Tuning the DNA reactivity of cis-platinum: conjugation to a mismatch-specific metallointercalator

A novel bimetallic conjugate combining a rhodium intercalator that selectively binds DNA mismatches and a reactive cis-platinum analogue that targets DNA by coordination has been prepared. The site-selectivity of the bimetallic complex in forming coordination adducts is examined using mismatched and well-matched oligonucleotides of different sequences. The results indicate that through the bifunctional complex, the platinum center can be targeted near mismatched sites. Interestingly, with mismatched, DNA both intrastrand and the less common interstrand cross-linked adducts are formed. The recognition of a DNA mismatch by the bulky Rh intercalator appears to direct the Pt unit, depending upon steric contraints, to react preferentially with mismatched DNA at a site that may or may not be the preferred site of Pt coordination. Thus, the presence of a permanent link to a site-specific intercalator is able to tune the reactivity of the cis-platinum analogue.     

Bifunctional rhodium intercalator conjugates as mismatch-directing DNA alkylating agents

A conjugate of a DNA mismatch-specific rhodium intercalator, containing the bulky chrysenediimine ligand, and an aniline mustard has been prepared, and targeting of mismatches in DNA by this conjugate has been examined. The preferential alkylation of mismatched over fully matched DNA is found by a mobility shift assay at concentrations where untethered organic mustards show little reaction. The binding site of the Rh intercalator was determined by DNA photocleavage, and the position of covalent modification was established on the basis of the enhanced depurination associated with N-alkylation. The site-selective alkylation at mismatched DNA renders these conjugates useful tools for the covalent tagging of DNA base pair mismatches and new chemotherapeutic design.     

Targeting abasic sites and single base bulges in DNA with metalloinsertors

The site-specific recognition of abasic sites and single base bulges in duplex DNA by sterically expansive rhodium metalloinsertors has been investigated. Through DNA photocleavage experiments, Rh(bpy)2(chrysi)3+ is shown to bind both abasic sites and single base bulges site-specifically and, upon irradiation, to cleave the backbone of the defect-containing DNA. Photocleavage titrations reveal that the metal complex binds DNA containing an abasic site with high affinity (2.6(5) x 106 M-1), comparably to the metalloinsertor and a CC mismatch. The complex binds single base bulge sites with lower affinity (approximately 105 M-1). Analysis of cleavage products and the correlation of affinities with helix destabilization suggest that Rh(bpy)2(chrysi)3+ binds both lesions via metalloinsertion, as observed for Rh binding at mismatched sites, a binding mode in which the mismatched or unpaired bases are extruded from the helix and replaced in the base stack by the sterically expansive ligand of the metalloinsertor.     

DNA strand cleavage near a CC mismatch directed by a metalloinsertor

Reagents for recognition and efficient cleavage of mismatched DNA without photoactivation were designed. They contain a combination of a mismatch-directing metalloinsertor, [Rh(bpy)2(chrysi)]3+ (bpy=2,2'-bipyridyl, chrysi=5,6-chrysenequinone diimine), and an oxidative cleavage functionality, [Cu(phen)2]+ (Cu). Both unconjugated (Rh+Cu) and conjugated (Rh-Cu) frameworks of the Rh insertor and Cu were prepared. Compared to Cu, both constructs Rh+Cu and Rh-Cu exhibit efficient site-specific DNA scission only with mismatched DNA, confirmed by experiments with 32P-labeled oligonucleotides. Furthermore, these studies indicate that DNA cleavage occurs near the mismatch in the minor groove and on both strands. Interestingly, the order of reactivity of the three systems with a CC mismatch is Rh+Cu>Rh-Cu>Cu. Rh binding appears to direct Cu reactivity with or without tethering. These results illustrate advantages and disadvantages in bifunctional conjugation.     

