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Protein kinase

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Protein phosphorylation

A protein kinase is a kinase enzyme that modifies other proteins by chemically adding phosphate groups to them (phosphorylation). Phosphorylation usually results in a functional change of the target protein (substrate) by changing enzyme activity, cellular location, or association with other proteins. The human genome contains about 500 protein kinase genes and they constitute about 2% of all human genes.[1] Up to 30% of all human proteins may be modified by kinase activity, and kinases are known to regulate the majority of cellular pathways, especially those involved in signal transduction. Protein kinases are also found in bacteria and plants.

Chemical activity

A ball-and-stick model of the inorganic phosphate molecule (HPO42−). Colour coding: P (orange); O (red); H (white).

The chemical activity of a kinase involves transferring a phosphate group from a nucleoside triphosphate (usually ATP) and covalently attaching it to specific amino acids with a free hydroxyl group. Most kinases act on both serine and threonine (serine/threonine kinases), others act on tyrosine (tyrosine kinases), and a number act on all three (dual-specificity kinases).[2] There are also protein kinases that phosphorylate other amino acids, including histidine kinases that phosphorylate histidine residues.[3]

Regulation

Because protein kinases have profound effects on a cell, their activity is highly regulated. Kinases are turned on or off by phosphorylation (sometimes by the kinase itself - cis-phosphorylation/autophosphorylation), by binding of activator proteins or inhibitor proteins, or small molecules, or by controlling their location in the cell relative to their substrates.

Structure

The catalytic subunits of many protein kinases are highly conserved, and several structures have been solved.[4][5]

Eukaryotic protein kinases are enzymes that belong to a very extensive family of proteins that share a conserved catalytic core.[6][7][8][9] There are a number of conserved regions in the catalytic domain of protein kinases. In the N-terminal extremity of the catalytic domain there is a glycine-rich stretch of residues in the vicinity of a lysine amino acid, which has been shown to be involved in ATP binding. In the central part of the catalytic domain, there is a conserved aspartic acid, which is important for the catalytic activity of the enzyme.[10]

Protein kinase groups

The human protein kinase family is divided into the following groups:

  • AGC kinases - containing PKA, PKC and PKG.
  • CaM kinases - containing the calcium/calmodulin-dependent protein kinases.
  • CK1 - containing the casein kinase 1 group.
  • CMGC - containing CDK, MAPK, GSK3 and CLK kinases.
  • STE - containing the homologs of yeast Sterile 7, Sterile 11, and Sterile 20 kinases.
  • TK - containing the tyrosine kinases.
  • TKL - containing the tyrosine-kinase like group of kinases.

Serine/threonine-specific protein kinases

Calcium/calmodulin-dependent protein kinase II (CaMKII) is an example of a serine/threonine-specific protein kinase.

Serine/threonine protein kinases (EC 2.7.11.1) phosphorylate the OH group of serine or threonine (which have similar side-chains). Activity of these protein kinases can be regulated by specific events (e.g., DNA damage), as well as numerous chemical signals, including cAMP/cGMP, diacylglycerol, and Ca2+/calmodulin. One very important group of protein kinases are the MAP kinases (acronym from: "mitogen-activated protein kinases"). Important subgroups are the kinases of the ERK subfamily, typically activated by mitogenic signals, and the stress-activated protein kinases JNK and p38. While MAP kinases are serine/threonine-specific, they are activated by combined phosphorylation on serine/threonine and tyrosine residues. Activity of MAP kinases is restricted by a number of protein phosphatases, which remove the phosphate groups that are added to specific serine or threonine residues of the kinase and are required to maintain the kinase in an active conformation. Two major factors influence activity of MAP kinases: a) signals that activate transmembrane receptors (either natural ligands or crosslinking agents) and proteins associated with them (mutations that simulate active state) b) signals that inactivate the phosphatases that restrict a given MAP kinase. Such signals include oxidant stress.[11]

Tyrosine-specific protein kinases

Tyrosine-specific protein kinases (EC 2.7.10.1 and EC 2.7.10.2) phosphorylate tyrosine amino acid residues, and like serine/threonine-specific kinases are used in signal transduction. They act primarily as growth factor receptors and in downstream signaling from growth factors;[12] some examples:

Receptor tyrosine kinases

These kinases consist of a transmembrane receptor with a tyrosine kinase domain protruding into the cytoplasm. They play an important role in regulating cell division, cellular differentiation, and morphogenesis. More than 50 receptor tyrosine kinases are known in mammals.

