Assembly of ER-associated protein degradation in vitro: dependence on cytosol, calnexin, and ATP

To investigate the mechanisms of ER-associated protein degradation (ERAD), this process was reconstituted in vitro. Established procedures for posttranslational translocation of radiolabeled prepro-alpha factor into isolated yeast microsomes were modified to inhibit glycosylation and to include a po...

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Bibliographic Details
Published in:The Journal of cell biology 1996-02, Vol.132 (3), p.291-298
Main Authors: McCracken, Ardythe A., Brodsky, Jeffrey L.
Format: Article
Language:English
Subjects:
adenosine triphosphate
Adenosine Triphosphate - metabolism
adenosintrifosfato
binding proteins
Biological Transport
Calcium-Binding Proteins - metabolism
Calnexin
Cell biology
Cell free system
Cellular biology
citoplasma
cytoplasm
cytoplasme
cytoplasmic organelles
Cytosol
Cytosol - metabolism
degradacion
degradation
Endoplasmic reticulum
Endoplasmic Reticulum - metabolism
feromonas
Fungal Proteins - metabolism
Glycoproteins - metabolism
Material degradation
Mating Factor
Microsomes
Microsomes - metabolism
Molecular chaperones
organite cellulaire
organulos citoplasmicos
Peptides - metabolism
pheromone
pheromones
Protein Precursors - metabolism
Protein Processing, Post-Translational
Protein transport
proteinas
proteinas aglutinantes
proteine
proteine de liaison
Proteins
reticulo endoplasmatico
reticulum endoplasmique
saccharomyces cerevisiae
Saccharomyces cerevisiae - genetics
Saccharomyces cerevisiae - metabolism
T lymphocytes
Yeast
Yeasts
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Description
Summary:To investigate the mechanisms of ER-associated protein degradation (ERAD), this process was reconstituted in vitro. Established procedures for posttranslational translocation of radiolabeled prepro-alpha factor into isolated yeast microsomes were modified to inhibit glycosylation and to include a posttranslocation "chase" incubation period to monitor degradation. Glycosylation was inhibited with a glyco-acceptor peptide to compete for core carbohydrates, or by using a radiolabeled alpha factor precursor that had been genetically engineered to eliminate all three glycosylation sites. Inhibition of glycosylation led to the production of unglycosylated pro-alpha factor (palphaF), a processed form of the alpha factor precursor shown to be a substrate of ERAD in vivo. With this system, both glycosylated and unglycosylated forms of pro-alpha factor were stable throughout a 90-min chase incubation. However, the addition of cytosol to the chase incubation reaction induced a selective and rapid degradation of palphaF. These results directly reflect the behavior of alpha factor precursor in vivo; i.e., palphaF is a substrate for ERAD, while glycosylated pro-alpha factor is not. Heat inactivation and trypsin treatment of cytosol, as well as addition of ATPgammaS to the chase incubations, led to a stabilization of palphaF. ERAD was observed in sec12 microsomes, indicating that export of palphaF via transport vesicles was not required. Furthermore, palphaF but not glycosylated pro-alpha factor was found in the supernatant of the chase incubation reactions, suggesting a specific transport system for this ERAD substrate. Finally, the degradation of palphaF was inhibited when microsomes from a yeast strain containing a disrupted calnexin gene were examined. Together, these results indicate that cytosolic protein factor(s), ATP hydrolysis, and calnexin are required for ER-associated protein degradation in yeast, and suggest the cytosol as the site for degradation.
ISSN:0021-9525
1540-8140
DOI:10.1083/jcb.132.3.291