Minor Groove Binding Polyamides Research Articles

DNA-Binding Properties of New Fluorescent AzaHx Amides: Methoxypyridylazabenzimidazolepyrroleimidazole/pyrrole.

DNA minor groove binding polyamides have been extensively developed to control abnormal gene expression. The establishment of novel, inherently fluorescent 2-(p-anisyl)benzimidazole (Hx) amides has provided an alternative path for studying DNA binding in cells by direct observation of cell localization. Because of the 2:1 antiparallel stacking homodimer binding mode of these molecules to DNA, modification of Hx amides to 2-(p-anisyl)-4-azabenzimidazole (AzaHx) amides has successfully extended the DNA-recognition repertoire from central CG [recognized by Hx-I (I=N-methylimidazole)] to central GC [recognized by AzaHx-P (P=N-methylpyrrole)] recognition. For potential targeting of two consecutive GG bases, modification of the AzaHx moiety to 2- and 3-pyridyl-aza-benzimidazole (Pyr-AzaHx) moieties was explored. The newly designed molecules are also small-sized, fluorescent amides with the Pyr-AzaHx moiety connected to two conventional five-membered heterocycles. Complementary biophysical methods were performed to investigate the DNA-binding properties of these molecules. The results showed that neither 3-Pyr-AzaHx nor 2-Pyr-AzaHx was able to mimic I-I=N-methylimidazole-N-methylimidazole to target GG dinucleotides specifically. Rather, 3-Pyr-AzaHx was found to function like AzaHx, f-I (f=formamide), or P-I as an antiparallel stacked dimer. 3-Pyr-AzaHx-PI (2) binds 5'-ACGCGT'-3' with improved binding affinity and high sequence specificity in comparison to its parent molecule AzaHx-PI (1). However, 2-Pyr-AzaHx is detrimental to DNA binding because of an unfavorable steric clash upon stacking in the minor groove.

Merging Two Strategies for Mixed-Sequence Recognition of Double-Stranded DNA: Pseudocomplementary Invader Probes.

The development of molecular strategies that enable recognition of specific double-stranded DNA (dsDNA) regions has been a longstanding goal as evidenced by the emergence of triplex-forming oligonucleotides, peptide nucleic acids (PNAs), minor groove binding polyamides, and—more recently—engineered proteins such as CRISPR/Cas9. Despite this progress, an unmet need remains for simple hybridization-based probes that recognize specific mixed-sequence dsDNA regions under physiological conditions. Herein, we introduce pseudocomplementary Invader probes as a step in this direction. These double-stranded probes are chimeras between pseudocomplementary DNA (pcDNA) and Invader probes, which are activated for mixed-sequence dsDNA-recognition through the introduction of pseudocomplementary base pairs comprised of 2-thiothymine and 2,6-diaminopurine, and +1 interstrand zipper arrangements of intercalator-functionalized nucleotides, respectively. We demonstrate that certain pseudocomplementary Invader probe designs result in very efficient and specific recognition of model dsDNA targets in buffers of high ionic strength. These chimeric probes, therefore, present themselves as a promising strategy for mixed-sequence recognition of dsDNA targets for applications in molecular biology and nucleic acid diagnostics.

Normal Tissue Tolerance of Microplanar Beam X-ray: A Long-term Observation

and 6 Gy. Twenty-four hours after irradiation, cells were re-plated and surviving fractions measured by clonogenic assay. Results: Polyamide treatment alone did not decrease surviving fraction in the absence of irradiation. The radiosensitization by polyamide treatment increased with radiation dose. Surviving fractions at 2 Gy were 0.660.07 and 0.550.05 (SER 1.2); at 4 Gy were 0.410.02 and 0.220.02 (SER 1.9); at 6 Gy were 0.220.07 and 0.110.01 (SER 2.0) for vehicle and polyamidetreated cells, respectively. Calculated D0 values were 4.16 Gy (vehicle) and 2.79 Gy (polyamide). SER: sensitization enhancement ratio. Errors are standard deviations (n Z 3). Conclusions: The polyamide demonstrated radiosensitization of UM-SCC12 cells in vitro. These results justify continued investigations into the therapeutic combination of irradiation and minor groove binding polyamides. Author Disclosure: N. Nickols: None. F. Yang: None. J.A. Ratikan: None. B.C. Li: None. W.H. McBride: None. P.B. Dervan: None.

