Ubc9

From Proteopedia

(Difference between revisions)

Revision as of 23:25, 25 February 2015

Ubc9 is a ubiquitin conjugating enzyme (E2) whose function involves transfer of ubiquitin or small ubiquitin-like modifier (SUMO) from ubiquitin activating enzyme (E1) to its designated substrate. is specifically involved in SUMO transfer ^[1].

Structure

Murine/human Ubc9 exhibits a single domain structure consisting of both alpha helices and beta-pleated sheets (PDB: 1U9A). has been identified as the active residue and is located on a loop of amino acids (78-108) between beta sheet four and alpha helix two ^[1]. Amino acids surrounding the active site have been shown to play a role in catalysis of SUMO transfer to substrate via the suppression the the substrate lysine side chain pKa, which serves the purpose of nucleophile activation ^[2].

Crystal structure has shown that Ubc9 is the central protein in the SUMO-RanGAP1-Ubc9-Nup358 (PDB: 1Z5S), which forms in such a way as to enhance conjugation and transfer of the SUMO to substrate ^[3].

Along with the formation of a thioester bond the its substrate, Ubc9 can also interact noncovelently with SUMO. Crystal structure of the (PDB: 2UYZ) shows that the Ubc9 residues involved in this interaction are located at the end of helix one, on beta strand one, and along the following loop. These residues were shown to interact with the beta sheet of SUMO1 ^[4].

Function

Ubc9 is enzymatically involved in the SUMOylation process. It is the enzyme responsible for ligating the SUMO to the protein. Depending on whether the reaction is done in vitro, it will ligate the SUMO directly to the substrate, and if done in vivo, the SUMO will be ligated to the conjugating enzyme and then put onto the substrate ^[5]. Initially, a thioester bond is formed between the SUMO and the E1 enzyme via an ATP-dependent reaction. The SUMO is then transferred to the active cysteine of the E2, in this case, Ubc9. The SUMO is then ligated to a lysine side chain amino group of the substrate, during which an E3 enzyme may or may not be recruited. The use of E3 mediated transfer serves functions such as increasing the specificity for the substrate to be SUMOylated ^[4].

Kinetic analysis has shown that the Ubc9 amino acids , which are in close proximity to the active site Cys93, play a role in substrate recongnition within the thioester Ubc9-SUMO1 complex. These amino acids are not found in other E2 enzymes, making their involvement in SUMO conjugation unique to Ubc9 ^[6].

SUMOylation has been shown to enhance processes such as DNA methyltransferse 1 enzymatic activity, which has a major regulatory effect on gene transcription ^[7]. The transcription factor AP-2 is SUMOylated by Ubc9, a process which decreases the transcription activation potential of AP-2, thus having an effect on gene transcription, and therefore likely having an effect on gene expression as well ^[8].

Noncovalent interaction between Ubc9 and SUMO distant from the active site have been shown to be critical in the formation of SUMO chains, upon which in vivo functions such as metabolic regulation and signaling are dependent. Mutagenesis studies on the noncovalent Ubc9-SUMO1 complex have shown that Ubc9H20D and SUMO1E67R mutation cause inhibition of noncovalent interaction between the two, and thus inhibit complex formation. A similar interaction is seen in the Ubc9-SUMO2 complex ^[4]. Lack of noncovalent interaction between Ubc9 and SUMO2 has been shown to inhibit SUMO2 chain formation ^[4]. NMR studies of Ubc9 have demonstrated that noncovalent interactions between SUMO-1 and Ubc9 play a critical role in the transfer of SUMO-1 from the activating enzyme (E1) to the conjugating enzyme (E2) ^[9].

Disease

Expression of Ubc9 has been found to be related to causing human diseases such as cancer, neurodegenerative diseases, and heart diseases. Studies have shown it to interact with tumor suppressor proteins such as p53, p63, and p73 and fundamental in the tumor progression and preventing apoptotic pathways ^[10].

Anything in this section will appear adjacent to the 3D structure and will be scrollable.

