A nickel complex cleaves uridine in folded RNA structures: application to E. coli tmRNA and related engineered molecules

To gain more insight about Escherichia coli tmRNA structure, NiCR, a square planar macrocyclic nickel (II) complex, was used to probe guanine N7 exposure. On the basis of this additional structural information, a refined secondary structure of the molecule is proposed. In addition to its known speci...

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Veröffentlicht in:	Journal of molecular biology 1998-06, Vol.279 (3), p.577-587
Hauptverfasser:	Hickerson, Robyn P, Watkins-Sims, Cristi D, Burrows, Cynthia J, Atkins, John F, Gesteland, Raymond F, Felden, Brice
Format:	Artikel
Sprache:	eng
Schlagworte:	Base Composition Base Composition - genetics Base Sequence Biochemistry, Molecular Biology Escherichia coli Escherichia coli - chemistry Free Radicals Free Radicals - metabolism Guanine Guanine - metabolism Life Sciences Magnesium Magnesium - pharmacology Molecular Probes Molecular Sequence Data Mutation Mutation - genetics Nickel Nickel - chemistry nickel complex Nucleic Acid Conformation Oligoribonucleotides Oligoribonucleotides - metabolism Organometallic Compounds Organometallic Compounds - chemistry Organometallic Compounds - metabolism pseudoknot RNA structure RNA, Bacterial RNA, Bacterial - chemistry structural probing Sulfuric Acid Esters Sulfuric Acid Esters - metabolism tmRNA Uridine Uridine - metabolism
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container_end_page	587
container_issue	3
container_start_page	577
container_title	Journal of molecular biology
container_volume	279
creator	Hickerson, Robyn P Watkins-Sims, Cristi D Burrows, Cynthia J Atkins, John F Gesteland, Raymond F Felden, Brice
description	To gain more insight about Escherichia coli tmRNA structure, NiCR, a square planar macrocyclic nickel (II) complex, was used to probe guanine N7 exposure. On the basis of this additional structural information, a refined secondary structure of the molecule is proposed. In addition to its known specificity for guanine N7, we show here that the chemical probe can also cleave at specific uridine residues. In contrast to the alkaline-labile modification of guanine, the reactivity of NiCR at these uridine residues results in direct strand scission. To better characterize the uridine cleavage sites and assess the importance of the RNA structure for the reaction to occur, smaller RNA molecules derived from one pseudoknot (PK4) of E. coli tmRNA containing two uridine cleavage sites were engineered and probed. It is shown that this pseudoknot can fold by itself in solution and that the expected uridine residues are also cleaved by the nickel complex, suggesting that only a local sequence and/or structural context is required for cleavage. In E. coli tmRNA, the five uridine cleavage sites are located in double-stranded regions. These sites contain a G-U wobble base-pair and a downstream uridine which is cleaved. Using smaller RNAs derived from one stem of PK4, systematic changes in the proposed recognition motif indicate that the G-U pair is required for cleavage. Furthermore, there is no cleavage if the G-U pair is reversed. If the recognition motif is moved within the stem, the cleavage site moves accordingly. Additionally, if the recognition motif is changed such that the G-U pair is flanked by two uridine residues, the reactivity occurs only at the 3′ uridine. Radical quenching studies have indicated that sulfate radical, as in the case of guanine oxidation, is involved in uridine oxidation. Although additional studies are required to better characterize the reaction, this paper reports a novel specificity for a chemical probe which may be useful for investigating structural motifs involving G-U pairs in folded RNAs.
