Sequence-specific trapping of topoisomerase I by DNA binding polyamide-camptothecin conjugates.

Hairpin pyrrole-imidazole polyamides are synthetic ligands that bind in the minor groove of DNA with affinities and specificities comparable to those of DNA binding proteins. Three polyamide-camptothecin conjugates 1-3 with linkers varying in length between 7, 13, and 18 atoms were synthesized to trap the enzyme Topoisomerase I and induce cleavage at predetermined DNA sites. One of these, polyamide-camptothecin conjugate 3 at nanomolar concentration (50 nM) in the presence of Topo I (37 degrees C), induces DNA cleavage between three and four base pairs from the polyamide binding site in high yield (77%).

Inhibition of major groove DNA binding bZIP proteins by positive patch polyamides.

Cell permeable synthetic ligands that bind to predetermined DNA sequences offer a chemical approach to gene regulation, provided inhibition of a broad range of DNA transcription factors can be achieved. DNA minor groove binding polyamides containing aminoalkyl substituents at the N-1 of a single pyrrole residue display inhibitory effects for a bZIP protein which binds exclusively in the DNA major groove. For major groove protein inhibition, specific protein-DNA contacts along the phosphate backbone were targeted with the positively charged dimethylamino substituent on the backbone of a minor groove binding polyamide hairpin. Remarkably, these polyamides bind DNA with enhanced affinity and uncompromised specificity when compared to polyamides with the aminoalkyl moiety at the C-terminus. By adding bZIP transcription factors to the class of protein-DNA complexes that can be disrupted by minor groove binding ligands, these results may increase the functional utility of polyamides as regulators of gene expression.

Sequence-specific recognition of DNA in the nucleosome by pyrrole-imidazole polyamides.

The ability of DNA-binding proteins to recognize their cognate sites in chromatin is restricted by the structure and dynamics of nucleosomal DNA, and by the translational and rotational positioning of the histone octamer. Here, we use six different pyrrole-imidazole polyamides as sequence-specific molecular probes for DNA accessibility in nucleosomes. We show that sites on nucleosomal DNA facing away from the histone octamer, or even partially facing the histone octamer, are fully accessible and that nucleosomes remain fully folded upon ligand binding. Polyamides only failed to bind where sites are completely blocked by interactions with the histone octamer. Removal of the amino-terminal tails of either histone H3 or histone H4 allowed these polyamides to bind. These results demonstrate that much of the DNA in the nucleosome is freely accessible for molecular recognition in the minor groove, and also support a role for the amino-terminal tails of H3 and H4 in modulating accessibility of nucleosomal DNA.

Towards a minimal motif for artificial transcriptional activators.

BACKGROUND: Most transcriptional activators minimally comprise two functional modules, one for DNA binding and the other for activation. Several activators also bear an oligomerization region and bind DNA as dimers or higher order oligomers. In a previous study we substituted these domains of a protein activator with synthetic counterparts [Mapp et al., Proc. Natl. Acad. Sci. USA 97 (2000) 3930-3935]. An artificial transcriptional activator, 4.2 kDa in size, comprised of a DNA binding hairpin polyamide tethered to a 20 residue activating peptide (AH) was shown to stimulate promoter specific transcription [Mapp et al., Proc. Natl. Acad. Sci. USA 97 (2000) 3930-3935]. The question arises as to the general nature and the versatility of this minimal activator motif and whether smaller ligands can be designed which maintain potent activation function. RESULTS: Here we have replaced the 20 amino acid AH peptide with eight or 16 residues derived from the activation domain of the potent viral activator VP16. The 16 residue activation module coupled to the polyamide activated transcription over two-fold better than the analogous AH conjugate. Altering the site of attachment of the activation module on the polyamide allowed reduction of the intervening linker from 36 atoms to eight without significant diminution of the activation potential. In this study we also exchanged the polyamide to target a different sequence without compromising the activation function further demonstrating the generality of this design. CONCLUSIONS: The polyamide activator conjugates described here represent a class of DNA binding ligands which are tethered to a second functional moiety, viz. an activation domain, that recruits elements of the endogenous transcriptional machinery. Our results define the minimal structural elements required to construct artificial, small molecule activators. If such activators are cell-permeable and can be targeted to designated sites in the genome, this series of conjugates may then serve as a tool to study mechanistic aspects of transcriptional regulation and eventually to modulate gene expression relevant to human diseases.

Fmoc solid phase synthesis of polyamides containing pyrrole and imidazole amino acids.