References

↑ ^1.0 ^1.1 Tong H, Hateboer G, Perrakis A, Bernards R, Sixma TK. Crystal structure of murine/human Ubc9 provides insight into the variability of the ubiquitin-conjugating system. J Biol Chem. 1997 Aug 22;272(34):21381-7. PMID:9261152
↑ Yunus AA, Lima CD. Lysine activation and functional analysis of E2-mediated conjugation in the SUMO pathway. Nat Struct Mol Biol. 2006 Jun;13(6):491-9. Epub 2006 May 28. PMID:16732283 doi:http://dx.doi.org/10.1038/nsmb1104
↑ Reverter D, Lima CD. Insights into E3 ligase activity revealed by a SUMO-RanGAP1-Ubc9-Nup358 complex. Nature. 2005 Jun 2;435(7042):687-92. PMID:15931224 doi:10.1038/nature03588
↑ ^4.0 ^4.1 ^4.2 ^4.3 Knipscheer P, van Dijk WJ, Olsen JV, Mann M, Sixma TK. Noncovalent interaction between Ubc9 and SUMO promotes SUMO chain formation. EMBO J. 2007 Jun 6;26(11):2797-807. Epub 2007 May 10. PMID:17491593
↑ Gupta MK, Gulick J, Liu R, Wang X, Molkentin JD, Robbins J. Sumo E2 enzyme UBC9 is required for efficient protein quality control in cardiomyocytes. Circ Res. 2014 Sep 26;115(8):721-9. doi: 10.1161/CIRCRESAHA.115.304760. Epub 2014, Aug 5. PMID:25097219 doi:http://dx.doi.org/10.1161/CIRCRESAHA.115.304760
↑ Tatham MH, Chen Y, Hay RT. Role of two residues proximal to the active site of Ubc9 in substrate recognition by the Ubc9.SUMO-1 thiolester complex. Biochemistry. 2003 Mar 25;42(11):3168-79. PMID:12641448 doi:http://dx.doi.org/10.1021/bi026861x
↑ Lee B, Muller MT. SUMOylation enhances DNA methyltransferase 1 activity. Biochem J. 2009 Jul 15;421(3):449-61. doi: 10.1042/BJ20090142. PMID:19450230 doi:http://dx.doi.org/10.1042/BJ20090142
↑ Kulinski A, Rustaeus S, Vance JE. Microsomal triacylglycerol transfer protein is required for lumenal accretion of triacylglycerol not associated with ApoB, as well as for ApoB lipidation. J Biol Chem. 2002 Aug 30;277(35):31516-25. Epub 2002 Jun 18. PMID:12072432 doi:http://dx.doi.org/10.1074/jbc.M202015200
↑ Tatham MH, Kim S, Yu B, Jaffray E, Song J, Zheng J, Rodriguez MS, Hay RT, Chen Y. Role of an N-terminal site of Ubc9 in SUMO-1, -2, and -3 binding and conjugation. Biochemistry. 2003 Aug 26;42(33):9959-69. PMID:12924945 doi:http://dx.doi.org/10.1021/bi0345283
↑ Kumar A, Ito A, Hirohama M, Yoshida M, Zhang KY. Identification of sumoylation inhibitors targeting a predicted pocket in Ubc9. J Chem Inf Model. 2014 Oct 27;54(10):2784-93. doi: 10.1021/ci5004015. Epub 2014, Sep 18. PMID:25191977 doi:http://dx.doi.org/10.1021/ci5004015

Proteopedia Page Contributors and Editors (what is this?)

Byron H. Young, Saieh Bijani, Michal Harel

Retrieved from "http://52.214.119.220/wiki/index.php/Ubc9"

