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Query: UNIPROT:P11021 (
BiP
)
2,049
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A complex array of chaperones and enzymes reside in the endoplasmic reticulum (ER) to assist the folding and assembly of and the disulfide bond formation in nascent secretory proteins. Here we characterize a novel human putative ER co-chaperone (
ERdj5
) containing domains resembling DnaJ, protein-disulfide isomerase, and thioredoxin domains. Homologs of
ERdj5
have been found in Caenorhabditis elegans and Mus musculus. In vitro experiments demonstrated that
ERdj5
interacts via its DnaJ domain with
BiP
in an ATP-dependent manner.
ERdj5
is a ubiquitous protein localized in the ER and is particularly abundant in secretory cells. Its transcription is induced during ER stress, suggesting potential roles for
ERdj5
in protein folding and translocation across the ER membrane.
...
PMID:ERdj5, an endoplasmic reticulum (ER)-resident protein containing DnaJ and thioredoxin domains, is expressed in secretory cells or following ER stress. 1241 43
Membrane and secretory proteins cotranslationally enter and are folded in the endoplasmic reticulum (ER). Misfolded or unassembled proteins are discarded by a process known as ER-associated degradation (ERAD), which involves their retrotranslocation into the cytosol. ERAD substrates frequently contain disulfide bonds that must be cleaved before their retrotranslocation. Here, we found that an
ER-resident protein ERdj5
had a reductase activity, cleaved the disulfide bonds of misfolded proteins, and accelerated ERAD through its physical and functional associations with EDEM (ER degradation-enhancing alpha-mannosidase-like protein) and an ER-resident chaperone
BiP
. Thus,
ERdj5
is a member of a supramolecular ERAD complex that recognizes and unfolds misfolded proteins for their efficient retrotranslocation.
...
PMID:ERdj5 is required as a disulfide reductase for degradation of misfolded proteins in the ER. 1865 71
Down-regulation of the unfolded protein response (UPR) can be therapeutically valuable in cancer treatment, and endoplasmic reticulum (ER)-resident chaperone proteins may thus be targets for developing novel chemotherapeutic strategies.
ERdj5
is a novel ER chaperone that regulates the ER-associated degradation of misfolded proteins through its associations with EDEM and the ER stress sensor
BiP
. To investigate whether
ERdj5
can regulate ER stress signaling pathways, we exposed neuroblastoma cells overexpressing
ERdj5
to ER stress inducers.
ERdj5
promoted apoptosis in tunicamycin, thapsigargin, and bortezomib-treated cells. To provide further evidence that
ERdj5
induces ER stress-regulated apoptosis, we targeted Bcl-2 to ER of
ERdj5
-overexpressing cells. Targeting the Bcl-2 to ER prevented the apoptosis induced by ER stress inducers but not by non-ER stress apoptotic stimuli, suggesting induction of ER stress-regulated apoptosis by
ERdj5
.
ERdj5
enhanced apoptosis by abolishing the ER stress-induced phosphorylation of eukaryotic translation initiation factor 2alpha (eIF2alpha) and the subsequent translational repression.
ERdj5
was found to inhibit the eIF2alpha phosphorylation under ER stress through inactivating the pancreatic endoplasmic reticulum kinase. The compromised integrated stress response observed in
ERdj5
-overexpressing ER-stressed cells due to repressed eIF2alpha phosphorylation correlated with impaired neuroblastoma cell resistance under ER stress. These results demonstrate that
ERdj5
decreases neuroblastoma cell survival by down-regulating the UPR, raising the possibility that this protein could be a target for anti-tumor approaches.
...
PMID:ERdj5 sensitizes neuroblastoma cells to endoplasmic reticulum stress-induced apoptosis. 1912 39
The mechanism, in molecular terms of protein quality control, specifically of how the cell recognizes and discriminates misfolded proteins, remains a challenge. In the secretory pathway the folding status of glycoproteins passing through the endoplasmic reticulum is marked by the composition of the N-glycan. The different glycoforms are recognized by specialized lectins. The folding sensor UGGT acts as an unusual molecular chaperone and covalently modifies the Man9 N-glycan of a misfolded protein by adding a glucose moiety and converts it to Glc1Man9 that rebinds the lectin calnexin. However, further links between the folding status of a glycoprotein and the composition of the N-glycan are unclear. There is little unequivocal evidence for other proteins in the ER recognizing the N-glycan and also acting as molecular chaperones. Nevertheless, based upon a few examples, we suggest that this function is carried out by individual proteins in several different complexes. Thus, calnexin binds the protein disulfide isomerase ERp57, that acts upon Glc1Man9 glycoproteins. In another example the protein disulfide isomerase
ERdj5
binds specifically to EDEM (which is probably a mannosidase) and a lectin OS9, and reduces the disulfide bonds of bound glycoproteins destined for ERAD. Thus the glycan recognition is performed by a lectin and the chaperone function performed by a specific partner protein that can recognize misfolded proteins. We predict that this will be a common arrangement of proteins in the ER and that members of protein foldase families such as PDI and PPI will bind specifically to lectins in the ER. Molecular chaperones
BiP
and GRp94 will assist in the folding of proteins bound in these complexes as well as in the folding of non-glycoproteins.
