Pseudoenzyme

Pseudoenzymes are variants of enzymes (usually proteins) that are catalytically-deficient (usually inactive), meaning that they perform little or no enzyme catalysis. [1] They are believed to be represented in all major enzyme families in the kingdoms of life, where they have important signaling and metabolic functions, many of which are only now coming to light.[2] Pseudoenzymes are becoming increasingly important to analyse, especially as the bioinformatic analysis of genomes reveals their ubiquity. Their important regulatory and sometimes disease-associated functions in metabolic and signalling pathways are also shedding new light on the non-catalytic functions of active enzymes, of moonlighting proteins [3] [4], the re-purposing of proteins in distinct cellular roles (Protein moonlighting). They are also suggesting new ways to target and interpret cellular signalling mechanisms using small molecules and drugs.[5] The most intensively analyzed, and certainly the best understood pseudoenzymes in terms of cellular signalling functions are probably the pseudokinases, the pseudoproteases and the pseudophosphatases. Recently, the pseudo-deubiquitylases have also begun to gain prominence.[6][7]

Structures and roles

The difference between enzymatically active and inactive homologues has been noted (and in some cases, understood when comparing catalytically active and inactive proteins residing in recognisable families) for some time at the sequence level,[8] and some pseudoenzymes have also been referred to as 'prozymes' when they were analysed in protozoan parasites.[9] The best studied pseudoenzymes reside amongst various key signalling superfamilies of enzymes, such as the proteases,[10] the protein kinases,[11][12][13][14][15][16][17] protein phosphatases [18][19] and ubiquitin modifying enzymes.[20][21] The role of pseudoenzymes as "pseudo scaffolds" has also been recognised [22] and pseudoenzymes are now beginning to be more thoroughly studied in terms of their biology and function, in large part because they are also interesting potential targets (or anti-targets) for drug design in the context of intracellular cellular signalling complexes.[23][24]

Examples classes

ClassFunctionExamples [25]
PseudokinaseAllosteric regulation of conventional protein kinase STRADα regulates activity of the conventional protein kinase, LKB1

JAK1-3 and TYK2 C-terminal tyrosine kinase domains are regulated by their adjacent pseudokinase domain KSR1/2 regulates activation of the conventional protein kinase, Raf

Allosteric regulation of other enzymesVRK3 regulates activity of the phosphatase, VHR
Pseudo-Histidine kinaseProtein interaction domainCaulobacter DivL binds the phosphorylated response regulator, DivK, allowing DivL to negatively regulate the asymmetric cell division regulatory kinase, CckA
Pseudophosphatase Occlusion of conventional phosphatase access to substrateEGG-4/EGG-5 binds to the phosphorylated activation loop of the kinase, MBK-2

