Dynamics and retention of misfolded proteins in native ER membranes.

When co-translationally inserted into endoplasmic reticulum (ER) membranes, newly synthesized proteins encounter the lumenal environment of the ER, which contains chaperone proteins that facilitate the folding reactions necessary for protein oligomerization, maturation and export from the ER. Here we show, using a temperature-sensitive variant of vesicular stomatitis virus G protein tagged with green fluorescent protein (VSVG-GFP), and fluorescence recovery after photobleaching (FRAP), the dynamics of association of folded and misfolded VSVG complexes with ER chaperones. We also investigate the potential mechanisms underlying protein retention in the ER. Misfolded VSVG-GFP complexes at 40 degrees C are highly mobile in ER membranes and do not reside in post-ER compartments, indicating that they are not retained in the ER by immobilization or retrieval mechanisms. These complexes are immobilized in ATP-depleted or tunicamycin-treated cells, in which VSVG-chaperone interactions are no longer dynamic. These results provide insight into the mechanisms of protein retention in the ER and the dynamics of protein-folding complexes in native ER membranes.

Characterization of a targeting motif for a flagellar membrane protein in Leishmania enriettii.

The surface membranes of eukaryotic flagella and cilia are contiguous with the plasma membrane. Despite the absence of obvious physical structures that could form a barrier between the two membrane domains, the lipid and protein compositions of flagella and cilia are distinct from the rest of the cell surface membrane. We have exploited a flagellar glucose transporter from the parasitic protozoan Leishmania enriettii as a model system to characterize the first targeting motif for a flagellar membrane protein in any eukaryotic organism. In this study, we demonstrate that the flagellar membrane-targeting motif is recognized by several species of Leishmania. Previously, we demonstrated that the 130 amino acid NH(2)-terminal cytoplasmic domain of isoform 1 glucose transporter was sufficient to target a nonflagellar integral membrane protein into the flagellar membrane. We have now determined that an essential flagellar targeting signal is located between amino acids 20 and 35 of the NH(2)-terminal domain. We have further analyzed the role of specific amino acids in this region by alanine replacement mutagenesis and determined that single amino acid substitutions did not abrogate targeting to the flagellar membrane. However, individual mutations located within a cluster of five contiguous amino acids, RTGTT, conferred differences in the degree of targeting to the flagellar membrane and the flagellar pocket, implying a role for these residues in the mechanism of flagellar trafficking.

Cytoskeletal association is important for differential targeting of glucose transporter isoforms in Leishmania.

The major glucose transporter of the parasitic protozoan Leishmania enriettii exists in two isoforms, one of which (iso-1) localizes to the flagellar membrane, while the other (iso-2) localizes to the plasma membrane of the cell body, the pellicular membrane. These two isoforms differ only in their cytosolic NH2-terminal domains. Using immunoblots and immunofluorescence microscopy of detergent-extracted cytoskeletons, we have demonstrated that iso-2 associates with the microtubular cytoskeleton that underlies the cell body membrane, whereas the flagellar membrane isoform iso-1 does not associate with the cytoskeleton. Deletion mutants that remove the first 25 or more amino acids from iso-1 are retargeted from the flagellum to the pellicular membrane, suggesting that these deletions remove a signal required for flagellar targeting. Unlike the full-length iso-1 protein, these deletion mutants associate with the cytoskeleton. Our results suggest that cytoskeletal binding serves as an anchor to localize the iso-2 transporter within the pellicular membrane, and that the flagellar targeting signal of iso-1 diverts this transporter into the flagellar membrane and away from the pellicular microtubules.