Naoshi Kojima

Construction of Highly Reactive Probes for Abasic Site Detection by Introduction of an Aromatic and a Guanidine Residue into an Aminooxy Group

Abasic sites (AP sites) arise from hydrolysis of glycosidic bonds of DNA that is damaged by various external and internal processes; unrepaired AP sites give rise to genetic mutations. We have constructed highly reactive AP-site-detecting probes by introducing a hydrophobic and a hydrophilic residue in an aminooxy group. Synthesized probes containing either a naphthalene or a guanidine residue conjugate effectively with AP sites. In particular, a probe containing both functional groups shows the highest reaction rate, indicating that the hydrophobic and hydrophilic interactions act cooperatively in reaction with AP sites. The guanidine residue also contributes to the solubility of the molecules in aqueous media. The biotinylated probes provide much more sensitive detection of AP sites in genomic DNA than the conventional aldehyde-reactive probe.

Synthesis of ribonucleic guanidine: replacement of the negative phosphodiester linkages of RNA with positive guanidinium linkages

Replacement of the negatively charged phosphodiester linkages of RNA with positively charged guanidinium linkages provides the polycationic ribonucleic guanidine (RNG). RNG is designed to bind strongly to target DNA/RNA through the specific interactions of nucleobases and the attractive electrostatic interactions of backbones, thus RNG is a putative antisense/antigene agent. Preparation of uridine and adenine building blocks for the RNG synthesis, as well as the stepwise synthesis of oligomeric RNG are reported. Pentameric homo uridyl, adenyl, and a pentameric mixed base sequence have been synthesized. The methods were also applied to a convenient solid-phase synthesis of RNG.

Interstrand cross-link of DNA by covalently linking a pair of abasic sites

A pair of apurinic/apyrimidinic sites formed in DNA has been covalently connected with bis(aminooxy) derivatives. The efficacy of the interstrand cross-link is associated with the structural tethering of two aminooxy groups. The interstrand cross-link constructed stable DNA scaffolds for enzyme alignment.

Electrochemical properties of interstrand cross-linked DNA duplexes labeled with Nile blue.

DNA molecules have attracted considerable attention as functional materials in various fields such as electrochemical sensors with redox-labeled DNA. However, the recently developed interstrand cross-link (ICL) technique for double-stranded DNA can adequately modify the electronic properties inside the duplex. Hence, the electrochemical investigation of ICL-DNA helps us to understand the electron transfer of redox-labeled DNA at an electrode surface, which would develop useful sensors. In this study, the first insight into this matter is presented. We prepared 17-mer DNA duplexes incorporating Nile blue (NB-DNA) at one end as a redox marker and a disulfide tether at the other end for immobilization onto an electrode. The duplexes were covalently cross-linked by bifunctional cross-linkers that utilize either a propyl or naphthalene residue to replace a base pair. Their electrochemical responses at the electrode surface were compared to evaluate the effect of the ICL on the electron-transfer reactions of the redox-labeled DNA duplexes. A direct transfer of electrons between NB and the electrode was observed for a standard DNA, as previously reported, whereas interstrand cross-linked DNA (CL-DNA) strands showed a decrease in the direct electron-transfer pathway. This is expected to result from constraining the elastic bending/flexibility of the duplex caused by the covalent cross-links. Interestingly, the CL-DNA incorporating naphthalene residues exhibited additional voltammetric peaks derived from DNA-mediated electron transfer (through base π stacking), which was not observed in the mismatched CL-DNA. The present results indicate that the ICL significantly affects electron transfer in the redox-labeled DNA at the electrode and can be an important determinant for electrochemical signaling in addition to its role in stabilizing the duplex structure.

Synthesis and Application of Highly Reactive Amino Linkers for Functional Oligonucleotides

Oligonucleotides are functionalized by conjugation with a variety of molecules, and aliphatic amino linkers have been frequently used as a tether for their modifications. This unit describes the syntheses and applications of novel amino linkers having a carbamate structure. Two major chemical properties of the primary amine are induced by the neighboring effect of the carbamate group, which are found to be optimum in an aminoethyl carbamate structure. First, the hydrophobic monomethoxytrityl group can be rapidly removed from the aminoethyl carbamate under very mild acidic conditions, while the deprotection is not completed in standard aliphatic amines even under high acid concentration. This significant feature enables the convenient purification of amino‐modified oligonucleotides by using the hydrophobic interaction of the monomethoxytrityl group with a reverse‐phase resin. Second, the introduction of the carbamate linkage reduces the pKa value of the neighboring primary amine, resulting in an increase in the conjugation yields with various functional molecules, such as those having active esters. The novel amino linkers that have an aminoethyl carbamate linkage indicate potent activity and are applicable for the preparation of various functional oligonucleotides. Curr. Protoc. Nucleic Acid Chem. 48:4.48.1‐4.48.23.