doi_str_mv	10.1006/jmbi.1998.1813
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On the basis of this additional structural information, a refined secondary structure of the molecule is proposed. In addition to its known specificity for guanine N7, we show here that the chemical probe can also cleave at specific uridine residues. In contrast to the alkaline-labile modification of guanine, the reactivity of NiCR at these uridine residues results in direct strand scission. To better characterize the uridine cleavage sites and assess the importance of the RNA structure for the reaction to occur, smaller RNA molecules derived from one pseudoknot (PK4) of E. coli tmRNA containing two uridine cleavage sites were engineered and probed. It is shown that this pseudoknot can fold by itself in solution and that the expected uridine residues are also cleaved by the nickel complex, suggesting that only a local sequence and/or structural context is required for cleavage. In E. coli tmRNA, the five uridine cleavage sites are located in double-stranded regions. These sites contain a G-U wobble base-pair and a downstream uridine which is cleaved. Using smaller RNAs derived from one stem of PK4, systematic changes in the proposed recognition motif indicate that the G-U pair is required for cleavage. Furthermore, there is no cleavage if the G-U pair is reversed. If the recognition motif is moved within the stem, the cleavage site moves accordingly. Additionally, if the recognition motif is changed such that the G-U pair is flanked by two uridine residues, the reactivity occurs only at the 3′ uridine. Radical quenching studies have indicated that sulfate radical, as in the case of guanine oxidation, is involved in uridine oxidation. 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On the basis of this additional structural information, a refined secondary structure of the molecule is proposed. In addition to its known specificity for guanine N7, we show here that the chemical probe can also cleave at specific uridine residues. In contrast to the alkaline-labile modification of guanine, the reactivity of NiCR at these uridine residues results in direct strand scission. To better characterize the uridine cleavage sites and assess the importance of the RNA structure for the reaction to occur, smaller RNA molecules derived from one pseudoknot (PK4) of E. coli tmRNA containing two uridine cleavage sites were engineered and probed. It is shown that this pseudoknot can fold by itself in solution and that the expected uridine residues are also cleaved by the nickel complex, suggesting that only a local sequence and/or structural context is required for cleavage. In E. coli tmRNA, the five uridine cleavage sites are located in double-stranded regions. These sites contain a G-U wobble base-pair and a downstream uridine which is cleaved. Using smaller RNAs derived from one stem of PK4, systematic changes in the proposed recognition motif indicate that the G-U pair is required for cleavage. Furthermore, there is no cleavage if the G-U pair is reversed. If the recognition motif is moved within the stem, the cleavage site moves accordingly. Additionally, if the recognition motif is changed such that the G-U pair is flanked by two uridine residues, the reactivity occurs only at the 3′ uridine. Radical quenching studies have indicated that sulfate radical, as in the case of guanine oxidation, is involved in uridine oxidation. Although additional studies are required to better characterize the reaction, this paper reports a novel specificity for a chemical probe which may be useful for investigating structural motifs involving G-U pairs in folded RNAs.