DNA fluorescence induced by polymethine cation pyrvinium binding.

Pyrvinium is a polymethine cation which shows interesting fluorescence emission and DNA binding properties. In diluted aqueous solution, pyrvinium pamoate induced a bright yellow fluorescence in kinetoplast DNA from Trypanosoma cruzi epimastigotes as well as in chicken erythrocyte nuclei under a wide range of excitations. No fading was observed after mounting in suitable media. Spectroscopic studies on pyrvinium solutions revealed bathochromic and hypochromic shifts in the absorption spectrum of its complex with DNA. A striking enhancement of pyrvinium fluorescence was found in solvents of high viscosity or after binding to DNA. Experimental results and the chemical structure of pyrvinium allow us to suggest that the minor groove of adenine-thymine DNA regions could be the specific binding site for this new DNA fluorochrome.     

Simultaneously monitoring DNA binding and helicase-catalyzed DNA unwinding by fluorescence polarization

A new method for helicase-catalyzed DNA unwinding is described. This assay takes advantage of the substantial change in fluorescence polarization (FP) upon helicase binding and DNA unwinding. The low anisotropy value, due to the fast tumbling of the free oligonucleotide in solution, increases abruptly upon binding of helicase to the fluorescein-labeled oligonucleotide. The high anisotropy of the helicase– DNA complex decreases as the fluorescein-labeled oligonucleotide is released from the complex through helicase-catalyzed DNA unwinding. This FP signal can be measured in real time by fluorescent spectroscopy. This assay can simultaneously monitor DNA binding and helicase-catalyzed DNA unwinding. It can also be used to determine the polarity in DNA unwinding mediated by helicase. This FP assay should facilitate the study of the mechanism by which helicase unwinds duplex DNA, and also aid in screening for helicase inhibitors, which are of growing interest as potential anticancer agents.     

Monovalent cation binding by curved DNA molecules containing variable numbers of a-tracts

Monovalent cation binding by DNA A-tracts, runs of four or more contiguous adenine or thymine residues, has been determined for two curved ∼200 basepair (bp) restriction fragments, one taken from the M13 origin of replication and the other from the VP1 gene of SV40. These two fragments have previously been shown to contain stable, centrally located bends of 44° and 46°, respectively, located within ∼60 bp “curvature modules” containing four or five irregularly spaced A-tracts. Transient electric birefringence measurements of these two fragments, sequence variants containing reduced numbers of A-tracts in the SV40 curvature module or changes in the residues flanking the A-tracts in the M13 curvature module, have been combined with the free solution electrophoretic mobilities of the same fragments using known equations to estimate the effective charge of each fragment. The effective charge is reduced, on average, by one-third charge for each A-tract in the curvature module, suggesting that each A-tract binds a monovalent cation approximately one-third of the time. Monovalent cation binding to two or more A-tracts is required to observe significant curvature of the DNA helix axis.     

Simultaneous DNA binding and bending by EcoRV endonuclease observed by real-time fluorescence

The complete catalytic cycle of EcoRV endonuclease has been observed by combining fluorescence anisotropy with fluorescence resonance energy transfer (FRET) measurements. Binding, bending, and cleavage of substrate oligonucleotides were monitored in real time by rhodamine-x anisotropy and by FRET between rhodamine and fluorescein dyes attached to opposite ends of a 14-mer DNA duplex. For the cognate GATATC site binding and bending are found to be nearly simultaneous, with association and bending rate constants of (1.45-1.6) x 10(8) M(-1) s(-1). On the basis of the measurement of k(off) by a substrate-trapping approach, the equilibrium dissociation constant of the enzyme-DNA complex in the presence of inhibitory calcium ions was calculated as 3.7 x 10(-12) M from the kinetic constants. Further, the entire DNA cleavage reaction can be observed in the presence of catalytic Mg(2+) ions. These measurements reveal that the binding and bending steps occur at equivalent rates in the presence of either Mg(2+) or Ca(2+), while a slow decrease in fluorescence intensity following bending corresponds to k(cat), which is limited by the cleavage and product dissociation steps. Measurement of k(on) and k(off) in the absence of divalent metals shows that the DNA binding affinity is decreased by 5000-fold to 1.4 x 10(-8) M, and no bending could be detected in this case. Together with crystallographic studies, these data suggest a model for the induced-fit conformational change in which the role of divalent metal ions is to stabilize the sharply bent DNA in an orientation suitable for accessing the catalytic transition state.     

