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DNA–Gelatin Complex Coacervation, UCST and First-Order Phase Transition of Coacervate to Anisotropic ion gel in 1‑Methyl-3-octylimidazolium Chloride Ionic Liquid Solutions

Study of kinetics of complex coacervation occurring in aqueous 1-octyl-3-methylimidazolium chloride ionic liquid solution of low charge density polypeptide (gelatin A) and 200 base pair DNA, and thermally activated coacervate into anisotropic gel transition, is reported here. Associative interaction...

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Published in:	The journal of physical chemistry. B 2012-12, Vol.116 (51), p.14805-14816
Main Authors:	Rawat, Kamla, Aswal, V. K, Bohidar, H. B
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Language:	English
Subjects:	Anisotropy Binding Borates - chemistry Charge Chlorides Deoxyribonucleic acid DNA - chemistry DNA - metabolism Gelatin - chemistry Gelatin - metabolism Gelatins Gels - chemistry Imidazoles - chemistry Ionic liquids Ionic Liquids - chemistry Ions - chemistry Kinetics Phase Transition Protein Binding Proteins Solutions - chemistry Transition Temperature
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creator	Rawat, Kamla Aswal, V. K Bohidar, H. B
description	Study of kinetics of complex coacervation occurring in aqueous 1-octyl-3-methylimidazolium chloride ionic liquid solution of low charge density polypeptide (gelatin A) and 200 base pair DNA, and thermally activated coacervate into anisotropic gel transition, is reported here. Associative interaction between DNA and gelatin A (GA) having charge ratio (DNA:GA = 16:1) and persistence length ratio (5:1) was studied at fixed DNA (0.005% (w/v)) and varying GA concentration (C GA = 0–0.25% (w/v)). The interaction profile was found to be strongly hierarchical and revealed three distinct binding regions: (i) Region I showed DNA-condensation (primary binding) for C GA < 0.10% (w/v), the DNA ζ potential decrease from −80 to −5 mV (95%) (partial charge neutralization), and a size decrease by ≈60%. (ii) Region II (0.10 < C GA < 0.15% (w/v)) indicated secondary binding, a 4-fold turbidity increase, a ζ potential decrease from −5 to 0 mV (complete charge neutralization), which resulted in the appearance of soluble complexes and initiation of coacervation. (iii) Region III (0.15 < C GA < 0.25% (w/v)) revealed growth of insoluble complexes followed by precipitation. The hydration of coacervate was found to be protein concentration specific in Raman studies. The binding profile of DNA-GA complex with IL concentration revealed optimum IL concentration (=0.05% (w/v)) was required to maximize the interactions. Small angle neutron scattering (SANS) data of coacervates gave static structure factor profiles, I(q) versus wave vector q, that were remarkably similar and invariant of protein concentration. This data could be split into two distinct regions: (i) for 0.0173 < q < 0.0353 Å–1, I(q) ∼ q –α with α = 1.35–1.67, and (ii) for 0.0353 < q < 0.35 Å–1, I(q) = I(0)/(1 + q 2ξ2). The correlation length found was ξ = 2 ± 0.1 nm independent of protein concentration. The viscoelastic length (≈8 nm) was found to have value close to the persistence length of the protein (≈10 nm). Rheology data indicated that the coacervate phase resided close to the gelation state of the protein. Thus, on a heating–cooling cycle (heating to 50 °C followed by cooling to 20 °C), the heterogeneous coacervate exhibited an irreversible first-order phase transition to an anisotropic ion gel. This established a coacervate–ion gel phase diagram having a well-defined UCST.
