Endoplasmic-reticulum-associated protein degradation
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Endoplasmic-reticulum-associated protein degradation (ERAD) designates a cellular pathway which targets misfolded proteins of the endoplasmic reticulum for ubiquitination and subsequent degradation by a protein-degrading complex, called the proteasome.
Mechanism
The process of ERAD can be divided into three steps:
Recognition of misfolded or mutated proteins in the endoplasmic reticulum
The recognition of misfolded or mutated proteins depends on the detection of substructures within proteins such as exposed hydrophobic regions, unpaired cysteine residues and immature glycans.
In mammalian cells for example, there exists a mechanism called glycan processing. In this mechanism, the lectin-type chaperones calnexin/calreticulin (CNX/CRT) provide immature glycoproteins the opportunity to reach their native conformation. They can do this by way of reglucosylating these glycoproteins by an enzyme called UDP-glucose-glycoprotein glucosyltransferase also known as UGGT. Terminally misfolded proteins, however, must be extracted from CNX/CRT. This is carried out by members of the EDEM (ER degradation-enhancing α-mannosidase-like protein) family (EDEM1-3) and ER mannosidase I. This mannosidase removes one mannose residue from the glycoprotein and the latter is recognized by EDEM. Eventually EDEM will target the misfolded glycoproteins for degradation by facilitating binding of ERAD lectins OS9 and XTP3-B.[1]
Retro-translocation into the cytosol
Because the ubiquitin–proteasome system (UPS) is located in the cytosol, terminally misfolded proteins have to be transported from the endoplasmic reticulum back into cytoplasm. Most evidence suggest that the Hrd1 E3 ubiquitin-protein ligase can function as a retrotranslocon or dislocon to transport substrates into the cytosol. Hrd1 is not required for all ERAD events, so it is likely that other proteins contribute to this process. For example, glycosylated substrates are recognized by the E3 Fbs2 lectin.[2] Further, this translocation requires a driving force that determines the direction of transport. Since polyubiquitination is essential for the export of substrates, it is widely thought that this driving force is provided by ubiquitin-binding factors. One of these ubiquitin-binding factors is the Cdc48p-Npl4p-Ufd1p complex in yeast. Humans have the homolog of Cdc48p known as valosin-containing protein (VCP/p97) with the same function as Cdc48p. VCP/p97 transports substrates from the endoplasmic reticulum to the cytoplasm with its ATPase activity.
Ubiquitin-dependent degradation by the proteasome
The ubiquitination of terminally misfolded proteins is caused by a cascade of enzymatic reactions. The first of these reactions takes place when the ubiquitin-activating enzyme E1 hydrolyses ATP and forms a high-energy thioester linkage between a cysteine residue in its active site and the C-terminus of ubiquitin. The resulting activated ubiquitin is then passed to E2, which is a ubiquitin-conjugating enzyme. Another group of enzymes, more specifically ubiquitin protein ligases called E3, bind to the misfolded protein. Next they align the protein and E2, thus facilitating the attachment of ubiquitin to lysine residues of the misfolded protein. Following successive addition of ubiquitin molecules to lysine residues of the previously attached ubiquitin, a polyubiquitin chain is formed. A polyubiquitinated protein is produced and this is recognized by specific subunits in the 19S capping complexes of the 26S proteasome. Hereafter, the polypeptide chain is fed into the central chamber of the 20S core region that contains the proteolytically active sites. Ubiquitin is cleaved before terminal digestion by deubiquitinating enzymes. This third step is very closely associated with the second one, since ubiquitination takes place during the translocation event. However, the proteasomal degradation takes place in the cytoplasm.
ERAD ubiquitination machinery
The ER membrane anchored RING finger containing ubiquitin ligases Hrd1 and Doa10 are the major mediators of substrate ubiquitination during ERAD. The tail anchored membrane protein Ubc6 as well as Ubc1 and the Cue1 dependent membrane bound Ubc7 are the ubiquitin conjugating enzymes involved in ERAD.
Checkpoints
As the variation of ERAD-substrates is enormous, several variations of the ERAD mechanism have been proposed. Indeed, it was confirmed that soluble, membrane and transmembrane proteins were recognized by different mechanisms. This led to the identification of 3 different pathways that constitute in fact 3 checkpoints.
- The first checkpoint is called ERAD-C and monitors the folding state of the cytosolic domains of membrane proteins. If defects are detected in the cytosolic domains, this checkpoint will remove the misfolded protein.
- When the cytosolic domains are found to be correctly folded, the membrane protein will pass to a second checkpoint where the luminal domains are monitored. This second checkpoint is called the ERAD-L pathway. Not only membrane proteins surviving the first checkpoint are controlled for their luminal domains, also soluble proteins are inspected by this pathway as they are entirely luminal and thus bypass the first checkpoint. If a lesion in the luminal domains is detected, the involved protein is processed for ERAD using a set of factors including the vesicular trafficking machinery that transports misfolded proteins from the endoplasmic reticulum to the Golgi apparatus.
- Also a third checkpoint has been described that relies on the inspection of transmembrane domains of proteins. It is called the ERAD-M pathway but it is not very clear in which order it has to be placed with regard to the two previously described pathways.
Diseases associated with ERAD-malfunctioning
As ERAD is a central element of the secretory pathway, disorders in its activity can cause a range of human diseases. These disorders can be classified into two groups.
The first group is the result of mutations in ERAD components, which subsequently lose their function. By losing their function, these components are no longer able to stabilize aberrant proteins, so that the latter accumulate and damage the cell. An example of a disease caused by this first group of disorders is Parkinson's disease. It is caused by a mutation in the parkin gene. Parkin is a protein that functions in complex with CHIP as a ubiquitin ligase and overcomes the accumulation and aggregation of misfolded proteins.