Binding of Ru(bpy)2(eilatin)2+ to matched and mismatched DNA

The DNA-binding properties of Ru(bpy)2(eilatin)(2+) have been investigated to determine if the sterically expansive eilatin ligand confers specificity for destabilized single-base mismatches in DNA. Competitive DNA photocleavage experiments employing a sequence-neutral metallointercalator, Rh(bpy)2(phi)(3+) (phi = 9,10-phenanthrenequinonediimine), and a mismatch-specific metalloinsertor, Rh(bpy)2(chrysi)(3+) (chrysi = chrysene-5,6-quinonediimine), reveal that the eilatin complex binds to a CC mismatched site with an apparent binding constant of 2.2(2) x 10(6) M(-1). Nonetheless, the selectivity in binding mismatched DNA is not high: competitive titrations with Rh(bpy)2(phi)(3+) show that the complex binds also to well-matched B-form sites. Thus, Ru(bpy)2(eilatin)(2+), despite containing the extremely expansive eilatin ligand, displays lower selectivity for the mismatch than does Rh(bpy)2(chrysi)(3+), a metalloinsertor containing the smaller, though still bulky, chrysene-5,6-quinonediimine ligand. In summary, the size and shape of the eilatin ligand allow stacking with both well-matched and mismatched DNA.     

Ru(Ⅲ)、Rh(Ⅲ)、Pd(Ⅱ)离子与ct-DNA的相互作用研究

本文以中药小檗碱作为分子探针，在0.01mol·L^-1醋酸-醋酸钠缓冲体系中，用紫外-可见吸收及荧光光谱法研究了Ru(Ⅲ)、Rh(Ⅲ)、Pd(Ⅱ)三种贵金属离子与DNA的键合相互作用。实验发现Ru(Ⅲ)离子对小檗碱-DNA二元体系的荧光有较强的猝灭作用;而Rh(Ⅲ)、Pd(Ⅱ)两种离子则对该二元体系产生显著的荧光敏化作用。考察了EDTA对贵金属离子、小檗碱及DNA三元混合体系的荧光光谱的影响，初步探讨了贵金属离子与DNA可能的键合机理。     

Solid-phase synthesis of positively charged deoxynucleic guanidine (DNG) tethering a Hoechst 33258 analogue: triplex and duplex stabilization by simultaneous minor groove binding

Deoxynucleic guanidine (DNG), a DNA analogue in which positively charged guanidine replaces the phosphodiester linkages, tethering to Hoechst 33258 fluorophore by varying lengths has been synthesized. A pentameric thymidine DNG was synthesized on solid phase in the 3' --> 5' direction that allowed stepwise incorporation of straight chain amino acid linkers and a bis-benzimidazole (Hoechst 33258) ligand at the 5'-terminus using PyBOP/HOBt chemistry. The stability of (DNA)(2).DNG-H triplexes and DNA.DNG-H duplexes formed by DNG and DNG-Hoechst 33258 (DNG-H) conjugates with 30-mer double-strand (ds) DNA, d(CGCCGCGCGCGCGAAAAACCCGGCGCGCGC)/d(GCGGCGCGCGCGCTTTTTGGGCCGCGCGCG), and single-strand (ss) DNA, 5'-CGCCGCGCGCGCGAAAAACCCGGCGCGCGC-3', respectively, has been evaluated by thermal melting and fluorescence emission experiments. The presence of tethered Hoechst ligand in the 5'-terminus of the DNG enhances the (DNA)(2).DNG-H triplex stability by a DeltaT(m) of 13 degrees C. The fluorescence emission studies of (DNA)(2).DNG-H triplex complexes show that the DNG moiety of the conjugates bind in the major groove while the Hoechst ligand resides in the A:T rich minor groove of dsDNA. A single G:C base pair mismatch in the target site decreases the (DNA)(2).DNG triplex stability by 11 degrees C, whereas (DNA)(2).DNG-H triplex stability was decreased by 23 degrees C. Inversion of A:T base pair into T:A base pair in the center of the binding site, which provides a mismatch selectively for DNG moiety, decreases the triplex stability by only 5-6 degrees C. Upon hybridization of DNG-Hoechst conjugates with the 30-mer ssDNA, the DNA.DNG-H duplex exhibited significant increase in the fluorescence emission due to the binding of the tethered Hoechst ligand in the generated DNA.DNG minor groove, and the duplex stability was enhanced by DeltaT(m) of 7 degrees C. The stability of (DNA)(2).DNG triplexes and DNA.DNG duplexes is independent of pH, whereas the stability of (DNA)(2).DNG-H triplexes decreases with increase in pH.     

