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Literature DB >> 19107417

Purification of SUMO conjugating enzymes and kinetic analysis of substrate conjugation.

Abstract

SUMO conjugation to protein substrates requires the concerted action of a dedicated E2 ubiquitin conjugation enzyme (Ubc9) and associated E3 ligases. Although Ubc9 can directly recognize and modify substrate lysine residues that occur within a consensus site for SUMO modification, E3 ligases can redirect specificity and enhance conjugation rates during SUMO conjugation in vitro and in vivo. In this chapter, we will describe methods utilized to purify SUMO conjugating enzymes and model substrates which can be used for analysis of SUMO conjugation in vitro. We will also describe methods to extract kinetic parameters during E3-dependent or E3-independent substrate conjugation.

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Year: 2009 PMID： 19107417 PMCID： PMC2739043 DOI： 10.1007/978-1-59745-566-4_11

Source DB: PubMed Journal: Methods Mol Biol ISSN： 1064-3745

22 in total

Review 1. SUMO, ubiquitin's mysterious cousin.

Authors: S Müller; C Hoege; G Pyrowolakis; S Jentsch
Journal: Nat Rev Mol Cell Biol Date: 2001-03 Impact factor: 94.444

Review 2. SUMO--nonclassical ubiquitin.

Authors: F Melchior
Journal: Annu Rev Cell Dev Biol Date: 2000 Impact factor: 13.827

3. Ulp1-SUMO crystal structure and genetic analysis reveal conserved interactions and a regulatory element essential for cell growth in yeast.

Authors: E Mossessova; C D Lima
Journal: Mol Cell Date: 2000-05 Impact factor: 17.970

4. Structural basis for E2-mediated SUMO conjugation revealed by a complex between ubiquitin-conjugating enzyme Ubc9 and RanGAP1.

Authors: Victor Bernier-Villamor; Deborah A Sampson; Michael J Matunis; Christopher D Lima
Journal: Cell Date: 2002-02-08 Impact factor: 41.582

Review 5. SP-RING for SUMO: new functions bloom for a ubiquitin-like protein.

Authors: M Hochstrasser
Journal: Cell Date: 2001-10-05 Impact factor: 41.582

6. The nucleoporin RanBP2 has SUMO1 E3 ligase activity.

Authors: Andrea Pichler; Andreas Gast; Jacob S Seeler; Anne Dejean; Frauke Melchior
Journal: Cell Date: 2002-01-11 Impact factor: 41.582

7. An E3-like factor that promotes SUMO conjugation to the yeast septins.

Authors: E S Johnson; A A Gupta
Journal: Cell Date: 2001-09-21 Impact factor: 41.582

8. A novel factor required for the SUMO1/Smt3 conjugation of yeast septins.

Authors: Y Takahashi; A Toh-e; Y Kikuchi
Journal: Gene Date: 2001-09-19 Impact factor: 3.688

9. Involvement of PIAS1 in the sumoylation of tumor suppressor p53.

Authors: T Kahyo; T Nishida; H Yasuda
Journal: Mol Cell Date: 2001-09 Impact factor: 17.970

10. SUMO modifications control assembly of synaptonemal complex and polycomplex in meiosis of Saccharomyces cerevisiae.

Authors: Chung-Hsu Cheng; Yu-Hui Lo; Shu-Shan Liang; Shih-Chieh Ti; Feng-Ming Lin; Chia-Hui Yeh; Han-Yi Huang; Ting-Fang Wang
Journal: Genes Dev Date: 2006-07-17 Impact factor: 11.361

27 in total

1. E2-mediated small ubiquitin-like modifier (SUMO) modification of thymine DNA glycosylase is efficient but not selective for the enzyme-product complex.

Authors: Christopher T Coey; Megan E Fitzgerald; Atanu Maiti; Katherine H Reiter; Catherine M Guzzo; Michael J Matunis; Alexander C Drohat
Journal: J Biol Chem Date: 2014-04-21 Impact factor: 5.157

2. Interactions of the Metalloregulatory Protein SloR from Streptococcus mutans with Its Metal Ion Effectors and DNA Binding Site.

Authors: Grace Spatafora; John Corbett; Louis Cornacchione; William Daly; Diego Galan; Michael Wysota; Patrick Tivnan; Justin Collins; Dillon Nye; Talya Levitz; Wendy A Breyer; Arthur Glasfeld
Journal: J Bacteriol Date: 2015-09-08 Impact factor: 3.490

3. Phage display to identify Nedd8-mimicking peptides as inhibitors of the Nedd8 transfer cascade.

Authors: Bo Zhao; Keya Zhang; Eric B Villhauer; Karan Bhuripanyo; Hiroaki Kiyokawa; Hermann Schindelin; Jun Yin
Journal: Chembiochem Date: 2013-07-03 Impact factor: 3.164

4. Detection of TAR DNA-binding protein 43 (TDP-43) oligomers as initial intermediate species during aggregate formation.

Authors: Rachel L French; Zachary R Grese; Himani Aligireddy; Dhruva D Dhavale; Ashley N Reeb; Niraja Kedia; Paul T Kotzbauer; Jan Bieschke; Yuna M Ayala
Journal: J Biol Chem Date: 2019-03-01 Impact factor: 5.157

5. Heat Shock-induced Phosphorylation of TAR DNA-binding Protein 43 (TDP-43) by MAPK/ERK Kinase Regulates TDP-43 Function.

Authors: Wen Li; Ashley N Reeb; Binyan Lin; Praveen Subramanian; Erin E Fey; Catherine R Knoverek; Rachel L French; Eileen H Bigio; Yuna M Ayala
Journal: J Biol Chem Date: 2017-02-06 Impact factor: 5.157

6. Measuring rates of ubiquitin chain formation as a functional readout of ligase activity.

Authors: Virginia P Ronchi; Arthur L Haas
Journal: Methods Mol Biol Date: 2012

7. A Hyperthermophilic Phage Decoration Protein Suggests Common Evolutionary Origin with Herpesvirus Triplex Proteins and an Anti-CRISPR Protein.

Authors: Nicholas P Stone; Brendan J Hilbert; Daniel Hidalgo; Kevin T Halloran; Jooyoung Lee; Erik J Sontheimer; Brian A Kelch
Journal: Structure Date: 2018-05-17 Impact factor: 5.006