doi_str_mv	10.1021/jp3102089
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K ; Bohidar, H. B</creator><creatorcontrib>Rawat, Kamla ; Aswal, V. K ; Bohidar, H. B</creatorcontrib><description><![CDATA[Study of kinetics of complex coacervation occurring in aqueous 1-octyl-3-methylimidazolium chloride ionic liquid solution of low charge density polypeptide (gelatin A) and 200 base pair DNA, and thermally activated coacervate into anisotropic gel transition, is reported here. Associative interaction between DNA and gelatin A (GA) having charge ratio (DNA:GA = 16:1) and persistence length ratio (5:1) was studied at fixed DNA (0.005% (w/v)) and varying GA concentration (C GA = 0–0.25% (w/v)). The interaction profile was found to be strongly hierarchical and revealed three distinct binding regions: (i) Region I showed DNA-condensation (primary binding) for C GA < 0.10% (w/v), the DNA ζ potential decrease from −80 to −5 mV (95%) (partial charge neutralization), and a size decrease by ≈60%. (ii) Region II (0.10 < C GA < 0.15% (w/v)) indicated secondary binding, a 4-fold turbidity increase, a ζ potential decrease from −5 to 0 mV (complete charge neutralization), which resulted in the appearance of soluble complexes and initiation of coacervation. (iii) Region III (0.15 < C GA < 0.25% (w/v)) revealed growth of insoluble complexes followed by precipitation. The hydration of coacervate was found to be protein concentration specific in Raman studies. The binding profile of DNA-GA complex with IL concentration revealed optimum IL concentration (=0.05% (w/v)) was required to maximize the interactions. Small angle neutron scattering (SANS) data of coacervates gave static structure factor profiles, I(q) versus wave vector q, that were remarkably similar and invariant of protein concentration. This data could be split into two distinct regions: (i) for 0.0173 < q < 0.0353 Å–1, I(q) ∼ q –α with α = 1.35–1.67, and (ii) for 0.0353 < q < 0.35 Å–1, I(q) = I(0)/(1 + q 2ξ2). The correlation length found was ξ = 2 ± 0.1 nm independent of protein concentration. The viscoelastic length (≈8 nm) was found to have value close to the persistence length of the protein (≈10 nm). Rheology data indicated that the coacervate phase resided close to the gelation state of the protein. Thus, on a heating–cooling cycle (heating to 50 °C followed by cooling to 20 °C), the heterogeneous coacervate exhibited an irreversible first-order phase transition to an anisotropic ion gel. 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B, 2012-12, Vol.116 (51), p.14805-14816</ispartof><rights>Copyright © 2012 American Chemical Society</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a447t-aa87346563c8c4ca861109cc79f699d81c47514f4e7857cf3ca29f37edfb2bd53</citedby><cites>FETCH-LOGICAL-a447t-aa87346563c8c4ca861109cc79f699d81c47514f4e7857cf3ca29f37edfb2bd53</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,776,780,27901,27902</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/23194173$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Rawat, Kamla</creatorcontrib><creatorcontrib>Aswal, V. K</creatorcontrib><creatorcontrib>Bohidar, H. B</creatorcontrib><title>DNA–Gelatin Complex Coacervation, UCST and First-Order Phase Transition of Coacervate to Anisotropic ion gel in 1‑Methyl-3-octylimidazolium Chloride Ionic Liquid Solutions</title><title>The journal of physical chemistry. B</title><addtitle>J. Phys. Chem. B</addtitle><description><![CDATA[Study of kinetics of complex coacervation occurring in aqueous 1-octyl-3-methylimidazolium chloride ionic liquid solution of low charge density polypeptide (gelatin A) and 200 base pair DNA, and thermally activated coacervate into anisotropic gel transition, is reported here. Associative interaction between DNA and gelatin A (GA) having charge ratio (DNA:GA = 16:1) and persistence length ratio (5:1) was studied at fixed DNA (0.005% (w/v)) and varying GA concentration (C GA = 0–0.25% (w/v)). The interaction profile was found to be strongly hierarchical and revealed three distinct binding regions: (i) Region I showed DNA-condensation (primary binding) for C GA < 0.10% (w/v), the DNA ζ potential decrease from −80 to −5 mV (95%) (partial charge neutralization), and a size decrease by ≈60%. (ii) Region II (0.10 < C GA < 0.15% (w/v)) indicated secondary binding, a 