Enthalpy–Entropy Compensation in Biomolecular Halogen Bonds Measured in DNA Junctions

Interest in noncovalent interactions involving halogens, particularly halogen bonds (X-bonds), has grown dramatically in the past decade, propelled by the use of X-bonding in molecular engineering and drug design. However, it is clear that a complete analysis of the structure–energy relationship mus...

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Veröffentlicht in:	Biochemistry (Easton) 2013-07, Vol.52 (29), p.4891-4903
Hauptverfasser:	Carter, Megan, Voth, Andrea Regier, Scholfield, Matthew R, Rummel, Brittany, Sowers, Lawrence C, Ho, P. Shing
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Sprache:	eng
Schlagworte:	Calorimetry, Differential Scanning Crystallization Crystallography DNA - chemistry Halogens - chemistry Hydrogen Bonding Thermodynamics
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container_issue	29
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creator	Carter, Megan Voth, Andrea Regier Scholfield, Matthew R Rummel, Brittany Sowers, Lawrence C Ho, P. Shing
description	Interest in noncovalent interactions involving halogens, particularly halogen bonds (X-bonds), has grown dramatically in the past decade, propelled by the use of X-bonding in molecular engineering and drug design. However, it is clear that a complete analysis of the structure–energy relationship must be established in biological systems to fully exploit X-bonds for biomolecular engineering. We present here the first comprehensive experimental study to correlate geometries with their stabilizing potentials for fluorine (F), chlorine (Cl), bromine (Br), or iodine (I) X-bonds in a biological context. For these studies, we determine the single-crystal structures of DNA Holliday junctions containing halogenated uracil bases that compete X-bonds against classic hydrogen bonds (H-bonds), estimate the enthalpic energies of the competing interactions in the crystal system through crystallographic titrations, and compare the enthalpic and entropic energies of bromine and iodine X-bonds in solution by differential scanning calorimetry. The culmination of these studies demonstrates that enthalpic stabilization of X-bonds increases with increasing polarizability from F to Cl to Br to I, which is consistent with the σ-hole theory of X-bonding. Furthermore, an increase in the X-bonding potential is seen to direct the interaction toward a more ideal geometry. However, the entropic contributions to the total free energies must also be considered to determine how each halogen potentially contributes to the overall stability of the interaction. We find that bromine has the optimal balance between enthalpic and entropic energy components, resulting in the lowest free energy for X-bonding in this DNA system. The X-bond formed by iodine is more enthalpically stable, but this comes with an entropic cost, which we attribute to crowding effects. Thus, the overall free energy of an X-bonding interaction balances the stabilizing electrostatic effects of the σ-hole against the competing effects on the local structural dynamics of the system.
doi_str_mv	10.1021/bi400590h
format	Article
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For these studies, we determine the single-crystal structures of DNA Holliday junctions containing halogenated uracil bases that compete X-bonds against classic hydrogen bonds (H-bonds), estimate the enthalpic energies of the competing interactions in the crystal system through crystallographic titrations, and compare the enthalpic and entropic energies of bromine and iodine X-bonds in solution by differential scanning calorimetry. The culmination of these studies demonstrates that enthalpic stabilization of X-bonds increases with increasing polarizability from F to Cl to Br to I, which is consistent with the σ-hole theory of X-bonding. Furthermore, an increase in the X-bonding potential is seen to direct the interaction toward a more ideal geometry. However, the entropic contributions to the total free energies must also be considered to determine how each halogen potentially contributes to the overall stability of the interaction. We find that bromine has the optimal balance between enthalpic and entropic energy components, resulting in the lowest free energy for X-bonding in this DNA system. The X-bond formed by iodine is more enthalpically stable, but this comes with an entropic cost, which we attribute to crowding effects. 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Shing</creatorcontrib><title>Enthalpy–Entropy Compensation in Biomolecular Halogen Bonds Measured in DNA Junctions</title><title>Biochemistry (Easton)</title><addtitle>Biochemistry</addtitle><description>Interest in noncovalent interactions involving halogens, particularly halogen bonds (X-bonds), has grown dramatically in the past decade, propelled by the use of X-bonding in molecular engineering and drug design. However, it is clear that a complete analysis of the structure–energy relationship must be established in biological systems to fully exploit X-bonds for biomolecular engineering. We present here the first comprehensive experimental study to correlate geometries with their stabilizing potentials for fluorine (F), chlorine (Cl), bromine (Br), or iodine (I) X-bonds in a biological context. For these studies, we determine the single-crystal structures of DNA Holliday junctions