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EspañolINTEGRAL MEMBRANE PROTEIN
An 'Integral Membrane Protein' ('IMP') is a protein molecule (or assembly of proteins) that is permanently attached to the biological membrane. Such proteins can be separated from the biological membranes only using detergents, nonpolar solvents, or sometimes denaturing agents.
IMPs comprise a very significant fraction of the proteins encoded in the genome.
3D structures of only ~160 different integral membrane proteins are currently determined at atomic resolution by X-ray crystallography or Nuclear magnetic resonance spectroscopy due to the difficulties with extraction and crystallization. In addition, structures of many water-soluble domains of IMPs are available in the Protein Data Bank. Their membrane-anchoring α-helices have been removed to facilitate the extraction and crystallization.
IMPs can be divided into two groups:
# Transmembrane proteins
# Integral monotopic proteins
Main articles: Transmembrane proteins
Transmembrane proteins span the entire biological membrane. This is the most common type of IMP.
Integral monotopic proteins are permanently attached to the membrane from one side.
Main articles: Peripheral membrane protein
Three-dimensional structures of the following integral monotopic proteins have been determined:
★ prostaglandin H2 synthases 1 and 2 (cyclooxygenases) [1],
★ lanosterol synthase and squalene-hopene cyclase [2],
★ microsomal prostaglandin E synthase [3],
★ carnitine O-palmitoyltransferase 2 [4].
There are also structures of integral monotopic ''domains'' of transmembrane proteins:
★ monoamine oxidases A and B [5],
★ fatty acid amide hydrolase [6],
★ mammalian cytochrome P450 oxidases [7],
★ corticosteroid 11-beta-dehydrogenases [8].
Such domains require detergents for extraction or crystallization, even after removal of their transmembrane helices. Therefore, they are often classified as integral monotopic ''proteins'' [9]
IMPs include transporters, channels, receptors, enzymes, structural membrane-anchoring domains, proteins involved in accumulation and transduction of energy, and proteins responsible for cell adhesion. Classification of transporters can be found in TCDB database.
★ Booth, P.J., Templer, R.H., Meijberg, W., Allen, S.J., Curran, A.R., and Lorch, M. 2001. In vitro studies of membrane protein folding. ''Crit. Rev. Biochem. Mol. Biol.'' 36: 501-603.
★ Bracey M.H., Cravatt B.F., Stevens R.C., Cravatt B.F. 2004. Structural commonalities among integral membrane enzymes. ''FEBS Lett.'' 567: 159-165.
★ Bowie J.U. 2001. Stabilizing membrane proteins. ''Curr. Op. Struct. Biol.'' 11: 397-402.
★ Bowie J.U. 2005. Solving the membrane protein folding problem. ''Nature'' 438: 581-589.
★ DeGrado W.F., Gratkowski H. and Lear J.D. 2003. How do helix-helix interactions help determine the folds of membrane proteins? Perspectives from the study of homo-oligomeric helical bundles. ''Protein Sci.'' 12: 647-665.
★ Popot J-L. and Engelman D.M. 2000. Helical membrane protein folding, stability, and evolution. ''Annu. Rev. Biochem.'' 69: 881-922.
★ ''Protein-lipid interactions'' (Ed. L.K. Tamm) Wiley, 2005.
★ Membrane proteins
★ Transmembrane proteins
★ Peripheral membrane proteins
Examples of integral membrane proteins:
★ Integrin
★ Cadherin
★ Insulin receptor
★ NCAM
★ Selectin
★ Some types of cell adhesion proteins
★ Some types of receptor proteins
★ Glycophorin
★ Rhodopsin
★ Band 3
★ CD36
★ Membrane PDB Database of 3D structures of integral membrane proteins and hydrophobic peptides with emphasis on crystallization conditions
★ Membrane proteins of known 3D structure from Stephen White laboratory
★ Orientations of proteins in membranes database Calculated spatial positions of transmembrane, integral monotopic, and peripheral proteins in membranes
IMPs comprise a very significant fraction of the proteins encoded in the genome.