Water-soluble NIR fluorescent probes based on squaraine and their application for protein labeling.

Water-soluble near-infrared (NIR) fluorescent labeling probes, named KSQ-3 and -4, which are based on a squaraine backbone, were synthesized and applied to biological labeling. The presented results demonstrate that the large, planar and hydrophobic squaraine dye becomes fully soluble in aqueous solution by the introduction of several sulfo group terminated alkyl substituents. Especially KSQ-4, which is substituted with four sulfo groups, exhibited perfect water solubility and significant fluorescence emission at the NIR region (817 nm) in the presence of bovine serum albumin (BSA). BSA was covalently labeled with KSQ-4, and the conjugate showed a strong absorption peak at 787 nm, which indicates compatibility with commercially available NIR laser diodes used for exciting the fluorophore. Furthermore, strong fluorescence emission was observed at 812 nm (phi = 0.08).     

Fluorescence light-up recognition of DNA nucleotide based on selective abasic site binding of an excited-state intramolecular proton transfer probe

DNA single-nucleotide polymorphism (SNP) detection has attracted much attention due to mutation-related diseases. Various fluorescence methods for SNP detection have been proposed and many are already in use. However, fluorescence enhancement for signal-on SNP identification without label modification still remains a challenge. Here, we find that the abasic site (AP site) in a DNA duplex can be developed as a binding pocket favorable for the occurrence of the excited-state intramolecular proton transfer (ESIPT) of a 3-hydroxyflavone, fisetin, which is used as a proof of concept for effective SNP identification. Fisetin binding at the AP site is highly selective for target thymine or cytosine facing the AP site by observation of a drastic increase in the ESIPT emission band. In addition, the target recognition selectivity based on this ESIPT process is not affected by flanking bases of the AP site. The binding selectivity of fisetin at the AP site is also confirmed by measurements of fluorescence resonance energy transfer, emission lifetime and DNA melting. The fluorescent signal-on sensing for SNP based on this fluorophore is substantially advantageous over the previously used fluorophores such as the AP site-specific signal-off organic ligands with a similar fluorescing mechanism before and after binding to DNA with hydrogen bonding interaction. We expect that this approach will be employed to develop a practical SNP detection method by locating an AP site toward a target and employing an ESIPT probe as readout.     

Detecting DNA mismatches with metallo-insertors: a molecular simulation study

Molecules that selectively recognize DNA mismatches (MMs) play a key role as nucleic acids probes and as chemotherapeutic agents. Metallo-insertors bind to the minor groove (mG) of double strand (ds) DNA, expelling the mismatched base pairs and acting as their π-stacking replacement. In contrast, metallo-intercalators bind to the major groove (MG) of ds DNA and π-stack to adjacent base pairs. In this study we focused on structural and energetic properties of Δ-[Rh(bpy)(2)(chrysi)](3+) (1), Δ-[Ru(bpy)(2)(ddpz)](2+) (2), and Δ-[Ru(bpy)(2)(eilatin)](2+) (3) as prototypical examples of metallo-insertors and intercalators. For all molecules we characterized both insertion and intercalation into a DNA dodecamer via force field based molecular dynamics (MD) and hybrid quantum-classical (QM/MM) MD simulations. A structural analysis of the 1-3/DNA noncovalent adducts reveals that the insertion provokes an untwist of the DNA, an opening of the mG and of the phosphate backbone in proximity of the mismatch, while the intercalation induces smaller changes of these structural parameters. This behavior appears to be correlated with the size of the inserting/intercalating ligand in proximity of the metal coordination site. Moreover, our simulations show that the different selectivity of 1 toward distinct MM types may be correlated with the thermodynamic stability of the MMs in the free DNA and with that of the corresponding insertion adduct. Understanding the factors which tune a specific insertion is of crucial importance for designing specific luminescent probes that selectively recognize MMs, as well as for developing more effective anticancer drugs active in MM repair of deficient cells lines.     

