Synthesis of a non-cationic, water-soluble perylenetetracarboxylic diimide and its interactions with G-quadruplex-forming DNA

A number of N,N'-disubstituted perylenetetracarboxylic diimides have been reported to bind effectively to DNA that adopts G-quadruplex motifs. In some cases, this binding may actively drive the transition from single-strand DNA to the quadruplex form. The perylenediimides in the reported cases all have amine-containing side chains, which are thought to interact with the grooves of the quadruplex and help dictate the selectivity of these compounds for quadruplex versus duplex DNA. We synthesized a polyethyleneglycol-swallowtailed (PEG-tailed) perylenediimide that is water-soluble even though it is uncharged. Binding to duplex and quadruplex DNA of this perylenediimide was studied by fluorescence quenching titrations under a variety of salt conditions, and the compound's effect on quadruplex formation was studied by non-denaturing gel electrophoresis. Our results indicate that while the molecule binds to single-stranded DNA quite effectively and with selectivity, it does not drive the transition of the DNA to the tetrameric quadruplex structure, supporting the idea that charge neutralization is a key component of perylene compounds that stabilize tetrameric quadruplexes.     

Kinetics of binding of single-stranded DNA binding protein from Escherichia coli to single-stranded nuclei acids

The time course of the reaction of Escherichia coli single-stranded DNA binding protein (E. coli SSB) with poly(dT) and M13mp8 single-stranded DNA has been measured by fluorescence stopped-flow experiments. For poly(dT), the fluorescence traces follow simple bimolecular behavior up to 80% saturation of the polymer with E. coli SSB. A mechanistic explanation of this binding behavior can be given as follows: (1) E. coli SSB is able to translocate very rapidly on the polymer, forming cooperative clusters. (2) In the rate-limiting step of the association reaction, E. coli SSB is bound to the polymer only by one or two of its four contact sites. As compared to poly(dT), association to single-stranded M13mp8 phage DNA is slower by at least 2 orders of magnitude. We attribute this finding to the presence of secondary structure elements (double-stranded structures) in the natural single-stranded DNA. These structures cannot be broken by E. coli SSB in a fast reaction. In order to fulfill its physiological function in reasonable time, E. coli SSB must bind newly formed single-stranded DNA immediately. The protein can, however, bind to such pieces of the newly formed single-stranded DNA which are too short to cover all four binding sites of the E. coli SSB tetramer.     

Structure of hnRNP D complexed with single-stranded telomere DNA and unfolding of the quadruplex by heterogeneous nuclear ribonucleoprotein D

Heterogeneous nuclear ribonucleoprotein D, also known as AUF1, has two DNA/RNA-binding domains, each of which can specifically bind to single-stranded d(TTAGGG)n, the human telomeric repeat. Here, the structure of the C-terminal-binding domain (BD2) complexed with single-stranded d(TTAGGG) determined by NMR is presented. The structure has revealed that each residue of the d(TAG) segment is recognized by BD2 in a base-specific manner. The interactions deduced from the structure have been confirmed by gel retardation experiments with mutant BD2 and DNA. It is known that single-stranded DNA with the telomeric repeat tends to form a quadruplex and that the quadruplex has an inhibitory effect on telomere elongation by telomerase. This time it is revealed that BD2 unfolds the quadruplex of such DNA upon binding. Moreover, the effect of BD2 on the elongation by telomerase was examined in vitro. These results suggest the possible involvement of heterogeneous nuclear ribonucleoprotein D in maintenance of the telomere 3'-overhang either through protection of a single-stranded DNA or destabilization of the potentially deleterious quadruplex structure for the elongation by telomerase.     

