GPCR oligomer

Crystallographic structure of the human κ-opioid receptor homo dimer (4djh) imbedded in a cartoon representation of a lipid bilayer. Each protomer is individually rainbow colored (N-terminus = blue, C-terminus = red). The receptor is complexed with the ligand JDTic that is depicted as a space-filling model (carbon = white, oxygen = red, nitrogen = blue).^[1]

A GPCR oligomer is a complex of a small number of G protein-coupled receptors, which is held together by covalent bonds or by intermolecular forces. Receptors within this complex are called protomers, while unconnected receptors are called monomers. Receptor homomers consist of identical, heteromers of different protomers.

The existence of receptor oligomers is a general phenomenon, whose discovery has superseded the prevailing paradigmatic concept of the function of receptors as plain monomers, and has far-reaching implications for the understanding of neurobiological diseases as well as for the development of drugs.^[2][3]

Discovery

For a long time it was assumed that receptors transmitted their effects exclusively from their basic functional forms – as monomers. The first clue to the existence of GPCR oligomers goes back to 1975 when Robert Lefkowitz observed that β-adrenoceptors display negative binding cooperativity.^[4] At the beginning of the 1980s, it was hypothesized, receptors could form larger complexes, the so-called mosaic form,^[5] where two receptors may interact directly with each other.^[6] Mass determination of β-adrenoceptors (1982)^[7] and muscarinic receptors (1983),^[8] supported the existence of homodimer or tetrameric complexes. In 1991, the phenomenon of receptor crosstalk was observed between adenosine A_2A (A2A) and dopamine D₂ receptor (DRD2) thus suggesting the formation of heteromers.^[9] While initially thought to be a heterodimer, a 2015 review indicated that the A2A-DRD2 complex is a heterotetramer composed of A2A and DRD2 homodimers (i.e., a complex of 4 GPCRs composed of 2 adenosine A2A receptors and 2 dopamine D2 receptors).^[10] Maggio and co-workers showed in 1993 the ability of the muscarinic M₃ receptor and α2C-adrenoceptor to heterodimerize.^[11] In 2005, evidence was provided that receptor oligomizeration plays functional role in a living organism.^[12] The crystal structure of CXCR4 dimer was published in 2010.^[13]

Consequences of oligomerization

First order GPCR oligomers are monomers, i.e., individual G-protein coupled receptors. Second and higher order GPCR oligomers consist of dimers, trimers, tetramers, and higher complexes. These oligomers have properties that differ from those of the monomers in several ways.^[14] The functional character of a receptor is dependent on its tertiary or quaternary structure. Touch receptors located on a larger area or at sensitive places, then, forces, which alter the shape as well as the internal mobility of the reorganized protomers; short, protomers act as allosteric modulators of another. This has consequences for:

• supply of cell surface receptors
• altered ligand binding sites
• G-protein coupling mechanisms
• GPCR-mediated signal transduction
• modifying the sensitization profile
• the tendency for endocytosis and internalization
• the fate of the receptors

See also

• Multiprotein complex
• D₁-D₂ dopamine receptor

References

Further reading

External links

• Lua error in package.lua at line 80: module 'strict' not found.
  • Lua error in package.lua at line 80: module 'strict' not found. – Lua error in package.lua at line 80: module 'strict' not found.
  • Lua error in package.lua at line 80: module 'strict' not found. – Lua error in package.lua at line 80: module 'strict' not found.