Sequence specific fluorescence detection of double strand DNA

Methods for the fluorescent detection of specific sequences of double strand DNA in homogeneous solution may be useful in the field of human genetics. A series of hairpin polyamides with tetramethyl rhodamine (TMR) attached to an internal pyrrole ring were synthesized, and the fluorescence properties of the polyamide-fluorophore conjugates in the presence and absence of duplex DNA were examined. We observe weak TMR fluorescence in the absence of DNA. Addition of ≥ 1:1 match DNA affords a significant fluorescence increase over equimolar mismatch DNA for each polyamide-TMR conjugate. Polyamide-fluorophore conjugates offer a new class of sensors for the detection of specific DNA sequences without the need for denaturation. The polyamide-dye fluorescence-based method can be used to screen in parallel the interactions between aromatic ring pairs and the minor groove of DNA even when the binding site contains a non-Watson-Crick DNA base pair. A ranking of the specificity of three polyamide ring pairs-Py/Py, Im/Py, and Im/Im-was established for all 16 possible base pairs of A, T, G, and C in the minor groove. We find that Im/Im is an energetically favorable ring pair for minor groove recognition of the T·G base pair

Sequence specific fluorescence detection of double strand DNA

Methods for the fluorescent detection of specific sequences of double strand DNA in homogeneous solution may be useful in the field of human genetics. A series of hairpin polyamides with tetramethyl rhodamine (TMR) attached to an internal pyrrole ring were synthesized, and the fluorescence properties of the polyamide-fluorophore conjugates in the presence and absence of duplex DNA were examined. We observe weak TMR fluorescence in the absence of DNA. Addition of ≥ 1:1 match DNA affords a significant fluorescence increase over equimolar mismatch DNA for each polyamide-TMR conjugate. Polyamide-fluorophore conjugates offer a new class of sensors for the detection of specific DNA sequences without the need for denaturation. The polyamide-dye fluorescence-based method can be used to screen in parallel the interactions between aromatic ring pairs and the minor groove of DNA even when the binding site contains a non-Watson-Crick DNA base pair. A ranking of the specificity of three polyamide ring pairs-Py/Py, Im/Py, and Im/Im-was established for all 16 possible base pairs of A, T, G, and C in the minor groove. We find that Im/Im is an energetically favorable ring pair for minor groove recognition of the T·G base pair

Influence of structural variation on nuclear localization of DNA-binding polyamide-fluorophore conjugates

A pivotal step forward in chemical approaches to controlling gene expression is the development of sequence-specific DNA-binding molecules that can enter live cells and traffic to nuclei unaided. DNA-binding polyamides are a class of programmable, sequence-specific small molecules that have been shown to influence a wide variety of protein–DNA interactions. We have synthesized over 100 polyamide-fluorophore conjugates and assayed their nuclear uptake profiles in 13 mammalian cell lines. The compiled dataset, comprising 1300 entries, establishes a benchmark for the nuclear localization of polyamide-dye conjugates. Compounds in this series were chosen to provide systematic variation in several structural variables, including dye composition and placement, molecular weight, charge, ordering of the aromatic and aliphatic amino-acid building blocks and overall shape. Nuclear uptake does not appear to be correlated with polyamide molecular weight or with the number of imidazole residues, although the positions of imidazole residues affect nuclear access properties significantly. Generally negative determinants for nuclear access include the presence of a ß-Ala-tail residue and the lack of a cationic alkyl amine moiety, whereas the presence of an acetylated 2,4-diaminobutyric acid-turn is a positive factor for nuclear localization. We discuss implications of these data on the design of polyamide-dye conjugates for use in biological systems

Shape Selective Recognition of the DNA Minor Groove by Hairpin Polyamides

Polyamides composed of N-methylpyrrole (Py), N-methylimidazole (Im), and 3-hydroxy-N-methylpyrrole (Hp) are crescent-shaped ligands that bind predetermined DNA sequences with affinities and specificities rivaling naturally occurring proteins. Inherent limitations of the thymine-selective Hp residue, including reduced affinity, diminished stability in aqueous solution, and loss of specificity in N-terminal pairings, have restricted the array of DNA sequences that can be specifically targeted with polyamides. The work described in this thesis addresses two major areas of research: the development of fluorescent conjugates of minor groove-binding polyamides as tools for genomic analysis and expansion of the minor groove recognition code by designing internal and N-terminal replacements for Hp. Fluorophore-polyamide conjugates were designed using different fluorescent probes, different sites of probe attachment with respect to the polyamide, and different chemical linkers separating the above moieties. Ring conjugates, connecting tetramethylrhodamine or cyanine probes to the N-methyl position of Py rings exhibited reasonable affinities and specificities for the cognate DNA sequences, and displayed fluorescent enhancement upon association with the minor groove. The cyanine conjugates, though less quenched than their TMR counterparts, also demonstrated the capacity for fluorescence resonance energy transfer (FRET). The advantages offered by polyamides relative to oligonucleotide-based probes for DNA detection suggest that polyamides might be useful tools for genomic analysis. The utility of polyamides as diagnostic tools or as therapeutic agents would be greatly enhanced by the development of novel thymine-specific residues. Efforts toward this end have employed two general design strategies for Hp replacement. One approach has sought to remove the hydroxyl recognition element in favor of purely shape selective discrimination of the T.A base pair, while other efforts have examined alternative hydroxy-substituted aromatic scaffolds that possess greater stability than Hp. Both of these approaches are discussed in the context of N-terminal, internal, and multiple recognition of T.A base pairs.</p

