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Mechanism of Cph1 Phytochrome Assembly from Stopped-Flow Kinetics and Circular Dichroism
The kinetics and mechanism of the autocatalytic assembly of holo-Cph1 phytochrome (from Synechocystis) from the apoprotein and the bilin chromophores phycocyanobilin (PCB) and phycoerythrobilin (PEB) were investigated by stopped flow and circular dichroism. At 1:1 stoichiometry, pH 7.9, and 10 °C, S...
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| Published in: | Biochemistry (Easton) 2003-11, Vol.42 (46), p.13684-13697 |
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| container_end_page | 13697 |
| container_issue | 46 |
| container_start_page | 13684 |
| container_title | Biochemistry (Easton) |
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| creator | Borucki, Berthold Otto, Harald Rottwinkel, Gregor Hughes, Jonathan Heyn, Maarten P Lamparter, Tilman |
| description | The kinetics and mechanism of the autocatalytic assembly of holo-Cph1 phytochrome (from Synechocystis) from the apoprotein and the bilin chromophores phycocyanobilin (PCB) and phycoerythrobilin (PEB) were investigated by stopped flow and circular dichroism. At 1:1 stoichiometry, pH 7.9, and 10 °C, SVD analysis of the kinetic data for PCB revealed three spectral components involving three transitions with time constants τ1 ∼ 150 ms, τ2 ∼ 2.5 s, and τ3 ∼ 50 s. τ1 was associated with a major red shift and transfer of oscillator strength from the Soret region to the 680 nm region. When the sulfhydryl group of cysteine 259 was blocked with iodoacetamide, preventing the formation of a covalent adduct, a noncovalent red-shifted complex (680 nm) was formed with a time constant of 200 ms. τ1 could thus be assigned to the formation of a noncovalent complex. The absorption changes during τ1 are due to the formation of the extended conformation of the linear tetrapyrrole and to its protonation in the binding pocket. From the concentration and pH dependence of the kinetics we obtained a value of 1.5 μM for the K D of this noncovalent complex and a value of 8.4 for the pK a of the proton donor. The τ2 component was associated with a blue shift of about 25 nm and was attributed to the formation of the covalent bond (Pr), accompanied with the loss of the 3−3‘ double bond to ring A. τ3 was due to photoconversion to Pfr. For PEB, which is not photochromic, the formation of the noncovalent complex is faster (τ1 = 70 ms), but the covalent bond formation is about 80 times slower (τ2 = 200 s) than with the natural chromophore PCB. The CD spectra of the PCB adduct in the 250−800 nm range show that the chromophore geometries in Pr and Pfr are similar to those in plant phytochrome. The opposite rotational strengths of Pr and Pfr in the longest wavelength band suggest that the photoisomerization induces a reversal of the chirality. The Cph1 complex with noncovalently bound PCB was still photochromic when cysteine 259 was blocked with IAA or with the bulkier IAF. The covalent linkage to cysteine 259 is thus not required for photoconversion. The CD spectra of the noncovalently bound PCB in Pr- and Pfr-like states are qualitatively similar to those of the covalent adducts, suggesting analogous structures in the binding pocket. The noncovalent interactions with the binding pocket are apparently sufficient to hold the chromophore in the appropriate geometry for photoisomerization. |
| doi_str_mv | 10.1021/bi035511n |
| format | article |
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At 1:1 stoichiometry, pH 7.9, and 10 °C, SVD analysis of the kinetic data for PCB revealed three spectral components involving three transitions with time constants τ1 ∼ 150 ms, τ2 ∼ 2.5 s, and τ3 ∼ 50 s. τ1 was associated with a major red shift and transfer of oscillator strength from the Soret region to the 680 nm region. When the sulfhydryl group of cysteine 259 was blocked with iodoacetamide, preventing the formation of a covalent adduct, a noncovalent red-shifted complex (680 nm) was formed with a time constant of 200 ms. τ1 could thus be assigned to the formation of a noncovalent complex. The absorption changes during τ1 are due to the formation of the extended conformation of the linear tetrapyrrole and to its protonation in the binding pocket. From the