Structure-function relations in oxaloacetate decarboxylase complex. Fluorescence and infrared approaches to monitor oxomalonate and Na(+) binding effect
Oxaloacetate decarboxylase (OAD) is a member of the Na(+) transport decarboxylase enzyme family found exclusively in anaerobic bacteria. OAD of Vibrio cholerae catalyses a key step in citrate fermentation, converting the chemical energy of the decarboxylation reaction into an electrochemical gradien...
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| description | Oxaloacetate decarboxylase (OAD) is a member of the Na(+) transport decarboxylase enzyme family found exclusively in anaerobic bacteria. OAD of Vibrio cholerae catalyses a key step in citrate fermentation, converting the chemical energy of the decarboxylation reaction into an electrochemical gradient of Na(+) ions across the membrane, which drives endergonic membrane reactions such as ATP synthesis, transport and motility. OAD is a membrane-bound enzyme composed of alpha, beta and gamma subunits. The alpha subunit contains the carboxyltransferase catalytic site.
In this report, spectroscopic techniques were used to probe oxomalonate (a competitive inhibitor of OAD with respect to oxaloacetate) and Na(+) effects on the enzyme tryptophan environment and on the secondary structure of the OAD complex, as well as the importance of each subunit in the catalytic mechanism. An intrinsic fluorescence approach, Red Edge Excitation Shift (REES), indicated that solvent molecule mobility in the vicinity of OAD tryptophans was more restricted in the presence of oxomalonate. It also demonstrated that, although the structure of OAD is sensitive to the presence of NaCl, oxomalonate was able to bind to the enzyme even in the absence of Na(+). REES changes due to oxomalonate binding were also observed with the alphagamma and alpha subunits. Infrared spectra showed that OAD, alphagamma and alpha subunits have a main component band centered between 1655 and 1650 cm(-1) characteristic of a high content of alpha helix structures. Addition of oxomalonate induced a shift of the amide-I band of OAD toward higher wavenumbers, interpreted as a slight decrease of beta sheet structures and a concomitant increase of alpha helix structures. Oxomalonate binding to alphagamma and alpha subunits also provoked secondary structure variations, but these effects were negligible compared to OAD complex.
Oxomalonate binding affects the tryptophan environment of the carboxyltransferase subunit, whereas Na(+) alters the tryptophan environment of the beta subunit, consistent with the function of these subunits within the enzyme complex. Formation of a complex between OAD and its substrates elicits structural changes in the alpha-helical as well as beta-strand secondary structure elements. |
| doi_str_mv | 10.1371/journal.pone.0010935 |
| format | Article |
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In this report, spectroscopic techniques were used to probe oxomalonate (a competitive inhibitor of OAD with respect to oxaloacetate) and Na(+) effects on the enzyme tryptophan environment and on the secondary structure of the OAD complex, as well as the importance of each subunit in the catalytic mechanism. An intrinsic fluorescence approach, Red Edge Excitation Shift (REES), indicated that solvent molecule mobility in the vicinity of OAD tryptophans was more restricted in the presence of oxomalonate. It also demonstrated that, although the structure of OAD is sensitive to the presence of NaCl, oxomalonate was able to bind to the enzyme even in the absence of Na(+). REES changes due to oxomalonate binding were also observed with the alphagamma and alpha subunits. Infrared spectra showed that OAD, alphagamma and alpha subunits have a main component band centered between 1655 and 1650 cm(-1) characteristic of a high content of alpha helix structures. Addition of oxomalonate induced a shift of the amide-I band of OAD toward higher wavenumbers, interpreted as a slight decrease of beta sheet structures and a concomitant increase of alpha helix structures. Oxomalonate binding to alphagamma and alpha subunits also provoked secondary structure variations, but these effects were negligible compared to OAD complex.
