Kaori Hashiya

Synthesis and Biological Properties of Highly Sequence-Specific-Alkylating N-Methylpyrrole–N-Methylimidazole Polyamide Conjugates

Four new alkylating N-methylpyrrole-N-methylimidazole (PI) polyamide conjugates (1-4) with seven-base-pair (bp) recognition ability were synthesized. Evaluation of their DNA-alkylating activity clearly showed accurate alkylation at match site(s). The cytotoxicities of conjugates 1-4 were determined against six human cancer cell lines, and the effect of these conjugates on the expression levels of the whole human genome in A549 cells were also investigated. A few genes among the top 20 genes were commonly downregulated by each conjugate, which reflects their sequence specificity. Conversely, many of the top 10 genes were commonly upregulated, which may have been caused by alkylation damage to DNA. Moreover, the antitumor activities of the PI polyamide conjugates 2 and 3 were investigated using nude mice transplanted with DU145 or A549. The intravenous administration of each liposomal conjugate in water yielded tumor-suppressing effects specifically toward DU145 cells and not A549 cells, which was pertinent to cytotoxicity.

Development of programmable small DNA-binding molecules with epigenetic activity for induction of core pluripotency genes.

Epigenetic modifications that govern the gene expression are often overlooked with the design of artificial genetic switches. N-Methylpyrrole-N-methylimidazole (PI) hairpin polyamides are programmable small DNA binding molecules that have been studied in the context of gene regulation. Recently, we synthesized a library of compounds by conjugating PI polyamides with SAHA, a chromatin-modifier. Among these novel compounds, PI polyamide-SAHA conjugate 1 was shown to epigenetically activate pluripotency genes in mouse embryonic fibroblasts. Here, we report the synthesis of the derivatives of conjugate 1 and demonstrate that these epigenetically active molecules could be developed to improve the induction of pluripotency factors.

Synthesis and biological evaluation of a targeted DNA-binding transcriptional activator with HDAC8 inhibitory activity

Development of multifunctional transcriptional activators is of increasing importance as they could trigger complicated gene networks. Recently, we developed a differential gene activating multifunctional small molecule SAHA-PIP (Sδ) by conjugating a histone deacetylase (HDAC) inhibitor, SAHA, to a selective DNA-binding pyrrole-imidazole polyamide (PIP). Epigenetic activity of Sδ was attributed to the active metal-binding (-NHOH) domain of SAHA. We synthesized a derivative of Sδ, called Jδ to evaluate the role of surface recognition domain (-phenyl) of SAHA in Sδ-mediated transcriptional activation. In vitro studies revealed that Jδ displayed potent inhibitory activity against HDAC8. Jδ retained the pluripotency gene-inducing ability of Sδ when used alone and in combination with Sδ; a notable increase in the pluripotency gene expression was observed. Interestingly, Jδ significantly induced the expression of HDAC8-controlled Otx2 and Lhx1. Our results suggest that the epigenetic activity of our multifunctional molecule could be altered to improve its efficiency as a transcriptional activator for intricate gene network(s).

Cysteine cyclic pyrrole-imidazole polyamide for sequence-specific recognition in the DNA minor groove.

Pyrrole-imidazole (PI) polyamides are small DNA-binding molecules that can recognize predetermined DNA sequences with high affinity and specificity. Hairpin PI polyamides have been studied intensively; however, cyclic PI polyamides have received less attention, mainly because of difficulties with their synthesis. Here, we describe a novel cyclization method for producing PI polyamides using cysteine and a chloroacetyl residue. The cyclization reaction is complete within 1 h and has a high conversion efficiency. The method can be used to produce long cyclic PI polyamides that can recognize 7 bp DNA sequences. A cyclic PI polyamide containing two β-alanine molecules had higher affinity and specificity than the corresponding hairpin PI polyamide, demonstrating that the cyclic PI polyamides can be used as a new type of DNA-binding molecule.

Next Generation Sequencing Studies Guide the Design of Pyrrole-Imidazole Polyamides with Improved Binding Specificity by the Addition of β-Alanine

The identification of binding sites for small molecules in genomic DNA is important in various applications. Previously, we demonstrated rapid transcriptional activation by our small molecule SAHA‐PIP. However, it was not clear whether the strong biological effects exerted by SAHA‐PIP were attributable to its binding specificity. Here, we used high‐throughput sequencing (Bind‐n‐seq) to determine the binding specificity of SAHA‐PIPs. Sequence specificity bias was determined for SAHA‐PIPs (3 and 4), and this showed enhanced 6 bp sequence‐specific binding compared with hairpin PIPs (1 and 2). This finding allowed us to investigate the role of the β‐alanine that links SAHA to PIP, and led in turn to the design of ββ‐PIPs (5 and 6), which showed enhanced binding specificity. Overall, we demonstrated the importance of β‐moieties for the binding specificity of PIPs and the use of cost‐effective high‐throughput screening of these small molecules for binding to the DNA minor groove.

