Unfolded protein response
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The unfolded protein response (UPR) is a cellular stress response related to the endoplasmic reticulum. It is a stress response that has been found to be conserved between all mammalian species, as well as yeast and worm organisms. This article focuses on the mammalian response.
The UPR is activated in response to an accumulation of unfolded or misfolded proteins in the lumen of endoplasmic reticulum. In this scenario, the UPR has two primary aims: initially to restore normal function of the cell by halting protein translation and activate the signaling pathways that lead to increase the production of molecular chaperones involved in protein folding. Where these objectives are not achieved within a certain time lap or the disruption is prolonged, the UPR aims to initiate the programmed cell death (apoptosis).
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[edit] Protein Folding in the Endoplasmic Reticulum
[edit] Protein synthesis
The term protein folding incorporates all the processes involved in the production of a protein after the nascent polypeptides are become synthesized by the ribosomes. The proteins destined to be secreted or sorted to others cell organelles carries an N-terminal signal sequence that will interact with a signal receptor protein (SRP). The SRP will lead the whole complex (Ribosome, RNA, polypeptide) to ER membrane. Once the sequence has “docked”, the protein continues translation, with the resultant strand being fed through the polypeptide translocator directly into the ER. Protein folding commences as soon as the polypeptide enters to the luminal environment, even as translation of the remaining polypeptide continues.
[edit] Protein folding & Quality control
Protein folding steps involve a range of enzymes and molecular chaperones to coordinate and regulate reactions, in addition to a range of substrates required in order for the reactions to take place. The most important of these to note are N-linked glycosylation and disulfide bond formation. N-linked glycosylation occurs as soon as the protein sequence passes into the ER through the translocon, where it is glycosylated with a sugar molecule that forms the key ligand for the lectin molecules calreticulin (CRT) and calnexin (CNX)1. Favoured by the highly oxidising environment of the ER, CRT and CNX facilitate formation of disulfide bonds, which confer structural stability to the protein in order for it to withstand adverse conditions such as extremes of pH and degradative enzymes.
The ER is capable of recognising malfolding proteins without causing disruption to the functioning of the ER. The aforementioned sugar molecule remains the means by which the cell monitors protein folding, as the malfolding protein becomes characteristically devoid of glucose residues, targeting it for identification and re-glycosylation by the enzyme UGGT (UGT-glucose:glycoprotein glucosyltransferase)1. If this fails to restore the normal folding process, exposed hydrophobic residues of the malfolded protein are bound by the protein glucose regulate protein 78 (Grp78), a heat shock protein 70kDa family member2 that prevents the protein from further transit and secretion3.
Where circumstances continue to cause a particular protein to malfold, the protein is recognised as posing a threat to the proper functioning of the ER, as they can aggregate to one another and accumulate. In such circumstances the protein is guided through endoplasmic reticulum-associated degradation (ERAD). The chaperone EDEM guides the retrotranslocation of the malfolded protein back into the cytosol in transient complexes with PDI and Grp784. Here it enters the ubiquitin-proteasome pathway, as it is tagged by multiple ubiquitin molecules, targeting it for degradation by cytosolic proteasomes.
Successful protein folding requires a tightly controlled environment of substrates that include glucose to meet the metabolic energy requirements of the functioning molecular chaperones; calcium that is stored bound to resident molecular chaperones and; redox buffers that maintain the oxidising environment required for disulfide bond formation5.
However where circumstances cause a more global disruption to protein folding that overwhelms the ER’s coping mechanisms, the UPR is activated.
[edit] Molecular mechanism involved in the UPR
[edit] Initiation of the UPR
The molecular chaperone BiP/Grp78 has a range of functions within the ER. It maintains specific transmembrane receptor proteins involved in initiating of the downstream signalling of the UPR in an inactive state by binding to their luminal domains. An overwhelming load of misfolded proteins requires more of the available BiP/Grp78 to bind to the exposed hydrophobic regions of these proteins, and consequently BiP/Grp78 dissociates from these receptors sites to meet this requirement. Dissociation from the intracellular receptor domains allows them to become active.
[edit] Functions of the UPR
The initial phases of UPR activation have two key roles:
Translation Attenuation and Cell Cycle Arrest by the PERK Receptor This occurs within minutes to hours of UPR activation to prevent further translational loading of the ER. PERK ((protein kinase-like endoplasmic reticulum kinase) activates itself by oligomerization and autophosphorylation of the free luminal domain. The activated cytosolic domain causes translational attenuation by directly phosphorylating the α subunit of the regulating initiator of the mRNA translation machinery, eIF26. This also produces translational attenuation of the protein machinery involved in running the cell cycle, producing cell cycle arrest in the G1 phase7.
