 10(6) M-1), and has enhanced affinity for telomere-derived quadruplexes formed by the oligonucleotides d(TG4) and d(T2G4T2G4T2G4T2G4) (Ka = 5.38 x 10(6) and 1.66 x 10(7) M-1, respectively). The antibody binds both types of quadruplexes but has preferential affinity for the parallel four-stranded structure. In vitro radioimmunofilter binding experiments demonstrated that purified anti-DNA quadruplex antibodies from anti-quadruplex antibody-producing tissue culture supernatants have at least 10-fold higher affinity for quadruplexes than for triplex and duplex DNA structures of similar base composition and length. The antibody binds intramolecular DNA triplexes formed by d(G4T3G4T3C4) and d(C4T3G4T3G4), and the duplex d(CGCGCGCGCG)2 with an affinities of 6. 76 x 10(5), 5.59 x 10(5), and 8.26 x 10(5) M-1, respectively. Competition experiments showed that melted quadruplexes are not effective competitors for antibody binding when compared to native structures, confirming that the quadruplex is bound structure-specifically. To our knowledge, this is the first immunological reagent known to specifically recognize quadruplex structures. Subsequent sequence analysis demonstrates homologies between the antibody complementarity determining regions and sequences from Myb family telomere binding proteins, which are hypothesized to control cell aging via telomeric DNA interactions. The presence of this antibody in the autoimmune repertoire suggests a possible linkage between autoimmunity, telomeric DNA binding proteins, and aging.     

Unique mode of GCC box recognition by the DNA-binding domain of ethylene-responsive element-binding factor (ERF domain) in plant

Ethylene-responsive element-binding proteins (EREBPs)have novel DNA-binding domains (ERF domains), which are widely conserved in plants, and interact specifically with sequences containing AGCCGCC motifs (GCC box). Deletion experiments show that some flanking region at the N terminus of the conserved 59-amino acid ERF domain is required for stable binding to the GCC box. Three ERF domain-containing fragments of EREBP2, EREBP4, and AtERF1 from tobacco and Arabidopsis, bind to the sequence containing the GCC box with a high binding affinity in the pM range. The high affinity binding is conferred by a monomeric ERF domain fragment, and DNA truncation experiments show that only 11-base pair DNA containing the GCC box is sufficient for stable ERF domain interaction. Systematic DNA mutation analyses demonstrate that the specific amino acid contacts are confined within the 6-base pair GCCGCC region of the GCC box, and the first G, the fourth G, and the sixth C exhibit highest binding specificity common in all three ERF domain-containing fragments studied. Other bases within the GCC box exhibit modulated binding specificity varying from protein to protein, implying that these positions are important for differential binding by different EREBPs. The conserved N-terminal half is likely responsible for formation of a stable complex with the GCC box and the divergent C-terminal half for modulating the specificity.     

From lipoic acid to multi-enzyme complexes

The EGF domain of heregulin has all the receptor binding characteristics of full-length heregulin and has strong homology to the ligands for erbB-1. Despite this, it does not bind erbB-1 but instead binds erbB-3 and erbB-4. The sequence similarity between HRG and the erbB-1 ligands suggest that a few residues are responsible for receptor binding specificity. To determine the sequences involved in receptor binding, we performed homologue scanning mutagenesis on the EGF domain of HRGalpha using sequences of TGFalpha or EGF. We found three sets of mutations in the N-terminal subdomain that were responsible for receptor binding specificity. Mutations in the C-terminal subdomain affected the binding affinity, but did appear to confer any specificity.     

Equilibrium binding of estrogen receptor with DNA using fluorescence anisotropy

Interaction of estrogen receptor (ER) with DNA sequences known as estrogen response elements (ERE) is required for estrogen regulation of the expression of target genes. To characterize the affinity and specificity of ER interaction with ERE sequences in vitro under equilibrium conditions, fluorescence anisotropy assays were performed using recombinant, purified ER and a fluorescein-labeled 35-base pair oligonucleotide bearing an idealized palindromic ERE. In buffer containing 100 mM KCl, the baculovirus-expressed, purified human ER bound with similar affinity to the consensus ERE and a mutant ERE with a single base pair change per half-site. Above 225 mM KCl, ER exhibited discrimination between the consensus and mutated ERE targets. Between 225 and 275 mM KCl, binding to the consensus ERE was independent of salt concentration and occurred with an equilibrium dissociation constant (Kd) of 1.8 +/- 0.6 nM, whereas binding to the mutant ERE was not detected at ER concentrations below 100 nM under the same conditions. At 300 mM KCl, the Kd for the consensus ERE increased approximately 25-fold, suggesting complex salt concentration dependence. Both estrogen-occupied and unoccupied ER bound to the consensus ERE sequence with similar affinity, indicating that estrogen affects ER activity at a step other than DNA binding. Unlike the full-length ER, the recombinant DNA binding domain of ER did not discriminate between the consensus and mutated ERE sequences even at buffer salt concentrations greater than 200 mM NaCl, suggesting that ER sequences outside the DNA binding domain may be important in promoting specific binding.     