Structure

The extracellular domain serves as the ligand-binding part of the molecule. It can be a separate unit that is attached to the rest of the receptor by a disulfide bond. The same mechanism can be used to bind two receptors together to form a homo- or heterodimer. The transmembrane element is a single α helix. The intracellular or cytoplasmic domain is responsible for the (highly conserved) kinase activity, as well as several regulatory functions.

Regulation

Ligand binding causes two reactions:

  1. Dimerization of two monomeric receptor kinases or stabilization of a loose dimer. Many ligands of receptor tyrosine kinases are multivalent. Some tyrosine receptor kinases (e.g., the platelet-derived growth factor receptor) can form heterodimers with other similar but not identical kinases of the same subfamily, allowing a highly varied response to the extracellular signal.
  2. Trans-autophosphorylation (phosphorylation by the other kinase in the dimer or higher order multimer complex) of the kinase.

Autophosphorylation of the activation loop causes the two subdomains of the intrinsic kinase to shift, opening the kinase domain for ATP binding. In the inactive form, the kinase subdomains are aligned so that ATP cannot reach the catalytic center of the kinase. When several amino acids suitable for phosphorylation are present in the kinase domain (e.g., the insulin-like growth factor receptor), the activity of the kinase can increase with the number of phosphorylated amino acids.

The structures of some autophosphorylation complexes of tyrosine receptor kinases (and other kinases) are known from crystals of protein kinases in which the phosphorylation site (Ser, Thr, or Tyr) of one monomer in the crystal is sitting the active site of another monomer of the crystal in the manner of a substrate.[14] The known structures of RTK autophosphorylation include phosphorylation sites in the activation loops of IGF1R (both Y1165 and Y1166), the kinase insert regions of FGFR1 and FGFR3, and the N or C terminal tails of KIT, EPHA2, CSF1R, and FGFR2.

Signal transduction

The active tyrosine kinase phosphorylates specific target proteins, which are often enzymes themselves. An important target is the ras protein signal-transduction chain.

Receptor-associated tyrosine kinases

Tyrosine kinases recruited to a receptor following hormone binding are receptor-associated tyrosine kinases and are involved in a number of signaling cascades, in particular those involved in cytokine signaling (but also others, including growth hormone). One such receptor-associated tyrosine kinase is Janus kinase (JAK), many of whose effects are mediated by STAT proteins. (See JAK-STAT pathway.)

Histidine-specific protein kinases

Histidine kinases are structurally distinct from most other protein kinases and are found mostly in prokaryotes as part of two-component signal transduction mechanisms.[15] A phosphate group from ATP is first added to a histidine residue within the kinase, and later transferred to an aspartate residue on a 'receiver domain' on a different protein, or sometimes on the kinase itself. The aspartyl phosphate residue is then active in signaling.

Histidine kinases are also found in plants, fungi, animals, and other eukaryotes. The pyruvate dehydrogenase family of kinases in animals is structurally related to histidine kinases, but instead phosphorylate serine residues, and probably do not use a phospho-histidine intermediate.

Mixed kinases

Some kinases have mixed kinase activities. For example, MEK (MAPKK), which is involved in the MAP kinase cascade, is a mixed serine/threonine and tyrosine kinase and, hence, is a dual-specificity kinase.

Inhibitors

Deregulated kinase activity is a frequent cause of disease, in particular cancer, wherein kinases regulate many aspects that control cell growth, movement and death. Drugs that inhibit specific kinases are being developed to treat several diseases, and some are currently in clinical use, including Gleevec (imatinib) and Iressa (gefitinib).

Kinase assays and profiling

Drug development of kinase inhibitors is enabled by kinase assays, the lead compounds are usually profiled for specificity before moving into further tests. Many profiling services are available that utilize fluorescent-based assays like the microscale thermophoresis assay to radioisotope based detections, and competition binding assays.