Increased Production of Proteins Involved in the Functions of the UPR UPR activation also results in upregulation of proteins involved in chaperoning malfolding proteins, protein folding and ERAD, including further production of Grp78. Ultimately this increases the cell’s molecular mechanisms by which it can deal with the malfolded protein load. These receptor proteins have been identified as:
• Inositol-requiring kinase 18, whose free luminal domain activates itself by homodimerisation and transautophosphorylation9. The activated domain is able to activate the transcription factor XBP1 (X-box binding protein) mRNA (the mammalian equivalent of the yeast Hac1 mRNA by cleavage and removal of a 252bp intron. The activated transcription factor upregulates UPR ‘stress genes’ by directly binding to stress element promoters in the nucleus10.
• ATF6 (activating transcription factor 6) is a basic leucine zipper transcription factor11.Upon Grp78 dissociation the entire 90kDa protein translocates to the Golgi, where it is cleaved by proteases to form an active 50kDa transcription factor12 that translocates to the nucleus. It binds to stress element promoters upstream of genes that are upregulated in the UPR 13.
The aim of these responses is to remove the accumulated protein load whilst preventing any further addition to the stress, so that normal function of the ER can be restored as soon as possible.
[edit] Initiating Apoptosis
In conditions of prolonged stress, the goal of the UPR changes from being one that promotes cellular survival to one that commits the cell to a pathway of programmed cell death (or apoptosis). Proteins downstream of all 3 UPR receptor pathways have been identified as having pro-apoptotic roles. However, the point at which the ‘apoptotic switch’ is activated has not yet been determined, but it is a logical consideration that his should be beyond a certain time period in which resolution of the stress has not been achieved. The 2 principal UPR receptors involved are Ire1 and PERK.
By binding with the protein TRAF2, Ire1 activates a JNK signaling pathway14, at which point human procaspase 4 is believed to cause apoptosis by activating downstream caspases. Although PERK is recognised to produce a translational block, certain genes can bypass this block. An important example is that the proapoptotic protein CHOP (CCAAT/-enhancer-binding protein homologous protein),is upregulated downstream of the bZIP transcription factor ATF4 (activating transcription factor 4) and uniquely responsive to ER stress15. CHOP causes downregulation of the anti-apoptotic mitochondrial protein Bcl-216, favouring a pro-apoptotic drive at the mitochondria by proteins that cause mitochondrial damage, cytochrome c release and caspase 3 activation.
[edit] Chemical inducers of the UPR
UPR inducers most notably include tunicamycin. Others are:
- thapsigargin [1] Lead to the release of Ca+2 from the ER lumen to the cytoplasm, affecting the function of lectins Calnexin and Calreticulin.
- A23187 [1]
- 2-deoxyglucose [1]
- dithiothreitol [1] Reduce the disulfide bridges of proteins. The denatured proteins accumulated inside the ER.
[edit] References
- ^ a b c d Kitamura,M
[edit] Further reading
- Blond-Elguindi, S., Cwiria, SE., Dower, WJ., Lipshutz, RJ., Sprang, SR., Sambrook, JF., Gething, MH (1993) Cell 75: 717-728
- Brewer, J., Diehl, J. (2000) Proc Natl Acad USA 97 (23): 12625-30
- Chen, X., Shen, J., Prywes, R. (2002) J Biol Chem 277 (15): 13045-53
- Cox, JS., Shamu, CE., Walter, P. (1993) Cell 73 (6): 1197-1206
- Hammond, C., Braakman, I., Helenius, A. 1994 PNAS 91: 913-917
- Harding, H. P., Zhang, Y., Ron, D. (1999) Nature 397 271-4
- Lee, A-H., Iwakoshi, N., Anderson, K., Glimcher, L. (2003) Proc Natl Acad Sci USA 100 (17) 9946-51
- Lee, AS (1987) Trends Biochem Sci 12 20-23
- Machamer, CE., Doms, RW., Bole, DG,. Helenius, A., Rose, JK. (1990) J Biol Chem 265 (12) 6879-6883
- McCullough, K., Martindale, J., Klotz, L., Aw, T., Holbrook, N (2001) Mol Cell Biol 21: 1249-1259
- Molinari, M., Galli, C., Piccaluga, V., Pieren, M., Paganetti, P. (2002) J Cell Biol 158 (2) 247-257
- Mori, K., Ogawa, O., Kawahara, T., Yanagi, H., Yura, T. (2000) Proc Natl Acad Sci USA 97 4660-4665
- Urano, F., Wang, X., Bertolotti, A., Zhang, Y., Chung, P., Harding, H., Ron, D (2000) Science 287 (5453) 664-666
- Wang, X-Z., Lawson, B., Brewer, J. W., Zinszner, H., Sanjay, A., Mi, L., Boorstein, R., Kreibich, G., Hendershot, L., Ron., D. (1996) Mol Cell Biol 16 (8) 4273-80
- Welihinda, A. A., Kaufman, R. J. (1996) J Biol Chem 271 (30) 18181-7
- Yoshida, H., Haze, K., Yanagi, H., Yura, T., Mori, K. (1998) J Biol Chem 273 (50): 33741-9