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. 1994 Dec 1;180(6):2163–2171. doi: 10.1084/jem.180.6.2163

An unstable beta 2-microglobulin: major histocompatibility complex class I heavy chain intermediate dissociates from calnexin and then is stabilized by binding peptide

PMCID: PMC2191763  PMID: 7964491

Abstract

Proper assembly of the class I heavy chain (HC), beta 2-microglobulin (beta 2m), and peptide must occur in the endoplasmic reticulum (ER) in order for MHC class I molecules to be expressed on the cell surface. Newly synthesized class I HC bind calnexin, an ER resident chaperone. These calnexin-associated class I HC appeared to lack the stable association with beta 2m in peptide transporter-deficient T2 cells since beta 2m-unassociated class I HC-specific HC10 antibody, but not beta 2m-associated class I HC-specific W6/32 antibody, coimmunoprecipitated calnexin. To determine the precursor-product relationship of the pool of HC that bind peptide, class I-restricted peptides were added to lysates of T2 cells in vitro. These peptides stabilized preexisting beta 2m-associated HC complexes (beta 2m+:HC:pep- ), but had no significant effect on the preexisting pool of calnexin- associated HC that lack beta 2m. Release of HC from calnexin appeared to be controlled by the binding of beta 2m, since beta 2m-deficient FO- 1 cells showed a prolonged association of class I HC with calnexin, while beta 2m-transfected FO-1 cells displayed a more rapid dissociation of class I HC from calnexin. Consistent with this result, the dissociation of class I HC from calnexin did not appear to be dependent on peptide binding since the dissociation rates were similar in peptide transporter-deficient T2 cells and in wild-type T1 cells. From these observations, we speculate that in the stepwise assembly of class I molecules, calnexin may mediate dimerization of class I HC with beta 2m, and that the unstable beta 2m+:HC:pep- complexes, after dissociation from calnexin, subsequently bind peptide to complete the assembly.

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Selected References

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