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Introduction of Histidine Analogs Leads to Enhanced Proton Transfer in Carbonic Anhydrase V

The rate-limiting step in the catalysis of the hydration of CO2by carbonic anhydrase involves transfer of protons between zinc-bound water and solution. This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to pr...

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Published in:	Archives of biochemistry and biophysics 1999-01, Vol.361 (2), p.264-270
Main Authors:	Earnhardt, J.Nicole, Wright, S.Kirk, Qian, Minzhang, Tu, Chingkuang, Laipis, Philip J., Viola, Ronald E., Silverman, David N.
Format:	Article
Language:	English
Subjects:	Animals carbon dioxide carbonic anhydrase Carbonic Anhydrases - genetics Carbonic Anhydrases - metabolism Catalysis chemical modification Cysteine - genetics Cysteine - metabolism Histidine - analogs & derivatives Histidine - metabolism Mice Mice, Inbred BALB C Mutagenesis, Site-Directed Oxygen Isotopes proton transfer Protons Substrate Specificity unnatural amino acid
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cited_by	cdi_FETCH-LOGICAL-c339t-bc80a044418b2c19d0d0a84112c31fd7e44c0d419a62871866a7f4bfa6ddaeb3
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container_title	Archives of biochemistry and biophysics
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creator	Earnhardt, J.Nicole Wright, S.Kirk Qian, Minzhang Tu, Chingkuang Laipis, Philip J. Viola, Ronald E. Silverman, David N.
description	The rate-limiting step in the catalysis of the hydration of CO2by carbonic anhydrase involves transfer of protons between zinc-bound water and solution. This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to provide novel internal proton transfer groups that enhance catalysis by murine carbonic anhydrase V (mCA V). This approach involves the site-directed mutation of a targeted residue to a cysteine which is then subsequently reacted with an imidazole analog containing an appropriately positioned leaving group. Compounds examined include 4-bromoethylimidazole (4-BEI), 2-chloromethylimidazole (2-CMI), 4-chloromethylimidazole (4-CMI), and a triazole analog. Two sites in mCA V, Lys 91 and Tyr 131, located on the rim of the active-site cavity have been targeted for the introduction of these imidazole analogs. Modification of the introduced Cys 131 with 4-BEI and 4-CMI resulted in enhancements of up to threefold in catalytic activity. The pH profiles indicate the presence of a new proton shuttle residue of pKanear 5.8, consistent with the introduction of a functional proton transfer group into the active site. This is the first example of incorporation by chemical modification of an unnatural amino acid analog of histidine that can act as a proton shuttle in an enzyme.
doi_str_mv	10.1006/abbi.1998.0984
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This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to provide novel internal proton transfer groups that enhance catalysis by murine carbonic anhydrase V (mCA V). This approach involves the site-directed mutation of a targeted residue to a cysteine which is then subsequently reacted with an imidazole analog containing an appropriately positioned leaving group. Compounds examined include 4-bromoethylimidazole (4-BEI), 2-chloromethylimidazole (2-CMI), 4-chloromethylimidazole (4-CMI), and a triazole analog. Two sites in mCA V, Lys 91 and Tyr 131, located on the rim of the active-site cavity have been targeted for the introduction of these imidazole analogs. Modification of the introduced Cys 131 with 4-BEI and 4-CMI resulted in enhancements of up to threefold in catalytic activity. The pH profiles indicate the presence of a new proton shuttle residue of pKanear 5.8, consistent with the introduction of a functional proton transfer group into the active site. 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This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to provide novel internal proton transfer groups that enhance catalysis by murine carbonic anhydrase V (mCA V). This approach involves the site-directed mutation of a targeted residue to a cysteine which is then subsequently reacted with an imidazole analog containing an appropriately positioned leaving group. Compounds examined include 4-bromoethylimidazole (4-BEI), 2-chloromethylimidazole (2-CMI), 4-chloromethylimidazole (4-CMI), and a triazole analog. Two sites in mCA V, Lys 91 and Tyr 131, located on the rim of the active-site cavity have been targeted for the introduction of these imidazole analogs. Modification of the introduced Cys 131 with 4-BEI and 4-CMI resulted in enhancements of up to threefold in catalytic activity. The pH profiles indicate the presence of a new proton shuttle residue of pKanear 5.8, consistent with the introduction of a functional proton transfer group into the active site. 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This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to provide novel internal proton transfer groups that enhance catalysis by murine carbonic anhydrase V (mCA V). This approach involves the site-directed mutation of a targeted residue to a cysteine which is then subsequently reacted with an imidazole analog containing an appropriately positioned leaving group. Compounds examined include 4-bromoethylimidazole (4-BEI), 2-chloromethylimidazole (2-CMI), 4-chloromethylimidazole (4-CMI), and a triazole analog. Two sites in mCA V, Lys 91 and Tyr 131, located on the rim of the active-site cavity have been targeted for the introduction of these imidazole analogs. Modification of the introduced Cys 131 with 4-BEI and 4-CMI resulted in enhancements of up to threefold in catalytic activity. The pH profiles indicate the presence of a new proton shuttle residue of pKanear 5.8, consistent with the introduction of a functional proton transfer group into the active site. This is the first example of incorporation by chemical modification of an unnatural amino acid analog of histidine that can act as a proton shuttle in an enzyme.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><pmid>9882455</pmid><doi>10.1006/abbi.1998.0984</doi><tpages>7</tpages></addata></record>
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subjects	Animals carbon dioxide carbonic anhydrase Carbonic Anhydrases - genetics Carbonic Anhydrases - metabolism Catalysis chemical modification Cysteine - genetics Cysteine - metabolism Histidine - analogs & derivatives Histidine - metabolism Mice Mice, Inbred BALB C Mutagenesis, Site-Directed Oxygen Isotopes proton transfer Protons Substrate Specificity unnatural amino acid
title	Introduction of Histidine Analogs Leads to Enhanced Proton Transfer in Carbonic Anhydrase V
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