Simultaneous fluorescence light-up and selective multicolor nucleobase recognition based on sequence-dependent strong binding of berberine to DNA abasic site

Label-free DNA nucleobase recognition by fluorescent small molecules has received much attention due to its simplicity in mutation identification and drug screening. However, sequence-dependent fluorescence light-up nucleobase recognition and multicolor emission with individual emission energy for individual nucleobases have been seldom realized. Herein, an abasic site (AP site) in a DNA duplex was employed as a binding field for berberine, one of isoquinoline alkaloids. Unlike weak binding of berberine to the fully matched DNAs without the AP site, strong binding of berberine to the AP site occurs and the berberine's fluorescence light-up behaviors are highly dependent on the target nucleobases opposite the AP site in which the targets thymine and cytosine produce dual emission bands, while the targets guanine and adenine only give a single emission band. Furthermore, more intense emissions are observed for the target pyrimidines than purines. The flanking bases of the AP site also produce some modifications of the berberine's emission behavior. The binding selectivity of berberine at the AP site is also confirmed by measurements of fluorescence resonance energy transfer, excited-state lifetime, DNA melting and fluorescence quenching by ferrocyanide and sodium chloride. It is expected that the target pyrimidines cause berberine to be stacked well within DNA base pairs near the AP site, which results in a strong resonance coupling of the electronic transitions to the particular vibration mode to produce the dual emissions. The fluorescent signal-on and emission energy-modulated sensing for nucleobases based on this fluorophore is substantially advantageous over the previously used fluorophores. We expect that this approach will be developed as a practical device for differentiating pyrimidines from purines by positioning an AP site toward a target that is available for readout by this alkaloid probe.     

Increasing the Sensitivity and Single‐Base Mismatch Selectivity of the Molecular Beacon Using Graphene Oxide as the “Nanoquencher”

Here, we report a novel, highly sensitive, selective and economical molecular beacon using graphene oxide as the “nanoquencher”. This novel molecular beacon system contains a hairpin‐structured fluorophore‐labeled oligonucleotide and a graphene oxide sheet. The strong interaction between hairpin‐structured oligonucleotide and graphene oxide keep them in close proximity, facilitating the fluorescence quenching of the fluorophore by graphene oxide. In the presence of a complementary target DNA, the binding between hairpin‐structured oligonucleotide and target DNA will disturb the interaction between hairpin‐structured oligonucleotide and graphene oxide, and release the oligonucleotide from graphene oxide, resulting in restoration of fluorophore fluorescence. In the present study, we show that this novel graphene oxide quenched molecular beacon can be used to detect target DNA with higher sensitivity and single‐base mismatch selectivity compared to the conventional molecular beacon.     

The selective recognition of mismatched d(GCGAGC)_2 by the cobalt(III) complex

Base mismatches arise naturally in the life cycleof a cell as a result of either polymerase error or DNAdamage. Under most circumstances the cell correctsthese mispairings using a complex repair system toprevent mutations in the genetic code. Experimental…     

Novel probes showing specific fluorescence enhancement on binding to a hexahistidine tag

