Biology:Phosphatome

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Short description: Set of phosphatase-encoding genes in an organism's genome

The phosphatome of an organism is the set of phosphatase genes in its genome. Phosphatases are enzymes that catalyze the removal of phosphate from biomolecules. Over half of all cellular proteins are modified by phosphorylation which typically controls their functions. Protein phosphorylation is controlled by the opposing actions of protein phosphatases and protein kinases. Most phosphorylation sites are not linked to a specific phosphatase, so the phosphatome approach allows a global analysis of dephosphorylation, screening to find the phosphatase responsible for a given reaction, and comparative studies between different phosphatases, similar to how protein kinase research has been impacted by the kinome approach.

The Protein Phosphatome

Protein phosphatases remove phosphates from proteins, usually on Serine, Threonine, and Tyrosine residues, reversing the action of protein kinases. The PTP family of protein phosphatases is tyrosine-specific, and several other families (PPPL, PPM, HAD) appear to be serine/threonine specific, while other families are unknown or have a variety of substrates (DSPs dephosphorylate any amino acid, while some protein phosphatases also have non-protein substrates). In the human genome, 20 different folds of protein are known to be phosphatases, of which 10 include protein phosphatases.[1]

Protein phosphatomes have been cataloged for human and 8 other key eukaryotes,[1] for Plasmodium and Trypanosomes [2] [3] [4] and phosphatomes have been used for functional analysis, by experimentally investing all known protein phosphatases, in the yeast Fusarium,[5] in Plasmodium [6] and in human cancer [7][8]

Large scale databases exist for human and animal phosphatomes Phosphatome.net, parasitic protozoans ProtozPhosDB and for the substrates of human phosphatases DEPOD.

Non-Protein Phosphatases

Non-protein phosphorylation has three general forms

  • As a regulatory mechanism to control the function of the substrate, similar to the role of protein phosphorylation. Phosphoinositide lipids are important signaling molecules that have a variety of dedicated kinases and phosphatases.
  • As an energetic intermediate. The phosphate bond is high-energy, so adding a phosphate increases the energy of a molecule, and removal of the phosphate can provide energy for an otherwise unfavorable reaction. For instance Glucose 6-phosphatase removes a phosphate group from glucose to complete gluconeogenesis.
  • In biosynthesis, where the phosphate is a functional part of the mature molecule, and dephosphorylation degrades it or changes function. Nucleotidases are phosphatases used in nucleotide biosynthesis and breakdown.

The human non-protein phosphatome has been cataloged,[1] but most phosphatome analyses are restricted to protein and lipid phosphatases that have regulatory functions.

Pseudophosphatases

The phosphatome includes proteins that are structurally closely related to phosphatases but lack catalytic activity. These retain biological function, and may regulate pathways that involve active phosphatases, or bind to phosphorylated substrates without cleaving them.[1][9] Examples include STYX, where the phosphatase domain has become a phospho-tyrosine binding domain, and GAK, whose inactive phosphatase domain instead binds phospholipids.

See also

References

  1. 1.0 1.1 1.2 1.3 Mark J. Chen, Jack E. Dixon & Gerard Manning (2017). "Genomics and evolution of protein phosphatases". Science Signaling 10 (474): eaag1796. doi:10.1126/scisignal.aag1796. PMID 28400531. 
  2. Rachel Brenchley, Humera Tariq, Helen McElhinney, Balazs Szoor, Julie Huxley-Jones, Robert David Stevens, Keith Matthews & Lydia Tabernero (2007). "The TriTryp phosphatome: analysis of the protein phosphatase catalytic domains". BMC Genomics 8: 434. doi:10.1186/1471-2164-8-434. PMID 18039372. 
  3. Jonathan M. Wilkes & Christian Doerig (2008). "The protein-phosphatome of the human malaria parasite Plasmodium falciparum". BMC Genomics 9: 412. doi:10.1186/1471-2164-9-412. PMID 18793411. 
  4. Tamanna Anwar & Samudrala Gourinath (2016). "Deep Insight into the Phosphatomes of Parasitic Protozoa and a Web Resource ProtozPhosDB". PLoS ONE 11 (12): e0167594. doi:10.1371/journal.pone.0167594. PMID 27930683. Bibcode2016PLoSO..1167594A. 
  5. Yingzi Yun, Zunyong Liu, Yanni Yin, Jinhua Jiang, Yun Chen, Jin-Rong Xu & Zhonghua Ma (2015). "Functional analysis of the Fusarium graminearum phosphatome". The New Phytologist 207 (1): 119–134. doi:10.1111/nph.13374. PMID 25758923. 
  6. David S. Guttery, Benoit Poulin, Abhinay Ramaprasad, Richard J. Wall, David J. P. Ferguson, Declan Brady, Eva-Maria Patzewitz, Sarah Whipple, Ursula Straschil, Megan H. Wright, Alyaa M. A. H. Mohamed, Anand Radhakrishnan, Stefan T. Arold, Edward W. Tate, Anthony A. Holder, Bill Wickstead, Arnab Pain & Rita Tewari (2014). "Genome-wide functional analysis of Plasmodium protein phosphatases reveals key regulators of parasite development and differentiation". Cell Host & Microbe 16 (1): 128–140. doi:10.1016/j.chom.2014.05.020. PMID 25011111. 
  7. Francesca Sacco, Pier Federico Gherardini, Serena Paoluzi, Julio Saez-Rodriguez, Manuela Helmer-Citterich, Antonella Ragnini-Wilson, Luisa Castagnoli & Gianni Cesareni (2012). "Mapping the human phosphatome on growth pathways". Molecular Systems Biology 8: 603. doi:10.1038/msb.2012.36. PMID 22893001. 
  8. Sofi G. Julien, Nadia Dube, Serge Hardy & Michel L. Tremblay (2011). "Inside the human cancer tyrosine phosphatome". Nature Reviews. Cancer 11 (1): 35–49. doi:10.1038/nrc2980. PMID 21179176. 
  9. Veronika Reiterer, Patrick A. Eyers & Hesso Farhan (2014). "Day of the dead: pseudokinases and pseudophosphatases in physiology and disease". Trends in Cell Biology 24 (9): 489–505. doi:10.1016/j.tcb.2014.03.008. PMID 24818526. 

External links

  • phosphatome.net. A database of protein phosphatases in 8 eukaryotic genomes.
  • Phosphatome Wiki Wiki focused on protein phosphatase classification and evolution.
  • DEPOD Database of protein phosphatase substrates, pathways, and interactions