...
PMID:Protein quality control in the ER: the recognition of misfolded proteins. 2034 46
ER-associated degradation (ERAD) is an ER quality-control process that eliminates terminally misfolded proteins.
ERdj5
was recently discovered to be a key ER-resident PDI family member protein that accelerates ERAD by reducing incorrect disulfide bonds in misfolded glycoproteins recognized by EDEM1. We here solved the crystal structure of full-length
ERdj5
, thereby revealing that
ERdj5
contains the N-terminal J domain and six tandem thioredoxin domains that can be divided into the N- and C-terminal clusters. Our systematic biochemical analyses indicated that two thioredoxin domains that constitute the C-terminal cluster form the highly reducing platform that interacts with EDEM1 and reduces EDEM1-recruited substrates, leading to their facilitated degradation. The pulse-chase experiment further provided direct evidence for the sequential movement of an ERAD substrate from calnexin to the downstream EDEM1-
ERdj5
complex, and then to the retrotranslocation channel, probably through
BiP
. We present a detailed molecular view of how
ERdj5
mediates ERAD in concert with EDEM1.
...
PMID:Structural basis of an ERAD pathway mediated by the ER-resident protein disulfide reductase ERdj5. 2132 81
Cholera toxin (CT) traffics from the host cell surface to the endoplasmic reticulum (ER), where the toxin's catalytic CTA1 subunit retrotranslocates to the cytosol to induce toxicity. In the ER, CT is captured by the E3 ubiquitin ligase Hrd1 via an undefined mechanism to prepare for retrotranslocation. Using loss-of-function and gain-of-function approaches, we demonstrate that the ER-resident factor
ERdj5
promotes CTA1 retrotranslocation, in part, via its J domain. This Hsp70 cochaperone regulates binding between CTA and the ER Hsp70
BiP
, a chaperone previously implicated in toxin retrotranslocation. Importantly,
ERdj5
interacts with the Hrd1 adaptor Sel1L directly through Sel1L's N-terminal lumenal domain, thereby linking
ERdj5
to the Hrd1 complex. Sel1L itself also binds CTA and facilitates toxin retrotranslocation. By contrast, EDEM1 and OS-9, two established Sel1L binding partners, do not play significant roles in CTA1 retrotranslocation. Our results thus identify two ER factors that promote ER-to-cytosol transport of CTA1. They also indicate that
ERdj5
, by binding to Sel1L, triggers
BiP
-toxin interaction proximal to the Hrd1 complex. We postulate this scenario enables the Hrd1-associated retrotranslocation machinery to capture the toxin efficiently once the toxin is released from
BiP
.
...
PMID:The ERdj5-Sel1L complex facilitates cholera toxin retrotranslocation. 2336 2
ERdj5
is a member of the protein disulfide isomerase family of proteins localized to the endoplasmic reticulum (ER) of mammalian cells. To date, only a limited number of substrates for
ERdj5
are known. Here we identify a number of endogenous substrates that form mixed disulfides with
ERdj5
, greatly expanding its client repertoire.
ERdj5
previously had been thought to exclusively reduce disulfides in proteins destined for dislocation to the cytosol for degradation. However, we demonstrate here that for one of the identified substrates, the low-density lipoprotein receptor (LDLR),
ERdj5
is required not for degradation, but rather for efficient folding. Our results demonstrate that the crucial role of
ERdj5
is to reduce non-native disulfides formed during productive folding and that this requirement is dependent on its interaction with
BiP
. Hence,
ERdj5
acts as the ER reductase, both preparing misfolded proteins for degradation and catalyzing the folding of proteins that form obligatory non-native disulfides.