The introduction of hexahistidine (His tag) is widely used as a tool for affinity purification of recombinant proteins, since the His tag binds selectively to nickel-nitrilotriacetic acid (Ni(2+)-NTA) complex. To develop efficient "turn-on" fluorescent probes for His-tagged proteins, we adopted a fluorophore displacement strategy, that is, we designed probes in which a hydroxycoumarin fluorophore is joined via a linker to a metal-NTA moiety, with which it forms a weak intramolecular complex, thereby quenching the fluorescence. In the presence of a His tag, with which the metal-NTA moiety binds strongly, the fluorophore is displaced, which results in a dramatic enhancement of fluorescence. We synthesized a series of hydroxycoumarins that were modified by various linkers with NTA (NTAC ligands), and investigated the chemical and photophysical properties of the free ligands and their metal complexes. From the viewpoint of fluorescence quenching, Ni(2+) and Co(2+) were the best metals. Fluorescence spectroscopy revealed a 1:1 binding stoichiometry for the Ni(2+) and Co(2+) complexes of NTACs in pH 7.4 aqueous buffer. As anticipated, these complexes showed weak intrinsic fluorescence, but addition of a His-tagged peptide (H-(His)(6)-Tyr-NH(2); Tyr was included to allow convenient concentration measurement) in pH 7.4 aqueous buffer resulted in up to a 22-fold increase in the fluorescence quantum yield. We found that the Co(2+) complexes showed superior properties. No fluorescence enhancement was seen in the presence of angiotensin I, which contains two nonadjacent histidine residues; this suggests that the probes are selective for the polyhistidine peptide.     

The selective recognition of mismatched d(GCGAGC)2 by the cobalt(III) complex

We studied the binding of [Co(phen)₂(HPIP)]CI₃ to mismatched d(GCGAGC)₂ containing two sheared G:A mispairs by NMR. The result shows that the complex was intercalated into G:A region from the minor groove and extended to the major groove, and could selectively recognize the mispairs.³¹P NMR indicates that the complex binding induced the change of the phosphate backbone in the mismatched base pairs region.     

TOTO binding affinity analysis using single-molecule fluorescence spectroscopy

The sequence dependence of the double-stranded DNA (dsDNA)-binding affinity of TOTO, a thiazole orange dimer that functions as a DNA-intercalating fluorophore, was measured using single-molecule methods. An analysis was performed of the distribution of excited-state lifetimes of single molecules of TOTO intercalated into dsDNA fragments containing four-base pair sequences shown previously to have high affinity for TOTO under conditions used in nuclear magnetic resonance (NMR) spectroscopy. For the current studies, the putative binding sites were located centrally in 30-base pair-long dsDNA fragments in which the remaining sequence was either all poly-AT or poly-GC. The lifetime of TOTO fluorescence when bound to these fragments was entirely determined by the background sequence, i.e. DNA fragments with a poly-AT background predominantly gave a fluorescence lifetime of 1.7 ns, whereas DNA fragments with a poly-GC background gave a lifetime of 2.0 ns, independent of the presence or absence of the putative binding sequence. By performing competitive binding experiments in which these DNA fragments competed for TOTO binding with pure poly-AT fragments and using single-molecule fluorescence methods to determine the number of each type of DNA fragment having a TOTO bound in an equilibrium mixture, the relative binding affinity of each putative binding site was determined. The results of these experiments showed clearly that TOTO has no preference for binding to the putative binding sites over binding poly-AT or poly-GC under the conditions of these measurements. This suggests that there is very little sequence dependence of TOTO binding under conditions that would likely predominate in most biological applications of this intercalating dye.     

Duplex‐Selective Ruthenium‐Based DNA Intercalators

We report the design and synthesis of small molecules that exhibit enhanced luminescence in the presence of duplex rather than single‐stranded DNA. The local environment presented by a well‐known [Ru(dipyrido[3,2‐a:2′,3′‐c]phenazine)L₂]²⁺‐based DNA intercalator was modified by functionalizing the bipyridine ligands with esters and carboxylic acids. By systematically varying the number and charge of the pendant groups, it was determined that decreasing the electrostatic interaction between the intercalator and the anionic DNA backbone reduced single‐strand interactions and translated to better duplex specificity. In studying this class of complexes, a single Ru^II complex emerged that selectively luminesces in the presence of duplex DNA with little to no background from interacting with single‐stranded DNA. This complex shows promise as a new dye capable of selectively staining double‐ versus single‐stranded DNA in gel electrophoresis, which cannot be done with conventional SYBR dyes.     

