1fsr Citations

Structural influence of hydrophobic core residues on metal binding and specificity in carbonic anhydrase II.

Cox JD, Hunt JA, Compher KM, Fierke CA, Christianson DW
Biochemistry 39 13687-94 (2000)
Related entries: 1fql, 1fqm, 1fqn, 1fqr, 1fr4, 1fr7, 1fsn, 1fsq

Cited: 18 times
EuropePMC logo PMID: 11076507

Abstract

Aromatic residues in the hydrophobic core of human carbonic anhydrase II (CAII) influence metal ion binding in the active site. Residues F93, F95, and W97 are contained in a beta-strand that also contains two zinc ligands, H94 and H96. The 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]. Substitution of these aromatic amino acids with smaller side chains enhances Cu(2+) affinity while decreasing Co(2+) and Zn(2+) affinity [Hunt, J. A., Mahiuddin, A., & Fierke, C. A. (1999) Biochemistry 38, 9054-9062]. Here, X-ray crystal structures of zinc-bound F93I/F95M/W97V and F93S/F95L/W97M CAIIs reveal the introduction of new cavities in the hydrophobic core, compensatory movements of surrounding side chains, and the incorporation of buried water molecules; nevertheless, the enzyme maintains tetrahedral zinc coordination geometry. However, a conformational change of direct metal ligand H94 as well as indirect (i.e., "second-shell") ligand Q92 accompanies metal release in both F93I/F95M/W97V and F93S/F95L/W97M CAIIs, thereby eliminating preorientation of the histidine ligands with tetrahedral geometry in the apoenzyme. Only one cobalt-bound variant, F93I/F95M/W97V CAII, maintains tetrahedral metal coordination geometry; F93S/F95L/W97M CAII binds Co(2+) with trigonal bipyramidal coordination geometry due to the addition of azide anion to the metal coordination polyhedron. The copper-bound variants exhibit either square pyramidal or trigonal bipyramidal metal coordination geometry due to the addition of a second solvent molecule to the metal coordination polyhedron. The key finding of this work is that aromatic core residues serve as anchors that help to preorient direct and second-shell ligands to optimize zinc binding geometry and destabilize alternative geometries. These geometrical constraints are likely a main determinant of the enhanced zinc/copper specificity of CAII as compared to small molecule chelators.

Reviews citing this publication (5)

  1. Carbonic anhydrase as a model for biophysical and physical-organic studies of proteins and protein-ligand binding. Krishnamurthy VM, Kaufman GK, Urbach AR, Gitlin I, Gudiksen KL, Weibel DB, Whitesides GM. Chem Rev 108 946-1051 (2008)
  2. Arsenate replacing phosphate: alternative life chemistries and ion promiscuity. Tawfik DS, Viola RE. Biochemistry 50 1128-1134 (2011)
  3. Metallo-β-lactamases in the Age of Multidrug Resistance: From Structure and Mechanism to Evolution, Dissemination, and Inhibitor Design. Bahr G, González LJ, Vila AJ. Chem Rev 121 7957-8094 (2021)
  4. Carbonic anhydrase II-based metal ion sensing: Advances and new perspectives. Hurst TK, Wang D, Thompson RB, Fierke CA. Biochim Biophys Acta 1804 393-403 (2010)
  5. Thermodynamic, kinetic, and structural parameterization of human carbonic anhydrase interactions toward enhanced inhibitor design. Linkuvienė V, Zubrienė A, Manakova E, Petrauskas V, Baranauskienė L, Zakšauskas A, Smirnov A, Gražulis S, Ladbury JE, Matulis D. Q Rev Biophys 51 e10 (2018)

Articles citing this publication (13)

  1. Clinical Variants of New Delhi Metallo-β-Lactamase Are Evolving To Overcome Zinc Scarcity. Stewart AC, Bethel CR, VanPelt J, Bergstrom A, Cheng Z, Miller CG, Williams C, Poth R, Morris M, Lahey O, Nix JC, Tierney DL, Page RC, Crowder MW, Bonomo RA, Fast W. ACS Infect Dis 3 927-940 (2017)
  2. Exploring local flexibility/rigidity in psychrophilic and mesophilic carbonic anhydrases. Chiuri R, Maiorano G, Rizzello A, del Mercato LL, Cingolani R, Rinaldi R, Maffia M, Pompa PP. Biophys J 96 1586-1596 (2009)
  3. Apo-human carbonic anhydrase II revisited: implications of the loss of a metal in protein structure, stability, and solvent network. Avvaru BS, Busby SA, Chalmers MJ, Griffin PR, Venkatakrishnan B, Agbandje-McKenna M, Silverman DN, McKenna R. Biochemistry 48 7365-7372 (2009)
  4. Characterization of the Copper(II) Binding Sites in Human Carbonic Anhydrase II. Nettles WL, Song H, Farquhar ER, Fitzkee NC, Emerson JP. Inorg Chem 54 5671-5680 (2015)
  5. Building reactive copper centers in human carbonic anhydrase II. Song H, Weitz AC, Hendrich MP, Lewis EA, Emerson JP. J Biol Inorg Chem 18 595-598 (2013)
  6. First- and second-shell metal binding residues in human proteins are disproportionately associated with disease-related SNPs. Levy R, Sobolev V, Edelman M. Hum Mutat 32 1309-1318 (2011)
  7. Solution structure of the 2A protease from a common cold agent, human rhinovirus C2, strain W12. Lee W, Watters KE, Troupis AT, Reinen NM, Suchy FP, Moyer KL, Frederick RO, Tonelli M, Aceti DJ, Palmenberg AC, Markley JL. PLoS One 9 e97198 (2014)
  8. Metal promiscuity and metal-dependent substrate preferences of Trypanosoma brucei methionine aminopeptidase 1. Marschner A, Klein CD. Biochimie 115 35-43 (2015)
  9. New fluorescent probes for carbonic anhydrases. Banerjee J, Haldar MK, Manokaran S, Mallik S, Srivastava DK. Chem Commun (Camb) 2723-2725 (2007)
  10. A study of the influence of the hydrophobic core residues of yeast iso-2-cytochrome c on phosphate binding: a probe of the hydrophobic core-surface charge interactions. Taniuchi H, Shi Y, San Miguel GI, Ferretti JA, Mack JW, Fisher A, Shah M, Schechter AN, Shiloach J. J Protein Chem 20 203-215 (2001)
  11. Carbonic anhydrase inspired poly(N-vinylimidazole)/zeolite Zn-β hybrid membranes for CO2 capture. Liu Y, Wang Z, Shi M, Li N, Zhao S, Wang J. Chem Commun (Camb) 54 7239-7242 (2018)
  12. Carbonic anhydrase modification for carbon management. Giri A, Pant D. Environ Sci Pollut Res Int 27 1294-1318 (2020)
  13. Non-crystallographic symmetry in proteins: Jahn-Teller-like and Butterfly-like effects? Silva JM, Giuntini S, Cerofolini L, Geraldes CFGC, Macedo AL, Ravera E, Fragai M, Luchinat C, Calderone V. J Biol Inorg Chem 24 91-101 (2019)


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