Targeted chemical wedges reveal the role of allosteric DNA modulation in protein-DNA assembly.

The cooperative assembly of multiprotein complexes results from allosteric modulations of DNA structure as well as direct intermolecular contacts between proteins. Such cooperative binding plays a critical role in imparting exquisite sequence specificity on the homeobox transcription factor (Hox) family of developmental transcription factors. A well-characterized example includes the interaction of Hox proteins with extradenticle (Exd), a highly conserved DNA binding transcription factor. Although direct interactions are important, the contribution of indirect interactions toward cooperative assembly of Hox and Exd remains unresolved. Here we use minor groove binding polyamides as structural wedges to induce perturbations at specific base steps within the Exd binding site. We find that allosteric modulation of DNA structure contributes nearly 1.5 kcal/mol to the binding of Exd to DNA, even in the absence of direct Hox contacts. In contrast to previous studies, the sequence-targeted chemical wedges reveal the role of DNA geometry in cooperative assembly of Hox-Exd complexes. Programmable polyamides may well serve as general probes to investigate the role of DNA modulation in the cooperative and highly specific assembly of other protein-DNA complexes.

Inhibition of DNA Binding by Human Estrogen-Related Receptor 2 and Estrogen Receptor α with Minor Groove Binding Polyamides

Human estrogen-related receptor 2 (hERR2, ESRRB, ERRbeta, NR3B2) belongs to a class of nuclear receptors that bind DNA through sequence-specific interactions with a 5'-AGGTCA-3' estrogen response element (ERE) half-site in the major groove and an upstream 5'-TNA-3' site in the minor groove. This minor groove interaction is mediated by a C-terminal extension (CTE) of the DNA binding domain and is unique to the estrogen-related receptors. We have used synthetic pyrrole-imidazole polyamides, which bind specific sequences in the minor groove, to demonstrate that DNA binding by hERR2 is sensitive to the presence of polyamides in both the upstream minor groove CTE site and the minor groove of the ERE half-site. Thus, polyamides can inhibit hERR2 by two mechanisms, by direct steric blockage of minor groove DNA contacts mediated by the CTE and by changing the helical geometry of DNA such that major groove interactions are weakened. To confirm the generality of the latter approach, we show that the dimeric human estrogen receptor alpha (hERalpha, ESR1, NR3A1), which binds in the major groove of the ERE, can be inhibited by a polyamide bound in the opposing minor groove of the ERE. These results highlight two mechanisms for inhibition of protein-DNA interactions and extend the repertoire of DNA recognition motifs that can be inhibited by polyamides. These molecules may thus be useful for controlling expression of hERR2- or hERalpha-responsive genes.

Inhibition of feline immunodeficiency virus (FIV) replication by DNA binding polyamides

Two DNA minor-groove binding polyamides 1 and 2 were designed and synthesized and evaluated for inhibition of FIV-34TF10 replication. Both 1 and 2 decreased the replication of FIV-34TF10 by 75% by acting at the level of the virus but outside of the LTR or env region.

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.

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.