Modeling DNA deformations induced by minor groove binding proteins

Molecular modeling is used to demonstrate that the major structural deformations of DNA caused by four different minor groove binding proteins, TBP, SRY, LEF-1, and PurR, can all be mimicked by stretching the double helix between two 3'-phosphate groups flanking the binding region. This deformation reproduces the widening of the minor groove and the overall bending and unwinding of DNA caused by protein binding. It also reproduces the principal kinks associated with partially intercalated amino acid side chains, observed with such interactions. In addition, when protein binding involves a local transition to an A-like conformation, phosphate neutralization, via the formation of protein-DNA salt bridges, appears to favor the resulting deformation.     

Linkage of cation binding and folding in human telomeric quadruplex DNA

Formation of DNA quadruplexes requires monovalent cation binding. To characterize the cation binding stoichiometry and linkage between binding and folding, we carried out KCl titrations of Tel22 (d[A(GGGTTA)₃]), a model of the human telomere sequence, using a fluorescent indicator to determine [K⁺]_free and circular dichroism to assess the extent of folding. At [K⁺]_free = 5 mM (sufficient for > 95% folding), the apparent binding stoichiometry is 3K⁺/Tel22; at [K⁺]_free = 20 mM, it increased to 8-10K⁺/Tel22. Thermodynamic analysis shows that at [K⁺]_free = 5 mM, K⁺ binding contributes approximately − 4.9 kcal/mol for folding Tel22. The overall folding free energy is − 2.4 kcal/mol, indicating that there are energetically unfavorable contributions to folding. Thus, quadruplex folding is driven almost entirely by the energy of cation binding with little or no contribution from other weak molecular interactions.     

DNA binding activity of Anabaena sensory rhodopsin transducer probed by fluorescence correlation spectroscopy

Anabaena sensory rhodopsin transducer (ASRT) is believed to be a major player in the photo-signal transduction cascade, which is triggered by Anabaena sensory rhodopsin. Here, we characterized DNA binding activity of ASRT probed by using fluorescence correlation spectroscopy. We observed clear decrease of diffusion coefficient of DNA upon binding of ASRT. The dissociation constant, K_D, of ASRT to 20?bp-long DNA fragments lied in micro-molar range and varied moderately with DNA sequence. Our results suggest that ASRT may interact with several different regions of DNA with different binding affinity for global regulation of several genes that need to be activated depending on the light illumination.     

Fast detection of quadruplex structure in DNA by the intrinsic fluorescence of a single-stranded DNA binding protein

Single-stranded guanine-rich (G-rich) DNA can fold into a four-stranded G-quadruplex structure and such structures are implicated in important biological processes and therapeutic applications. So far, bioinformatic analysis has identified up to several hundred thousand of putative quadruplex sequences in the genome of human and other animal. Given such a large number of sequences, a fast assay would be desired to experimentally verify the structure of these sequences. Here we describe a method that identifies the quadruplex structure by a single-stranded DNA binding protein from a thermoautotrophic archaeon. This protein binds single-stranded DNA in the unfolded, but not in the folded form. Upon binding to DNA, its fluorescence can be quenched by up to 70%. Formation of quadruplex greatly reduces fluorescence quenching in a K+-dependent manner. This structure-dependent quenching provides simple and fast detection of quadruplex in DNA at low concentration without DNA labelling.     

Changes in Na+,K(+)-ATPase structure induced by cation binding. Approach by Raman spectroscopy.

Raman analysis of Na+,K(+)-ATPase structural changes induced by cation binding reveals a slight decrease ( < 10%) of the alpha-helical content upon E1-E2 transition. Pronounced conformational changes of the enzyme are unlikely as the character of the environment of tyrosine residues remains unaltered. However, local changes can take place as evidenced by changes in tryptophan vibration at about 880 cm-1.     

