Metal Binding Specificity in Carbonic Anhydrase Is Influenced by Conserved Hydrophobic Core Residues

Metal Binding Specificity in Carbonic Anhydrase Is Influenced by Conserved Hydrophobic Core Residues

The role of highly conserved aromatic residues surrounding the zinc binding site of human carbonic anhydrase II (CAII) in determining the metal ion binding specificity of this enzyme has been examined by mutagenesis. Residues F93, F95, and W97 are located along a β-strand containing two residues tha...

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Bibliographic Details
Published in:Biochemistry (Easton) Vol. 38; no. 28; pp. 9054 - 9062
Main Authors: Hunt, Jennifer A, Ahmed, Mahiuddin, Fierke, Carol A
Format: Journal Article
Language:English
Published: United States American Chemical Society 13-07-1999
Subjects:
Amino Acids - chemistry
Amino Acids - genetics
Amino Acids - metabolism
Apoenzymes - chemistry
Apoenzymes - metabolism
Binding Sites
Carbonic Anhydrases - chemistry
Carbonic Anhydrases - genetics
Carbonic Anhydrases - metabolism
Cobalt - metabolism
Conserved Sequence
Copper - metabolism
Enzyme Stability - genetics
Histidine - metabolism
Humans
Kinetics
Metalloproteins - chemistry
Metalloproteins - genetics
Metalloproteins - metabolism
Models, Molecular
Mutagenesis, Insertional
Phenylalanine - metabolism
Protein Denaturation
Spectrum Analysis
Substrate Specificity - genetics
Tryptophan - metabolism
Zinc - chemistry
Zinc - metabolism
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Summary:The role of highly conserved aromatic residues surrounding the zinc binding site of human carbonic anhydrase II (CAII) in determining the metal ion binding specificity of this enzyme has been examined by mutagenesis. Residues F93, F95, and W97 are located along a β-strand containing two residues that coordinate zinc, H94 and H96, and these aromatic amino acids contribute to the high zinc affinity and slow zinc dissociation rate constant of CAII [Hunt, J. A., and Fierke, C. A. (1997) J. Biol. Chem. 272, 20364−20372]. Substitutions of these aromatic amino acids with smaller side chains enhance the copper affinity (up to 100-fold) while decreasing the affinity of both cobalt and zinc, thereby altering the metal binding specificity up to 104-fold. Furthermore, the free energy of the stability of native CAII, determined by solvent-induced denaturation, correlates positively with increased hydrophobicity of the amino acids at positions 93, 95, and 97 as well as with cobalt and zinc affinity. Conversely, increased copper affinity correlates with decreased protein stability. Zinc specificity is therefore enhanced by formation of the native enzyme structure. These data suggest that the hydrophobic cluster in CAII is important for orienting the histidine residues to stabilize metals bound with a distorted tetrahedral geometry and to destabilize the trigonal bipyramidal geometry of bound copper. Knowledge of the structural factors that lead to high metal ion specificity will aid in the design of metal ion biosensors and de novo catalytic sites.
Bibliography:Supported by National Institutes of Health (Grant GM40602) and the Office of Naval Research. J.A.H. was partially supported by an NIH Postdoctoral Fellowship (GM17467).
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istex:FF58ED35862B295A0DE720A65401324F75390F94
ISSN:0006-2960
1520-4995
DOI:10.1021/bi9900166