...
PMID:ERdj5 is the ER reductase that catalyzes the removal of non-native disulfides and correct folding of the LDL receptor. 2376 72
During endoplasmic reticulum (ER)-associated degradation (ERAD), terminally misfolded proteins are retrotranslocated from the ER to the cytosol and degraded by the ubiquitin-proteasome system. Misfolded glycoproteins are recognized by calnexin and transferred to EDEM1, followed by the ER disulfide reductase
ERdj5
and the
BiP
complex. The mechanisms involved in ERAD of nonglycoproteins, however, are poorly understood. Here we show that nonglycoprotein substrates are captured by
BiP
and then transferred to
ERdj5
without going through the calnexin/EDEM1 pathway; after cleavage of disulfide bonds by
ERdj5
, the nonglycoproteins are transferred to the ERAD scaffold protein SEL1L by the aid of
BiP
for dislocation into the cytosol. When glucose trimming of the N-glycan groups of the substrates is inhibited, glycoproteins are also targeted to the nonglycoprotein ERAD pathway. These results indicate that two distinct pathways for ERAD of glycoproteins and nonglycoproteins exist in mammalian cells, and these pathways are interchangeable under ER stress conditions.
...
PMID:Glycosylation-independent ERAD pathway serves as a backup system under ER stress. 2396 69
Mutations in rhodopsin, the light-sensitive protein of rod cells, are the most common cause of autosomal dominant retinitis pigmentosa (ADRP). Many rod opsin mutations, such as P23H, lead to misfolding of rod opsin with detrimental effects on photoreceptor function and viability. Misfolded P23H rod opsin and other mutations in the intradiscal domain are characterized by the formation of an incorrect disulphide bond between C185 and C187, as opposed to the correct and highly conserved C110-C187 disulphide bond. Therefore, we tested the hypothesis that incorrect disulphide bond formation might be a factor that affects the biogenesis of rod opsin by studying wild-type (WT) or P23H rod opsin in combination with amino acid substitutions that prevent the formation of incorrect disulphide bonds involving C185. These mutants had altered traffic dynamics, suggesting a requirement for regulation of disulphide bond formation/reduction during rod opsin biogenesis. Here, we show that the
BiP
co-chaperone and reductase protein
ERdj5
(DNAJC10) regulates this process.
ERdj5
overexpression promoted the degradation, improved the endoplasmic reticulum mobility and prevented the aggregation of P23H rod opsin.
ERdj5
reduction by shRNA delayed rod opsin degradation and promoted aggregation. The reductase and co-chaperone activity of
ERdj5
were both required for these effects on P23H rod opsin. Furthermore, mutations in these functional domains acted as dominant negatives that affected WT rod opsin biogenesis. Collectively, these data identify
ERdj5
as a member of the proteostasis network that regulates rod opsin biogenesis and supports a role for disulphide bond formation/reduction in rod opsin biogenesis and disease.
...
PMID:The co-chaperone and reductase ERdj5 facilitates rod opsin biogenesis and quality control. 2505 72
Cholera toxin (CT) intoxicates cells by trafficking from the cell surface to the endoplasmic reticulum (ER), where the catalytic CTA1 subunit hijacks components of the ER-associated degradation (ERAD) machinery to retrotranslocate to the cytosol and induce toxicity. In the ER, CT targets to the ERAD machinery composed of the E3 ubiquitin ligase Hrd1-Sel1L complex, in part via the activity of the Sel1L-binding partner
ERdj5
. This J protein stimulates
BiP
's ATPase activity, allowing
BiP
to capture the toxin. Presumably, toxin release from
BiP
must occur before retrotranslocation. Here, using loss-and gain-of-function approaches coupled with binding studies, we demonstrate that the ER-resident nucleotide exchange factors (NEFs) Grp170 and Sil1 induce CT release from
BiP
in order to promote toxin retrotranslocation. In addition, we find that after NEF-dependent release from
BiP
, the toxin is transferred to protein disulfide isomerase; this ER redox chaperone is known to unfold CTA1, which allows the toxin to cross the Hrd1-Sel1L complex. Our data thus identify two NEFs that trigger toxin release from
BiP
to enable successful retrotranslocation and clarify the fate of the toxin after it disengages from
BiP
.
...
PMID:The nucleotide exchange factors Grp170 and Sil1 induce cholera toxin release from BiP to enable retrotranslocation. 2587 69
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