A novel major groove binding site in B-form DNA for ethidium cation

A stably-bound external binding site for ethidium cation in the major groove of B-form DNA is proposed. This complex is stabilized by hydrogen bonding between this ligand and the nucleophilic centers O6 and N7 of guanine, both of which are accessible via the major groove. This binding site is not the same as the well-characterized electrostatically-stabilized external binding site, but rather is seen to be a covalently bound complex which is stabilized by two hydrogen bonds between the ethidium ligand and guanine in the double stranded (ds) B-form DNA. This site [(1), R. Monaco, F. Hasheer. J Biomol Struct Dyn 10, 675 (1993)] can only exist at very low occupancy ratios. The existence of this binding site leads directly to the expectation that there will exist particular mechanistic steps along the pathway of interaction between ethidium and ds B-DNA at low and high ligand concentrations that involve this binding mode. This would not only explain observations published recently [for example, see (2-6), W. Wilson, I. Lopp. Biopolymers 18, 3025 (1979); L. Wakelin, M. Waring. J Mol Biol 144, 183-214 (1980); A. Karpetyan, N. Mehrabian, G. Terzikian, A. Antonian, P. Vardevanian, M. Frank-Kamenetshii. Proceedings of the 10th Conversation, SUNY Albany, 275 (1998); P. Vardevanyan, A. Antonyan, G. Manukyan, A. Karapetyan. Experimental and Molecular Medicine 33, 205 (2001); P. Vardevanyan, A. Antonyan, L. Minasbekan, A. Karapetyan. Proceedings of the 2002 Miami Nature Biotechnology Winter Symposium, 2(S1), 144 (2002)] but also give insight into discrepancies reported in the literature over the years by different workers studying the mechanism of interaction between ethidium and DNA. In this paper this novel binding interaction is discussed, and it is shown how the elucidation of this interaction led to the proposal of two distinct mechanisms of intercalation between ds B-DNA and ethidium cation for high and low concentrations of ligand. Modeling studies show the stability, configuration, and relative energies of this outside binding site. It is expected that this externally bound complex between ethidium cation and ds B-form DNA will be experimentally detectable using fluorescent polarization and/or linear and circular dichroism spectroscopic studies [(7, 8) E. Tuite, U. Sehlstedt, P. Hagmar, B. Norden, M. Takahashi. Euro J Biochem 243, 482-492 (1997); T. Hard. Biopolymers 26, 613-618 (1987)].     

Fibronectin inhibits cytokine production induced by CpG DNA in macrophages without direct binding to DNA

Fibronectin (FN) is known to have four DNA-binding domains although their physiological significance is unknown. Primary murine peritoneal macrophages have been shown to exhibit markedly lower responsiveness to CpG motif-replete plasmid DNA (pDNA), Toll-like receptor-9 (TLR9) ligand, compared with murine macrophage-like cell lines. The present study was conducted to examine whether FN having DNA-binding domains is involved in this phenomenon. The expression of FN was significantly higher in primary macrophages than in a macrophage-like cell line, RAW264.7, suggesting that abundant FN might suppress the responsiveness in the primary macrophages. However, electrophoretic analysis revealed that FN did not bind to pDNA in the presence of a physiological concentration of divalent cations. Surprisingly, marked tumor necrosis factor - (TNF-)α production from murine macrophages upon CpG DNA stimulation was significantly reduced by exogenously added FN in a concentration-dependent manner but not by BSA, laminin or collagen. FN did not affect apparent pDNA uptake by the cells. Moreover, FN reduced TNF-α production induced by polyI:C (TLR3 ligand), and imiquimod (TLR7 ligand), but not by LPS (TLR4 ligand), or a non-CpG pDNA/cationic liposome complex. The confocal microscopic study showed that pDNA was co-localized with FN in the same intracellular compartment in RAW264.7, suggesting that FN inhibits cytokine signal transduction in the endosomal/lysosomal compartment. Taken together, the results of the present study has revealed, for the first time, a novel effect of FN whereby the glycoprotein modulates cytokine signal transduction via CpG-DNA/TLR9 interaction in macrophages without direct binding to DNA through its putative DNA-binding domains.     

pH-dependent fluorescence of uncharged benzothiazole-based dyes binding to DNA.

Uncharged benzothiazole-based dyes were synthesized, and their fluorescence properties were examined. These fluorescent dyes showed an intense fluorescence in aqueous solution in the presence of DNA. In addition, the fluorescence intensities were pH dependent, while those of the positively charged dyes were nearly independent of pH. The pH-dependent photophysical behavior suggests that interaction of protonated dyes with DNA results in high intensities of fluorescent emission.     