Oxomalonate binding affects the tryptophan environment of the carboxyltransferase subunit, whereas Na(+) alters the tryptophan environment of the beta subunit, consistent with the function of these subunits within the enzyme complex. Formation of a complex between OAD and its substrates elicits structural changes in the alpha-helical as well as beta-strand secondary structure elements.</description><identifier>ISSN: 1932-6203</identifier><identifier>EISSN: 1932-6203</identifier><identifier>DOI: 10.1371/journal.pone.0010935</identifier><identifier>PMID: 20543879</identifier><language>eng</language><publisher>United States: Public Library of Science</publisher><subject>Amino acids ; Anaerobic bacteria ; Aqueous solutions ; Archaeoglobus fulgidus ; Bacteria ; Binding ; Biochemistry ; Biochemistry, Molecular Biology ; Biochemistry/Biomacromolecule-Ligand Interactions ; Biochemistry/Experimental Biophysical Methods ; Biochemistry/Membrane Proteins and Energy Transduction ; Carboxy-Lyases - chemistry ; Carboxy-Lyases - metabolism ; Carboxyltransferase ; Catalysis ; Chemical energy ; Chemical synthesis ; Citric acid ; Corrosion inhibitors ; Decarboxylation ; E coli ; Electrochemistry ; Electrophoretic mobility ; Enzymes ; Escherichia coli ; Fermentation ; Fluorescence ; Infrared spectra ; Klebsiella aerogenes ; Klebsiella pneumoniae ; Laboratories ; Life Sciences ; Ligands ; Malonates - metabolism ; Models, Molecular ; Molecular biology ; Oxaloacetate decarboxylase ; Prostheses ; Protein Binding ; Protein structure ; Protein Structure, Secondary ; Proteins ; Secondary structure ; Sodium - metabolism ; Sodium chloride ; Solvents ; Spectrometry, Fluorescence - methods ; Spectrophotometry, Infrared - methods ; Spectrum analysis ; Structure-Activity Relationship ; Structure-function relationships ; Substrates ; Transport ; Tryptophan ; Vibrio cholerae ; Water-borne diseases ; Waterborne diseases</subject><ispartof>PloS one, 2010-06, Vol.5 (6), p.e10935-e10935</ispartof><rights>2010 Granjon et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License: https://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.</rights><rights>Distributed under a Creative Commons Attribution 4.0 International License</rights><rights>Granjon et al. 2010</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c591t-e2b8a60df875aca13617f797994453fdaa5636063318b389821cbe8b8b9d2f3e3</citedby><cites>FETCH-LOGICAL-c591t-e2b8a60df875aca13617f797994453fdaa5636063318b389821cbe8b8b9d2f3e3</cites><orcidid>0000-0001-9371-9580</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://www.ncbi.nlm.nih.gov/pmc/articles/PMC2881705/pdf/$$EPDF$$P50$$Gpubmedcentral$$Hfree_for_read</linktopdf><linktohtml>$$Uhttps://www.ncbi.nlm.nih.gov/pmc/articles/PMC2881705/$$EHTML$$P50$$Gpubmedcentral$$Hfree_for_read</linktohtml><link.rule.ids>230,314,723,776,780,860,881,2096,2915,23847,27903,27904,53769,53771,79346,79347</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/20543879$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink><backlink>$$Uhttps://hal.science/hal-00599375$$DView record in HAL$$Hfree_for_read</backlink></links><search><contributor>Hofmann, Andreas</contributor><creatorcontrib>Granjon, Thierry</creatorcontrib><creatorcontrib>Maniti, Ofelia</creatorcontrib><creatorcontrib>Auchli, Yolanda</creatorcontrib><creatorcontrib>Dahinden, Pius</creatorcontrib><creatorcontrib>Buchet, René</creatorcontrib><creatorcontrib>Marcillat, Olivier</creatorcontrib><creatorcontrib>Dimroth, Peter</creatorcontrib><title>Structure-function relations in oxaloacetate decarboxylase complex. Fluorescence and infrared approaches to monitor oxomalonate and Na(+) binding effect</title><title>PloS one</title><addtitle>PLoS One</addtitle><description>Oxaloacetate decarboxylase (OAD) is a member of the Na(+) transport decarboxylase enzyme family found exclusively in anaerobic bacteria. OAD of Vibrio cholerae catalyses a key step in citrate fermentation, converting the chemical energy of the decarboxylation reaction into an electrochemical gradient of Na(+) ions across the membrane, which drives endergonic membrane reactions such as ATP synthesis, transport and motility. OAD is a membrane-bound enzyme composed of alpha, beta and gamma subunits. The alpha subunit contains the carboxyltransferase catalytic site.
