Premature degradation of CFTRΔF508 causes cystic fibrosis (CF). CFTRΔF508 folding defects are conditional and folding correctors are being developed as CF therapeutics. How the cellular environment impacts CFTRΔF508 folding efficiency and the identity of CFTRΔF508's correctable folding defects is unclear. We report that inactivation of the RMA1 or CHIP ubiquitin ligase permits a pool of CFTRΔF508 to escape the endoplasmic reticulum. Combined RMA1 or CHIP inactivation and Corr-4a treatment enhanced CFTRΔF508 folding to 3–7-fold greater levels than those elicited by Corr-4a. Some, but not all, folding defects in CFTRΔF508 are correctable. CHIP and RMA1 recognize different regions of CFTR and a large pool of nascent CFTRΔF508 is ubiquitinated by RMA1 before Corr-4a action. RMA1 recognizes defects in CFTRΔF508 related to misassembly of a complex that contains MSD1, NBD1, and the R-domain. Corr-4a acts on CFTRΔF508 after MSD2 synthesis and was ineffective at rescue of ΔF508 dependent folding defects in amino-terminal regions. In contrast, misfolding caused by the rare CF-causing mutation V232D in MSD1 was highly correctable by Corr-4a. Overall, correction of folding defects recognized by RMA1 and/or global modulation of ER quality control has the potential to increase CFTRΔF508 folding and provide a therapeutic approach for CF
