Jiro Kondo scite author profile

The double-helix structure of DNA, in which complementary strands reversibly hybridize to each other, not only explains how genetic information is stored and replicated, but also has proved very attractive for the development of nanomaterials. The discovery of metal-mediated base pairs has prompted the generation of short metal-DNA hybrid duplexes by a bottom-up approach. Here we describe a metallo-DNA nanowire-whose structure was solved by high-resolution X-ray crystallography-that consists of dodecamer duplexes held together by four different metal-mediated base pairs (the previously observed C-Ag-C, as well as G-Ag-G, G-Ag-C and T-Ag-T) and linked to each other through G overhangs involved in interduplex G-Ag-G. The resulting hybrid nanowires are 2 nm wide with a length of the order of micrometres to millimetres, and hold the silver ions in uninterrupted one-dimensional arrays along the DNA helical axis. The hybrid nanowires are further assembled into three-dimensional lattices by interactions between adenine residues, fully bulged out of the double helix.

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Crystal structure of a NIR‐Emitting DNA‐Stabilized Ag₁₆ Nanocluster

Cerretani

et al. 2019

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DNA has been used as a scaffold to stabilize small, atomically monodisperse silver nanoclusters, which have attracted attention due to their intriguing photophysical properties. Herein, we describe the X‐ray crystal structure of a DNA‐encapsulated, near‐infrared emitting Ag16 nanocluster (DNA–Ag16NC). The asymmetric unit of the crystal contains two DNA–Ag16NCs and the crystal packing between the DNA–Ag16NCs is promoted by several interactions, such as two silver‐mediated base pairs between 3′‐terminal adenines, two phosphate–Ca2+–phosphate interactions, and π‐stacking between two neighboring thymines. Each Ag16NC is confined by two DNA decamers that take on a horse‐shoe‐like conformation and is almost fully shielded from the solvent environment. This structural insight will aid in the determination of the structure/photophysical property relationship for this class of emitters and opens up new research opportunities in fluorescence imaging and sensing using noble‐metal clusters.

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Crystal Structure of Metallo DNA Duplex Containing Consecutive Watson–Crick‐like T–Hg^II–T Base Pairs

et al. 2014

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The metallo DNA duplex containing mercury-mediated T-T base pairs is an attractive biomacromolecular nanomaterial which can be applied to nanodevices such as ion sensors. Reported herein is the first crystal structure of a B-form DNA duplex containing two consecutive T-Hg(II)-T base pairs. The Hg(II) ion occupies the center between two T residues. The N3-Hg(II) bond distance is 2.0 Å. The relatively short Hg(II)-Hg(II) distance (3.3 Å) observed in consecutive T-Hg(II)-T base pairs suggests that the metallophilic attraction could exist between them and may stabilize the B-form double helix. To support this, the DNA duplex is largely distorted and adopts an unusual nonhelical conformation in the absence of Hg(II). The structure of the metallo DNA duplex itself and the Hg(II)-induced structural switching from the nonhelical form to the B-form provide the basis for structure-based design of metal-conjugated nucleic acid nanomaterials.

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Structures, physicochemical properties, and applications of T–Hg^II–T, C–Ag^I–C, and other metallo-base-pairs

et al. 2015

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Recently, metal-mediated base-pairs (metallo-base-pairs) have been studied extensively with the aim of exploring novel base-pairs; their structures, physicochemical properties, and applications have been studied. This trend has become more evident after the discovery of Hg(II)-mediated thymine-thymine (T-Hg(II)-T) and Ag(I)-mediated cytosine-cytosine (C-Ag(I)-C) base-pairs. In this article, we focus on the basic science and applications of these metallo-base-pairs, which are composed of natural bases.

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Classification of pseudo pairs between nucleotide bases and amino acids by analysis of nucleotide–protein complexes

Kondo

Westhof

2011

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Nucleotide bases are recognized by amino acid residues in a variety of DNA/RNA binding and nucleotide binding proteins. In this study, a total of 446 crystal structures of nucleotide–protein complexes are analyzed manually and pseudo pairs together with single and bifurcated hydrogen bonds observed between bases and amino acids are classified and annotated. Only 5 of the 20 usual amino acid residues, Asn, Gln, Asp, Glu and Arg, are able to orient in a coplanar fashion in order to form pseudo pairs with nucleotide bases through two hydrogen bonds. The peptide backbone can also form pseudo pairs with nucleotide bases and presents a strong bias for binding to the adenine base. The Watson–Crick side of the nucleotide bases is the major interaction edge participating in such pseudo pairs. Pseudo pairs between the Watson–Crick edge of guanine and Asp are frequently observed. The Hoogsteen edge of the purine bases is a good discriminatory element in recognition of nucleotide bases by protein side chains through the pseudo pairing: the Hoogsteen edge of adenine is recognized by various amino acids while the Hoogsteen edge of guanine is only recognized by Arg. The sugar edge is rarely recognized by either the side-chain or peptide backbone of amino acid residues.

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Jiro Kondo

A metallo-DNA nanowire with uninterrupted one-dimensional silver array

Crystal structure of a NIR‐Emitting DNA‐Stabilized Ag₁₆ Nanocluster

Crystal Structure of Metallo DNA Duplex Containing Consecutive Watson–Crick‐like T–Hg^II–T Base Pairs

Structures, physicochemical properties, and applications of T–Hg^II–T, C–Ag^I–C, and other metallo-base-pairs

Classification of pseudo pairs between nucleotide bases and amino acids by analysis of nucleotide–protein complexes

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Jiro Kondo

A metallo-DNA nanowire with uninterrupted one-dimensional silver array

Crystal structure of a NIR‐Emitting DNA‐Stabilized Ag16 Nanocluster

Crystal Structure of Metallo DNA Duplex Containing Consecutive Watson–Crick‐like T–HgII–T Base Pairs

Structures, physicochemical properties, and applications of T–HgII–T, C–AgI–C, and other metallo-base-pairs

Classification of pseudo pairs between nucleotide bases and amino acids by analysis of nucleotide–protein complexes

Contact Info

Product

Resources

About

Crystal structure of a NIR‐Emitting DNA‐Stabilized Ag₁₆ Nanocluster

Crystal Structure of Metallo DNA Duplex Containing Consecutive Watson–Crick‐like T–Hg^II–T Base Pairs

Structures, physicochemical properties, and applications of T–Hg^II–T, C–Ag^I–C, and other metallo-base-pairs