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Sandbox 820

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Revision as of 21:36, 24 February 2015

UBA1

Function

UBA1 is an E1 protein involved in the ubiquitination pathway found in Saccharomyces cerevisia, baker’s yeast1-4. Ubiquitination, a post-translational modification that conjugates ubiquitin to a target protein, has been shown to have important cellular effects, such as the marking of a protein for degradation4. Ubiquitination is carried out in a three step enzymatic cascade2 that utilizes E1, E2, and E3 enzymes. The ubiquitin cascade starts when E1 is adenylated at its carboxyl terminal glycine3, then the ubiquitin is linked to a cysteine in the E1 resulting in an E1~Ub thioester bond2,3,4. This ATP consuming step is followed by a ubiquitin transfer to an E2. An E3 enzyme, along with E2, then catalyzes (induces) the ubiquitination of the target protein.3,4

Structural highlights

The of Uba1 consists of six structural domains (IAD, AAD, FCCH, SCCH, 4HB, and UFD), four of which pack together to create a central cavity.{Lee, 2008} The cavity is divided into two distinct clefts (left and right) by the SCCH/AAD linker fragment.{Lee, 2008} Uba1 exists as a in solution, with two monomers interacting in a noncovalent manner. Ubiquitin binds to the cysteine located on the right cleft of Uba1 which allows for Ubiquitin to orient itself relative to the active site located on the left cleft.{Lee, 2008} The structure of results in a change in conformation that buries a significant portion of Uba1 exposed surface area.{Lee, 2008} The located on the SCCH domain of Uba1 forms a thioester with the C-terminus of Ubiquitin, forming a thioester complex.{Lee, 2008} It is suggested that a significant conformation change occurs when Ubiquitin binds to Uba1 due to the large distance (~35 Å) between the catalytic cysteine residue and the adenylation active site.{Lee, 2008; Walden, 2003} When Ubiquitin binds, Uba1 then coordinates the transfer of Ubiquitin onto an E2 enzyme.{Lee, 2008} The E2 enzyme with Uba1 in the cavity where a transthioesterfication of Ubiquitin from the catalytic cysteine of Uba1 to the catalytic cysteine of the E2 occurs.{Lee, 2008} The E2, in conjunction with the E3 enzyme, transfers the Ubiquitin onto its final substrate.

References

Lee I, Schindelin H. Structural Insights into E1-Catalyzed Ubiquitin Activation and Transfer to Conjugating Enzymes. Cell 134, 268–278 (2008).

Walden H, Podgorski MS, Huang DT, Miller DW, Howard RJ, Minor DL Jr, Holton JM, Schulman BA. The structure of the APPBP1-UBA3-NEDD8-ATP complex reveals the basis for selective ubiquitin-like protein activation by an E1. Molecular Cell 12, 1427–1437 (2003).

1. Groettrup, M.; Pelzer, C.; Schmidtke, G.; Hofmann, K. Activating the ubiquitin family: UBA6 challenges the field. Trends Biochem. Sci. 2008, 33, 230-237. DOI:http://dx.doi.org/10.1016/j.tibs.2008.01.005

2. Chen, Z. J.; Sun, L. J. Nonproteolytic Functions of Ubiquitin in Cell Signaling. Mol. Cell 2009, 33, 275-286. DOI:http://dx.doi.org/10.1016/j.molcel.2009.01.014. 3. McGrath, J. P.; Jentsch, S.; Varshavsky, A. UBA 1: an essential yeast gene encoding ubiquitin-activating enzyme. EMBO J. 1991, 10, 227-236. 4. Lee, I.; Schindelin, H. Structural Insights into E1-Catalyzed Ubiquitin Activation and Transfer to Conjugating Enzymes. Cell 2008, 134, 268-278. DOI:http://dx.doi.org/10.1016/j.cell.2008.05.046.