STYX competes with DUSP4 for binding to ERK1/2

Allosteric regulation of conventional phosphatases MTMR13 binds and promotes lipid phosphatase activity of MTMR2
Regulation of protein localisation in a cellSTYX acts as a nuclear anchor for ERK1/2
Regulation of signalling complex assemblySTYX binds the F-box protein, FBXW7, to inhibit its recruitment to the SCF Ubiquitin ligase complex
PseudoproteaseAllosteric regulator of conventional proteasecFLIP binds and inhibits the cysteine protease, Caspase-8, to block extrinsic apoptosis
Regulation of protein localisation in a cellMammalian iRhom proteins bind and regulate trafficking single pass transmembrane proteins to plasma membrane or ER-associated degradation pathway
Pseudodeubiquitinase (pseudoDUB)Allosteric regulator of conventional DUBKIAA0157 is crucial to assembly of a higher order heterotetramer with DUB, BRCC36, and DUB activity
Pseudoligase (pseudo-Ubiquitin E2)Allosteric regulator of conventional E2 ligaseMms2 is a ubiquitin E2 variant (UEV) that binds active E2, Ubc13, to direct K63 ubiquitin linkages
Regulation of protein localisation in a cellTsg101 is a component of the ESCRT-I trafficking complex, and plays a key role in HIV-1 Gag binding and HIV budding
Pseudoligase (pseudo-Ubiquitin E3)Possible allosteric regulator of conventional RBR family E3 ligaseBRcat regulates interdomain architecture in RBR family E3 Ubiquitin ligases, such as Parkin and Ariadne-1/2
PseudonucleaseAllosteric regulator of conventional nucleaseCPSF-100 is a component of the pre-mRNA 3´ end processing complex containing the active counterpart, CPSF-73
PseudoATPaseAllosteric regulator of conventional ATPaseEccC comprises two pseudoATPase domains that regulate the N-terminal conventional ATPase domain
PseudoGTPaseAllosteric regulator of conventional GTPaseGTP-bound Rnd1 or Rnd3/RhoE bind p190RhoGAP to regulate the catalytic activity of the conventional GTPase, RhoA
Scaffold for assembly of signalling complexesMiD51, which is catalytically dead but binds GDP or ADP, is part of a complex that recruits Drp1 to mediate mitochondrial fission. CENP-M cannot bind GTP or switch conformations, but is essential for nucleating the CENP-I, CENP-H, CENP-K small GTPase complex to regulate kinetochore assembly
Regulation of protein localisation in a cellYeast light intermediate domain (LIC) is a pseudoGTPase, devoid of nucleotide binding, which binds the dynein motor to cargo. Human LIC binds GDP in preference to GTP, suggesting nucleotide binding could confer stability rather than underlying a switch mechanism.
PseudochitinaseSubstrate recruitment or sequestrationYKL-39 binds, but does not process, chitooligosaccharides via 5 binding subsites
Pseudosialidase Scaffold for assembly of signalling complexesCyRPA nucleates assembly of the P. falciparum PfRh5/PfRipr complex that binds the erythrocyte receptor, basigin, and mediates host cell invasion
Pseudolyase Allosteric activation of conventional enzyme counterpartProzyme heterodimerisation with S-adenosylmethionine decarboxylase (AdoMetDC) activates catalytic activity 1000-fold
Pseudotransferase Allosteric activation of cellular enzyme counterpartViral GAT recruits cellular PFAS to deaminate RIG-I and counter host antiviral defence. T. brucei deoxyhypusine synthase (TbDHS) dead paralog, DHSp, binds to and activates DHSc >1000-fold.
Pseudo-histone acetyl transferase (pseudoHAT) Possible scaffold for assembly of signalling complexesHuman O-GlcNAcase (OGA) lacks catalytic residues and acetyl CoA binding, unlike bacterial counterpart
Pseudo-phospholipase Possible scaffold for assembly of signalling complexesFAM83 family proteins presumed to have acquired new functions in preference to ancestral phospholipase D catalytic activity
Allosteric inactivation of conventional enzyme counterpartViper phospholipase A2 inhibitor structurally resembles the human cellular protein it targets, phospholipase A2.
Pseudo-oxidoreductase Allosteric inactivation of conventional enzyme counterpartALDH2*2 thwarts assembly of the active counterpart, ALDH2*1, into a tetramer.
Pseudo-dismutase Allosteric activation of conventional enzyme counterpartCopper chaperone for superoxide dismutase (CCS) binds and activates catalysis by its enzyme counterpart, SOD1
Pseudo-dihydroorotase Regulating folding or complex assembly of conventional enzyme Pseudomonas pDHO is required for either folding of the aspartate transcarbamoylase catalytic subunit, or its assembly into an active oligomer
Pseudo-RNase Facilitating complex assembly/stability and promoting association of catalytic paralog KREPB4 may act as a pseudoenzyme to form the noncatalytic half of an RNase III heterodimer with the editing endonuclease(s)[26]
gollark: It's a bit bland and entirely uninhabited.
gollark: We do have access to that now since claim-entry stuff is denied.
gollark: I think I accidentally erased them at some point.
gollark: It's really a shame I can't actually find any screenshots of any servers predating mid-2019.
gollark: I think the main advantage of OC ones is just that they don't need fuel, because power is disabled.

