Occurrence and Function of Hoogsteen Base Pairs in Nucleic Acids

Zhou, Huiqing

January 2016

<p>Nucleic acids (DNA and RNA) play essential roles in the central dogma of biology for the storage and transfer of genetic information. The unique chemical and conformational structures of nucleic acids – the double helix composed of complementary Watson-Crick base pairs, provide the structural basis to carry out their biological functions. DNA double helix can dynamically accommodate Watson-Crick and Hoogsteen base-pairing, in which the purine base is flipped by ~180° degrees to adopt syn rather than anti conformation as in Watson-Crick base pairs. There is growing evidence that Hoogsteen base pairs play important roles in DNA replication, recognition, damage or mispair accommodation and repair. Here, we constructed a database for existing Hoogsteen base pairs in DNA duplexes by a structure-based survey from the Protein Data Bank, and structural analyses based on the resulted Hoogsteen structures revealed that Hoogsteen base pairs occur in a wide variety of biological contexts and can induce DNA kinking towards the major groove. As there were documented difficulties in modeling Hoogsteen or Watson-Crick by crystallography, we collaborated with the Richardsons’ lab and identified potential Hoogsteen base pairs that were mis-modeled as Watson-Crick base pairs which suggested that Hoogsteen can be more prevalent than it was thought to be. We developed solution NMR method combined with the site-specific isotope labeling to characterize the formation of, or conformational exchange with Hoogsteen base pairs in large DNA-protein complexes under solution conditions, in the absence of the crystal packing force. We showed that there are enhanced chemical exchange, potentially between Watson-Crick and Hoogsteen, at a sharp kink site in the complex formed by DNA and the Integration Host Factor protein. In stark contrast to B-form DNA, we found that Hoogsteen base pairs are strongly disfavored in A-form RNA duplex. Chemical modifications N1-methyl adenosine and N1-methyl guanosine that block Watson-Crick base-pairing, can be absorbed as Hoogsteen base pairs in DNA, but rather potently destabilized A-form RNA and caused helix melting. The intrinsic instability of Hoogsteen base pairs in A-form RNA endows the N1-methylation as a functioning post-transcriptional modification that was known to facilitate RNA folding, translation and potentially play roles in the epitranscriptome. On the other hand, the dynamic property of DNA that can accommodate Hoogsteen base pairs could be critical to maintaining the genome stability.</p> / Dissertation

Biochemistry

DNA

Hoogsteen

RNA

solution NMR

structure

Crystallographic studies on Echinomycin bisintercalation on DNA and an alternating D-alanyl,L-homoalanyl PNA. / Kristallographische Studien über Echinomycin im Bisinterkalation mit DNS und ein alternierenden D-Alanyl,L-homoalanyl PNS

Cuesta Seijo, Jose Antonio

28 June 2005

No description available.

540 Chemie

Mathematics and Computer Science

Echinomycin

Hoogsteen Basenpaarung

PNS

Echinomycin

Hoogsteen basepairing

PNA

35.90

SP 000: Strukturchemie

Utilization of nucleobase pairing to develop supramolecular polymers, electron transfer systems, and interaction with biological molecules

Lawrence, Candace Michelle

15 June 2011

Hydrogen bonding is seen extensively in Nature. It is manifest in DNA/RNA nucleic acid (nucleobase) pairing, the defining feature of the double helix, as well as in secondary structures in protein folding such as hairpin loops. This importance, thus coupled with the aesthetic appeal of nucleobase hydrogen-bonding interactions, has inspired us to design and synthesize new hydrogen-bonded assemblies that make use of Watson-Crick and Hoogsteen interactions. Currently, novel supramolecular architectures are being developed for the formation of supramolecular polymers via Watson-Crick hydrogen bonding of guanosine and cytidine. Supramolecular polymer formation occurs through hydrogen bonding, electronic interactions, and metal chelation, and allows for a highly thermodynamic system that can easily be broken and reformed through external stimuli. By synthesizing linear, metal-nucleobase, and functionalized guanosine entities, a variety of new “monomers” have been obtained. Their use in construction of main chain and side chain polymers, and G-quartet hydrogels are now being explored. The hydrogen bonding motifs used to develop supramolecular polymers are also attractive for developing through bond electron transfer systems. One inspiration for developing artificial donor-acceptor systems (i.e., linked through non-covalent interactions) comes from the light harvesting systems found in Nature. Triggered by a pulse of UV light, electron transfer across bridges, including charge separation and charge recombination processes can occur and the rates can be determined. As one part of this study, collaborators Igor Rubtsov and David Beratan studied how perturbing the vibrational modes of the bridge via IR pulse excitation, affected electron transfer. Mid-IR excitation of the donor-acceptor systems slowed the rate of electron transfer, likely because the molecular vibrations either disrupted the bridging hydrogen bonds or distorted the electronic interactions of the bridge. This observance could lend itself to the possibility of designing IR-controlled molecular switches and other devices Another mode of hydrogen bonding, Hoogsteen interactions, was explored in the context of developing a guanosine-quadruplex binder. Specifically, a pyrrole-based inosine was designed to direct hydrogen bonding via an extended Hoogsteen interaction in order to bind to quadruplex DNA. Quadruplex DNA has been studied as a folded form of DNA and, if stabilized, can inhibit gene replication especially amongst cancer strands. In summary, the candidate’s research efforts have focused on exploiting hydrogen bonding in nucleobases to construct novel supramolecular assemblies that could see eventual applications in materials chemistry, nanotechnology, and gene therapy. / text

Supramolecular polymers

Electron transfer

Hoogsteen base pairing

Hydrogen bonding

Hydrogen-bonded assemblies

Structural Studies of Biomolecules by Dynamic Nuclear Polarization Solid-State NMR Spectroscopy

Conroy, Daniel William

29 August 2019

No description available.

Chemistry

Solid-State NMR Spectroscopy

Dynamic Nuclear Polarization

Dinitroxide

Biradical

Polarizing Agent

Solid-Phase Peptide Synthesis

TOAC

DNA

Hoogsteen Base-Pairing

Nucleosome Core Particle

Amyloid Fibril

Prion Protein