Sequence-specific electron injection into DNA from an intermolecular electron donor

Electron transfer in DNA has been intensively studied to elucidate its biological roles and for applications in bottom-up DNA nanotechnology. Recently, mechanisms of electron transfer to DNA have been investigated; however, most of the systems designed are intramolecular. Here, we synthesized pyrene-conjugated pyrrole-imidazole polyamides (PPIs) to achieve sequence-specific electron injection into DNA in an intermolecular fashion. Electron injection from PPIs into DNA was detected using 5-bromouracil as an electron acceptor. Twelve different 5-bromouracil-containing oligomers were synthesized to examine the electron-injection ability of PPI. Product analysis demonstrated that the electron transfer from PPIs was localized in a range of 8 bp from the binding site of the PPIs. These results demonstrate that PPIs can be a useful tool for sequence-specific electron injection.

Sequence-specific DNA alkylation and transcriptional inhibition by long-chain hairpin pyrrole–imidazole polyamide–chlorambucil conjugates targeting CAG/CTG trinucleotide repeats

Introducing novel building blocks to solid-phase peptide synthesis, we readily synthesized long-chain hairpin pyrrole-imidazole (PI) polyamide-chlorambucil conjugates 3 and 4 via the introduction of an amino group into a GABA (γ-turn) contained in 3, to target CAG/CTG repeat sequences, which are associated with various hereditary disorders. A high-resolution denaturing polyacrylamide sequencing gel revealed sequence-specific alkylation both strands at the N3 of adenines or guanines in CAG/CTG repeats by conjugates 3 and 4, with 11bp recognition. In vitro transcription assays using conjugate 4 revealed that specific alkylation inhibited the progression of RNA polymerase at the alkylating sites. Chiral substitution of the γ-turn with an amino group resulted in higher binding affinity observed in SPR assays. These assays suggest that conjugates 4 with 11bp recognition has the potential to cause specific DNA damage and transcriptional inhibition at the alkylating sites.

Sequence‐Specific DNA Recognition by Cyclic Pyrrole–Imidazole Cysteine‐Derived Polyamide Dimers

Pyrrole-imidazole (PI) polyamides bind to the minor groove of the DNA duplex in a sequence-specific manner and thus have the potential to regulate gene expression. To date, various types of PI polyamides have been designed as sequence-specific DNA binding ligands. One of these, cysteine cyclic PI polyamides containing two β-alanine molecules, were designed to recognize a 7 bp DNA sequence with high binding affinity. In this study, an efficient cyclization reaction between a cysteine and a chloroacetyl residue was used for dimerization in the synthesis of a unit that recognizes symmetrical DNA sequences. To evaluate specific DNA binding properties, dimeric PI polyamide binding was measured by using a surface plasmon resonance (SPR) method. Extending this molecular design, we synthesized a large dimeric PI polyamide that can recognize a 14 bp region in duplex DNA.

Sequence-Specific DNA Alkylation by Tandem Py–Im Polyamide Conjugates

Tandem N-methylpyrrole-N-methylimidazole (Py-Im) polyamides with good sequence-specific DNA-alkylating activities have been designed and synthesized. Three alkylating tandem Py-Im polyamides with different linkers, which each contained the same moiety for the recognition of a 10 bp DNA sequence, were evaluated for their reactivity and selectivity by DNA alkylation, using high-resolution denaturing gel electrophoresis. All three conjugates displayed high reactivities for the target sequence. In particular, polyamide 1, which contained a β-alanine linker, displayed the most-selective sequence-specific alkylation towards the target 10 bp DNA sequence. The tandem Py-Im polyamide conjugates displayed greater sequence-specific DNA alkylation than conventional hairpin Py-Im polyamide conjugates (4 and 5). For further research, the design of tandem Py-Im polyamide conjugates could play an important role in targeting specific gene sequences.

Construction and characterization of Cy3- or Cy5-conjugated hairpin pyrrole–imidazole polyamides binding to DNA in the nucleosome

Sequence-specific DNA-binding modules, N-methylpyrrole (Py)-N-methylimidazole-(Im) polyamides have been recently conjugated with fluorophores, and some of these conjugates could be used for the detection of specific DNA sequences. In this study, we synthesized two Py-Im polyamides 1 and 2, which interact with the 145-bp nucleosome positioning sequence 601. We conjugated the cyanine dye Cy3 or Cy5 with 1 or 2. In the absence of target DNA, the fluorescent conjugate of a Py-Im polyamide had lower fluorescence intensity compared with Cy3 or Cy5 alone. In the presence of either the target DNA or the nucleosome, the fluorescence intensity of the conjugates increased. Furthermore, we observed a Förster resonance energy transfer between the Cy3-Py-Im polyamide and the Cy5-Py-Im polyamide on the nucleosome. These results open up the possibilities that fluorescent conjugates of Py-Im polyamides can be used for characterization of the dynamic interactions within protein-DNA complexes.