See also

References

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  2. Kwon A, Scott S, Taujale R, Yeung W, Kochut KJ, Eyers PA, Kannan N (April 2019). "Tracing the origin and evolution of pseudokinases across the tree of life". Science Signaling. 12 (578): eaav3810. doi:10.1126/scisignal.aav3810. PMC 6997932. PMID 31015289.
  3. Jeffery CJ (Feb 2019). "The demise of catalysis, but new functions arise: pseudoenzymes as the phoenixes of the protein world". Biochemical Society Transactions. 47 (1): 371–379. doi:10.1042/BST20180473. PMID 30710059.
  4. Jeffery CJ (Dec 2019). "Multitalented actors inside and outside the cell: recent discoveries add to the number of moonlighting proteins". Biochemical Society Transactions. 47 (6): 1941–1948. doi:10.1042/BST20190798. PMID 31803903.
  5. Eyers PA, Murphy JM (November 2016). "The evolving world of pseudoenzymes: proteins, prejudice and zombies". BMC Biology. 14 (1): 98. doi:10.1186/s12915-016-0322-x. PMC 5106787. PMID 27835992.
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  9. Willert EK, Fitzpatrick R, Phillips MA (May 2007). "Allosteric regulation of an essential trypanosome polyamine biosynthetic enzyme by a catalytically dead homolog". Proceedings of the National Academy of Sciences of the United States of America. 104 (20): 8275–80. doi:10.1073/pnas.0701111104. PMC 1895940. PMID 17485680.
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  12. Manning G, Whyte DB, Martinez R, Hunter T, Sudarsanam S (December 2002). "The protein kinase complement of the human genome". Science. 298 (5600): 1912–34. doi:10.1126/science.1075762. PMID 12471243.
  13. Boudeau J, Miranda-Saavedra D, Barton GJ, Alessi DR (September 2006). "Emerging roles of pseudokinases". Trends in Cell Biology. 16 (9): 443–52. doi:10.1016/j.tcb.2006.07.003. PMID 16879967.
  14. Eyers PA, Keeshan K, Kannan N (April 2017). "Tribbles in the 21st Century: The Evolving Roles of Tribbles Pseudokinases in Biology and Disease". Trends in Cell Biology. 27 (4): 284–298. doi:10.1016/j.tcb.2016.11.002. PMC 5382568. PMID 27908682.
  15. Reiterer V, Eyers PA, Farhan H (September 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.
  16. Murphy JM, Czabotar PE, Hildebrand JM, Lucet IS, Zhang JG, Alvarez-Diaz S, Lewis R, Lalaoui N, Metcalf D, Webb AI, Young SN, Varghese LN, Tannahill GM, Hatchell EC, Majewski IJ, Okamoto T, Dobson RC, Hilton DJ, Babon JJ, Nicola NA, Strasser A, Silke J, Alexander WS (September 2013). "The pseudokinase MLKL mediates necroptosis via a molecular switch mechanism". Immunity. 39 (3): 443–53. doi:10.1016/j.immuni.2013.06.018. PMID 24012422.
  17. Wishart MJ, Dixon JE (August 1998). "Gathering STYX: phosphatase-like form predicts functions for unique protein-interaction domains". Trends in Biochemical Sciences. 23 (8): 301–6. doi:10.1016/s0968-0004(98)01241-9. PMID 9757831.
  18. Reiterer V, Eyers PA, Farhan H (September 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.
  19. Chen MJ, Dixon JE, Manning G (April 2017). "Genomics and evolution of protein phosphatases". Science Signaling. 10 (474): eaag1796. doi:10.1126/scisignal.aag1796. PMID 28400531.
  20. Zeqiraj E, Tian L, Piggott CA, Pillon MC, Duffy NM, Ceccarelli DF, Keszei AF, Lorenzen K, Kurinov I, Orlicky S, Gish GD, Heck AJ, Guarné A, Greenberg RA, Sicheri F (September 2015). "Higher-Order Assembly of BRCC36-KIAA0157 Is Required for DUB Activity and Biological Function". Molecular Cell. 59 (6): 970–83. doi:10.1016/j.molcel.2015.07.028. PMC 4579573. PMID 26344097.
  21. Strickson S, Emmerich CH, Goh ET, Zhang J, Kelsall IR, Macartney T, Hastie CJ, Knebel A, Peggie M, Marchesi F, Arthur JS, Cohen P (April 2017). "Roles of the TRAF6 and Pellino E3 ligases in MyD88 and RANKL signaling". Proceedings of the National Academy of Sciences of the United States of America. 114 (17): E3481–E3489. doi:10.1073/pnas.1702367114. PMC 5410814. PMID 28404732.
  22. Aggarwal-Howarth S, Scott JD (April 2017). "Pseudoscaffolds and anchoring proteins: the difference is in the details". Biochemical Society Transactions. 45 (2): 371–379. doi:10.1042/bst20160329. PMC 5497583. PMID 28408477.
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  26. McDermott SM, Stuart K (November 2017). "The essential functions of KREPB4 are developmentally distinct and required for endonuclease association with editosomes". RNA. 23 (11): 1672–1684. doi:10.1261/rna.062786.117. PMC 5648035. PMID 28802260.
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