Bap31 enhances the endoplasmic reticulum export and quality control of human class I MHC molecules.

The assembly of class I MHC molecules and their export from the endoplasmic reticulum (ER) is governed by chaperones and accessory proteins. We present evidence that the putative cargo receptor protein Bap31 participates in the transport and the quality control of human class I molecules. Transfection of the human adenocarcinoma cell line HeLa with yellow fluorescent protein-Bap31 chimeras increased surface levels of class I in a dose-dependent manner, by as much as 3.7-fold. The increase in surface class I resulted from an increase in the rate of export of newly synthesized class I molecules to the cell surface and from an increase in the stability of the exported molecules. We propose that Bap31 performs quality control on class I molecules in two distinct phases: first, by exporting peptide-loaded class I molecules to the ER/Golgi intermediate compartment, and second, by retrieving class I molecules that have lost peptides in the acidic post-ER environment. This function of Bap31 is conditional or redundant, because we find that Bap31 deficiency does not reduce surface class I levels. Overexpression of the Bap31 homolog, Bap29, decreases surface class levels in HeLa, indicating that it does not substitute for Bap31.

Probing for membrane domains in the endoplasmic reticulum: retention and degradation of unassembled MHC class I molecules.

Quality control of protein biosynthesis requires ER-retention and ER-associated degradation (ERAD) of unassembled/misfolded molecules. Although some evidence exists for the organization of the ER into functionally distinct membrane domains, it is unknown if such domains are involved in the retention and ERAD of unassembled proteins. Here, it is shown that unassembled MHC class I molecules are retained in the ER without accumulating at ER-exit sites or in the ERGIC of beta2m-/- cells. Furthermore, these molecules did not cluster in the ER membrane and appeared to be highly mobile even when ERAD or their association with calnexin were inhibited. However, upon ATP depletion, they were reversibly segregated into an ER membrane domain, distinct from ER exit sites, which included calnexin and COPII, but not the ERGIC marker protein p58. This quality control domain was also observed upon prolonged inhibition of proteasomes. Microtubules were required for its appearance. Segregation of unfolded proteins, ER-resident chaperones, and COPII may be a temporal adaptation to cell stress.

Cutting edge: Tapasin is retained in the endoplasmic reticulum by dynamic clustering and exclusion from endoplasmic reticulum exit sites.

Tapasin retains empty or suboptimally loaded MHC class I molecules in the endoplasmic reticulum (ER). However, the molecular mechanism of this process and how tapasin itself is retained in the ER are unknown. These questions were addressed by tagging tapasin with the cyan fluorescent protein or yellow fluorescent protein (YFP) and probing the distribution and mobility of the tagged proteins. YFP-tapasin molecules were functional and could be isolated in association with TAP, as reported for native tapasin. YFP-tapasin was excluded from ER exit sites even after accumulation of secretory cargo due to disrupted anterograde traffic. Almost all tapasin molecules were clustered, and these clusters diffused freely in the ER. Tapasin oligomers appear to be retained by the failure of the export machinery to recognize them as cargo.