References

  1. ^ Manning G, Whyte DB, et al. (2002). "The protein kinase complement of the human genome". Science. 298 (5600): 1912–1934. doi:10.1126/science.1075762. PMID 12471243.
  2. ^ Dhanasekaran N, Premkumar Reddy E (September 1998). "Signaling by dual specificity kinases". Oncogene. 17 (11 Reviews): 1447–55. doi:10.1038/sj.onc.1202251. PMID 9779990.
  3. ^ Besant PG, Tan E, Attwood PV (March 2003). "Mammalian protein histidine kinases". Int. J. Biochem. Cell Biol. 35 (3): 297–309. doi:10.1016/S1357-2725(02)00257-1. PMID 12531242.
  4. ^ Stout TJ, Foster PG, Matthews DJ (2004). "High-throughput structural biology in drug discovery: protein kinases". Curr. Pharm. Des. 10 (10): 1069–82. doi:10.2174/1381612043452695. PMID 15078142.
  5. ^ van Linden OP, Kooistra AJ, Leurs R, de Esch IJ, de Graaf C (2013). "KLIFS: A knowledge-based structural database to navigate kinase-ligand interaction space". J. Med. Chem. 57 (2): 249–77. doi:10.1021/jm400378w. PMID 23941661.
  6. ^ Hanks SK (2003). "Genomic analysis of the eukaryotic protein kinase superfamily: a perspective". Genome Biol. 4 (5): 111. doi:10.1186/gb-2003-4-5-111. PMC 156577. PMID 12734000.{{cite journal}}: CS1 maint: unflagged free DOI (link)
  7. ^ Hanks SK, Hunter T (May 1995). "Protein kinases 6. The eukaryotic protein kinase superfamily: kinase (catalytic) domain structure and classification". FASEB J. 9 (8): 576–96. PMID 7768349.
  8. ^ Hunter T (1991). "Protein kinase classification". Meth. Enzymol. Methods in Enzymology. 200: 3–37. doi:10.1016/0076-6879(91)00125-G. ISBN 9780121821012. PMID 1835513.
  9. ^ Hanks SK, Quinn AM (1991). "Protein kinase catalytic domain sequence database: identification of conserved features of primary structure and classification of family members". Meth. Enzymol. Methods in Enzymology. 200: 38–62. doi:10.1016/0076-6879(91)00126-H. ISBN 9780121821012. PMID 1956325.
  10. ^ Knighton DR, Zheng JH, Ten Eyck LF, Ashford VA, Xuong NH, Taylor SS, Sowadski JM (July 1991). "Crystal structure of the catalytic subunit of cyclic adenosine monophosphate-dependent protein kinase". Science. 253 (5018): 407–14. doi:10.1126/science.1862342. PMID 1862342.
  11. ^ Vlahopoulos, S; Zoumpourlis, VC (August 2004). "JNK: a key modulator of intracellular signaling". Biochemistry. Biokhimiia. 69 (8): 844–54. doi:10.1023/B:BIRY.0000040215.02460.45. PMID 15377263. {{cite journal}}: Unknown parameter |name-list-format= ignored (|name-list-style= suggested) (help)
  12. ^ Higashiyama, Shigeki; Iwabuki, Hidehiko; Morimoto, Chie; Hieda, Miki; Inoue, Hirofumi; Matsushita, Natsuki (February 2008). "Membrane-anchored growth factors, the epidermal growth factor family: Beyond receptor ligands". Cancer Science. 99 (2): 214–20. doi:10.1111/j.1349-7006.2007.00676.x. PMID 18271917.
  13. ^ Carpenter, Graham (August 2000). "The EGF receptor: a nexus for trafficking and signaling". BioEssays. 22 (8): 697–707. doi:10.1002/1521-1878(200008)22:8<697::AID-BIES3>3.0.CO;2-1. PMID 10918300.
  14. ^ Xu, Q.; Malecka, K. L.; Fink, L.; Jordan, E. J.; Duffy, E.; Kolander, S.; Peterson, J. R.; Dunbrack, R. L., Jr. (1 December 2015). "Identifying three-dimensional structures of autophosphorylation complexes in crystals of protein kinases". Science Signaling. 8 (405): rs13–rs13. doi:10.1126/scisignal.aaa6711.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  15. ^ Wolanin PW, Thomason PA, Stock JB (2002). "Histidine protein kinases: key signal transducers outside the animal kingdom". Genome Biology. 3 (10): reviews3013.1–3013.8. doi:10.1186/gb-2002-3-10-reviews3013. PMC 244915. PMID 12372152.{{cite journal}}: CS1 maint: unflagged free DOI (link)