Development of novel chemical probes to detect abasic sites in DNA.

We chemically synthesized a series of aminooxy derivatives to develop novel probes for sensitive detection of abasic (AP) sites in DNA. The results of the conjugation reactions showed that the probes could efficiently react to AP sites by introducing an aromatic or a guanidino group in their structures. In particular, the probe having both functional groups showed the most effective reactivity, indicating that hydrophobic and electrostatic interactions cooperatively acted in the reaction of the probe to AP sites. We then synthesized a biotinylated probe and succeeded in more sensitive detection of AP sites in genomic DNA than with the conventional aldehyde reactive probe (ARP).

Synthesis and Application of Interstrand Cross‐Linked Duplexes by Covalently Linking a Pair of Abasic Sites

Interstrand cross‐linking of DNA or RNA inhibits the double strands from dissociating into single strands. This article contains detailed procedures for the synthesis of a novel interstrand cross‐linker that comprises a bis‐aminooxy naphthalene derivative and a description of its use in the preparation of sequence‐specific interstrand cross‐linked oligonucleotide duplexes. The interstrand cross‐linker covalently connects a pair of apurinic/apyrimidinic sites in DNA/RNA duplexes with bis(aminooxy) groups. The resulting oxime linkages are stable under physiological conditions and greatly improve the thermal stability of the duplex. In addition, we construct a novel anti‐miRNA oligonucleotide (AMO) flanked by interstrand cross‐linked 2′‐O‐methylated RNA duplexes (CLs). AMO flanked by CLs at the 5′‐ and 3′‐termini exhibited high inhibition activity toward miRNA function in cells. The novel interstrand cross‐linker indicates potent activity and is applicable in biophysical studies, oligonucleotide therapeutics, and materials science.

Immobilization of DNA with nitrogen mustard–biotin conjugate for global epigenetic analysis

We report the quantitative analysis of 5-methylcytosine, a representative epigenetic modification in genomic DNA, with an enzyme-linked immunosorbent assay (ELISA). We synthesized a novel hetero-bifunctional linker molecule consisting of nitrogen mustard and biotin to capture DNA on the surface of biosensing devices. The molecule can successfully immobilize genomic DNA on a streptavidin coated 96-well microplate, which was then employed for immunochemical epigenetic assessment. We achieved the sensitive and quantitative detection of 5-mC in genomic DNA samples. The CpG methylation ratios obtained from our system for mouse brain and mouse small intestine genomes were 79% and 82%, respectively. These numbers are in good agreement with the previously reported methylation ratio of 75-85%, which was identified by whole genome bisulfite sequencing. Accordingly, the present technology using our novel bifunctional linker molecule provides a fast, easy, and inexpensive method for epigenetic assessment, without the need for any conventional bisulfite treatment, polymerase chain reaction (PCR), or sequencing.

Comparison of the chemical properties of a novel amino-linker with various amino modifications.

We previously reported a series of new amino-linkers, consisting of an aminoethyl carbamate structure (Komatsu, 2008). We have now examined the chemical properties of oligonucleotides modified with an ssH-linker, which is the simplest and most cost-effective derivative of the series. Although it was previously shown that monomethoxytrityl protection on a primary amine of the ssH-linker was cleaved under weakly acidic conditions (1% acetic acid), we found that the deprotection also proceeded in aqueous buffer solutions (pH 6.0, 7.0). The MMT group was removed much faster than other commercially available amino-linkers, and this property enabled the ssH-modified oligonucleotides to be conveniently purified with a cartridge column. Furthermore, the ssH-modified oligonucleotides were utilized in on-support labeling reactions. As compared with other amino-linkers, the ssH-linker was superior in terms of its purification and reaction efficiencies.