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Sandbox 820

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UBA1

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@@ Line 3: / Line 3: @@
 == Function ==
-UBA1's place in the Ubiquitination process, E1 what that means etc.
+UBA1 is an E1 protein involved in the ubiquitination pathway found in Saccharomyces cerevisia, baker’s yeast1-4. Ubiquitination, a post-translational modification that conjugates ubiquitin to a target protein, has been shown to have important cellular effects, such as the marking of a protein for degradation4. Ubiquitination is carried out in a three step enzymatic cascade2 that utilizes E1, E2, and E3 enzymes. The ubiquitin cascade starts when E1 is adenylated at its carboxyl terminal glycine3, then the ubiquitin is linked to a cysteine in the E1 resulting in an E1~Ub thioester bond2,3,4. This ATP consuming step is followed by a ubiquitin transfer to an E2. An E3 enzyme, along with E2, then catalyzes (induces) the ubiquitination of the target protein.3,4
 == Structural highlights ==
-The <scene name='69/695713/Uba1/1'>monomeric structure</scene> of Uba1 consists of six structural domains (IAD, AAD, FCCH, SCCH, 4HB, and UFD), four of which pack together to create a central canyon.{Lee, 2008}  The canyon is divided into two distinct clefts (left and right) by the SCCH/AAD linker fragment.{Lee, 2008} Uba1 exists as a <scene name='69/695713/Uba1/6'>dimer</scene> in solution, with two monomers interacting in a noncovalent manner. Ubiquitin binds to the cysteine located on the right cleft of Uba1 which allows for Ubiquitin to orient itself relative to the active site located on the left cleft.{Lee, 2008} The structure of <scene name='69/695713/Uba1_monomeric_ub/2'>Ubiquitin bound to Uba1</scene> results in a change in conformation that buries a significant portion of Uba1 exposed surface area.{Lee, 2008}  The <scene name='69/695713/Uba1_monomeric_ub_catcys_hi/1'>catalytic cysteine</scene> located on the SCCH domain of Uba1 forms a thioester with the C-terminus of Ubiquitin, forming a  thioester complex.{Lee, 2008} It is suggested that a significant conformation change occurs when Ubiquitin binds to Uba1 due to the large distance (~35 Å) between the catalytic cysteine residue and the adenylation active site.{Lee, 2008; Walden, 2003} When Ubiquitin binds, Uba1 then coordinates the transfer of Ubiquitin onto an E2 enzyme.{Lee, 2008} A transthioesterfication of Ubiquitin from the catalytic cysteine of Uba1 to the catalytic cysteine of the E2 occurs when Uba1 and E2 interact.{Lee, 2008} The E2, in conjunction with the E3 enzyme, transfers the Ubiquitin onto its final substrate.
+The <scene name='69/695713/Uba1/1'>monomeric structure</scene> of Uba1 consists of six structural domains (IAD, AAD, FCCH, SCCH, 4HB, and UFD), four of which pack together to create a central cavity.{Lee, 2008}  The cavity is divided into two distinct clefts (left and right) by the SCCH/AAD linker fragment.{Lee, 2008} Uba1 exists as a <scene name='69/695713/Uba1/6'>dimer</scene> in solution, with two monomers interacting in a noncovalent manner. Ubiquitin binds to the cysteine located on the right cleft of Uba1 which allows for Ubiquitin to orient itself relative to the active site located on the left cleft.{Lee, 2008} The structure of <scene name='69/695713/Uba1_monomeric_ub/2'>Ubiquitin bound to Uba1</scene> results in a change in conformation that buries a significant portion of Uba1 exposed surface area.{Lee, 2008}  The <scene name='69/695713/Uba1_monomeric_ub_catcys_hi/1'>catalytic cysteine</scene> located on the SCCH domain of Uba1 forms a thioester with the C-terminus of Ubiquitin, forming a  thioester complex.{Lee, 2008} It is suggested that a significant conformation change occurs when Ubiquitin binds to Uba1 due to the large distance (~35 Å) between the catalytic cysteine residue and the adenylation active site.{Lee, 2008; Walden, 2003} When Ubiquitin binds, Uba1 then coordinates the transfer of Ubiquitin onto an E2 enzyme.{Lee, 2008} The E2 enzyme <scene name='69/695713/Uba1_ubc4/1'>interacts</scene> with Uba1 in the cavity where   a transthioesterfication of Ubiquitin from the catalytic cysteine of Uba1 to the catalytic cysteine of the E2 occurs.{Lee, 2008} The E2, in conjunction with the E3 enzyme, transfers the Ubiquitin onto its final substrate.
 == References ==
 Lee I, Schindelin H. Structural Insights into E1-Catalyzed Ubiquitin Activation and Transfer to Conjugating Enzymes. Cell 134, 268–278 (2008).
 Walden H, Podgorski MS, Huang DT, Miller DW, Howard RJ, Minor DL Jr, Holton JM, Schulman BA. The structure of the APPBP1-UBA3-NEDD8-ATP complex reveals the basis for selective ubiquitin-like protein activation by an E1. Molecular Cell 12, 1427–1437 (2003).
+. Groettrup, M.; Pelzer, C.; Schmidtke, G.; Hofmann, K. Activating the ubiquitin family: UBA6 challenges the field. Trends Biochem. Sci. 2008, 33, 230-237. DOI:http://dx.doi.org/10.1016/j.tibs.2008.01.005
+. Chen, Z. J.; Sun, L. J. Nonproteolytic Functions of Ubiquitin in Cell Signaling. Mol. Cell 2009, 33, 275-286. DOI:http://dx.doi.org/10.1016/j.molcel.2009.01.014.
+. McGrath, J. P.; Jentsch, S.; Varshavsky, A. UBA 1: an essential yeast gene encoding ubiquitin-activating enzyme. EMBO J. 1991, 10, 227-236.
+. Lee, I.; Schindelin, H. Structural Insights into E1-Catalyzed Ubiquitin Activation and Transfer to Conjugating Enzymes. Cell 2008, 134, 268-278. DOI:http://dx.doi.org/10.1016/j.cell.2008.05.046.