concentration and pH dependence of the kinetics we obtained a value of 1.5 μM for the K D of this noncovalent complex and a value of 8.4 for the pK a of the proton donor. The τ2 component was associated with a blue shift of about 25 nm and was attributed to the formation of the covalent bond (Pr), accompanied with the loss of the 3−3‘ double bond to ring A. τ3 was due to photoconversion to Pfr. For PEB, which is not photochromic, the formation of the noncovalent complex is faster (τ1 = 70 ms), but the covalent bond formation is about 80 times slower (τ2 = 200 s) than with the natural chromophore PCB. The CD spectra of the PCB adduct in the 250−800 nm range show that the chromophore geometries in Pr and Pfr are similar to those in plant phytochrome. The opposite rotational strengths of Pr and Pfr in the longest wavelength band suggest that the photoisomerization induces a reversal of the chirality. The Cph1 complex with noncovalently bound PCB was still photochromic when cysteine 259 was blocked with IAA or with the bulkier IAF. The covalent linkage to cysteine 259 is thus not required for photoconversion. The CD spectra of the noncovalently bound PCB in Pr- and Pfr-like states are qualitatively similar to those of the covalent adducts, suggesting analogous structures in the binding pocket. The noncovalent interactions with the binding pocket are apparently sufficient to hold the chromophore in the appropriate geometry for photoisomerization.</description><identifier>ISSN: 0006-2960</identifier><identifier>EISSN: 1520-4995</identifier><identifier>DOI: 10.1021/bi035511n</identifier><identifier>PMID: 14622015</identifier><language>eng</language><publisher>United States: American Chemical Society</publisher><subject>Apoproteins - chemistry ; Bacterial Proteins ; Circular Dichroism ; Cyanobacteria - chemistry ; Data Interpretation, Statistical ; Escherichia coli - metabolism ; Hydrogen-Ion Concentration ; Iodoacetamide - pharmacology ; Kinetics ; Phycobilins ; Phycocyanin - chemistry ; Phycoerythrin - chemistry ; Phytochrome - chemistry ; Protein Kinases - chemistry ; Pyrroles - chemistry ; Spectrophotometry - methods ; Tetrapyrroles</subject><ispartof>Biochemistry (Easton), 2003-11, Vol.42 (46), p.13684-13697</ispartof><rights>Copyright © 2003 American Chemical Society</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a349t-bd479043c92deed59b0fc3cb3d267213909f0070518cedcb86f44b894d81f803</citedby><cites>FETCH-LOGICAL-a349t-bd479043c92deed59b0fc3cb3d267213909f0070518cedcb86f44b894d81f803</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/14622015$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Borucki, Berthold</creatorcontrib><creatorcontrib>Otto, Harald</creatorcontrib><creatorcontrib>Rottwinkel, Gregor</creatorcontrib><creatorcontrib>Hughes, Jonathan</creatorcontrib><creatorcontrib>Heyn, Maarten P</creatorcontrib><creatorcontrib>Lamparter, Tilman</creatorcontrib><title>Mechanism of Cph1 Phytochrome Assembly from Stopped-Flow Kinetics and Circular Dichroism</title><title>Biochemistry (Easton)</title><addtitle>Biochemistry</addtitle><description>The kinetics and mechanism of the autocatalytic assembly of holo-Cph1 phytochrome (from Synechocystis) from the apoprotein and the bilin chromophores phycocyanobilin (PCB) and phycoerythrobilin (PEB) were investigated by stopped flow and circular dichroism. At 1:1 stoichiometry, pH 7.9, and 10 °C, SVD analysis of the kinetic data for PCB revealed three spectral components involving three transitions with time constants τ1 ∼ 150 ms, τ2 ∼ 2.5 s, and τ3 ∼ 50 s. τ1 was associated with a major red shift and transfer of oscillator strength from the Soret region to the 680 nm region. When the sulfhydryl group of cysteine 259 was blocked with iodoacetamide, preventing the formation of a covalent adduct, a noncovalent red-shifted complex (680 nm) was formed with a time constant of 200 ms. τ1 could thus be assigned to the formation of a noncovalent complex. The absorption changes during τ1 are due to the formation of the extended conformation of the linear tetrapyrrole and to its protonation in the binding pocket. From the concentration and pH dependence of the kinetics we obtained a value of 1.5 μM for the K D of this noncovalent complex and a value of 8.4 for the pK a of the proton donor. The τ2 