3pu3 Citations

Structural basis for human PHF2 Jumonji domain interaction with metal ions.

Horton JR, Upadhyay AK, Hashimoto H, Zhang X, Cheng X
J Mol Biol 406 1-8 (2011)
Related entries: 3ptr, 3pu8, 3pua, 3pus

Cited: 35 times
EuropePMC logo PMID: 21167174

Abstract

PHF2 belongs to a class of α-ketoglutarate-Fe(2)(+)-dependent dioxygenases. PHF2 harbors a plant homeodomain (PHD) and a Jumonji domain. PHF2, via its PHD, binds Lys4-trimethylated histone 3 in submicromolar affinity and has been reported to have the demethylase activity of monomethylated lysine 9 of histone 3 in vivo. However, we did not detect demethylase activity for PHF2 Jumonji domain (with and without its linked PHD) in the context of histone peptides. We determined the crystal structures of PHF2 Jumonji domain in the absence and presence of additional exogenous metal ions. When Fe(2+) or Ni(2+) was added at a high concentration (50 mM) and allowed to soak in the preformed crystals, Fe(2+) or Ni(2+) was bound by six ligands in an octahedral coordination. The side chains of H249 and D251 and the two oxygen atoms of N-oxalylglycine (an analog of α-ketoglutarate) provide four coordinations in the equatorial plane, while the hydroxyl oxygen atom of Y321 and one water molecule provide the two axial coordinations as the fifth and sixth ligands, respectively. The metal binding site in PHF2 closely resembles the Fe(2+) sites in other Jumonji domains examined, with one important difference-a tyrosine (Y321 of PHF2) replaces histidine as the fifth ligand. However, neither Y321H mutation nor high metal concentration renders PHF2 an active demethylase on histone peptides. Wild type and Y321H mutant bind Ni(2+) with an approximately equal affinity of 50 μM. We propose that there must be other regulatory factors required for the enzymatic activity of PHF2 in vivo or that perhaps PHF2 acts on non-histone substrates. Furthermore, PHF2 shares significant sequence homology throughout the entire region, including the above-mentioned tyrosine at the corresponding iron-binding position, with that of Schizosaccharomyces pombe Epe1, which plays an essential role in heterochromatin function but has no known enzymatic activity.

Reviews - 3pu3 mentioned but not cited (2)

  1. The role of histone demethylases in cancer therapy. Hoffmann I, Roatsch M, Schmitt ML, Carlino L, Pippel M, Sippl W, Jung M. Mol Oncol 6 683-703 (2012)
  2. Modulation of epigenetic targets for anticancer therapy: clinicopathological relevance, structural data and drug discovery perspectives. Andreoli F, Barbosa AJ, Parenti MD, Del Rio A. Curr Pharm Des 19 578-613 (2013)

Articles - 3pu3 mentioned but not cited (2)

  1. Structural basis for human PHF2 Jumonji domain interaction with metal ions. Horton JR, Upadhyay AK, Hashimoto H, Zhang X, Cheng X. J Mol Biol 406 1-8 (2011)
  2. Coordinated methyl-lysine erasure: structural and functional linkage of a Jumonji demethylase domain and a reader domain. Upadhyay AK, Horton JR, Zhang X, Cheng X. Curr Opin Struct Biol 21 750-760 (2011)


Reviews citing this publication (10)

  1. Histone lysine demethylases as targets for anticancer therapy. Højfeldt JW, Agger K, Helin K. Nat Rev Drug Discov 12 917-930 (2013)
  2. 2-Oxoglutarate-Dependent Oxygenases. Islam MS, Leissing TM, Chowdhury R, Hopkinson RJ, Schofield CJ. Annu Rev Biochem 87 585-620 (2018)
  3. Mechanisms of human histone and nucleic acid demethylases. Walport LJ, Hopkinson RJ, Schofield CJ. Curr Opin Chem Biol 16 525-534 (2012)
  4. Inhibitors of Protein Methyltransferases and Demethylases. Kaniskan HÜ, Martini ML, Jin J. Chem Rev 118 989-1068 (2018)
  5. Histone demethylases in chromatin biology and beyond. Dimitrova E, Turberfield AH, Klose RJ. EMBO Rep 16 1620-1639 (2015)
  6. Chemical and Biochemical Perspectives of Protein Lysine Methylation. Luo M. Chem Rev 118 6656-6705 (2018)
  7. Structure-function relationships of human JmjC oxygenases-demethylases versus hydroxylases. Markolovic S, Leissing TM, Chowdhury R, Wilkins SE, Lu X, Schofield CJ. Curr Opin Struct Biol 41 62-72 (2016)
  8. Small-molecular modulators of cancer-associated epigenetic mechanisms. Itoh Y, Suzuki T, Miyata N. Mol Biosyst 9 873-896 (2013)
  9. Structural analysis of enzymes used for bioindustry and bioremediation. Tanokura M, Miyakawa T, Guan L, Hou F. Biosci Biotechnol Biochem 79 1391-1401 (2015)
  10. Cellular Dynamics of Transition Metal Exchange on Proteins: A Challenge but a Bonanza for Coordination Chemistry. Moulis JM. Biomolecules 10 E1584 (2020)

Articles citing this publication (21)

