Cystic fibrosis arises from the misfolding and premature degradation of CFTR Delta F508, a Cl- ion channel with a single amino acid deletion. Yet, the quality-control machinery that selects CFTR Delta F508 for degradation and the mechanism for its misfolding are not well defined. We identified an ER membrane-associated ubiquitin ligase complex containing the E3 RMA1, the E2 Ubc6e, and Derlin-1 that cooperates with the cytosolic Hsc70/CHIP E3 complex to triage CFTR and CFTR Delta F508. Derlin-1 serves to retain CFTR in the ER membrane and interacts with RMA1 and Ubc6e to promote CFTR's proteasomal degradation. RMA1 is capable of recognizing folding defects in CFTR Delta F508 coincident with translation, whereas the CHIP E3 appears to act posttranslationally. A folding defect in CFTR Delta F508 detected by RMA1 involves the inability of CFTR's second membrane-spanning domain to productively interact with amino-terminal domains. Thus, the RMA1 and CHIP E3 ubiquitin ligases act sequentially in ER membrane and cytosol to monitor the folding status of CFTR and CFTR Delta F508.
CFTRΔF508 exhibits a correctable protein-folding defect that leads to its misfolding and premature degradation, which is the cause of cystic fibrosis (CF). Herein we report on the characterization of the CFTRΔF508 biogenic intermediate that is selected for proteasomal degradation and identification of cellular components that polyubiquitinate CFTRΔF508. Nonubiquitinated CFTRΔF508 accumulates in a kinetically trapped, but folding competent conformation, that is maintained in a soluble state by cytosolic Hsc70. Ubiquitination of Hsc70-bound CFTRΔF508 requires CHIP, a U box containing cytosolic cochaperone. CHIP is demonstrated to function as a scaffold that nucleates the formation of a multisubunit E3 ubiquitin ligase whose reconstituted activity toward CFTR is dependent upon Hdj2, Hsc70, and the E2 UbcH5a. Inactivation of the Hsc70–CHIP E3 leads CFTRΔF508 to accumulate in a nonaggregated state, which upon lowering of cell growth temperatures, can fold and reach the cell surface. Inhibition of CFTRΔF508 ubiquitination can increase its cell surface expression and may provide an approach to treat CF.
Cystic fibrosis transmembrane conductance regulator (CFTR) is a polytopic membrane protein that functions as a Cl ؊ channel and consists of two membrane spanning domains (MSDs), two cytosolic nucleotide binding domains (NBDs), and a cytosolic regulatory domain. Cytosolic 70-kDa heat shock protein (Hsp70), and endoplasmic reticulum-localized calnexin are chaperones that facilitate CFTR biogenesis. Hsp70 functions in both the cotranslational folding and posttranslational degradation of CFTR. Yet, the mechanism for calnexin action in folding and quality control of CFTR is not clear. Investigation of this question revealed that calnexin is not essential for CFTR or CFTR⌬F508 degradation. We identified a dependence on calnexin for proper assembly of CFTR's membrane spanning domains. Interestingly, efficient folding of NBD2 was also found to be dependent upon calnexin binding to CFTR. Furthermore, we identified folding defects caused by deletion of F508 that occurred before and after the calnexin-dependent association of MSD1 and MSD2. Early folding defects are evident upon translation of the NBD1 and R-domain and are sensed by the RMA-1 ubiquitin ligase complex. INTRODUCTIONCystic fibrosis transmembrane conductance regulator (CFTR) is a membrane glycoprotein that is localized to the apical surface of epithelial cells that line ducts of glands and airways. CFTR functions as an ATP-gated Cl Ϫ channel that is critical for proper hydration of the mucosal layer that lines lung airways (Welsh and Smith, 1993). Individuals who inherit two mutant forms of CFTR have exceedingly viscous mucous and, due to chronic lung infections, develop cystic fibrosis and often die from lung failure. CFTR is a member of the ATP-binding cassette (ABC) transporter superfamily (Hyde et al., 1990) and is a 1480-amino acid protein that contains two membrane spanning domains (MSDs), MSD1 and MSD2; two cytosolic nucleotide binding domains (NBDs), NBD1 and NBD2; and a regulatory (R) domain (Riordan et al., 1989). The proper folding and assembly of CFTR subdomains in the endoplasmic reticulum (ER) is required for CFTR to engage the COPII machinery and be packaged into vesicles for transport to the plasma membrane (Kopito, 1999;Wang et al., 2004). The folding pathway of this complex polytopic membrane protein has been a topic of great interest, because misfolding results in premature recognition of CFTR by the ER quality control system (ERQC) and degradation by the ubiquitin proteasome system (Skach, 2000). In fact, the most common disease-causing mutation of CFTR, ⌬F508CFTR, results in almost complete degradation of the protein by the ERQC system, which gives rise to a loss of function phenotype and lung disease (Ward and Kopito, 1994).The assembly of CFTR into an ion channel is complicated because it requires the coordinated folding and assembly of its membrane and cytoplasmic domains into a functional unit (Du et al., 2005;Riordan, 2005;Cui et al., 2007). CFTR is a modular protein, and its domains can collapse to a protease-resistant conformation i...
As advanced technology increasingly infiltrated into classroom, the flipped classroom has come to light in secondary educational settings. The flipped classroom is a new instructional approach that intends to flip the traditional teacher-centered classroom into student centered. The purpose of this research is to investigate the impact of the flipped classroom instructional pedagogy in a ninth grade health education class.
SummaryThe NarX-NarL and NarQ-NarP sensor-response regulator pairs control Escherichia coli gene expression in response to nitrate and nitrite. Previous analysis suggests that the Nar two-component systems form a cross-regulation network in vivo. Here we report on the kinetics of phosphoryl transfer between different sensor-regulator combinations in vitro. NarX exhibited a noticeable kinetic preference for NarL over NarP, whereas NarQ exhibited a relatively slight kinetic preference for NarL. These findings were substantiated in reactions containing one sensor and both response regulators, or with two sensors and a single response regulator. We isolated 21 NarX mutants with missense substitutions in the cytoplasmic central and transmitter modules. These confer phenotypes that reflect defects in phosphoNarL dephosphorylation. Five of these mutants, all with substitutions in the transmitter DHp domain, also exhibited NarP-blind phenotypes. Phosphoryl transfer assays in vitro confirmed that these NarX mutants have defects in catalysing NarP phosphorylation. By contrast, the corresponding NarQ mutants conferred phenotypes indicating comparable interactions with both NarP and NarL. Our overall results reveal asymmetry in the Nar cross-regulation network, such that NarQ interacts similarly with both response regulators, whereas NarX interacts preferentially with NarL.
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