DNA bending induced by high mobility group proteins studied by fluorescence resonance energy transfer.

The HMG domains of the chromosomal high mobility group proteins homologous to the vertebrate HMG1 and HMG2 proteins preferentially recognize distorted DNA structures. DNA binding also induces a substantial bend. Using fluorescence resonance energy transfer (FRET), we have determined the changes in the end-to-end distance consequent on the binding of selected insect counterparts of HMG1 to two DNA fragments, one of 18 bp containing a single dA(2) bulge and a second of 27 bp with two dA(2) bulges. The observed changes are consistent with overall bend angles for the complex of the single HMG domain with one bulge and of two domains with two bulges of approximately 90-100 degrees and approximately 180-200 degrees, respectively. The former value contrasts with an inferred value of 150 degrees reported by Heyduk et al. (1) for the bend induced by a single domain. We also observe that the induced bend angle is unaffected by the presence of the C-terminal acidic region. The DNA bend of approximately 95 degrees observed in the HMG domain complexes is similar in magnitude to that induced by the TATA-binding protein (80 degrees), each monomeric unit of the integration host factor (80 degrees), and the LEF-1 HMG domain (107 degrees). We suggest this value may represent a steric limitation on the extent of DNA bending induced by a single DNA-binding motif.     

Stopped-flow fluorescence studies of HMG-domain protein binding to cisplatin-modified DNA

High-mobility group (HMG) domain proteins bind specifically to the major DNA adducts formed by the anticancer drug cisplatin and can modulate the biological response to this inorganic compound. Stopped-flow fluorescence studies were performed to investigate the kinetics of formation and dissociation of complexes between HMG-domain proteins and a series of 16-mer oligonucleotide probes containing both a 1,2-intrastrand d(GpG) cisplatin cross-link and a fluorescein-modified deoxyuridine residue. Rate constants, activation parameters, and dissociation constants were determined for complexes formed by HMG1 domain A and the platinated DNA probes. The sequence context of the cisplatin adduct modulates the value of the associative rate constant for HMG1 domain A by a factor of 2-4, contributing significantly to differences in binding affinity. The rates of association or dissociation of the protein-DNA complex were similar for a 71 bp platinated DNA analogue. Additional kinetic studies performed with HMG1 domain B, an F37A domain A mutant, and the full-length HMG1 protein highlight differences in the binding properties of the HMG domains. The stopped-flow studies demonstrate the utility of the fluorescein-dU probe in studying protein-DNA complexes. The kinetic data will assist in determining what role these proteins might play in the cisplatin mechanism of action.     

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.     

The environment of the high-affinity cation binding site on actin and the separation between cation and ATP sites as revealed by proton NMR and fluorescence spectroscopy

The lanthanide ions Lu3+ (diamagnetic) and Gd3+ (paramagnetic broadening probe) were used to displace Ca2+ from the high-affinity cation binding site on G-actin. The effects of these higher-affinity ions on the proton nuclear magnetic resonance spectrum of actin were recorded. The aliphatic proton envelope in the Gd-actin sample exhibited a complex array of changes due to the proximity of Gd to several aliphatic residues. No such changes were observed in the diamagnetic Lu-actin control spectrum. By contrast, the aromatic proton envelope remained largely unaffected in both Gd-actin and Lu-actin samples. However, the adenosine moiety on the actin-bound ATP became increasingly mobilized without the triphosphate chain being released from the ATP binding site. Maximum adenosine mobilization occurred with approximately 1 mol of lanthanide ion bound per mol of actin. The absence of changes in the aromatic proton envelope suggests that the high-affinity cation binding site is in a region well removed from the adenosine moiety of bound ATP as well as any aromatic side-chains. The separation of the ATP and cation sites was further explored using the fluorescent ATP analogues FTP and epsilon-ATP. Tb3+ bound to the high-affinity cation site was found to be separated by 16 A from the FTP chromophore bound to the nucleotide binding site on actin. Since this distance is greater than can be accommodated on a model of the Tb-ATP complex, we conclude that the sites are physically separate. This conclusion was further reinforced by experiments involving the quenching of epsilon-ATP fluorescence by Mn2+.(ABSTRACT TRUNCATED AT 250 WORDS)