[There are numerous theories addressing the causes of Parkinson's disease, besides the one presented here. Many of these can be found in the section of Wikipedia devoted to Parkinson's disease.]
In contrast to this first group of disorders, the second group is caused by premature degradation of secretory or membrane proteins. In this way, these proteins aren't able to be deployed to distal compartments, as is the case in cystic fibrosis.
ERAD and HIV
As described before, the addition of polyubiquitin chains to ERAD substrates is crucial for their export. HIV uses an efficient mechanism to dislocate a single-membrane-spanning host protein, CD4, from the ER and submits it to ERAD. The Vpu protein of HIV-1 is a protein on the ER membrane and targets newly made CD4 in the endoplasmic reticulum for degradation by cytosolic proteasomes.[3] Vpu only utilizes part of the ERAD process to degrade CD4. CD4 is normally a stable protein and is not likely to be a target for ERAD. However, HIV produces the membrane protein Vpu that binds to CD4. The Vpu protein mainly retains the CD4 in the ER by SCFβ-TrCP-dependent ubiquitination of the CD4 cytosolic tail and transmembrane domain (TMD) interactions.[3] The CD4 Gly415 is a contributor to CD4-Vpu interactions, several TMD-mediated mechanisms by HIV-1 Vpu are necessary to downregulate CD4 and thus promote viral pathogenesis. CD4 retained in the ER will be a target for a variant ERAD pathway rather than predominantly appearing at the plasma membrane without the presence of Vpu through the RESET pathway. Vpu mediates the CD4 retention in the ER and the addition of degradation. As Vpu is phosphorylated, it mimics substrates for the E3 complex SCFβTrCP. In cells that are infected with HIV, SCFβTrCP interacts with Vpu and ubiquitinates CD4, which is subsequently degraded by the proteasome. Vpu itself escapes from the degradation.
Questions
The big open questions related to ERAD are:
- How are misfolded proteins more specifically recognized?
- How ERAD substrates/luminal substrates and membrane substrates are differentiated for retrotranslocation?
- Is the retrotranslocation conserved across the yeast to human system?
- What is the channel for the retrotranslocation of luminal ER proteins?
- Which E3 ligase finally tags the proteins for the proteasomal degradation?[citation needed]
See also
References
- ^ Groisman B, Shenkman M, Ron E, Lederkremer GZ (January 2011). "Mannose trimming is required for delivery of a glycoprotein from EDEM1 to XTP3-B and to late endoplasmic reticulum-associated degradation steps". The Journal of Biological Chemistry. 286 (2): 1292–300. doi:10.1074/jbc.M110.154849. PMC 3020737. PMID 21062743.
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: CS1 maint: unflagged free DOI (link) - ^ Groisman B, Avezov E, Lederkremer GZ (September 2006). "The E3 Ubiquitin Ligases HRD1 and SCFFbs2 Recognize the Protein Moiety and Sugar Chains, Respectively, of an ER‐Associated Degradation Substrate". Israel Journal of Chemistry. 46 (2): 189–96. doi:10.1560/2QPD-9WP9-NCYK-58X3.
- ^ a b Magadán JG, Pérez-Victoria FJ, Sougrat R, Ye Y, Strebel K, Bonifacino JS (April 2010). "Multilayered mechanism of CD4 downregulation by HIV-1 Vpu involving distinct ER retention and ERAD targeting steps". PLoS Pathogens. 6 (4): e1000869. doi:10.1371/journal.ppat.1000869. PMC 2861688. PMID 20442859.
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: CS1 maint: unflagged free DOI (link)
Further reading
- Magadán JG, Bonifacino JS (January 2012). "Transmembrane domain determinants of CD4 Downregulation by HIV-1 Vpu". Journal of Virology. 86 (2): 757–72. doi:10.1128/JVI.05933-11. PMC 3255848. PMID 22090097.
- Meusser B, Hirsch C, Jarosch E, Sommer T (August 2005). "ERAD: the long road to destruction". Nature Cell Biology. 7 (8): 766–72. doi:10.1038/ncb0805-766. PMID 16056268.
- Ding WX, Yin XM (February 2008). "Sorting, recognition and activation of the misfolded protein degradation pathways through macroautophagy and the proteasome". Autophagy. 4 (2): 141–50. doi:10.4161/auto.5190. PMID 17986870.
- Vashist S, Ng DT (April 2004). "Misfolded proteins are sorted by a sequential checkpoint mechanism of ER quality control". The Journal of Cell Biology. 165 (1): 41–52. doi:10.1083/jcb.200309132. PMC 2172089. PMID 15078901.
- Ruddock LW, Molinari M (November 2006). "N-glycan processing in ER quality control". Journal of Cell Science. 119 (Pt 21): 4373–80. doi:10.1242/jcs.03225. PMID 17074831.
- Vembar SS, Brodsky JL (December 2008). "One step at a time: endoplasmic reticulum-associated degradation". Nature Reviews. Molecular Cell Biology. 9 (12): 944–57. doi:10.1038/nrm2546. PMC 2654601. PMID 19002207.
- Benyair R, Ron E, Lederkremer GZ (December 2011). "Protein quality control, retention, and degradation at the endoplasmic reticulum". International Review of Cell and Molecular Biology. 292: 197–280. doi:10.1016/B978-0-12-386033-0.00005-0. ISBN 9780123860330. PMID 22078962.