</description><subject>Base Composition</subject><subject>Base Composition - genetics</subject><subject>Base Sequence</subject><subject>Biochemistry, Molecular Biology</subject><subject>Escherichia coli</subject><subject>Escherichia coli - chemistry</subject><subject>Free Radicals</subject><subject>Free Radicals - metabolism</subject><subject>Guanine</subject><subject>Guanine - metabolism</subject><subject>Life Sciences</subject><subject>Magnesium</subject><subject>Magnesium - pharmacology</subject><subject>Molecular Probes</subject><subject>Molecular Sequence Data</subject><subject>Mutation</subject><subject>Mutation - genetics</subject><subject>Nickel</subject><subject>Nickel - chemistry</subject><subject>nickel complex</subject><subject>Nucleic Acid Conformation</subject><subject>Oligoribonucleotides</subject><subject>Oligoribonucleotides - metabolism</subject><subject>Organometallic Compounds</subject><subject>Organometallic Compounds - chemistry</subject><subject>Organometallic Compounds - metabolism</subject><subject>pseudoknot</subject><subject>RNA structure</subject><subject>RNA, Bacterial</subject><subject>RNA, Bacterial - chemistry</subject><subject>structural probing</subject><subject>Sulfuric Acid Esters</subject><subject>Sulfuric Acid Esters - metabolism</subject><subject>tmRNA</subject><subject>Uridine</subject><subject>Uridine - metabolism</subject><issn>0022-2836</issn><issn>1089-8638</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1998</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp1kTFv1DAUgK0KVI7SlQ3JExMJduI4NtupKhTpBFJVZstxXsDFsYPtnMq_x9GdujH5Se973-APobeU1JQQ_vFxHmxNpRQ1FbS9QDtKhKwEb8ULtCOkaapGtPwVep3SIyGka5m4RJeSMyp7uUNPe-yt-Q0OmzAvDp6wcaCPkPAa7Wg9YOvxFNwII77_tscpx9XkNUL6hPWyOGt0tsHjHPBtXRzO4jxvoPYjjuB0LofgfxYTxDLOwYFZHaQ36OWkXYLr83uFfny-fbi5qw7fv3y92R8qw0ifK2qk7DoqWw3DNFAYaN8B7Vk7SjM1DLgQAxcMtBFygIY1ICbREsE6xjVvdHuFPpy8v7RTS7Szjn9V0Fbd7Q_K-gRxVoT0VHIqj7Tg70_4EsOfFVJWs00GnNMewpoU5V3HedMXsD6BJoaUIkzPckrUVkZtZdRWRm1lysG7s3kdZhif8XOKshenPZTfOFqIKhkL3sBoI5isxmD_p_4H2pOdKg</recordid><startdate>19980612</startdate><enddate>19980612</enddate><creator>Hickerson, Robyn P</creator><creator>Watkins-Sims, Cristi D</creator><creator>Burrows, Cynthia J</creator><creator>Atkins, John F</creator><creator>Gesteland, Raymond F</creator><creator>Felden, Brice</creator><general>Elsevier Ltd</general><general>Elsevier</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>7QL</scope><scope>7TM</scope><scope>C1K</scope><scope>1XC</scope><scope>VOOES</scope><orcidid>https://orcid.org/0000-0003-2803-0626</orcidid></search><sort><creationdate>19980612</creationdate><title>A nickel complex cleaves uridine in folded RNA structures: application to E. coli tmRNA and related engineered molecules</title><author>Hickerson, Robyn P ; Watkins-Sims, Cristi D ; Burrows, Cynthia J ; Atkins, John F ; Gesteland, Raymond F ; Felden, Brice</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c407t-1c9955193aebfb1eb175e1743d9cf24e688b684eac89be242e8f83084546a62a3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>1998</creationdate><topic>Base Composition</topic><topic>Base Composition - genetics</topic><topic>Base Sequence</topic><topic>Biochemistry, Molecular Biology</topic><topic>Escherichia coli</topic><topic>Escherichia coli - chemistry</topic><topic>Free Radicals</topic><topic>Free Radicals - metabolism</topic><topic>Guanine</topic><topic>Guanine - metabolism</topic><topic>Life Sciences</topic><topic>Magnesium</topic><topic>Magnesium - pharmacology</topic><topic>Molecular Probes</topic><topic>Molecular Sequence Data</topic><topic>Mutation</topic><topic>Mutation - genetics</topic><topic>Nickel</topic><topic>Nickel - chemistry</topic><topic>nickel complex</topic><topic>Nucleic Acid Conformation</topic><topic>Oligoribonucleotides</topic><topic>Oligoribonucleotides - metabolism</topic><topic>Organometallic Compounds</topic><topic>Organometallic Compounds - chemistry</topic><topic>Organometallic Compounds - metabolism</topic><topic>pseudoknot</topic><topic>RNA structure</topic><topic>RNA, Bacterial</topic><topic>RNA, Bacterial - chemistry</topic><topic>structural probing</topic><topic>Sulfuric Acid Esters</topic><topic>Sulfuric Acid Esters - metabolism</topic><topic>tmRNA</topic><topic>Uridine</topic><topic>Uridine - metabolism</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Hickerson, Robyn P</creatorcontrib><creatorcontrib>Watkins-Sims, Cristi D</creatorcontrib><creatorcontrib>Burrows, Cynthia J</creatorcontrib><creatorcontrib>Atkins, John F</creatorcontrib><creatorcontrib>Gesteland, Raymond F</creatorcontrib><creatorcontrib>Felden, Brice</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Bacteriology