CHEM 245
Biochemistry

J. D. Cronk    Syllabus    Topics

BIOCHEMISTRY TOPICS

Carbonic anhydrase

Catalysis with a metal ion cofactor.

Carbonic anhydrase [EC 4.2.1.1] is a zinc metalloenzyme that catalyzes the interconversion of carbon dioxide and bicarbonate ion by hydration/dehydration.

Equation for reaction catalyzed by carbonic anhydrase

Carbonic anhydrase (CA) was the first enzyme to have been discovered to contain zinc and is still one of the prototypes of zinc-containing enzymes. The CA isozymes from mammals are among the most well-studied enzymes in biochemistry. Since the interconversion reaction occurs at a significant uncatalyzed rate in solution, the rate enhancement by CA is modest. Nonetheless, some CAs are among the fastest enzymes known. The human isozyme CA II has a kcat/KM of 1.5 × 108 M−1sec−1, a value for catalytic efficiency that approaches the theoretical limit of diffusion control.

Ribbon diagram of carbonic anhydrase II from human

The figure at left shows the structure of a human CA isozyme. The ribbon representation of protein secondary structure shows that it is mostly a β sheet. The twist of the beta sheet creates an active site. pocket, at the bottom of which lies the catalytic zinc, shown in the figure as a magenta sphere.

The side chains of the histidine residues that coordinate the zinc ion are shown, as well as an an inhibitor that occupies the fourth coordinate position. The role of zinc in CA is that of an electrophilic catalyst. The pKa of zinc-coordinated water is lowered to such an extent that a significant proportion exist as nucleophilic (and reactive) hydroxide ion at physiological pH.

Recall that CO2, as a metabolic product, is an acid anhydride, meaning it reacts with water to produce carbonic acid, which in turn is an unstable species that rapidly decomposes producing hydronium ion (usually we'll abbreviate this as H+(aq)) and bicarbonate.

Zinc is the key

Zinc is an essential element for eukaryotic and probably most organisms, and it is the second most abundant trace metal in most higher animals (after iron). Its role as a key component of numerous enzymes, carbonic anhydrase being a prominent example. Others include alcohol dehyrogenase, zinc metalloproteases such as thermolysin and carboxypeptidase A, and class II aldolase from bacteria. The occurrence of zinc in an impressive variety of proteins makes the biochemistry of zinc a fascinating and diverse specialty. The properties of zinc that determine its biological utility include a flexible coordination geometry, Lewis acidity, intermediate polarizability, and redox stability. In proteins, zinc is most commonly observed in a tetrahedral coordination geometry, with the side chains of His, Cys, and Asp or Glu as ligands. In zinc enzymes, water is often a ligand, in which case the ability of zinc to act as a Lewis base is often the key to the catalytic mechanism. The pKa of zinc-coordinated water is lowered to such an extent that a significant proportion exist as nucleophilic (and reactive) hydroxide ion at physiological pH.

Image of zinc site in pea carbonic anhydrase

Left: The zinc ion at the catalytic center, or active site, of carbonic anhydrase from pea chloroplast. The zinc ion (light blue) is bound by a histidine side chain from below via its Nε2 atom, and two cysteine side chains on either side. A roughly tetrahedral coordination sphere is completed by an oxygen from acetic acid (above), here acting as an analog of the substrate bicarbonate. Drawn from pdb file 1ekj (see Kimber & Pai, 2000), using PyMOL.

Carbonic anhydrases and convergent evolution

Carbonic anhydrases provide a striking case of enzymes of completely different overall structure and phylogenetic origin having arisen independently, yet adopting the same basic catalytic strategy. By far the best characterized are the α (alpha) class CAs, often represented in biochemistry textbooks by human CA II (shown above in the first structure figure), a CA isozyme that is plentiful in erythrocytes (red blood ncells). The β (beta) class is the next most well-studied, and the β-CAs are important in higher plants and many prokaryoic and simple eukaryotic organisms, both photosynthetic and heterotrophic. The following key points relate to convergent evolution of the CAs.

Below shows representative structures of β and γ CAs: (left) E. coli carbonic anhydrase (ECCA), a β-CA; and (right) an archaeal γ-CA from Methanosarcina thermophila. The β-CA is the only CA class with significant α helix content.

Ribbon diagram of two beta carbonic anhydrase structures Two views of the ribbon representation of the gamma CA structure

Above: Structure of γ-CA from Methanosarcina thermophila. (a) Ribbon diagram of the trimeric gamma carbonic anhydrase. (b) Same as (a), but rotated about 90° around a horizontal axis in the plane of the figure. The γ-CA monomer displays an unusual "beta helix" architetcture. Drawn from pdb file 1qrg (see Ref. 7).

Above: Two representative β-CA structures. (a) E. coli carbonic anhydrase (ECCA). Drawn from pdb file 2esf (see Ref. 5). (b) Octomeric plant CA, from Pisum sativum (garden pea) chloroplast. Drawn from pdb file 1ekj (see Ref. 6).

The ribbon diagrams (above and left) show α helices in red, β strands in yellow, and connecting loops in blue. The zinc ions are represented as small gray spheres, and ligands to the metal are shown explicitly in stick form.

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Learning objectives

Page updated 11-15-2016

References

  1. Carbonic Anhydrase - Molecule of the Month (January 2004). Protein Data Bank (PDB)
  2. Donald Voet, Judith G. Voet, Charlotte W. Pratt. Fundamentals of Biochemistry, 4th ed.; Ch. 6, pp.145-146.
  3. The PyMOL Molecular Graphics System, Version 1.8 Schrödinger, LLC.
  4. Christianson DW. (1991). Structural Biology of Zinc. Adv. Prot. Chem. 42, 281-355.
  5. Christianson DW & Cox JD. (1999) Catalysis By Metal-Activated Hydroxide in Zinc and Manganese Metalloenzymes. Annu. Rev. Biochem. 68, 33-57.
  6. Coleman JE. (1992). Zinc Proteins: Enzymes, Storage Proteins, Transcription Factors, and Replication Proteins. Annu. Rev. Biochem. 61, 897-946.
  7. Lipscomb WN & Strater N. (1996). Recent Advances in Zinc Enzymology. Chem. Rev. 96, 2375-2433.
  8. Kimber M, Pai EF. (2000). The active site architecture of Pisum sativum beta-carbonic anhydrase is a mirror image of that of alpha carbonic anhydrases. EMBO J. 19: 1407-1418.
  9. Christianson DW & Cox JD. (1999) Catalysis By Metal-Activated Hydroxide in Zinc and Manganese Metalloenzymes. Ann Rev Biochem 68, 33-57.
  10. Smith KS, Jakubzick C, Whittam TS, Ferry JG. (1999) Carbonic anhydrase is an ancient enzyme widespread in prokaryotes, Proc. Natl. Acad. Sci. U. S. A. 96: 15184-15189.
  11. McDowall J. Carbonic Anhydrase - Protein Focus, Jan 2004. InterPro.
  12. Cronk JD, Rowlett RS, et al. (2006). Identification of a novel noncatalytic bicarbonate binding site in eubacterial beta carbonic anhydrase. Biochemistry 45: 4351-4361.
  13. Kimber M, Pai EF. (2000). The active site architecture of Pisum sativum beta-carbonic anhydrase is a mirror image of that of alpha carbonic anhydrases. EMBO J. 19: 1407-1418.
  14. Iverson TM, Alber BE, Kisker C, Ferry JG, Rees DC. (2000). A closer look at the active site of gamma carbonic anhydrases: high-resolution crystallographic studies of the carbonic anhydrase from Methanosarcina thermophila. Biochemistry 39: 9222-9231.