In this report, spectroscopic techniques were used to probe oxomalonate (a competitive inhibitor of OAD with respect to oxaloacetate) and Na(+) effects on the enzyme tryptophan environment and on the secondary structure of the OAD complex, as well as the importance of each subunit in the catalytic mechanism. An intrinsic fluorescence approach, Red Edge Excitation Shift (REES), indicated that solvent molecule mobility in the vicinity of OAD tryptophans was more restricted in the presence of oxomalonate. It also demonstrated that, although the structure of OAD is sensitive to the presence of NaCl, oxomalonate was able to bind to the enzyme even in the absence of Na(+). REES changes due to oxomalonate binding were also observed with the alphagamma and alpha subunits. Infrared spectra showed that OAD, alphagamma and alpha subunits have a main component band centered between 1655 and 1650 cm(-1) characteristic of a high content of alpha helix structures. Addition of oxomalonate induced a shift of the amide-I band of OAD toward higher wavenumbers, interpreted as a slight decrease of beta sheet structures and a concomitant increase of alpha helix structures. Oxomalonate binding to alphagamma and alpha subunits also provoked secondary structure variations, but these effects were negligible compared to OAD complex.
Oxomalonate binding affects the tryptophan environment of the carboxyltransferase subunit, whereas Na(+) alters the tryptophan environment of the beta subunit, consistent with the function of these subunits within the enzyme complex. Formation of a complex between OAD and its substrates elicits structural changes in the alpha-helical as well as beta-strand secondary structure elements.</description><subject>Amino acids</subject><subject>Anaerobic bacteria</subject><subject>Aqueous solutions</subject><subject>Archaeoglobus fulgidus</subject><subject>Bacteria</subject><subject>Binding</subject><subject>Biochemistry</subject><subject>Biochemistry, Molecular Biology</subject><subject>Biochemistry/Biomacromolecule-Ligand Interactions</subject><subject>Biochemistry/Experimental Biophysical Methods</subject><subject>Biochemistry/Membrane Proteins and Energy Transduction</subject><subject>Carboxy-Lyases - chemistry</subject><subject>Carboxy-Lyases - metabolism</subject><subject>Carboxyltransferase</subject><subject>Catalysis</subject><subject>Chemical energy</subject><subject>Chemical synthesis</subject><subject>Citric acid</subject><subject>Corrosion inhibitors</subject><subject>Decarboxylation</subject><subject>E coli</subject><subject>Electrochemistry</subject><subject>Electrophoretic mobility</subject><subject>Enzymes</subject><subject>Escherichia coli</subject><subject>Fermentation</subject><subject>Fluorescence</subject><subject>Infrared spectra</subject><subject>Klebsiella aerogenes</subject><subject>Klebsiella pneumoniae</subject><subject>Laboratories</subject><subject>Life Sciences</subject><subject>Ligands</subject><subject>Malonates - metabolism</subject><subject>Models, Molecular</subject><subject>Molecular biology</subject><subject>Oxaloacetate decarboxylase</subject><subject>Prostheses</subject><subject>Protein Binding</subject><subject>Protein structure</subject><subject>Protein Structure, Secondary</subject><subject>Proteins</subject><subject>Secondary structure</subject><subject>Sodium - metabolism</subject><subject>Sodium chloride</subject><subject>Solvents</subject><subject>Spectrometry, Fluorescence - methods</subject><subject>Spectrophotometry, Infrared - methods</subject><subject>Spectrum analysis</subject><subject>Structure-Activity Relationship</subject><subject>Structure-function relationships</subject><subject>Substrates</subject><subject>Transport</subject><subject>Tryptophan</subject><subject>Vibrio cholerae</subject><subject>Water-borne diseases</subject><subject>Waterborne