Binding properties of human telomeric quadruplex multimers: a new route for drug design

Human telomeric G-quadruplex structures are known to be promising targets for an anticancer therapy. In the past decade, several research groups have been focused on the design of new ligands trying to optimize the interactions between these small molecules and the G-quadruplex motif. In most of these studies, the target structures were the single quadruplex units formed by short human DNA telomeric sequences (typically 21-26 nt). However, the 3′-terminal single-stranded human telomeric DNA is actually 100-200 bases long and can form higher-order structures by clustering several consecutive quadruplex units (multimers). Despite the increasing number of structural information on longer DNA telomeric sequences, very few data are available on the binding properties of these sequences compared with the shorter DNA telomeric sequences.In this paper we use a combination of spectroscopic (CD, UV and fluorescence) and calorimetric techniques (ITC) to compare the binding properties of the (TTAGGG)₈TT structure formed by two adjacent quadruplex units with the binding properties of the (AG₃TT)₄ single quadruplex structure. The three side-chained triazatruxene derivative azatrux and TMPyP4 cationic porphyrin were used as quadruplex ligands. We found that, depending on the drug, the number of binding sites per quadruplex unit available in the multimer structure was smaller or greater than the one expected on the basis of the results obtained from individual quadruplex binding studies. This work suggests that the quadruplex units along a multimer structure do not behave as completely independent. The presence of adjacent quadruplexes results in a diverse binding ability not predictable from single quadruplex binding studies. The existence of quadruplex-quadruplex interfaces in the full length telomeric overhang may provide an advantageous factor in drug design to enhance both affinity and selectivity for DNA telomeric quadruplexes.     

A Parallel Quadruplex DNA Is Bound Tightly but Unfolded Slowly by Pif1 Helicase

DNA sequences that can form intramolecular quadruplex structures are found in promoters of proto-oncogenes. Many of these sequences readily fold into parallel quadruplexes. Here we characterize the ability of yeast Pif1 to bind and unfold a parallel quadruplex DNA substrate. We found that Pif1 binds more tightly to the parallel quadruplex DNA than single-stranded DNA or tailed duplexes. However, Pif1 unwinding of duplexes occurs at a much faster rate than unfolding of a parallel intramolecular quadruplex. Pif1 readily unfolds a parallel quadruplex DNA substrate in a multiturnover reaction and also generates some product under single cycle conditions. The rate of ATP hydrolysis by Pif1 is reduced when bound to a parallel quadruplex compared with single-stranded DNA. ATP hydrolysis occurs at a faster rate than quadruplex unfolding, indicating that some ATP hydrolysis events are non-productive during unfolding of intramolecular parallel quadruplex DNA. However, product eventually accumulates at a slow rate.     

Sequence dependence of fluorescence emission and quenching of doubly thiazole orange labeled DNA: effective design of a hybridization-sensitive probe

We have designed a doubly thiazole orange labeled nucleoside showing high fluorescence intensity for a hybrid with the target DNA and effective quenching for a single-stranded state. Knowing how much the fluorescence emission and quenching of this probe depend on the probe sequence and why there is such a sequence dependence is important for effective probe design, we synthesized more than 30 probe sequences and measured their fluorescence intensities. When the probe hybridized with the target DNA strands, there was strong emission, whereas the emission intensity was much weaker before hybridization; however, self-dimerization of probes suppressed fluorescence quenching. In particular, the G/C base pairs neighboring the labeled nucleotide in a self-dimeric structure resulted in a low quenching ability for the probe before hybridization. On the other hand, mismatched base pair formation around the labeled site decreased the fluorescence intensity because the neighboring sequence is the binding site of the tethered thiazole orange dyes. The hybridization enhanced the fluorescence of the probe even when the labeled nucleotide was located at the end of the probe strand; however, the partial lack of duplex structure resulted in a decrease in the fluorescence intensity of the hybrid.     

Purification and characterization of the coliphage N4-coded single-stranded DNA binding protein

We have purified and characterized a single-stranded DNA binding protein (N4 SSB) induced after coliphage N4 infection. It has a monomeric molecular weight of 31,000 and contains 10 tyrosine and 1-2 tryptophan amino acid residues. Its fluorescence spectrum is dominated by the tyrosine residues, and their fluorescence is quenched when the protein binds single-stranded DNA. Fluorescence quenching was used as an assay to quantitate binding of the protein to single-stranded nucleotides. The N4 single-stranded DNA binding protein binds cooperatively to single-stranded nucleic acids and binds single-stranded DNA more tightly than RNA. The binding involves displacement of cations from the DNA and anions from the protein. The apparent binding affinity is very salt-dependent, decreasing as much as 1,000-fold for a 10-fold increase in NaCl concentration. The degree of cooperativity (omega) is relatively independent of salt concentration. At 37 degrees C in 0.22 M NaCl, the protein has an intrinsic binding constant for M13 viral DNA of 3.8 x 10(4) M-1, a cooperativity factor omega of 300, and binding site size of 11 nucleotides per monomer. The protein lowers the melting point of poly(dA.dT).poly(dA-dT) by greater than 60 degrees C but cannot lower the melting transition or assist in the renaturation of natural DNA. N4 single-stranded DNA binding protein enhances the rate of DNA synthesis catalyzed by the N4 DNA polymerase by increasing the processivity of the N4 DNA polymerase and melting out hairpin structures that block polymerization.     