@@ Line 12: / Line 12: @@
 == Function ==
-''Ubc9'' is enzymatically involved in the SUMOylation process. It is the enzyme responsible for ligating the SUMO to the protein. Depending on whether the reaction is done ''in vitro'', it will ligate the SUMO directly to the substrate, and if done ''in vivo'', the SUMO will be ligated to the conjugating enzyme and then put onto the substrate <ref name="protein control">PMID:25097219</ref>. Initially, a thioester bond is formed between the SUMO and the E1 enzyme via an ATP-dependent reaction. The SUMO is then transferred to the active cystein of the E2, in this case, Ubc9. The SUMO is then ligated to a lysine side chain amino group of the substrate, during which an E3 enzyme may or may not be recruited. The use of E3 mediated transfer serves functions such as increasing the specificity for the substrate to be SUMOylated <ref name="ubcsumocomplex"/>.
+''Ubc9'' is enzymatically involved in the SUMOylation process. It is the enzyme responsible for ligating the SUMO to the protein. Depending on whether the reaction is done ''in vitro'', it will ligate the SUMO directly to the substrate, and if done ''in vivo'', the SUMO will be ligated to the conjugating enzyme and then put onto the substrate <ref name="protein control">PMID:25097219</ref>. Initially, a thioester bond is formed between the SUMO and the E1 enzyme via an ATP-dependent reaction. The SUMO is then transferred to the active cysteine of the E2, in this case, Ubc9. The SUMO is then ligated to a lysine side chain amino group of the substrate, during which an E3 enzyme may or may not be recruited. The use of E3 mediated transfer serves functions such as increasing the specificity for the substrate to be SUMOylated <ref name="ubcsumocomplex"/>.
 Kinetic analysis has shown that the Ubc9 amino acids <scene name='69/694804/Cys93lys101asp100/2'>Asp100 and Lys101</scene>, which are in close proximity to the active site Cys93, play a role in substrate recongnition within the thioester Ubc9-SUMO1 complex. These amino acids are not found in other E2 enzymes, making their involvement in SUMO conjugation unique to Ubc9 <ref name="asp100lys101">PMID:12641448</ref>.
@@ Line 18: / Line 18: @@
 SUMOylation has been shown to enhance processes such as DNA methyltransferse 1 enzymatic activity, which has a major regulatory effect on gene transcription <ref name="DNMT1 activity">PMID:19450230</ref>. The transcription factor AP-2 is SUMOylated by Ubc9, a process which decreases the transcription activation potential of AP-2, thus having an effect on gene transcription, and therefore likely having an effect on gene expression as well <ref name="factor AP2">PMID:12072432</ref>.
-Noncovalent interaction between Ubc9 and SUMO distant from the active site have been shown to be critical in the formation of SUMO chains, upon which ''in vivo'' functions such as metabolic regulation and signaling are dependent. Mutagenesis studies on the noncovalent ''Ubc9''-SUMO1 complex have shown that ''Ubc9H20D'' and ''SUMO1E67R'' mutation cause inhibition of noncovalent interaction between the two, and thus inhibit complex formation. A similar interaction is seen in the ''Ubc9''-SUMO2 complex <ref name="ubcsumocomplex"/>. Lack of noncovalent interaction between ''Ubc9'' and SUMO2 has been shown to inhibit SUMO2 chain formation <ref name="ubcsumocomplex"/>. NMR studies of Ubc9 have shown that noncovalent interaction between SUMO-1 and Ubc9 play a critical role in the transfer of SUMO-1 from the activating enzyme (E1) to the conjugating enzyme (E2) <ref name="noncovalent Nterminal">PMID:12924945</ref>.
+Noncovalent interaction between Ubc9 and SUMO distant from the active site have been shown to be critical in the formation of SUMO chains, upon which ''in vivo'' functions such as metabolic regulation and signaling are dependent. Mutagenesis studies on the noncovalent ''Ubc9''-SUMO1 complex have shown that ''Ubc9H20D'' and ''SUMO1E67R'' mutation cause inhibition of noncovalent interaction between the two, and thus inhibit complex formation. A similar interaction is seen in the ''Ubc9''-SUMO2 complex <ref name="ubcsumocomplex"/>. Lack of noncovalent interaction between ''Ubc9'' and SUMO2 has been shown to inhibit SUMO2 chain formation <ref name="ubcsumocomplex"/>. NMR studies of Ubc9 have demonstrated that noncovalent interactions between SUMO-1 and Ubc9 play a critical role in the transfer of SUMO-1 from the activating enzyme (E1) to the conjugating enzyme (E2) <ref name="noncovalent Nterminal">PMID:12924945</ref>.
 == Disease ==

Ubc9

From Proteopedia

Revision as of 23:25, 25 February 2015

Structure

Function

Disease

References

Proteopedia Page Contributors and Editors (what is this?)

Views

Personal tools

Navigation

Search

Toolbox