A dsDNA-lighted fluorophore for monitoring protein-ligand interaction through binding-mediated DNA protection

Because of their important roles in cellular functions, life activities, drug screening, and disease treatment, the development of efficient methods for monitoring protein-ligand interaction is essential. In this study, inspired by our previous studies on DNA conformation-selective fluorescent indicators, we developed a new sensing platform for monitoring protein-ligand interaction and detecting protein activity based on binding-mediated DNA protection and the dsDNA-lighted fluorophore, ethyl-4-[3,6-bis(1-methyl-4-vinylpyridium iodine)-9 H-carbazol-9-yl)] butanoate(EBCB). The ligand was purposefully linked to the 3?-terminal of a hairpin DNA probe to selectively bind with the target protein and protect the DNA from cleavage by exonuclease III. By virtue of EBCB's outstanding capacity to discriminate DNA conformation, the protein-ligand interaction could be effectively monitored through a fluorescence change in EBCB. A high fluorescence signal was detected when the hairpin DNA was protected in the presence of the target protein, whereas a much lower signal was observed in the presence of nontarget proteins.Our results demonstrated that the proposed strategy had high potential, such as high selectivity and relatively high sensitivity, for monitoring protein-ligand interaction and detecting protein activity. We believe these results will pave the way for applying dsDNA-lighted fluorophore EBCB as an effective signal transducer for DNA conformation transformation-mediated biochemical sensing.     

Fluorescence resonance energy transfer by quencher adsorption into hydrogels containing fluorophores

We synthesized anionic hydrogels containing fluorophores and investigated the adsorption of a cationic quencher having an amino group into hydrogels by fluorescence resonance energy transfer (FRET). FRET from the fluorophore to the quencher in hydrogels was examined by fluorescence intensity and fluorescence decay using a fluorescence spectrophotometer and femtosecond laser spectroscopy. The fluorescence intensity of the fluorophore‐containing hydrogels decreased rapidly with increasing amounts of adsorbed cationic quencher. The fluorescence emission of the fluorophore in the quencher‐adsorbed hydrogels containing fluorophores decayed more rapidly than that of the original hydrogels. The aforementioned result indicates that the fluorescence of the fluorophore‐containing hydrogels is quenched due to FRET from the fluorophore to the quencher as the cationic quenchers can approach the fluorophores in hydrogels by electrostatic interactions. © 2006 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 44: 3245–3252, 2006     

Excited-state intramolecular proton transfer distinguishes microenvironments in single- and double-stranded DNA

Herein, the efficient interaction of an environment-sensitive fluorophore that undergoes excited-state intramolecular proton transfer (ESIPT) with DNA has been realized by conjugation of a 3-hydroxychromone (3HC) with polycationic spermine. On binding to a double-stranded DNA (dsDNA), the ratio of the two emission bands of the 3HC conjugates changes up to 16-fold, so that emission of the ESIPT product increases dramatically. This suggests an efficient screening of the 3HC fluorophore from the water molecules in the DNA complex, which is probably realized by its intercalation into dsDNA. In sharp contrast, the 3HC conjugates show only moderate changes in the dual emission on binding to a single-stranded DNA (ssDNA), indicating a much higher fluorophore exposure to water at the binding site. Thus, the 3-hydroxychromone fluorophore being conjugated to spermine discriminates the binding of this polycation to dsDNA from that to ssDNA. Consequently, ESIPT-based dyes are promising for monitoring the interaction of polycationic molecules with DNA and probing the microenvironment of their DNA binding sites.