G-quartets direct assembly of HIV-1 nucleocapsid protein along single-stranded DNA

The d(TTGGGGGGTACAGTGCA) sequence, derived from the human immunodeficiency virus type 1 (HIV-1) central DNA flap, can form in vitro an intermolecular parallel DNA quadruplex. This work demonstrates that the HIV-1 nucleocapsid protein (NCp) exhibits a high affinity (10⁸ M^–1) for this quadruplex. This interaction is predominantly hydrophobic, maintained by a stabilization between G-quartet planes and the C-terminal zinc finger of the protein. It also requires 5 nt long tails flanking the quartets plus both the second zinc-finger and the N-terminal domain of NCp. The initial binding nucleates an ordered arrangement of consecutive NCp along the four single-stranded tails. Such a process requires the N-terminal zinc finger, and was found to occur for DNA site sizes shorter than usual in a sequence-dependent manner. Concurrently, NCp binding is efficient on a G′2 quadruplex also derived from the HIV-1 central DNA flap. Apart from their implication within the DNA flap, these data lead to a model for the nucleic acid architecture within the viral nucleocapsid, where adjacent single-stranded tails and NCp promote a compact assembly of NCp and nucleic acid growing from stably and primary bound NCp.     

Purification and characterization of the bacteriophage T7 gene 2.5 protein. A single-stranded DNA-binding protein.

Bacteriophage T7 gene 2.5 protein has been purified to homogeneity from cells overexpressing its gene. Native gene 2.5 protein consists of a dimer of two identical subunits of molecular weight 25,562. Gene 2.5 protein binds specifically to single-stranded DNA with a stoichiometry of approximately 7 nucleotides bound per monomer of gene 2.5 protein; binding appears to be noncooperative. Electron microscopic analysis shows that gene 2.5 protein is able to disrupt the secondary structure of single-stranded DNA. The single-stranded DNA is extended into a chain of gene 2.5 protein dimers bound along the DNA. In fluorescence quenching and nitrocellulose filter binding assays, the binding constants of gene 2.5 protein to single-stranded DNA are 1.2 x 10(6) M-1 and 3.8 x 10(6) M-1, respectively. Escherichia coli single-stranded DNA-binding protein and phage T4 gene 32 protein bind to single-stranded DNA more tightly by a factor of 25. Fluorescence spectroscopy suggests that tyrosine residue(s), but not tryptophan residues, on gene 2.5 protein interacts with single-stranded DNA.     

Conformational change in the herpes simplex single-strand binding protein induced by DNA

Protease digestion of the herpes simplex virus type 1 major single-strand DNA binding protein ICP8 showed that the cleavage patterns observed in the presence and absence of single-stranded DNA oligonucleotides are substantially different with protection of cleavage sites between amino acids 293 and 806 observed in the presence of oligonucleotide. Experiments using ICP8 modified with fluorescein-5-maleimide (FM) showed that the fluorescence signal exhibited increased susceptibility to antibody quenching and a significant decrease in polarization of the FM fluorescence was observed in the presence compared to the absence of oligonucleotide. Taken together, these results indicate that ICP8 undergoes a conformational change upon binding to single-stranded DNA.     