ピロール‐イミダゾールポリアミドによるＤＮＡ塩基配列認識の進歩 ポスト・ゲノム時代の創薬

By the completion of the human genome project, many diseases including cancer, hereditary and viral diseases can be understood by the DNA sequence level. Control of the specific gene expression will provide ultimate gene therapy. Minor groove binding polyamides containing N-methylpyrrole and N-methylimidazole amino acids exhibit promising performance based on the recognition of nucleic acid sequences. Various types of sequence-specific DNA binding agents are developed and used for the regulation of gene expression. We synthesized novel type of polyamide-alkylator conjugates. These synthetic compounds alkylated predetermined DNA sequences selectively, and also some of them possessed selective potency for certain cancer cell lines. In this review, we will focus on recent progress of minor groove binding polyamides that play important roles in the rational recognition of nucleic acid sequences. One of the future directions of rational design of molecular medicine in the post genome era is proposed.

Inhibition of Ets-1 DNA Binding and Ternary Complex Formation between Ets-1, NF-κB, and DNA by a Designed DNA-binding Ligand

Sequence-specific pyrrole-imidazole polyamides can be designed to interfere with transcription factor binding and to regulate gene expression, both in vitro and in living cells. Polyamides bound adjacent to the recognition sites for TBP, Ets-1, and LEF-1 in the human immunodeficiency virus, type 1 (HIV-1), long terminal repeat inhibited transcription in cell-free assays and viral replication in human peripheral blood lymphocytes. The DNA binding activity of the transcription factor Ets-1 is specifically inhibited by a polyamide bound in the minor groove. Ets-1 is a member of the winged-helix-turn-helix family of transcription factors and binds DNA through a recognition helix bound in the major groove with additional phosphate contacts on either side of this major groove interaction. The inhibitory polyamide possibly interferes with phosphate contacts made by Ets-1, by occupying the adjacent minor groove. Full-length Ets-1 binds the HIV-1 enhancer through cooperative interactions with the p50 subunit of NF-kappaB, and the Ets-inhibitory polyamide also blocks formation of ternary Ets-1. NF-kappaB.DNA complexes on the HIV-1 enhancer. A polyamide bound adjacent to the recognition site for NF-kappaB also inhibits NF-kappaB binding and ternary complex formation. These results broaden the application range of minor groove-binding polyamides and demonstrate that these DNA ligands are powerful inhibitors of DNA-binding proteins that predominantly use major groove contacts and of cooperative protein-DNA ternary complexes.

Recognition of the four Watson-Crick base pairs in the DNA minor groove by synthetic ligands.

The design of synthetic ligands that read the information stored in the DNA double helix has been a long-standing goal at the interface of chemistry and biology. Cell-permeable small molecules that target predetermined DNA sequences offer a potential approach for the regulation of gene expression. Oligodeoxynucleotides that recognize the major groove of double-helical DNA via triple-helix formation bind to a broad range of sequences with high affinity and specificity. Although oligonucleotides and their analogues have been shown to interfere with gene expression, the triple-helix approach is limited to recognition of purines and suffers from poor cellular uptake. The subsequent development of pairing rules for minor-groove binding polyamides containing pyrrole (Py) and imidazole (Im) amino acids offers a second code to control sequence specificity. An Im/Py pair distinguishes G x C from C x G and both of these from A x T/T x A base pairs. A Py/Py pair specifies A,T from G,C but does not distinguish AT from T x A. To break this degeneracy, we have added a new aromatic amino acid, 3-hydroxypyrrole (Hp), to the repertoire to test for pairings that discriminate A x T from T x A. We find that replacement of a single hydrogen atom with a hydroxy group in a Hp/Py pairing regulates affinity and specificity by an order of magnitude. By incorporation of this third amino acid, hydroxypyrrole-imidazole-pyrrole polyamides form four ring-pairings (Im/Py, Py/Im, Hp/Py and Py/Hp) which distinguish all four Watson-Crick base pairs in the minor groove of DNA.

Targeting the minor groove of DNA

Small molecules that specifically bind with high affinity to any predetermined DNA sequence in the human genome will be useful tools in molecular biology and, potentially, in human medicine. Pairing rules have been developed to control rationally the sequence specifity of minor groove binding polyamides containing N-methylimidazole and N-methylpyrrole amino acids. Using simple molecular shapes and a two-letter aromatic amino acid code, pyrrole-imidazole polyamides achieve affinities and specificities comparable to DNA-binding proteins.

