Discrimination between the endoplasmic reticulum and mitochondria by spontaneously inserting tail-anchored proteins.

Tail-anchored (TA) proteins insert into their target organelles by incompletely elucidated posttranslational pathways. Some TA proteins spontaneously insert into protein-free liposomes, yet target a specific organelle in vivo. Two spontaneously inserting cytochrome b5 forms, b5-ER and b5-RR, which differ only in the charge of the C-terminal region, target the endoplasmic reticulum (ER) or the mitochondrial outer membrane (MOM), respectively. To bridge the gap between the cell-free and in cellula results, we analyzed targeting in digitonin-permeabilized adherent HeLa cells. In the absence of cytosol, the MOM was the destination of both b5 forms, whereas in cytosol the C-terminal negative charge of b5-ER determined targeting to the ER. Inhibition of the transmembrane recognition complex (TRC) pathway only partially reduced b5 targeting, while strongly affecting the classical TRC substrate synaptobrevin 2 (Syb2). To identify additional pathways, we tested a number of small inhibitors, and found that Eeyarestatin I (ESI ) reduced insertion of b5-ER and of another spontaneously inserting TA protein, while not affecting Syb2. The effect was independent from the known targets of ESI , Sec61 and p97/VCP. Our results demonstrate that the MOM is the preferred destination of spontaneously inserting TA proteins, regardless of their C-terminal charge, and reveal a novel, substrate-specific ER-targeting pathway.

A positive signal prevents secretory membrane cargo from recycling between the Golgi and the ER.

The Golgi complex and ER are dynamically connected by anterograde and retrograde trafficking pathways. To what extent and by what mechanism outward-bound cargo proteins escape retrograde trafficking has been poorly investigated. Here, we analysed the behaviour of several membrane proteins at the ER/Golgi interface in live cells. When Golgi-to-plasma membrane transport was blocked, vesicular stomatitis virus glycoprotein (VSVG), which bears an ER export signal, accumulated in the Golgi, whereas an export signal-deleted version of VSVG attained a steady state determined by the balance of retrograde and anterograde traffic. A similar behaviour was displayed by EGF receptor and by a model tail-anchored protein, whose retrograde traffic was slowed by addition of VSVG's export signal. Retrograde trafficking was energy- and Rab6-dependent, and Rab6 inhibition accelerated signal-deleted VSVG's transport to the cell surface. Our results extend the dynamic bi-directional relationship between the Golgi and ER to include surface-directed proteins, uncover an unanticipated role for export signals at the Golgi complex, and identify recycling as a novel factor that regulates cargo transport out of the early secretory pathway.

The WRB Subunit of the Get3 Receptor is Required for the Correct Integration of its Partner CAML into the ER.

Calcium-modulating cyclophilin ligand (CAML), together with Tryptophan rich basic protein (WRB, Get1 in yeast), constitutes the mammalian receptor for the Transmembrane Recognition Complex subunit of 40 kDa (TRC40, Get3 in yeast), a cytosolic ATPase with a central role in the post-translational targeting pathway of tail-anchored (TA) proteins to the endoplasmic reticulum (ER) membrane. CAML has also been implicated in other cell-specific processes, notably in immune cell survival, and has been found in molar excess over WRB in different cell types. Notwithstanding the stoichiometric imbalance, WRB and CAML depend strictly on each other for expression. Here, we investigated the mechanism by which WRB impacts CAML levels. We demonstrate that CAML, generated in the presence of sufficient WRB levels, is inserted into the ER membrane with three transmembrane segments (TMs) in its C-terminal region. By contrast, without sufficient levels of WRB, CAML fails to adopt this topology, and is instead incompletely integrated to generate two aberrant topoforms; these congregate in ER-associated clusters and are degraded by the proteasome. Our results suggest that WRB, a member of the recently proposed Oxa1 superfamily, acts catalytically to assist the topogenesis of CAML and may have wider functions in membrane biogenesis than previously appreciated.

Uncovering common principles in protein export of malaria parasites.

For proliferation, the malaria parasite Plasmodium falciparum needs to modify the infected host cell extensively. To achieve this, the parasite exports proteins containing a Plasmodium export element (PEXEL) into the host cell. Phosphatidylinositol-3-phosphate binding and cleavage of the PEXEL are thought to mediate protein export. We show that these requirements can be bypassed, exposing a second level of export control in the N terminus generated after PEXEL cleavage that is sufficient to distinguish exported from nonexported proteins. Furthermore, this region also corresponds to the export domain of a second group of exported proteins lacking PEXELs (PNEPs), indicating shared export properties among different exported parasite proteins. Concordantly, export of both PNEPs and PEXEL proteins depends on unfolding, revealing translocation as a common step in export. However, translocation of transmembrane proteins occurs at the parasite plasma membrane, one step before translocation of soluble proteins, indicating unexpectedly complex translocation events at the parasite periphery.

Mechanisms of insertion of tail-anchored proteins into the membrane of the endoplasmic reticulum.

Tail-anchored proteins (TAPs) are a subclass of type II integral membrane proteins that carry out important and diverse functions within cells. Structurally, TAPs present an N-terminal domain exposed to the cytosol and a single transmembrane domain (TMD) close to the C-terminus, the latter is responsible for the targeting and insertion into the proper intracellular membrane (endoplasmic reticulum (ER), mitochondria, peroxisomes). Due to this particular topology, TAPs insert obligatorily into membranes by post-translational pathways and are excluded from the classical SRP dependent co-translational ER insertion. ER-targeted TAPs can follow two distinct ways of insertion according to the hydrophobicity of their TMD. In the "assisted" pathway, TAPs with more hydrophobic TMDs insert in the ER membrane with the requirement of energy and the involvement of proteinaceous component(s). By contrast neither energy, nor membrane or cytosolic proteins are necessary and do not even improve the "unassisted" insertion of TAPs with moderately hydrophobic TMDs. In this review, we discuss the most relevant recent data regarding the molecular mechanism that underlies these processes.

The role of cytosolic proteins in the insertion of tail-anchored proteins into phospholipid bilayers.

Tail-anchored (TA) proteins are membrane proteins that contain an N-terminal domain exposed to the cytosol and a single transmembrane segment near the C-terminus followed by few or no polar residues. TA proteins with a mildly hydrophobic transmembrane domain, such as cytochrome b5 (b5), are able to insert post-translationally into pure lipid vesicles without assistance from membrane proteins. Here, we investigated whether any cytosolic proteins are needed to maintain b5 in a competent state for transmembrane integration. Using b5 constructs translated in vitro or produced in bacteria, we demonstrate that cytosolic proteins are neither necessary nor facilitatory for the unassisted translocation of b5. Furthermore, we demonstrate that no cytosolic protein is involved in the translocation of a C-terminal domain of 85 residues appended to the transmembrane domain of b5. Nevertheless, b5 does bind cytosolic proteins, and in their presence but not in their absence, its insertion into liposomes is inhibited by the thiol oxidant diamide and the alkylating agent N-ethylmaleimide. The effect of diamide is also observed in living cells. Thus, the specific in vivo targeting of b5 might be achieved by interaction with redox-sensitive targeting factors that hinder its nonspecific insertion into any permissive bilayer.