GG sequence of DNA and the human telomeric sequence react with cis-diammine-diaquaplatinum at comparable rates

G-quadruplex structures of telomeric sequences are of growing interest because they inhibit telomerase, an enzyme involved in the maintenance of telomere length of cancer cells. As we have shown previously, the antiparallel structure of G-quadruplexes can be cross-linked in vitro by the anti-tumour drug cisplatin. The question arises whether platination of quadruplex structures of human telomeric sequences by cisplatin could be relevant from a biological point of view. Therefore, we have compared the kinetics of reactions of the diaqua form of cisplatin, cis-[Pt(NH(3))(2)(H(2)O)(2)](2+), with the human telomeric quadruplex structure, a duplex DNA and a single-stranded DNA containing one specific platination GG site. The ratio between the platination rate constants was obtained using two intramolecular competition experiments: either a construct with a junction between duplex DNA containing a unique GG platination site and the quadruplex structure of the human telomeric sequence AG(3)(T(2)AG(3))(3), or a construct with a junction between duplex DNA and a single strand containing each a unique GG platination site. Those competition experiments allowed us to conclude that the platination of the quadruplex is favoured over that of the GG duplex by a factor of about two whereas the GG duplex is platinated three times faster than the GG single strand.     

Interaction of tyrosine 65 of RecA protein with the first and second DNA strands

We investigated the structure of the active RecA-DNA complex by analyzing the environment of tyrosine residue 65, which is on the DNA-binding surface of the protein. We prepared a modified RecA protein in which the tyrosine residue was replaced by tryptophan, a natural fluorescent reporter, and measured the change in its fluorescence upon binding of DNA and cofactor. The fluorescence of the inserted tryptophan 65 (Trp65) was centered at 345 nm, indicating a partly exposed residue. Binding cofactor, adenosine 5'-O-3-thiotriphosphate (ATPgammaS), alone at a low salt concentration did not change the fluorescence of Trp65, confirming that the residue is not close to the nucleotide. In contrast, the binding of single-stranded DNA quenched the fluorescence of Trp65 in both the presence and absence of ATPgammaS. Trp65 fluorescence was also quenched upon binding a second DNA strand. The fluorescence change depended upon the presence and absence of ATPgammaS, reflecting the difference in the DNA binding. These results indicate that residue 65 is close to both the first and second DNA strands. The degree of quenching depended upon the base composition of DNA, suggesting that the residue 65 interacts with the DNA bases. Binding of DNA with ATPgammaS as well as binding of ATPgammaS alone at high salt concentration shifted the fluorescence emission peak from 345 to 330 nm, indicating a change from a polar to a non-polar environment. Therefore, the environment change around residue 65 would also be linked to a change in conformation and thus the activation of the protein.     

A simple motif for protein recognition in DNA secondary structures

DNA in a single-stranded form (ssDNA) exists transiently within the cell and comprises the telomeres of linear chromosomes and the genomes of some DNA viruses. As with RNA, in the single-stranded state, some DNA sequences are able to fold into complex secondary and tertiary structures that may be recognized by proteins and participate in gene regulation. To better understand how such DNA elements might fold and interact with proteins, and to compare recognition features to those of a structured RNA, we used in vitro selection to identify ssDNAs that bind an RNA-binding peptide from the HIV Rev protein with high affinity and specificity. The large majority of selected binders contain a non-Watson-Crick G.T base-pair and an adjacent C:G base-pair and both are essential for binding. This GT motif can be presented in different DNA contexts, including a nearly perfect duplex and a branched three-helix structure, and appears to be recognized in large part by arginine residues separated by one turn of an alpha-helix. Interestingly, a very similar GT motif is necessary also for protein binding and function of a well-characterized model ssDNA regulatory element from the proenkephalin promoter.     

Lead is unusually effective in sequence-specific folding of DNA

DNA quadruplex structures based on the guanine quartet are typically stabilized by monovalent cations such as K(+), Na(+), or NH(+)(3). Certain divalent cations can also induce quadruplex formation, such as Sr(2+). Here we show that Pb(2+) binds with unusually high affinity to the thrombin binding aptamer, d(GGTTGGTGTGGTTGG), inducing a unimolecular folded structure. At micromolar concentrations the binding is stoichiometric, and a single lead cation suffices to fold the aptamer. The lead-induced changes in UV and CD spectra are characteristic of folded quadruplexes, although the long wavelength CD maximum occurs at 312 nm rather than the typical value of 293 nm. The one-dimensional exchangeable proton NMR spectrum shows resonances expected for imino protons involved in guanine quartet base-pairing. Furthermore, two-dimensional NMR experiments reveal NOE contacts typically seen in folded structures formed by guanine quartets, such as the K(+) form of the thrombin aptamer. Only sequences capable of forming guanine quartets appear to bind Pb(+2) tightly and change conformation. This sequence-specific, tight DNA binding may be relevant to possible genotoxic effects of lead in the environment.     