Design of Sequence‐Specific DNA‐Binding Ligands

AbstractDouble‐stranded DNA can be viewed as a multifunctional, modular receptor that can be read sequence‐selectively in a digital way (base pair per base pair) by a complementary, similarly modular ligand. This principle has been exploited in several approaches to design sequence‐specific DNA‐binding ligands, such as triplex‐forming oligonucleotides, peptide nucleic acids and minor groove binding polyamides.

Effects of the A.T/T.A degeneracy of pyrrole--imidazole polyamide recognition in the minor groove of DNA.

Pairing rules have been developed to predict the sequence specificity of minor groove binding polyamides containing pyrrole (Py) and imidazole (Im) amino acids. An Im/Py pair distinguishes G.C from C.G and both of these from A.T/T.A base pairs. A Py/Py pair appears not to distinguish A.T from T.A base pairs. To test the extent of this degeneracy, the affinity and binding orientation of the hairpin polyamide ImPyPy-gamma-PyPyPy-beta-Dp were measured for eight possible five base pair 5'-TG(A,T)(3)-3' match sites. Affinity cleavage experiments using a polyamide with an EDTA.Fe(II) moiety at the carboxy terminus, ImPyPy-gamma-PyPyPy-beta-Dp-EDTA.Fe(II), are consistent with formation of an oriented 1:1 hairpin polyamide complex at all eight 5'-TG(A,T)(3)-3' binding sites [20 mM HEPES, 200 mM NaCl, 50 mg/ml glycogen, pH 7.0, 22 degrees C, 5 mM DTT, 1 mM Fe(II)]. Quantitative DNase I footprint titration experiments reveal that ImPyPy-gamma-PyPyPy-beta-Dp binds all eight 5'-TG(A,T)(3)-3' target sites with only a 12-fold difference in the equilibrium association constants between the strongest site, 5'-TGTTT-3' (Ka = 2.1 x 10(8) M-1), and the weakest site, 5'-TGAAT-3' (Ka = 1.8 x 10(7) M-1) (10 mM Tris.HCl, 10 mM KCl, 10 mM MgCl2, 5 mM CaCl2, pH 7.0, 22 degrees C). This relatively small range indicates that the Py/Py pair is approximately degenerate for recognition of A,T base pairs, affording generality with regard to targeting sequences of mixed A.T/T.A composition.

Solid Phase Synthesis of Polyamides Containing Imidazole and Pyrrole Amino Acids

The solid phase synthesis of sequence specific DNA binding polyamides containing N-methylimidazole (Im) and N-methylpyrrole (Py) amino acids is described. Two monomer building blocks, Boc-Py-OBt ester and Boc-Im acid, are prepared on a 50 g scale without column chromatography. Using commercially available Boc-β-alanine-Pam resin, cycling protocols were optimized to afford high stepwise coupling yields (>99%). Deprotection by aminolysis affords up to 100 mg quantities of polyamide. Solid phase methodology increases both the number and complexity of minor groove binding polyamides which can be synthesized and analyzed with regard to DNA binding affinity and sequence specificity. The solid phase synthesis of a representative eight-residue polyamide is reported.

Cyclic polyamides for recognition in the minor groove of DNA.

Small molecules that specifically bind with high affinity to any designated DNA sequence in the human genome would be useful tools in molecular biology and potentially in human medicine. Simple rules have been developed to rationally alter the sequence specificity of minor groove-binding polyamides containing N-methylimidazole and N-methylpyrrole amino acids. Crescent-shaped polyamides bind as antiparallel dimers with each polyamide making specific contacts with each strand on the floor of the minor groove. Cyclic polyamides have now been synthesized that bind designated DNA sequences at subnanomolar concentrations.