containing halogenated uracil bases that compete X-bonds against classic hydrogen bonds (H-bonds), estimate the enthalpic energies of the competing interactions in the crystal system through crystallographic titrations, and compare the enthalpic and entropic energies of bromine and iodine X-bonds in solution by differential scanning calorimetry. The culmination of these studies demonstrates that enthalpic stabilization of X-bonds increases with increasing polarizability from F to Cl to Br to I, which is consistent with the σ-hole theory of X-bonding. Furthermore, an increase in the X-bonding potential is seen to direct the interaction toward a more ideal geometry. However, the entropic contributions to the total free energies must also be considered to determine how each halogen potentially contributes to the overall stability of the interaction. We find that bromine has the optimal balance between enthalpic and entropic energy components, resulting in the lowest free energy for X-bonding in this DNA system. The X-bond formed by iodine is more enthalpically stable, but this comes with an entropic cost, which we attribute to crowding effects. Thus, the overall free energy of an X-bonding interaction balances the stabilizing electrostatic effects of the σ-hole against the competing effects on the local structural dynamics of the system.</description><subject>Calorimetry, Differential Scanning</subject><subject>Crystallization</subject><subject>Crystallography</subject><subject>DNA - chemistry</subject><subject>Halogens - chemistry</subject><subject>Hydrogen Bonding</subject><subject>Thermodynamics</subject><issn>0006-2960</issn><issn>1520-4995</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkLFOwzAQhi0EoqUw8AIoCxIMAduxnXiEUiiowAJijBznQlMlcbCToRvvwBvyJLhq6YTE5PPpu_90H0LHBF8QTMllVjKMucTzHTQknOKQScl30RBjLEIqBR6gA-cW_stwzPbRgEZxImPGhuht0nRzVbXL788vX1rTLoOxqVtonOpK0wRlE1yXpjYV6L5SNpiqyryDb5omd8EjKNdbyFfYzdNV8NA3ejXmDtFeoSoHR5t3hF5vJy_jaTh7vrsfX81CFbGkCymnkCkQgjMqdSSKIqZaiEKTTOlcsUglWY6BUACsY5LxjMi4EJrzhCsZQzRCZ-vc1pqPHlyX1qXTUFWqAdO7lHC_h_jL5f8oEz5Vyoh49HyNamucs1CkrS1rZZcpwelKebpV7tmTTWyf1ZBvyV_HHjhdA0q7dGF623ghfwT9AHToiJo</recordid><startdate>20130723</startdate><enddate>20130723</enddate><creator>Carter, Megan</creator><creator>Voth, Andrea Regier</creator><creator>Scholfield, Matthew R</creator><creator>Rummel, Brittany</creator><creator>Sowers, Lawrence C</creator><creator>Ho, P. 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Shing</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Enthalpy–Entropy Compensation in Biomolecular Halogen Bonds Measured in DNA Junctions</atitle><jtitle>Biochemistry (Easton)</jtitle><addtitle>Biochemistry</addtitle><date>2013-07-23</date><risdate>2013</risdate><volume>52</volume><issue>29</issue><spage>4891</spage><epage>4903</epage><pages>4891-4903</pages><issn>0006-2960</issn><eissn>1520-4995</eissn><abstract>Interest in noncovalent interactions involving halogens, particularly halogen bonds (X-bonds), has grown dramatically in the past decade, propelled by the use of X-bonding in molecular engineering and drug design. However, it is clear that a complete analysis of the structure–energy relationship must be established in biological systems to fully exploit X-bonds for biomolecular engineering. We present here the first comprehensive experimental study to correlate geometries with their stabilizing potentials for fluorine (F), chlorine (Cl), bromine (Br), or iodine (I) X-bonds in a biological context. For these studies, we determine the single-crystal structures of DNA Holliday junctions containing halogenated uracil bases that compete X-bonds against classic hydrogen bonds (H-bonds), estimate the enthalpic energies of the competing interactions in the crystal system through crystallographic titrations, and compare the enthalpic and entropic energies of bromine and iodine X-bonds in solution by differential scanning calorimetry. The culmination of these studies demonstrates that enthalpic stabilization of X-bonds increases with increasing polarizability from F to Cl to Br to I, which is consistent with the σ-hole theory of X-bonding. Furthermore, an increase in the X-bonding potential is seen to direct the interaction toward a more ideal geometry. However, the entropic contributions to the total free energies must also be considered to determine how each halogen potentially contributes to the overall stability of the interaction. We find that bromine has the optimal balance between enthalpic and entropic energy components, resulting in the lowest free energy for X-bonding in this DNA system. The X-bond formed by iodine is more enthalpically stable, but this comes with an entropic cost, which we attribute to crowding effects. Thus, the overall free energy of an X-bonding interaction balances the stabilizing electrostatic effects of the σ-hole against the competing effects on the local structural dynamics of the system.</abstract><cop>United States</cop><pub>American Chemical Society</pub><pmid>23789744</pmid><doi>10.1021/bi400590h</doi><tpages>13</tpages></addata></record>
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subjects	Calorimetry, Differential Scanning Crystallization Crystallography DNA - chemistry Halogens - chemistry Hydrogen Bonding Thermodynamics
title	Enthalpy–Entropy Compensation in Biomolecular Halogen Bonds Measured in DNA Junctions
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