Expanding the repertoire of heterocycle ring pairs for programmable minor groove DNA recognition

The discrimination of the four Watson−Crick base pairs by minor groove DNA-binding polyamides have been attributed to the specificity of three five-membered aromatic amino acid subunits, 1-methyl-1H-imidazole (Im), 1-methyl-1H-pyrrole (Py), and 3-hydroxy-1H-pyrrole (Hp) paired four different ways. The search for additional ring pairs that demonstrate DNA-sequence specificity has led us to a new class of 6−5 fused bicycle rings as minor groove recognition elements. The affinities and specificities of the hydroxybenzimidazole/pyrrole (Hz/Py) and hydroxybenzimidazole/benzimidazole (Hz/Bi) pairs for each of the respective Watson−Crick base pairs within the sequence context 5‘-TGGXCA-3‘ (X = A, T, G, C) were measured by quantitative DNaseI footprinting titrations. The Hz/Py and Hz/Bi distinguish T·A from A·T. Hairpin polyamides containing multiple Hz/Py pairs were examined and were shown to mimic the Hp/Py pair with regard to affinity and specificity. Therefore, the Hz/Py pair may be considered a second-generation replacement for the Hp/Py pair

DNA minor-groove recognition by 3-methylthiophene/pyrrole pair

Hairpin polyamides are synthetic oligomers, which fold and bind to specific DNA sequences in a programmable manner. Internal side-by-side pairings of the aromatic amino acid residues 1-methyl-1H-pyrrole (Py), 1-methyl-1H-imidazole (Im), and 3-hydroxy-1-methyl-1H-pyrrole (Hp) confer the ability to distinguish between all four Watson-Crick base pairs in the minor groove of B-form DNA. In a broad search to expand the heterocycle repertoire, we found that when 3-methylthiophene (Tn), which presents a S-atom to the minor groove, is paired with Py, it exhibits a modest threefold specificity for TA>AT presumably by shape-selective recognition. In this study, we explore the scope and limitations of this lead by incorporating multiple Tn residues within a single hairpin polyamide. It was found that hairpin polyamides containing more that one Tn/Py pair exhibit lowered affinities and specificities for their match sites. It appears that little deviation is permissible from the parent five-membered ring 1-methyl-1H-pyrrole-2-carboxamide scaffold for DNA recognition

DNA minor-groove recognition by 3-methylthiophene/pyrrole pair

Hairpin polyamides are synthetic oligomers, which fold and bind to specific DNA sequences in a programmable manner. Internal side-by-side pairings of the aromatic amino acid residues 1-methyl-1H-pyrrole (Py), 1-methyl-1H-imidazole (Im), and 3-hydroxy-1-methyl-1H-pyrrole (Hp) confer the ability to distinguish between all four Watson-Crick base pairs in the minor groove of B-form DNA. In a broad search to expand the heterocycle repertoire, we found that when 3-methylthiophene (Tn), which presents a S-atom to the minor groove, is paired with Py, it exhibits a modest threefold specificity for TA>AT presumably by shape-selective recognition. In this study, we explore the scope and limitations of this lead by incorporating multiple Tn residues within a single hairpin polyamide. It was found that hairpin polyamides containing more that one Tn/Py pair exhibit lowered affinities and specificities for their match sites. It appears that little deviation is permissible from the parent five-membered ring 1-methyl-1H-pyrrole-2-carboxamide scaffold for DNA recognition

Shape selective recognition of T•A base pairs by hairpin polyamides containing N-terminal 3-methoxy (and 3-chloro) thiophene residues

Hairpin polyamides selectively recognize predetermined DNA sequences with affinities comparable to naturally occurring proteins. Internal side-by-side pairs of unsymmetrical aromatic rings within the minor groove of DNA distinguish each of the four Watson-Crick base pairs. In contrast, N-terminal ring pairs exhibit less specificity, with the exception of Im/Py targeting G.C base pairs. In an effort to explore the sequence specificity of new ring pairs, a series of hairpin polyamides containing 3-substituted-thiophene-2-carboxamide residues at the N-terminus was synthesized. An N-terminal 3-methoxy (or 3-chloro) thiophene residue paired opposite Py displayed 6- (and 3-) fold selectivity for T.A relative to A.T base pair, while disfavoring G,C base pairs by >200-fold. Our data suggests shape selective recognition with projection of the 3-thiophene substituent (methoxy or chloro) to the floor of the minor groove