4-fold turbidity increase, a ζ potential decrease from −5 to 0 mV (complete charge neutralization), which resulted in the appearance of soluble complexes and initiation of coacervation. (iii) Region III (0.15 < C GA < 0.25% (w/v)) revealed growth of insoluble complexes followed by precipitation. The hydration of coacervate was found to be protein concentration specific in Raman studies. The binding profile of DNA-GA complex with IL concentration revealed optimum IL concentration (=0.05% (w/v)) was required to maximize the interactions. Small angle neutron scattering (SANS) data of coacervates gave static structure factor profiles, I(q) versus wave vector q, that were remarkably similar and invariant of protein concentration. This data could be split into two distinct regions: (i) for 0.0173 < q < 0.0353 Å–1, I(q) ∼ q –α with α = 1.35–1.67, and (ii) for 0.0353 < q < 0.35 Å–1, I(q) = I(0)/(1 + q 2ξ2). The correlation length found was ξ = 2 ± 0.1 nm independent of protein concentration. The viscoelastic length (≈8 nm) was found to have value close to the persistence length of the protein (≈10 nm). Rheology data indicated that the coacervate phase resided close to the gelation state of the protein. Thus, on a heating–cooling cycle (heating to 50 °C followed by cooling to 20 °C), the heterogeneous coacervate exhibited an irreversible first-order phase transition to an anisotropic ion gel. This established a coacervate–ion gel phase diagram having a well-defined UCST.]]></description><subject>Anisotropy</subject><subject>Binding</subject><subject>Borates - chemistry</subject><subject>Charge</subject><subject>Chlorides</subject><subject>Deoxyribonucleic acid</subject><subject>DNA - chemistry</subject><subject>DNA - metabolism</subject><subject>Gelatin - chemistry</subject><subject>Gelatin - metabolism</subject><subject>Gelatins</subject><subject>Gels - chemistry</subject><subject>Imidazoles - chemistry</subject><subject>Ionic liquids</subject><subject>Ionic Liquids - chemistry</subject><subject>Ions - chemistry</subject><subject>Kinetics</subject><subject>Phase Transition</subject><subject>Protein Binding</subject><subject>Proteins</subject><subject>Solutions - chemistry</subject><subject>Transition Temperature</subject><issn>1520-6106</issn><issn>1520-5207</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2012</creationdate><recordtype>article</recordtype><recordid>eNqNkd9qFDEUxgex2Fq98AUkN4KCU_N3klwuo62FbSt0ez1kk4ybJTOZJjPietVXEB_Ed-qTmGXXeiPoxeE7HH7nO3C-oniB4AmCGL1bDyQrFPJRcYQYhmUu_njfVwhWh8XTlNYQYoZF9aQ4xARJijg5Kn6-v5zd3_04s16Nrgd16AZvv2ZV2sYveRb6t-Cmvl4A1Rtw6mIay6tobASfVipZsIiqT26LgdD-WbNgDGDWuxTGGAanwRb4bD3IN9D93fcLO642viRl0OPGu84Z9S14N3WgXvkQnbHgPPR5b-5uJ2fAdfDT9kh6Vhy0yif7fK_Hxc3ph0X9sZxfnZ3Xs3mpKOVjqZTghFasIlpoqpWoEIJSay7bSkojkKacIdpSywXjuiVaYdkSbk27xEvDyHHxeuc7xHA72TQ2nUvaeq96G6bUIM4Iw5Jj_m-UESqgJOQ_0GxXcQExzuibHapjSCnathmi61TcNAg229Sbh9Qz-3JvOy07ax7I3zFn4NUOUDo16zDFPv_uL0a_AB2Bta8</recordid><startdate>20121227</startdate><enddate>20121227</enddate><creator>Rawat, Kamla</creator><creator>Aswal, V. K</creator><creator>Bohidar, H. B</creator><general>American Chemical Society</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>7TM</scope><scope>7SR</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><scope>L7M</scope></search><sort><creationdate>20121227</creationdate><title>DNA–Gelatin Complex Coacervation, UCST and First-Order Phase Transition of Coacervate to Anisotropic ion gel in 1‑Methyl-3-octylimidazolium Chloride Ionic Liquid Solutions</title><author>Rawat, Kamla ; Aswal, V. K ; Bohidar, H. B</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a447t-aa87346563c8c4ca861109cc79f699d81c47514f4e7857cf3ca29f37edfb2bd53</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2012</creationdate><topic>Anisotropy</topic><topic>Binding</topic><topic>Borates - chemistry</topic><topic>Charge</topic><topic>Chlorides</topic><topic>Deoxyribonucleic acid</topic><topic>DNA - chemistry</topic><topic>DNA - metabolism</topic><topic>Gelatin - chemistry</topic><topic>Gelatin - metabolism</topic><topic>Gelatins</topic><topic>Gels - chemistry</topic><topic>Imidazoles - chemistry</topic><topic>Ionic liquids</topic><topic>Ionic Liquids - chemistry</topic><topic>Ions - chemistry</topic><topic>Kinetics</topic><topic>Phase Transition</topic><topic>Protein