Abstracts (Microbiology B)</collection><collection>Nucleic Acids Abstracts</collection><collection>Environmental Sciences and Pollution Management</collection><collection>Hyper Article en Ligne (HAL)</collection><collection>Hyper Article en Ligne (HAL) (Open Access)</collection><jtitle>Journal of molecular biology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hickerson, Robyn P</au><au>Watkins-Sims, Cristi D</au><au>Burrows, Cynthia J</au><au>Atkins, John F</au><au>Gesteland, Raymond F</au><au>Felden, Brice</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A nickel complex cleaves uridine in folded RNA structures: application to E. coli tmRNA and related engineered molecules</atitle><jtitle>Journal of molecular biology</jtitle><addtitle>J Mol Biol</addtitle><date>1998-06-12</date><risdate>1998</risdate><volume>279</volume><issue>3</issue><spage>577</spage><epage>587</epage><pages>577-587</pages><issn>0022-2836</issn><eissn>1089-8638</eissn><abstract>To gain more insight about Escherichia coli tmRNA structure, NiCR, a square planar macrocyclic nickel (II) complex, was used to probe guanine N7 exposure. On the basis of this additional structural information, a refined secondary structure of the molecule is proposed. In addition to its known specificity for guanine N7, we show here that the chemical probe can also cleave at specific uridine residues. In contrast to the alkaline-labile modification of guanine, the reactivity of NiCR at these uridine residues results in direct strand scission. To better characterize the uridine cleavage sites and assess the importance of the RNA structure for the reaction to occur, smaller RNA molecules derived from one pseudoknot (PK4) of E. coli tmRNA containing two uridine cleavage sites were engineered and probed. It is shown that this pseudoknot can fold by itself in solution and that the expected uridine residues are also cleaved by the nickel complex, suggesting that only a local sequence and/or structural context is required for cleavage. In E. coli tmRNA, the five uridine cleavage sites are located in double-stranded regions. These sites contain a G-U wobble base-pair and a downstream uridine which is cleaved. Using smaller RNAs derived from one stem of PK4, systematic changes in the proposed recognition motif indicate that the G-U pair is required for cleavage. Furthermore, there is no cleavage if the G-U pair is reversed. If the recognition motif is moved within the stem, the cleavage site moves accordingly. Additionally, if the recognition motif is changed such that the G-U pair is flanked by two uridine residues, the reactivity occurs only at the 3′ uridine. Radical quenching studies have indicated that sulfate radical, as in the case of guanine oxidation, is involved in uridine oxidation. Although additional studies are required to better characterize the reaction, this paper reports a novel specificity for a chemical probe which may be useful for investigating structural motifs involving G-U pairs in folded RNAs.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>9641979</pmid><doi>10.1006/jmbi.1998.1813</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0003-2803-0626</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Base Composition Base Composition - genetics Base Sequence Biochemistry, Molecular Biology Escherichia coli Escherichia coli - chemistry Free Radicals Free Radicals - metabolism Guanine Guanine - metabolism Life Sciences Magnesium Magnesium - pharmacology Molecular Probes Molecular Sequence Data Mutation Mutation - genetics Nickel Nickel - chemistry nickel complex Nucleic Acid Conformation Oligoribonucleotides Oligoribonucleotides - metabolism Organometallic Compounds Organometallic Compounds - chemistry Organometallic Compounds - metabolism pseudoknot RNA structure RNA, Bacterial RNA, Bacterial - chemistry structural probing Sulfuric Acid Esters Sulfuric Acid Esters - metabolism tmRNA Uridine Uridine - metabolism
title	A nickel complex cleaves uridine in folded RNA structures: application to E. coli tmRNA and related engineered molecules
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