Study of the interaction of glyceraldehyde-3-phosphate dehydrogenase with DNA

Glyceraldehyde-3-phosphate dehydrogenase binds to homologous and heterologous single-stranded but not double-stranded DNA. Binding to RNA, poly(A) and poly(dA-dT) has also been observed. Enzyme binding to these nucleic acids leads to the formation of an insoluble complex which can be sedimented at low speed. The interaction of glyceraldehyde-3-phosphate dehydrogenase with DNA is strongly inhibited by NAD and NADH but not by NADP. Adenine nucleotides, which inhibit the dehydrogenase activity by competing with NAD for its binding site (Yang, S.T. and Deal, W.C., Jr. (1969) Biochemistry 8, 2806--2813), also inhibit enzyme binding to DNA, whereas glyceraldehyde-3-phosphate and inorganic phosphate are non-inhibitory. These results suggest that DNA interacts through the NAD binding sites of glyceraldehyde-3-phosphate dehydrogenase. In accordance with this idea, it was found that DNA also binds to lactate dehydrogenase, an enzyme containing a similar dinucleotide binding domain, and that this binding is inhibited by NADH. A study of the base specificity of the DNA-glyceraldehyde-3-phosphate dehydrogenase interaction using dinucleoside monophosphates shows that inhibition of DNA binding by the dinucleotides requires the presence of a 3'-terminal adenosine and is greater when the 5'-terminus contains a pyrimidine instead of a purine. These results suggest that the dinucleotides bind at the NAD site of the dehydrogenase and that the enzyme would interact preferentially with PypA dinucleotides present in the nucleic acid.     

Dimerization specificity of P22 and 434 repressors is determined by multiple polypeptide segments

The repressor protein of bacteriophage P22 binds to DNA as a homodimer. This dimerization is absolutely required for DNA binding. Dimerization is mediated by interactions between amino acids in the carboxyl (C)-terminal domain. We have constructed a plasmid, p22CT-1, which directs the overproduction of just the C-terminal domain of the P22 repressor (P22CT-1). Addition of P22CT-1 to DNA-bound P22 repressor causes the dissociation of the complex. Cross-linking experiments show that P22CT-1 forms specific heterodimers with the intact P22 repressor protein, indicating that inhibition of P22 repressor DNA binding by P22CT-1 is mediated by the formation of DNA binding-inactive P22 repressor:P22CT-1 heterodimers. We have taken advantage of the highly conserved amino acid sequences within the C-terminal domains of the P22 and 434 repressors and have created chimeric proteins to help identify amino acid regions required for dimerization specificity. Our results indicate that the dimerization specificity region of these proteins is concentrated in three segments of amino acid sequence that are spread across the C-terminal domain of each of the two phage repressors. We also show that the set of amino acids that forms the cooperativity interface of the P22 repressor may be distinct from those that form its dimer interface. Furthermore, cooperativity studies of the wild-type and chimeric proteins suggest that the location of cooperativity interface in the 434 repressor may also be distinct from that of its dimerization interface. Interestingly, changes in the dimer interface decreases the ability of the 434 repressor to discriminate between its wild-type binding sites, O(R)1, O(R)2, and O(R)3. Since 434 repressor discrimination between these sites depends in large part on the ability of this protein to recognize sequence-specific differences in DNA structure and flexibility, this result indicates that the C-terminal domain is intimately involved in the recognition of sequence-dependent differences in DNA structure and flexibility.     

Topotecan lactone selectively binds to double- and single-stranded DNA in the absence of topoisomerase I

We report the first experimental observation that a clinically important camptothecin [CPT; topotecan (TPT), a water-soluble CPT] binds directly and noncovalently to double-stranded DNA and single-stranded DNA structures in the absence of topoisomerase I, but only in the lactone form. We observed clear DNA sequence specificity of the TPT lactone binding to duplex DNA, which was comprised of alternating purine-pyrimidine sequences that contained dT. These structural studies of direct TPT lactone-DNA binding support several important considerations involving possible mechanism(s) of anticancer activity of CPT-type drugs containing a 20(S) lactone moiety.     

Effect of chemical modification of oligohomopyrimidine on triplex formation: thermodynamic and kinetic studies

To investigate the effect of chemical modification of the third strand on the stability of triplex DNA, we have examined the thermodynamic properties of the triplex formation between a 23-mer double-stranded homopurine-homopyrimidine and each of five kinds of 15-mer chemically modified single-stranded homopyrimidines by isothermal titration calorimetry, and the kinetic properties by interaction analysis system. The modifications of the third strand included two base modifications, two sugar moiety modifications, and one phosphate backbone modification. The thermodynamic and kinetic parameters for the triplex formation were similar in magnitude among the two base-modified and two sugar-modified single strands. By contrast, the binding constant for the triplex formation with the single strand with phosphorothioate backbone was more than ten times as small as that for the other triplex formation. On the basis of the kinetic analyses, the single strand with phosphorothioate backbone was more difficult to associate with and easier to dissociate from the target double strand than the other single strands, which resulted in the much smaller binding constant.