| Contents |
| Structure |
| Integral transmembrane protein |
| Integral monotopic proteins |
| Function |
| References |
| See also |
| Examples |
| External links |
Structure
3D structures of only ~160 different integral membrane proteins are currently determined at atomic resolution by X-ray crystallography or Nuclear magnetic resonance spectroscopy due to the difficulties with extraction and crystallization. In addition, structures of many water-soluble domains of IMPs are available in the Protein Data Bank. Their membrane-anchoring α-helices have been removed to facilitate the extraction and crystallization.
IMPs can be divided into two groups:
# Transmembrane proteins
# Integral monotopic proteins
Integral transmembrane protein
Main articles: Transmembrane proteins
Transmembrane proteins span the entire biological membrane. This is the most common type of IMP.
Integral monotopic proteins
Integral monotopic proteins are permanently attached to the membrane from one side.
Main articles: Peripheral membrane protein
Three-dimensional structures of the following integral monotopic proteins have been determined:
★ prostaglandin H2 synthases 1 and 2 (cyclooxygenases) [1],
★ lanosterol synthase and squalene-hopene cyclase [2],
★ microsomal prostaglandin E synthase [3],
★ carnitine O-palmitoyltransferase 2 [4].
There are also structures of integral monotopic ''domains'' of transmembrane proteins:
★ monoamine oxidases A and B [5],
★ fatty acid amide hydrolase [6],
★ mammalian cytochrome P450 oxidases [7],
★ corticosteroid 11-beta-dehydrogenases [8].
Such domains require detergents for extraction or crystallization, even after removal of their transmembrane helices. Therefore, they are often classified as integral monotopic ''proteins'' [9]
Function
IMPs include transporters, channels, receptors, enzymes, structural membrane-anchoring domains, proteins involved in accumulation and transduction of energy, and proteins responsible for cell adhesion. Classification of transporters can be found in TCDB database.
References
★ Booth, P.J., Templer, R.H., Meijberg, W., Allen, S.J., Curran, A.R., and Lorch, M. 2001. In vitro studies of membrane protein folding. ''Crit. Rev. Biochem. Mol. Biol.'' 36: 501-603.
★ Bracey M.H., Cravatt B.F., Stevens R.C., Cravatt B.F. 2004. Structural commonalities among integral membrane enzymes. ''FEBS Lett.'' 567: 159-165.
★ Bowie J.U. 2001. Stabilizing membrane proteins. ''Curr. Op. Struct. Biol.'' 11: 397-402.
★ Bowie J.U. 2005. Solving the membrane protein folding problem. ''Nature'' 438: 581-589.
★ DeGrado W.F., Gratkowski H. and Lear J.D. 2003. How do helix-helix interactions help determine the folds of membrane proteins? Perspectives from the study of homo-oligomeric helical bundles. ''Protein Sci.'' 12: 647-665.
★ Popot J-L. and Engelman D.M. 2000. Helical membrane protein folding, stability, and evolution. ''Annu. Rev. Biochem.'' 69: 881-922.
★ ''Protein-lipid interactions'' (Ed. L.K. Tamm) Wiley, 2005.
See also
★ Membrane proteins
★ Transmembrane proteins
★ Peripheral membrane proteins
Examples
Examples of integral membrane proteins:
★ Integrin
★ Cadherin
★ Insulin receptor
★ NCAM
★ Selectin
★ Some types of cell adhesion proteins
★ Some types of receptor proteins
★ Glycophorin
★ Rhodopsin
★ Band 3
★ CD36
External links
★ Membrane PDB Database of 3D structures of integral membrane proteins and hydrophobic peptides with emphasis on crystallization conditions
★ Membrane proteins of known 3D structure from Stephen White laboratory
★ Orientations of proteins in membranes database Calculated spatial positions of transmembrane, integral monotopic, and peripheral proteins in membranes
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