Mislocalization of Cancer-associated Thyroid Hormone Receptor Mutants.

The thyroid hormone receptor (TR) is essential for the proper regulation of metabolism and development, as it regulates gene expression in response to thyroid hormone. Nuclear localization signals (NLSs) and nuclear export signals (NESs) allow for TR transport into and out of the nucleus, respectively. Previous research suggests that nuclear import, nuclear retention, and nuclear export of TR are associated with modulation of gene expression, the alteration of which can contribute to various diseases. Here, we examined the impact of cancer-associated mutations on TR localization patterns as a way of analyzing key structural components of TR and to further explore the correlation between TR trafficking, misfolding, and disease. Through mammalian cell transfection of expression plasmids for green fluorescent protein (GFP) and mCherry-tagged TRα1 and quantitative fluorescence microscopy, we examined particular groups of TRα1 mutations that were observed in patients with hepatocellular carcinoma, renal cell carcinoma, and thyroid cancer, and are associated with NLSs and NESs of TRα1. We also investigated structural alterations of the mutants by in silico modeling. Our results show striking shifts towards a more cytoplasmic localization for many of the mutants and an increased tendency to form cytosolic and nuclear aggregates.

The influence of CD40 on the association of the B cell antigen receptor with lipid rafts in mature and immature cells.

Cholesterol- and sphingolipid-rich membrane microdomains termed lipid rafts appear to play a central role in B cell activation. In mature B cells, signaling through the B cell antigen receptor(BCR) is initiated from within rafts and leads to activation. In immature B cells, the BCR is excluded from rafts and signaling leads to apoptosis. CD40, a member of the tumor necrosis receptor family, is expressed by B cells throughout development and has been shown to influence the results of the engagement of antigen by the BCR in both mature B and immature B cells. Here evidence is provided that CD40 is excluded from the lipid rafts of both mature and immature B cells and remains excluded from rafts even after cross-linking. Nevertheless, in mature B cells CD40 signaling influences the association of the BCR with rafts resulting in an increase in the amount of BCR that translocates into rafts following ligand binding and a subsequent acceleration of the movement of the BCR from rafts. In immature B cells, the cross-linked BCR remains excluded from rafts in the presence of CD40 signaling, conditions under which BCR-induced apoptosis is blocked. These results indicate that CD40 functions outside lipid rafts to influence raft-dependent events in mature B cells and raft-independent events in immature B cells.

Floating the raft hypothesis: the roles of lipid rafts in B cell antigen receptor function.

The initiation of antibody responses to foreign antigens requires that B cells receive and integrate a variety of signals through an array of cell surface receptors including the B cell antigen receptor (BCR) as well as a number of essential coreceptors. Recent evidence indicates that cholesterol-rich plasma membrane microdomains, referred to here as lipid rafts, serve as platforms for BCR signaling and trafficking in B cells. The existence of rafts suggests a previously unappreciated level of organization at the B cell surface that may explain, at least in part, how BCR signaling is coordinated. Here the current evidence that lipid rafts play a key role in B cell responses is reviewed.

Cutting edge: B cell antigen receptor signaling occurs outside lipid rafts in immature B cells.

B cell Ag receptor (BCR) signaling changes dramatically during B cell development, resulting in activation in mature B cells and apoptosis, receptor editing, or anergy in immature B cells. BCR signaling in mature B cells was shown to be initiated by the translocation of the BCR into cholesterol- and sphingolipid-enriched membrane microdomains that include the Src family kinase Lyn and exclude the phosphatase CD45. Subsequently the BCR is rapidly internalized into the cell. Here we show that the BCR in the immature B cell line, WEHI-231, does not translocate into lipid rafts following cross-linking nor is the BCR rapidly internalized. The immature BCR initiates signaling from outside lipid rafts as evidenced by the immediate induction of an array of phosphoproteins and subsequent apoptosis. The failure of the BCR in immature B cells to enter lipid rafts may contribute to the dramatic difference in the outcome of signaling in mature and immature B cells.

The assembly and stability of MHC class II-(alpha beta)2 superdimers.

X-ray crystallography of several MHC class II molecules revealed a structure described as a dimer of heterodimers, or a superdimer. This discovery led to the hypothesis that MHC class II molecules may interact with the TCR and CD4 as an (alpha beta)2 superdimer, potentially providing more stable and stimulatory interactions than can be provided by the simple alpha beta heterodimer alone. In this study, using chemical cross-linking, we provide evidence for the existence of the superdimers surface of B cells. We further characterize the superdimers and demonstrate that in lysates of B cells, I-Ek dimers and superdimers are derived from the same population of I-Ek molecules. Purified, I-Ek molecules in solution also exist as a mixture of 60-kDa dimers and 120-kDa superdimers, indicating that I-Ek has an intrinsic ability to form 120-kDa complexes in the absence of other cellular components. Peptide mapping showed that the alpha beta and (alpha beta)2 complexes are closely related and that the superdimers do not contain additional polypeptides not present in the dimers. The (alpha beta)2 complex displays thermal and pH stability similar to that of the alpha beta complex, both being denatured by SDS at temperatures above 50 degrees C and at a pH below 5. These data support the model that MHC class II has an intrinsic ability to assume the (alpha beta)2 superdimeric conformation, which may be important for interactions with the TCR and CD4 coreceptor.

HLA-DM is present in one-fifth the amount of HLA-DR in the class II peptide-loading compartment where it associates with leupeptin-induced peptide (LIP)-HLA-DR complexes.

HLA-DM has been shown in vitro to catalyze the release of invariant chain (Ii) derived peptides from the peptide-binding groove of class II molecules, thereby facilitating the binding of antigenic peptides. Previous studies showed that at steady state, the majority of DM resides in the class II peptide-loading compartment (IIPLC) where Ii dissociates from class II molecules and antigenic peptides are bound. Here we characterize the expression of DM in vivo in subcellular fractions containing the IIPLC. Using quantitative immunoblotting, we show that in the cell as a whole, class II molecules are expressed in 23-fold molar excess of DM. However, DM is concentrated in the IIPLC, where it is present in a considerably higher concentration relative to the class II molecules, in a molar ratio of 5DR:1 DM. This molar ratio of DM to DR in the IIPLC in vivo is consistent with the catalytic function proposed for DM from studies in vitro. We also provide both biochemical and genetic evidence that DM associates with complexes which contain Ii fragments and class II molecules in the IIPLC. Such complexes are only observed in leupeptin-treated cells in which Ii fails to be completely degraded and complexes containing the leupeptin-induced fragment of Ii (LIP) and class II molecules accumulate in the IIPLC. This observation is consistent with LIP-class II complexes being a substrate for DM in vivo and suggests that interactions of DM and LIP-class II are extremely transient under normal conditions.