Ubiquitin Structure & Function
From Proteopedia
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[[Image:1ubiq.png|300 px|right]] | [[Image:1ubiq.png|300 px|right]] | ||
=Function= | =Function= | ||
| - | At first, ubiquitin was believed to be a hormone involed in inducing the differentiation of lymphocytes and activating adenylate cyclase <ref>Vijay-Kumar, S., Begg, CE., Wilkinson, KD and Cook, WJ. 1985. Three-dimensional structure of ubiquitin of 2.8 angstrom resolution. ''Proc Natl Acad Sci'' 82:3582-3585</ref>. However, today, ubiquitin is primarily known for its role in intracellular ATP-dependent protein degradation. This is accomplished through the process of | + | At first, ubiquitin was believed to be a hormone involed in inducing the differentiation of lymphocytes and activating adenylate cyclase <ref>Vijay-Kumar, S., Begg, CE., Wilkinson, KD and Cook, WJ. 1985. Three-dimensional structure of ubiquitin of 2.8 angstrom resolution. ''Proc Natl Acad Sci'' 82:3582-3585</ref>. However, today, ubiquitin is primarily known for its role in intracellular ATP-dependent protein degradation. This is accomplished through the process of several seperate reactions: |
=== Activation === | === Activation === | ||
| - | + | The first step of ubiquitin activation involves the formation of a ubiqiotin-adenylate intermediate. This reaction requires an E1 ubiquitin-activating enzyme. The second step of ubiquitin activation transfers ubiquitin to the E1 active site cysteine residue and AMP is released. This step results in a thioester linkage between the C-terminal carboxyl group of ubiquitin and the E1 cysteine sulfhydryl group. | |
| + | === Ubiquitin Conjugation === | ||
| + | === Proofreading === | ||
| + | === Conjugate Metabolism === | ||
[[Image:diubq.png|500 px|center]] | [[Image:diubq.png|500 px|center]] | ||
[[Image:Ubq_pathway.png|500 px|center]] | [[Image:Ubq_pathway.png|500 px|center]] | ||
<references/> | <references/> | ||
Revision as of 06:07, 27 March 2010
Ubiquitin is a single 8565 Mr polypeptide consisting of 76 amino acid residues. Ubiquitin is highly known for its role in ATP-dependant protein degradation.
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| 1ubq, resolution 1.80Å () | |||||||||
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| Resources: | FirstGlance, OCA, PDBsum, RCSB | ||||||||
| Coordinates: | save as pdb, mmCIF, xml | ||||||||
Contents |
Introduction
Ubiquitin is one of the most highly conserved eukaryotic proteins. Primary structures found throughout ubiquitin are identical in all bovine, insects and human ubiquitin. The only difference observed amongst these species is seen in the terminal Gly-Gly residues. Yeast and oat ubiquitin only differ in three of the 76 residues when compared to ubiquitin found in higher eukaryotes. Ubiquitin can not only be found in the nucleus, but in the cytoplasm and cell-surface membrane as well. One interesting characteristic of ubiquitin is its stability. Ubiquitin is able to withstand a range of pH levels and temperatures and is very resistant to tryptic digestion, while still containing seven Lysine and four arginine residues. Many aspects of ubiquitin's structure aid in this durability. Ubiquitin contains a hydrophobic core. Three hydrophobic residues found on the α-helix and 11 of the 13 hydrophobic residues from the β-sheet are involved in constructing this hydrophobic core. The main contributor to the ubiquitin stability is the vast amount of hydrogen-bonding interactions observed. The whole structure of ubiquitin undergoes significant hydrogen bonding, aside from the COOH terminus.
Function
At first, ubiquitin was believed to be a hormone involed in inducing the differentiation of lymphocytes and activating adenylate cyclase [1]. However, today, ubiquitin is primarily known for its role in intracellular ATP-dependent protein degradation. This is accomplished through the process of several seperate reactions:
Activation
The first step of ubiquitin activation involves the formation of a ubiqiotin-adenylate intermediate. This reaction requires an E1 ubiquitin-activating enzyme. The second step of ubiquitin activation transfers ubiquitin to the E1 active site cysteine residue and AMP is released. This step results in a thioester linkage between the C-terminal carboxyl group of ubiquitin and the E1 cysteine sulfhydryl group.
Ubiquitin Conjugation
Proofreading
Conjugate Metabolism
- ↑ Vijay-Kumar, S., Begg, CE., Wilkinson, KD and Cook, WJ. 1985. Three-dimensional structure of ubiquitin of 2.8 angstrom resolution. Proc Natl Acad Sci 82:3582-3585
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