component was associated with a blue shift of about 25 nm and was attributed to the formation of the covalent bond (Pr), accompanied with the loss of the 3−3‘ double bond to ring A. τ3 was due to photoconversion to Pfr. For PEB, which is not photochromic, the formation of the noncovalent complex is faster (τ1 = 70 ms), but the covalent bond formation is about 80 times slower (τ2 = 200 s) than with the natural chromophore PCB. The CD spectra of the PCB adduct in the 250−800 nm range show that the chromophore geometries in Pr and Pfr are similar to those in plant phytochrome. The opposite rotational strengths of Pr and Pfr in the longest wavelength band suggest that the photoisomerization induces a reversal of the chirality. The Cph1 complex with noncovalently bound PCB was still photochromic when cysteine 259 was blocked with IAA or with the bulkier IAF. The covalent linkage to cysteine 259 is thus not required for photoconversion. The CD spectra of the noncovalently bound PCB in Pr- and Pfr-like states are qualitatively similar to those of the covalent adducts, suggesting analogous structures in the binding pocket. The noncovalent interactions with the binding pocket are apparently sufficient to hold the chromophore in the appropriate geometry for photoisomerization.</description><subject>Apoproteins - chemistry</subject><subject>Bacterial Proteins</subject><subject>Circular Dichroism</subject><subject>Cyanobacteria - chemistry</subject><subject>Data Interpretation, Statistical</subject><subject>Escherichia coli - metabolism</subject><subject>Hydrogen-Ion Concentration</subject><subject>Iodoacetamide - pharmacology</subject><subject>Kinetics</subject><subject>Phycobilins</subject><subject>Phycocyanin - chemistry</subject><subject>Phycoerythrin - chemistry</subject><subject>Phytochrome - chemistry</subject><subject>Protein Kinases - chemistry</subject><subject>Pyrroles - chemistry</subject><subject>Spectrophotometry - methods</subject><subject>Tetrapyrroles</subject><issn>0006-2960</issn><issn>1520-4995</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2003</creationdate><recordtype>article</recordtype><recordid>eNptkE1P3DAQhq2qqCy0B_4A8qVIPYSOv-L4iBa2lFIViT1wsxzb0ZomcbAT0f33BO2KXjiNXs0z70gPQicEzglQ8r0OwIQgpP-AFkRQKLhS4iNaAEBZUFXCITrK-XGOHCT_hA4JLykFIhbo4be3G9OH3OHY4OWwIfhusx2j3aTYeXyRs-_qdoubOeL7MQ6Dd8Wqjc_4V-j9GGzGpnd4GZKdWpPwZXi9nOs-o4PGtNl_2c9jtF5drZfXxe2fHz-XF7eFYVyNRe24VMCZVdR574SqobHM1szRUlLCFKgGQIIglfXO1lXZcF5XiruKNBWwY3S2qx1SfJp8HnUXsvVta3ofp6wlYVKSqpzBbzvQpphz8o0eUuhM2moC-tWifrM4s6f70qnuvPtP7rXNQLEDQh79v7e9SX91KZkUen13rx9u1lSuqNDXM_91xxub9WOcUj8reefxCyymh2M</recordid><startdate>20031125</startdate><enddate>20031125</enddate><creator>Borucki, Berthold</creator><creator>Otto, Harald</creator><creator>Rottwinkel, Gregor</creator><creator>Hughes, Jonathan</creator><creator>Heyn, Maarten P</creator><creator>Lamparter, Tilman</creator><general>American Chemical Society</general><scope>BSCLL</scope><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></search><sort><creationdate>20031125</creationdate><title>Mechanism of Cph1 Phytochrome Assembly from Stopped-Flow Kinetics and Circular Dichroism</title><author>Borucki, Berthold ; Otto, Harald ; Rottwinkel, Gregor ; Hughes, Jonathan ; Heyn, Maarten P ; Lamparter, Tilman</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a349t-bd479043c92deed59b0fc3cb3d267213909f0070518cedcb86f44b894d81f803</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2003</creationdate><topic>Apoproteins - chemistry</topic><topic>Bacterial Proteins</topic><topic>Circular Dichroism</topic><topic>Cyanobacteria - chemistry</topic><topic>Data Interpretation, Statistical</topic><topic>Escherichia coli - metabolism</topic><topic>Hydrogen-Ion Concentration</topic><topic>Iodoacetamide - pharmacology</topic><topic>Kinetics</topic><topic>Phycobilins</topic><topic>Phycocyanin - chemistry</topic><topic>Phycoerythrin - chemistry</topic><topic>Phytochrome - chemistry</topic><topic>Protein Kinases - chemistry</topic><topic>Pyrroles - chemistry</topic><topic>Spectrophotometry - methods</topic><topic>Tetrapyrroles</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Borucki, Berthold</creatorcontrib><creatorcontrib>Otto, Harald</creatorcontrib><creatorcontrib>Rottwinkel, Gregor</creatorcontrib><creatorcontrib>Hughes, Jonathan</creatorcontrib><creatorcontrib>Heyn, Maarten