New Insights into Quinine–DNA Binding Using Raman Spectroscopy and Molecular Dynamics Simulations

Quinine’s ability to bind DNA and potentially inhibit transcription and translation has been examined as a mode of action for its antimalarial activity. UV absorption and fluorescence-based studies have lacked the chemical specificity to develop an unambiguous molecular-level picture of the binding...

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Veröffentlicht in:	The journal of physical chemistry. B 2018-11, Vol.122 (43), p.9840-9851
Hauptverfasser:	Punihaole, David, Workman, Riley J, Upadhyay, Shiv, Van Bruggen, Craig, Schmitz, Andrew J, Reineke, Theresa M, Frontiera, Renee R
Format:	Artikel
Sprache:	eng
Schlagworte:	absorption biocrystallization DNA DNA - chemistry geometry Hydrogen Bonding Hydrogen-Ion Concentration mechanism of action molecular dynamics Molecular Dynamics Simulation Nucleic Acid Conformation nucleobases parasites phosphates Plasmodium Quantum Theory quinine Quinine - chemistry quinoline Raman spectroscopy simulation models solvents Spectrum Analysis, Raman transcription (genetics) translation (genetics) vibration
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container_issue	43
container_start_page	9840
container_title	The journal of physical chemistry. B
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creator	Punihaole, David Workman, Riley J Upadhyay, Shiv Van Bruggen, Craig Schmitz, Andrew J Reineke, Theresa M Frontiera, Renee R
description	Quinine’s ability to bind DNA and potentially inhibit transcription and translation has been examined as a mode of action for its antimalarial activity. UV absorption and fluorescence-based studies have lacked the chemical specificity to develop an unambiguous molecular-level picture of the binding interaction. To address this, we use Raman spectroscopy and molecular dynamics (MD) to investigate quinine–DNA interactions. We demonstrate that quinine’s strongest Raman band in the fingerprint region, which derives from a symmetric stretching mode of the quinoline ring, is highly sensitive to the local chemical environment and pH. The frequency shifts observed for this mode in solvents of varying polarity can be explained in terms of the Stark effect using a simple Onsager solvation model, indicating that the vibration reports on the local electrostatic environment. However, specific chemical interactions between the quinoline ring and its environment, such as hydrogen bonding and π-stacking, perturb the frequency of this mode in a more complicated but predictable manner. We use this vibration as a spectroscopic probe to investigate the binding interaction between quinine and DNA. We find that, when the quinoline ring is protonated, quinine weakly intercalates into DNA by forming π-stacking interactions with the base pairs. The Raman spectra indicate that quinine can intercalate into DNA with a ratio reaching up to roughly one molecule per 25 base pairs. Our results are confirmed by MD simulations, which also show that the quinoline ring adopts a t-shaped π-stacking geometry with the DNA base pairs, whereas the quinuclidine head group weakly interacts with the phosphate backbone in the minor groove. We expect that the spectral correlations determined here will enable future studies to probe quinine’s antimalarial activities, such as disrupting hemozoin biocrystallization, which is hypothesized to be, among other things, one of its primary modes of action against Plasmodium parasites.