Binding</topic><topic>Proteins</topic><topic>Solutions - chemistry</topic><topic>Transition Temperature</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Rawat, Kamla</creatorcontrib><creatorcontrib>Aswal, V. K</creatorcontrib><creatorcontrib>Bohidar, H. B</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><collection>Nucleic Acids Abstracts</collection><collection>Engineered Materials Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>The journal of physical chemistry. B</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Rawat, Kamla</au><au>Aswal, V. K</au><au>Bohidar, H. B</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>DNA–Gelatin Complex Coacervation, UCST and First-Order Phase Transition of Coacervate to Anisotropic ion gel in 1‑Methyl-3-octylimidazolium Chloride Ionic Liquid Solutions</atitle><jtitle>The journal of physical chemistry. B</jtitle><addtitle>J. Phys. Chem. B</addtitle><date>2012-12-27</date><risdate>2012</risdate><volume>116</volume><issue>51</issue><spage>14805</spage><epage>14816</epage><pages>14805-14816</pages><issn>1520-6106</issn><eissn>1520-5207</eissn><abstract><![CDATA[Study of kinetics of complex coacervation occurring in aqueous 1-octyl-3-methylimidazolium chloride ionic liquid solution of low charge density polypeptide (gelatin A) and 200 base pair DNA, and thermally activated coacervate into anisotropic gel transition, is reported here. Associative interaction between DNA and gelatin A (GA) having charge ratio (DNA:GA = 16:1) and persistence length ratio (5:1) was studied at fixed DNA (0.005% (w/v)) and varying GA concentration (C GA = 0–0.25% (w/v)). The interaction profile was found to be strongly hierarchical and revealed three distinct binding regions: (i) Region I showed DNA-condensation (primary binding) for C GA < 0.10% (w/v), the DNA ζ potential decrease from −80 to −5 mV (95%) (partial charge neutralization), and a size decrease by ≈60%. (ii) Region II (0.10 < C GA < 0.15% (w/v)) indicated secondary binding, a 4-fold turbidity increase, a ζ potential decrease from −5 to 0 mV (complete charge neutralization), which resulted in the appearance of soluble complexes and initiation of coacervation. (iii) Region III (0.15 < C GA < 0.25% (w/v)) revealed growth of insoluble complexes followed by precipitation. The hydration of coacervate was found to be protein concentration specific in Raman studies. The binding profile of DNA-GA complex with IL concentration revealed optimum IL concentration (=0.05% (w/v)) was required to maximize the interactions. Small angle neutron scattering (SANS) data of coacervates gave static structure factor profiles, I(q) versus wave vector q, that were remarkably similar and invariant of protein concentration. This data could be split into two distinct regions: (i) for 0.0173 < q < 0.0353 Å–1, I(q) ∼ q –α with α = 1.35–1.67, and (ii) for 0.0353 < q < 0.35 Å–1, I(q) = I(0)/(1 + q 2ξ2). The correlation length found was ξ = 2 ± 0.1 nm independent of protein concentration. The viscoelastic length (≈8 nm) was found to have value close to the persistence length of the protein (≈10 nm). Rheology data indicated that the coacervate phase resided close to the gelation state of the protein. Thus, on a heating–cooling cycle (heating to 50 °C followed by cooling to 20 °C), the heterogeneous coacervate exhibited an irreversible first-order phase transition to an anisotropic ion gel. This established a coacervate–ion gel phase diagram having a well-defined UCST.]]></abstract><cop>United States</cop><pub>American Chemical Society</pub><pmid>23194173</pmid><doi>10.1021/jp3102089</doi><tpages>12</tpages></addata></record>
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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	Anisotropy Binding Borates - chemistry Charge Chlorides Deoxyribonucleic acid DNA - chemistry DNA - metabolism Gelatin - chemistry Gelatin - metabolism Gelatins Gels - chemistry Imidazoles - chemistry Ionic liquids Ionic Liquids - chemistry Ions - chemistry Kinetics Phase Transition Protein Binding Proteins Solutions - chemistry Transition Temperature
title	DNA–Gelatin Complex Coacervation, UCST and First-Order Phase Transition of Coacervate to Anisotropic ion gel in 1‑Methyl-3-octylimidazolium Chloride Ionic Liquid Solutions
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