diseases</subject><issn>1932-6203</issn><issn>1932-6203</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2010</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>BENPR</sourceid><sourceid>DOA</sourceid><recordid>eNqFUl1rFDEUHUSxdfUfiAZ80CK75mNmkrwIpVhbWPRBfQ6ZzJ3dWTLJNsmU7T_x55pxt6Utgk-53Jxz7uXcUxSvCV4QxsmnjR-D03ax9Q4WGBMsWfWkOCaS0XlNMXt6rz4qXsS4wbhioq6fF0cUVyUTXB4Xv3-kMJo0Bph3ozOp9w4FsHoqIuod8jttvTaQdALUgtGh8bsbqyMg44ethd0CndvRB4gGnAGkXZt5XdABWqS325DZa4goeTR41ycfsqYfsqqbJCf4N_3h4wlqetf2boWg68Ckl8WzTtsIrw7vrPh1_uXn2cV8-f3r5dnpcm4qSdIcaCN0jdtO8EobTVhNeMcll7IsK9a1Wlc1q3HNGBENE1JQYhoQjWhkSzsGbFa83eturY_qYGpUhEpaUiwlzojLPaL1eqO2oR90uFFe9-pvw4eV0iH1xoKiFCi0TdlUUJaam8aUUFbEGOAC5z2z1ufDtLEZoM2OpaDtA9GHP65fq5W_VlQIwvP9ZsXJXmD9iHZxulRTLx9ZSsara5Kx7w_Dgr8aISY19PlI1moHfoyKlzUWFWXi_0jGqBSk5hn57hHy35aVe5QJPsYA3d2qBKspvbcsNaVXHdKbaW_uu3NHuo0r-wPlzPA6</recordid><startdate>20100603</startdate><enddate>20100603</enddate><creator>Granjon, Thierry</creator><creator>Maniti, Ofelia</creator><creator>Auchli, Yolanda</creator><creator>Dahinden, Pius</creator><creator>Buchet, René</creator><creator>Marcillat, Olivier</creator><creator>Dimroth, Peter</creator><general>Public Library of Science</general><general>Public Library of Science (PLoS)</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>3V.</scope><scope>7QG</scope><scope>7QL</scope><scope>7QO</scope><scope>7RV</scope><scope>7SN</scope><scope>7SS</scope><scope>7T5</scope><scope>7TG</scope><scope>7TM</scope><scope>7U9</scope><scope>7X2</scope><scope>7X7</scope><scope>7XB</scope><scope>88E</scope><scope>8AO</scope><scope>8C1</scope><scope>8FD</scope><scope>8FE</scope><scope>8FG</scope><scope>8FH</scope><scope>8FI</scope><scope>8FJ</scope><scope>8FK</scope><scope>ABJCF</scope><scope>ABUWG</scope><scope>AEUYN</scope><scope>AFKRA</scope><scope>ARAPS</scope><scope>ATCPS</scope><scope>AZQEC</scope><scope>BBNVY</scope><scope>BENPR</scope><scope>BGLVJ</scope><scope>BHPHI</scope><scope>C1K</scope><scope>CCPQU</scope><scope>D1I</scope><scope>DWQXO</scope><scope>FR3</scope><scope>FYUFA</scope><scope>GHDGH</scope><scope>GNUQQ</scope><scope>H94</scope><scope>HCIFZ</scope><scope>K9.</scope><scope>KB.</scope><scope>KB0</scope><scope>KL.</scope><scope>L6V</scope><scope>LK8</scope><scope>M0K</scope><scope>M0S</scope><scope>M1P</scope><scope>M7N</scope><scope>M7P</scope><scope>M7S</scope><scope>NAPCQ</scope><scope>P5Z</scope><scope>P62</scope><scope>P64</scope><scope>PATMY</scope><scope>PDBOC</scope><scope>PIMPY</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PRINS</scope><scope>PTHSS</scope><scope>PYCSY</scope><scope>RC3</scope><scope>7X8</scope><scope>1XC</scope><scope>5PM</scope><scope>DOA</scope><orcidid>https://orcid.org/0000-0001-9371-9580</orcidid></search><sort><creationdate>20100603</creationdate><title>Structure-function relations in oxaloacetate decarboxylase complex. 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Academic</collection><collection>Hyper Article en Ligne (HAL)</collection><collection>PubMed Central (Full Participant titles)</collection><collection>DOAJ Directory of Open Access Journals</collection><jtitle>PloS one</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Granjon, Thierry</au><au>Maniti, Ofelia</au><au>Auchli, Yolanda</au><au>Dahinden, Pius</au><au>Buchet, René</au><au>Marcillat, Olivier</au><au>Dimroth, Peter</au><au>Hofmann, Andreas</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Structure-function relations in oxaloacetate decarboxylase complex. Fluorescence and infrared approaches to monitor oxomalonate and Na(+) binding effect</atitle><jtitle>PloS one</jtitle><addtitle>PLoS One</addtitle><date>2010-06-03</date><risdate>2010</risdate><volume>5</volume><issue>6</issue><spage>e10935</spage><epage>e10935</epage><pages>e10935-e10935</pages><issn>1932-6203</issn><eissn>1932-6203</eissn><abstract>Oxaloacetate decarboxylase (OAD) is a member of the Na(+) transport decarboxylase enzyme family found exclusively in anaerobic bacteria. OAD of Vibrio cholerae catalyses a key step in citrate fermentation, converting the chemical energy of the decarboxylation reaction into an electrochemical gradient of Na(+) ions across the membrane, which drives endergonic membrane reactions such as ATP synthesis, transport and motility. OAD is a membrane-bound enzyme composed of alpha, beta and gamma subunits. The alpha subunit contains the carboxyltransferase catalytic site.