doi_str_mv	10.1021/acs.jpcb.8b05795
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UV absorption and fluorescence-based studies have lacked the chemical specificity to develop an unambiguous molecular-level picture of the binding interaction. To address this, we use Raman spectroscopy and molecular dynamics (MD) to investigate quinine–DNA interactions. We demonstrate that quinine’s strongest Raman band in the fingerprint region, which derives from a symmetric stretching mode of the quinoline ring, is highly sensitive to the local chemical environment and pH. The frequency shifts observed for this mode in solvents of varying polarity can be explained in terms of the Stark effect using a simple Onsager solvation model, indicating that the vibration reports on the local electrostatic environment. However, specific chemical interactions between the quinoline ring and its environment, such as hydrogen bonding and π-stacking, perturb the frequency of this mode in a more complicated but predictable manner. We use this vibration as a spectroscopic probe to investigate the binding interaction between quinine and DNA. We find that, when the quinoline ring is protonated, quinine weakly intercalates into DNA by forming π-stacking interactions with the base pairs. The Raman spectra indicate that quinine can intercalate into DNA with a ratio reaching up to roughly one molecule per 25 base pairs. Our results are confirmed by MD simulations, which also show that the quinoline ring adopts a t-shaped π-stacking geometry with the DNA base pairs, whereas the quinuclidine head group weakly interacts with the phosphate backbone in the minor groove. 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However, specific chemical interactions between the quinoline ring and its environment, such as hydrogen bonding and π-stacking, perturb the frequency of this mode in a more complicated but predictable manner. We use this vibration as a spectroscopic probe to investigate the binding interaction between quinine and DNA. We find that, when the quinoline ring is protonated, quinine weakly intercalates into DNA by forming π-stacking interactions with the base pairs. The Raman spectra indicate that quinine can intercalate into DNA with a ratio reaching up to roughly one molecule per 25 base pairs. Our results are confirmed by MD simulations, which also show that the quinoline ring adopts a t-shaped π-stacking geometry with the DNA base pairs, whereas the quinuclidine head group weakly interacts with the phosphate backbone in the minor groove. 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B</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Punihaole, David</au><au>Workman, Riley J</au><au>Upadhyay, Shiv</au><au>Van Bruggen, Craig</au><au>Schmitz, Andrew J</au><au>Reineke, Theresa M</au><au>Frontiera, Renee R</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>New Insights into Quinine–DNA Binding Using Raman Spectroscopy and Molecular Dynamics Simulations</atitle><jtitle>The journal of physical chemistry. B</jtitle><addtitle>J. Phys. Chem. B</addtitle><date>2018-11-01</date><risdate>2018</risdate><volume>122</volume><issue>43</issue><spage>9840</spage><epage>9851</epage><pages>9840-9851</pages><issn>1520-6106</issn><issn>1520-5207</issn><eissn>1520-5207</eissn><abstract>Quinine’s ability to bind DNA and potentially inhibit transcription and translation has been examined as a mode of action for its antimalarial activity. UV absorption and fluorescence-based studies have lacked the chemical specificity to develop an unambiguous molecular-level picture of the binding interaction. To address this, we use Raman spectroscopy and molecular dynamics (MD) to investigate quinine–DNA interactions. We demonstrate that quinine’s strongest Raman band in the fingerprint region, which derives from a symmetric stretching mode of the quinoline ring, is highly sensitive to the local chemical environment and pH. The frequency shifts observed for this mode in solvents of varying polarity can be explained in terms of the Stark effect using a simple Onsager solvation model, indicating that the vibration reports on the local electrostatic environment. However, specific chemical interactions between the quinoline ring and its environment, such as hydrogen bonding and π-stacking, perturb the frequency of this mode in a more complicated but predictable manner. We use this vibration as a spectroscopic probe to investigate the binding interaction between quinine and DNA. We find that, when the quinoline ring is protonated, quinine weakly intercalates into DNA by forming π-stacking interactions with the base pairs. The Raman spectra indicate that quinine can intercalate into DNA with a ratio reaching up to roughly one molecule per 25 base pairs. Our results are confirmed by MD simulations, which also show that the quinoline ring adopts a t-shaped π-stacking geometry with the DNA base pairs, whereas the quinuclidine head group weakly interacts with the phosphate backbone in the minor groove. 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subjects	absorption biocrystallization DNA DNA - chemistry geometry Hydrogen Bonding Hydrogen-Ion Concentration mechanism of action molecular dynamics Molecular Dynamics Simulation Nucleic Acid Conformation nucleobases parasites phosphates Plasmodium Quantum Theory quinine Quinine - chemistry quinoline Raman spectroscopy simulation models solvents Spectrum Analysis, Raman transcription (genetics) translation (genetics) vibration
title	New Insights into Quinine–DNA Binding Using Raman Spectroscopy and Molecular Dynamics Simulations
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