  1. OsVIL2 functions with PRC2 to induce flowering by repressing OsLFL1 in rice. Yang J, Lee S, Hang R, Kim SR, Lee YS, Cao X, Amasino R, An G. Plant J 73 566-578 (2013)
  2. The histone demethylase Phf2 acts as a molecular checkpoint to prevent NAFLD progression during obesity. Bricambert J, Alves-Guerra MC, Esteves P, Prip-Buus C, Bertrand-Michel J, Guillou H, Chang CJ, Vander Wal MN, Canonne-Hergaux F, Mathurin P, Raverdy V, Pattou F, Girard J, Postic C, Dentin R. Nat Commun 9 2092 (2018)
  3. Protein similarity networks reveal relationships among sequence, structure, and function within the Cupin superfamily. Uberto R, Moomaw EW. PLoS One 8 e74477 (2013)
  4. Oxidative cyclizations in orthosomycin biosynthesis expand the known chemistry of an oxygenase superfamily. McCulloch KM, McCranie EK, Smith JA, Sarwar M, Mathieu JL, Gitschlag BL, Du Y, Bachmann BO, Iverson TM. Proc Natl Acad Sci U S A 112 11547-11552 (2015)
  5. PHD finger protein 2 (PHF2) represses ribosomal RNA gene transcription by antagonizing PHF finger protein 8 (PHF8) and recruiting methyltransferase SUV39H1. Shi G, Wu M, Fang L, Yu F, Cheng S, Li J, Du JX, Wong J. J Biol Chem 289 29691-29700 (2014)
  6. Crystal structure of a novel N-substituted L-amino acid dioxygenase from Burkholderia ambifaria AMMD. Qin HM, Miyakawa T, Jia MZ, Nakamura A, Nakamura A, Ohtsuka J, Xue YL, Kawashima T, Kasahara T, Hibi M, Ogawa J, Tanokura M. PLoS One 8 e63996 (2013)
  7. PHF2 regulates homology-directed DNA repair by controlling the resection of DNA double strand breaks. Alonso-de Vega I, Paz-Cabrera MC, Rother MB, Wiegant WW, Checa-Rodríguez C, Hernández-Fernaud JR, Huertas P, Freire R, van Attikum H, Smits VAJ. Nucleic Acids Res 48 4915-4927 (2020)
  8. An H3K9 methylation-dependent protein interaction regulates the non-enzymatic functions of a putative histone demethylase. Raiymbek G, An S, Khurana N, Gopinath S, Larkin A, Biswas S, Trievel RC, Cho US, Ragunathan K. Elife 9 e53155 (2020)
  9. Structural investigations of the nickel-induced inhibition of truncated constructs of the JMJD2 family of histone demethylases using X-ray absorption spectroscopy. Giri NC, Passantino L, Sun H, Zoroddu MA, Costa M, Maroney MJ. Biochemistry 52 4168-4183 (2013)
  10. Histone H3 N-terminal mimicry drives a novel network of methyl-effector interactions. Chen J, Horton J, Sagum C, Zhou J, Cheng X, Bedford MT. Biochem J 478 1943-1958 (2021)
  11. Synthesis of 2-oxoglutarate derivatives and their evaluation as cosubstrates and inhibitors of human aspartate/asparagine-β-hydroxylase. Brewitz L, Nakashima Y, Schofield CJ. Chem Sci 12 1327-1342 (2020)
  12. Regioselectivity of hyoscyamine 6β-hydroxylase-catalysed hydroxylation as revealed by high-resolution structural information and QM/MM calculations. Kluza A, Wojdyla Z, Mrugala B, Kurpiewska K, Porebski PJ, Niedzialkowska E, Minor W, Weiss MS, Borowski T. Dalton Trans 49 4454-4469 (2020)
  13. Human Oxygenase Variants Employing a Single Protein FeII Ligand Are Catalytically Active. Brasnett A, Pfeffer I, Brewitz L, Chowdhury R, Nakashima Y, Tumber A, McDonough MA, Schofield CJ. Angew Chem Int Ed Engl 60 14657-14663 (2021)
  14. Identification of family determining residues in Jumonji-C lysine demethylases: A sequence-based, family wide classification. Slama P. Proteins 84 397-407 (2016)
  15. A metal-binding site in the RTN1-C protein: new perspectives on the physiological role of a neuronal protein. Nepravishta R, Polizio F, Paci M, Melino S. Metallomics 4 480-487 (2012)
  16. A complete methyl-lysine binding aromatic cage constructed by two domains of PHF2. Horton JR, Zhou J, Chen Q, Zhang X, Bedford MT, Cheng X. J Biol Chem 299 102862 (2023)
  17. A study on the structure, mechanism, and biochemistry of kanamycin B dioxygenase (KanJ)-an enzyme with a broad range of substrates. Mrugała B, Miłaczewska A, Porebski PJ, Niedzialkowska E, Guzik M, Minor W, Borowski T. FEBS J 288 1366-1386 (2021)
  18. Cyclic peptides target the aromatic cage of a PHD-finger reader domain to modulate epigenetic protein function. Coleman OD, Macdonald J, Thomson B, Ward JA, Stubbs CJ, McAllister TE, Clark S, Amin S, Cao Y, Abboud MI, Zhang Y, Sanganee H, Huber KVM, Claridge TDW, Kawamura A. Chem Sci 14 7136-7146 (2023)
  19. KDM7 Demethylases: Regulation, Function and Therapeutic Targeting. Shao P, Liu Q, Qi HH. Adv Exp Med Biol 1433 167-184 (2023)
  20. Kinetic and inhibition studies on human Jumonji-C (JmjC) domain-containing protein 5. Tumber A, Salah E, Brewitz L, Corner TP, Schofield CJ. RSC Chem Biol 4 399-413 (2023)
  21. Phosphorylation of PHF2 by AMPK releases the repressive H3K9me2 and inhibits cancer metastasis. Dong Y, Hu H, Zhang X, Zhang Y, Sun X, Wang H, Kan W, Tan MJ, Shi H, Zang Y, Li J. Signal Transduct Target Ther 8 95 (2023)


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