Rectangular coordination polymer nanoplates: large-scale, rapid synthesis and their application as a fluorescent sensing platform for DNA detection

In this paper, we report on the large-scale, rapid synthesis of uniform rectangular coordination polymer nanoplates (RCPNs) assembled from Cu(II) and 4,4'-bipyridine for the first time. We further demonstrate that such RCPNs can be used as a very effective fluorescent sensing platform for multiple DNA detection with a detection limit as low as 30 pM and a high selectivity down to single-base mismatch. The DNA detection is accomplished by the following two steps: (1) RCPN binds dye-labeled single-stranded DNA (ssDNA) probe, which brings dye and RCPN into close proximity, leading to fluorescence quenching; (2) Specific hybridization of the probe with its target generates a double-stranded DNA (dsDNA) which detaches from RCPN, leading to fluorescence recovery. It suggests that this sensing system can well discriminate complementary and mismatched DNA sequences. The exact mechanism of fluorescence quenching involved is elucidated experimentally and its use in a human blood serum system is also demonstrated successfully.     

Surface lysine and tyrosine residues are required for interaction of the major herpes simplex virus type 1 DNA-binding protein with single-stranded DNA.

Modification of the herpes simplex virus type 1 major DNA-binding protein (ICP8) with reagents and conditions specific for arginine, lysine, and tyrosine residues indicates that surface lysine and tyrosine residues are required for the interaction of this protein with single-stranded DNA. Modification of either of these two amino acids resulted in a loss and/or modification of binding activity as judged by nitrocellulose filter assays and gel shift. Modification specific for arginine residues did not affect binding within the limits of the assays used. Finally, quenching of the intrinsic tryptophan fluorescence of ICP8 in the presence of single-stranded DNA either suggests involvement of this amino acid in the binding reaction or reflects a conformational change in the protein upon binding.     

Absorption and fluorescence studies of the binding of the recA gene product from E. coli to single-stranded and double-stranded DNA. Ionic strength dependence

The binding of the recA gene product from E. coli to double-stranded and single-stranded nucleic acids has been investigated by following the change in melting temperature of duplex DNA and the fluorescence of single-stranded DNA or poly(dA) modified by reaction with chloroacetaldehyde. At low ionic strength, in the absence of Mg2+ ions, RecA protein binds preferentially to duplex DNA or poly(dA-dT). This leads to an increase of the DNA melting temperature. Stabilization of duplex DNA decreases when ionic strength or pH increases. In the presence of Mg2+ ions, preferential binding to single-stranded polynucleotides is observed. Precipitation occurs when duplex DNA begins to melt in the presence of RecA protein. From competition experiments, different single-stranded and double-stranded polydeoxynucleotides can be ranked according to their ability to bind RecA protein. Structural changes induced in nucleic acids upon RecA binding are discussed together with conformational changes induced in RecA protein upon magnesium binding.     

Mapping DNA conformations and interactions within the binding cleft of bacteriophage T4 single-stranded DNA binding protein (gp32) at single nucleotide resolution

In this study, we use single-stranded DNA (oligo-dT) lattices that have been position-specifically labeled with monomer or dimer 2-aminopurine (2-AP) probes to map the local interactions of the DNA bases with the nucleic acid binding cleft of gp32, the single-stranded binding (ssb) protein of bacteriophage T4. Three complementary spectroscopic approaches are used to characterize these local interactions of the probes with nearby nucleotide bases and amino acid residues at varying levels of effective protein binding cooperativity, as manipulated by changing lattice length. These include: (i) examining local quenching and enhancing effects on the fluorescence spectra of monomer 2-AP probes at each position within the cleft; (ii) using acrylamide as a dynamic-quenching additive to measure solvent access to monomer 2-AP probes at each ssDNA position; and (iii) employing circular dichroism spectra to characterize changes in exciton coupling within 2-AP dimer probes at specific ssDNA positions within the protein cleft. The results are interpreted in part by what we know about the topology of the binding cleft from crystallographic studies of the DNA binding domain of gp32 and provide additional insights into how gp32 can manipulate the ssDNA chain at various steps of DNA replication and other processes of genome expression.