P</creatorcontrib><creatorcontrib>Lamparter, Tilman</creatorcontrib><collection>Istex</collection><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><jtitle>Biochemistry (Easton)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Borucki, Berthold</au><au>Otto, Harald</au><au>Rottwinkel, Gregor</au><au>Hughes, Jonathan</au><au>Heyn, Maarten P</au><au>Lamparter, Tilman</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Mechanism of Cph1 Phytochrome Assembly from Stopped-Flow Kinetics and Circular Dichroism</atitle><jtitle>Biochemistry (Easton)</jtitle><addtitle>Biochemistry</addtitle><date>2003-11-25</date><risdate>2003</risdate><volume>42</volume><issue>46</issue><spage>13684</spage><epage>13697</epage><pages>13684-13697</pages><issn>0006-2960</issn><eissn>1520-4995</eissn><abstract>The kinetics and mechanism of the autocatalytic assembly of holo-Cph1 phytochrome (from Synechocystis) from the apoprotein and the bilin chromophores phycocyanobilin (PCB) and phycoerythrobilin (PEB) were investigated by stopped flow and circular dichroism. At 1:1 stoichiometry, pH 7.9, and 10 °C, SVD analysis of the kinetic data for PCB revealed three spectral components involving three transitions with time constants τ1 ∼ 150 ms, τ2 ∼ 2.5 s, and τ3 ∼ 50 s. τ1 was associated with a major red shift and transfer of oscillator strength from the Soret region to the 680 nm region. When the sulfhydryl group of cysteine 259 was blocked with iodoacetamide, preventing the formation of a covalent adduct, a noncovalent red-shifted complex (680 nm) was formed with a time constant of 200 ms. τ1 could thus be assigned to the formation of a noncovalent complex. The absorption changes during τ1 are due to the formation of the extended conformation of the linear tetrapyrrole and to its protonation in the binding pocket. From the concentration and pH dependence of the kinetics we obtained a value of 1.5 μM for the K D of this noncovalent complex and a value of 8.4 for the pK a of the proton donor. The τ2 component was associated with a blue shift of about 25 nm and was attributed to the formation of the covalent bond (Pr), accompanied with the loss of the 3−3‘ double bond to ring A. τ3 was due to photoconversion to Pfr. For PEB, which is not photochromic, the formation of the noncovalent complex is faster (τ1 = 70 ms), but the covalent bond formation is about 80 times slower (τ2 = 200 s) than with the natural chromophore PCB. The CD spectra of the PCB adduct in the 250−800 nm range show that the chromophore geometries in Pr and Pfr are similar to those in plant phytochrome. The opposite rotational strengths of Pr and Pfr in the longest wavelength band suggest that the photoisomerization induces a reversal of the chirality. The Cph1 complex with noncovalently bound PCB was still photochromic when cysteine 259 was blocked with IAA or with the bulkier IAF. The covalent linkage to cysteine 259 is thus not required for photoconversion. The CD spectra of the noncovalently bound PCB in Pr- and Pfr-like states are qualitatively similar to those of the covalent adducts, suggesting analogous structures in the binding pocket. The noncovalent interactions with the binding pocket are apparently sufficient to hold the chromophore in the appropriate geometry for photoisomerization.</abstract><cop>United States</cop><pub>American Chemical Society</pub><pmid>14622015</pmid><doi>10.1021/bi035511n</doi><tpages>14</tpages></addata></record> |
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| ispartof | Biochemistry (Easton), 2003-11, Vol.42 (46), p.13684-13697 |
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| source | American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list) |
| subjects | Apoproteins - chemistry Bacterial Proteins Circular Dichroism Cyanobacteria - chemistry Data Interpretation, Statistical Escherichia coli - metabolism Hydrogen-Ion Concentration Iodoacetamide - pharmacology Kinetics Phycobilins Phycocyanin - chemistry Phycoerythrin - chemistry Phytochrome - chemistry Protein Kinases - chemistry Pyrroles - chemistry Spectrophotometry - methods Tetrapyrroles |
| title | Mechanism of Cph1 Phytochrome Assembly from Stopped-Flow Kinetics and Circular Dichroism |
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