In this report, spectroscopic techniques were used to probe oxomalonate (a competitive inhibitor of OAD with respect to oxaloacetate) and Na(+) effects on the enzyme tryptophan environment and on the secondary structure of the OAD complex, as well as the importance of each subunit in the catalytic mechanism. An intrinsic fluorescence approach, Red Edge Excitation Shift (REES), indicated that solvent molecule mobility in the vicinity of OAD tryptophans was more restricted in the presence of oxomalonate. It also demonstrated that, although the structure of OAD is sensitive to the presence of NaCl, oxomalonate was able to bind to the enzyme even in the absence of Na(+). REES changes due to oxomalonate binding were also observed with the alphagamma and alpha subunits. Infrared spectra showed that OAD, alphagamma and alpha subunits have a main component band centered between 1655 and 1650 cm(-1) characteristic of a high content of alpha helix structures. Addition of oxomalonate induced a shift of the amide-I band of OAD toward higher wavenumbers, interpreted as a slight decrease of beta sheet structures and a concomitant increase of alpha helix structures. Oxomalonate binding to alphagamma and alpha subunits also provoked secondary structure variations, but these effects were negligible compared to OAD complex.
Oxomalonate binding affects the tryptophan environment of the carboxyltransferase subunit, whereas Na(+) alters the tryptophan environment of the beta subunit, consistent with the function of these subunits within the enzyme complex. Formation of a complex between OAD and its substrates elicits structural changes in the alpha-helical as well as beta-strand secondary structure elements.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>20543879</pmid><doi>10.1371/journal.pone.0010935</doi><orcidid>https://orcid.org/0000-0001-9371-9580</orcidid><oa>free_for_read</oa></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 1932-6203 |
| ispartof | PloS one, 2010-06, Vol.5 (6), p.e10935-e10935 |
| issn | 1932-6203 1932-6203 |
| language | eng |
| recordid | cdi_plos_journals_1292420990 |
| source | MEDLINE; DOAJ Directory of Open Access Journals; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; PubMed Central; Free Full-Text Journals in Chemistry; Public Library of Science (PLoS) |
| subjects | Amino acids Anaerobic bacteria Aqueous solutions Archaeoglobus fulgidus Bacteria Binding Biochemistry Biochemistry, Molecular Biology Biochemistry/Biomacromolecule-Ligand Interactions Biochemistry/Experimental Biophysical Methods Biochemistry/Membrane Proteins and Energy Transduction Carboxy-Lyases - chemistry Carboxy-Lyases - metabolism Carboxyltransferase Catalysis Chemical energy Chemical synthesis Citric acid Corrosion inhibitors Decarboxylation E coli Electrochemistry Electrophoretic mobility Enzymes Escherichia coli Fermentation Fluorescence Infrared spectra Klebsiella aerogenes Klebsiella pneumoniae Laboratories Life Sciences Ligands Malonates - metabolism Models, Molecular Molecular biology Oxaloacetate decarboxylase Prostheses Protein Binding Protein structure Protein Structure, Secondary Proteins Secondary structure Sodium - metabolism Sodium chloride Solvents Spectrometry, Fluorescence - methods Spectrophotometry, Infrared - methods Spectrum analysis Structure-Activity Relationship Structure-function relationships Substrates Transport Tryptophan Vibrio cholerae Water-borne diseases Waterborne diseases |
| title | Structure-function relations in oxaloacetate decarboxylase complex. Fluorescence and infrared approaches to monitor oxomalonate and Na(+) binding effect |
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