Hemocyanin

Hemocyanin, copper containing domain
Single Oxygenated Functional Unit from the hemocyanin of an octopus
Identifiers
Symbol Hemocyanin_M
Pfam PF00372
InterPro IPR000896
PROSITE PDOC00184
SCOP 1lla
Hemocyanin, all-alpha domain
crystal structure of hexameric haemocyanin from panulirus interruptus refined at 3.2 angstroms resolution
Identifiers
Symbol Hemocyanin_N
Pfam PF03722
InterPro IPR005204
PROSITE PDOC00184
SCOP 1lla
Hemocyanin, ig-like domain
crystallographic analysis of oxygenated and deoxygenated states of arthropod hemocyanin shows unusual differences
Identifiers
Symbol Hemocyanin_C
Pfam PF03723
InterPro IPR005203
PROSITE PDOC00184
SCOP 1lla

Hemocyanins (also spelled haemocyanins) are respiratory proteins in the form of metalloproteins containing two copper atoms that reversibly bind a single oxygen molecule (O2). Oxygenation causes a color change between the colorless Cu(I) deoxygenated form and the blue Cu(II) oxygenated form. Hemocyanins carry oxygen in the hemolymph of most molluscs, and some arthropods, including the horseshoe crab, Limulus polyphemus. They are second only to hemoglobin in frequency of use as an oxygen transport molecule.[1] Unlike the hemoglobin in red blood cells found in vertebrates, hemocyanins are not bound to blood cells but are instead suspended directly in the hemolymph.

Contents

Explanation

Although the respiratory function of hemocyanin is similar to that of hemoglobin, there are a significant number of differences in its molecular structure and mechanism. Whereas hemoglobin carries its iron atoms in porphyrin rings (heme groups), the copper atoms of hemocyanin are bound as prosthetic groups coordinated by histidine residues. Species using hemocyanin for oxygen transportation are commonly crustaceans living in cold environments with low oxygen pressure. Under these circumstances hemoglobin oxygen transportation is less efficient than hemocyanin oxygen transportation.

Most hemocyanins bind with oxygen non-cooperatively and are roughly one-fourth as efficient as hemoglobin at transporting oxygen per amount of blood. Hemoglobin binds oxygen cooperatively due to steric conformation changes in the protein complex, which increases hemoglobin's affinity for oxygen when partially oxygenated. In some hemocyanins of horseshoe crabs and some other species of arthropods, cooperative binding is observed, with Hill coefficients of 1.6 - 3.0. Hill coefficients vary depending on species and laboratory measurement settings. Hemoglobin, for comparison, has a Hill coefficient of usually 2.8 - 3.0. In these cases of cooperative binding hemocyanin was arranged in protein sub-complexes of 6 subunits (hexamer) each with one oxygen binding site; binding of oxygen on one unit in the complex would increase the affinity of the neighboring units. Each hexamer complex was arranged together to form a larger complex of dozens of hexamers. In one study, cooperative binding was found to be dependent on hexamers being arranged together in the larger complex, suggesting cooperative binding between hexamers. Hemocyanin oxygen-binding profile is also affected by dissolve-salt ion levels and pH.

Hemocyanin is made of many individual subunit proteins, each of which contains two copper atoms and can bind one oxygen molecule (O2). Each subunit weighs about 75 kilodaltons (kDa). Subunits may be arranged in dimers or hexamers depending on species, the dimer or hexamer complex is likewise arranged in chains or clusters in weights exceeding 1500 kDa. The subunits are usually homogeneous, or heterogeneous with two variant subunit types. Because of the large size of hemocyanin, it is usually found free-floating in the blood, unlike hemoglobin, which must be contained in cells because its small size would lead it to clog and damage blood-filtering organs such as the kidneys. This free-floating nature can allow for increased hemocyanin density over hemoglobin and increased oxygen carrying capacity. On the other hand, free-floating hemocyanin can increase viscosity and increase the energy expenditure needed to pump blood.

Catalytic activity

It is interesting to compare hemocyanin to the phenol oxidases (e.g. tyrosinase), homologous enzymes sharing its type 3 Cu active site coordination. Hemocyanin also exhibits phenol oxidase activity, but with slowed kinetics from greater steric bulk at the active site. Partial denaturation actually improves hemocyanin’s phenol oxidase activity by providing greater access to the active site. [2]

Structure

Spectroscopy of oxyhemocyanin shows several salient features:

  1. resonance Raman spectroscopy shows symmetric binding
  2. UV-Vis spectroscopy shows strong absorbances at 350 and 580 nm.
  3. OxyHc is EPR-silent indicating the absence of unpaired electrons
  4. Infrared spectroscopy shows ν(O-O) of 755 cm-1

(1) rules out a mononuclear peroxo complex (2) does not match with the UV-Vis spectra of mononuclear peroxo and Kenneth Karlin's trans-peroxo models.[3] (4) shows a considerably weaker O-O bond compared with Karlin's trans-peroxo model.[3]

On the other hand, Nobumasa Kitajima's model shows ν(O-O) of 741 cm-1 and UV-Vis absorbances at 349 and 551 nm, which agree with the experimental observations for oxyHc.[4]

The weak O-O bond of oxyhemocyanin is because of metal-ligand backdonation into the σ* orbitals. The donation of electrons into the O-O antibonding orbitals weakens the O-O bond, giving a lower than expected infrared stretching frequency.

Immunotherapeutical effects

The hemocyanin found in Concholepas concholepas blood has immunotherapeutic effects against bladder and prostate cancer. Researchers in 2006 primed mice with C. concholepas before implantation of bladder tumor (MBT-2) cells. Mice treated with C. concholepas showed significant antitumor effects: prolonged survival, decreased tumor growth and incidence, and lack of toxic effects.[5]

See also

References

  1. ^ http://www.hull.ac.uk/chemistry/bioinorganic/Main%20hemocyanin%20page.htm
  2. ^ Decker (August 2000). "Tyrosinase/catecholoxidase activity of hemocyanins: structural basis and molecular mechanism". http://www.sciencedirect.com. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TCV-40W5V6F-J&_user=521824&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_acct=C000059577&_version=1&_urlVersion=0&_userid=521824&md5=19f7d0f5a6ce73e94c9b9f9496a44504. Retrieved 2008-07-31. 
  3. ^ a b K. D. Karlin, R. W. Cruse, Y. Gultneh, A. Farooq, J. C. Hayes and J. Zubieta (1987). "Dioxygen-copper reactivity. Reversible binding of O2 and CO to a phenoxo-bridged dicopper(I) complex". J. Am. Chem. Soc. 109 (9): 2668–2679. doi:10.1021/ja00243a019. 
  4. ^ N. Kitajima, K. Fujisawa, C. Fujimoto, Y. Morooka, S. Hashimoto, T. Kitagawa, K. Toriumi, K. Tatsumi and A. Nakamura (1992). "A new model for dioxygen binding in hemocyanin. Synthesis, characterization, and molecular structure of the μ-η2:η2 peroxo dinuclear copper(II) complexes, [Cu(HB(3,5-R2pz)3)]2(O2) (R = isopropyl and Ph)". J. Am. Chem. Soc. 114 (4): 1277–1291. doi:10.1021/ja00030a025. 
  5. ^ [1] This Month in Investigative Urology, ScienceDirect