[structure: see text]. Polyamides containing N-methylimidazole (Im) and N-methylpyrrole (Py) amino acids are synthetic ligands that have an affinity and specificity for DNA comparable to those of many naturally occurring DNA binding proteins. A machine-assisted Fmoc solid phase synthesis of polyamides has been optimized to afford high stepwise coupling yields (>99%). Two monomer building blocks, Fmoc-Py acid and Fmoc-Im acid, were prepared in multigram scale. Cleavage by aminolysis followed by HPLC purification affords up to 200 mg quantities of polyamide with purities and yields greater than or equal to those reported using Boc chemistry. A broader set of reaction conditions will increase the number and complexity of minor groove binding polyamides which may be prepared and help ensure compatibility with many commercially available peptide synthesizers.

Expanding the recognition of the minor groove of DNA by incorporation of beta-alanine in hairpin polyamides.

In order to expand the recognition code by hairpin polyamides to include DNA sequences of the type 5'-CWWC-3' two polyamides, PyPyPyPy-(R)(H2N)gamma-ImPyPyIm-beta-Dp (1) and PyPyPyPy-(R)(H2N)gamma-ImPy-beta-Im-beta-Dp (2) were synthesized which have in common an Py/Im pair in the terminal position for targeting C x G but differ with respect to internal placement of a beta-alanine residue. The equilibrium association constants (Ka) were determined at four DNA sites which differ at a single common position, 5'-TNTACA-3' (N = T, A, G, C). Quantitative DNase I footprint titration experiments reveal that the eight-ring hairpin PyPyPyPy-(R)(H2N)gamma-ImPyPyIm-beta-Dp (1) binds the four binding sites with similar affinities, Ka = 1.3-1.9 x 10(10) M(-1) indicating that there is no preference for the position N. In contrast, a redesigned polyamide PyPyPyPy-(R)(H2N)gamma-ImPy-beta-Im-beta-Dp (2) that places an internal flexible aliphatic beta-alanine to the 5'-side of a key imidazole group bound the match site 5'-TCTACA-3' with high affinity and good sequence discrimination (Ka(match) = 4.9 x 10(10) M(-1) and the single base pair mismatch sites with 5- to 25-fold lower affinity). These results expand the repertoire of sequences targetable by hairpins and emphasize the importance of beta-alanine as a key element for minor groove recognition.

Toward rules for 1:1 polyamide:DNA recognition.

Polyamides composed of four amino acids, imidazole (Im), pyrrole (Py), hydroxypyrrole (Hp), and beta-alanine (beta), are synthetic ligands that form highly stable complexes in the minor groove of DNA. Although specific pairing rules within the 2:1 motif can be used to distinguish the four Watson. Crick base pairs, a comparable recognition code for 1:1 polyamide:DNA complexes had not been described. To set a quantitative baseline for the field, the sequence specificities of Im, Py, Hp, and beta for the four Watson. Crick base pairs were determined for two polyamides, Im-beta-ImPy-beta-Im-beta-ImPy-beta-Dp (1, for Im, Py, and beta) and Im-beta-ImHp-beta-Im-beta-ImPy-beta-Dp (2, for Hp), in a 1:1 complex within the DNA sequence context 5'-AAAGAGAAGAG-3'. Im residues do not distinguish G,C from A,T but bind all four base pairs with high affinity. Py and beta residues exhibit > or = 10-fold preference for A,T over G,C base pairs. The Hp residue displays a unique preference for a single A.T base pair with an energetic penalty.

Alternative heterocycles for DNA recognition: an N-methylpyrazole/N-methylpyrrole pair specifies for A.T/T.A base pairs.

Side-by-side pairs of three five-membered rings, N-methylpyrrole (Py), N-methylimidazole (Im), and N-methylhydroxy-pyrrole (Hp), have been demonstrated to distinguish each of the four Watson Crick base pairs in the minor groove of DNA. However, not all DNA sequences targeted by these pairing rules achieve affinities and specificities comparable to DNA binding proteins. We have initiated a search for new heterocycles which can expand the sequence repetoire currently available. Two heterocyclic aromatic amino acids. N-methylpyrazole (Pz) and 4-methylthiazole (Th), were incorporated into a single position of an eight-ring polyamide of sequence ImImXPy-gamma-lmPyPyPy-beta-Dp to examine the modulation of affinity and specificity for DNA binding by a Pz/Py pair and or a Th/Py pair. The X/Py pairings Pz/Py and Th/Py were evaluated by quantitative DNase I footprint titrations on a DNA fragment with the four sites 5'-TGGNCA-3' (N=T, A, G, C). The Pz/Py pair binds T.A and A.T with similar affinity to a Py/Py pair but with improved specificity. disfavoring both G.C and C.G by about 100-fold. The Th/Py pair binds poorly to all four Watson Crick base pairs. These results demonstrate that in some instances new heterocyclic aromatic amino acid pairs can be incorporated into imidazole-pyrrole polyamides to mimic the DNA specificity of Py/Py pairs which may be relevant as biological criteria in animal studies become important.