The Get1/2 insertase forms a channel to mediate the insertion of tail-anchored proteins into the ER.

Tail-anchored (TA) proteins contain a single C-terminal transmembrane domain (TMD) that is captured by the cytosolic Get3 in yeast (TRC40 in humans). Get3 delivers TA proteins to the Get1/2 complex for insertion into the endoplasmic reticulum (ER) membrane. How Get1/2 mediates insertion of TMDs of TA proteins into the membrane is poorly understood. Using bulk fluorescence and microfluidics assays, we show that Get1/2 forms an aqueous channel in reconstituted bilayers. We estimate the channel diameter to be ∼2.5 nm wide, corresponding to the circumference of two Get1/2 complexes. We find that the Get3 binding can seal the Get1/2 channel, which dynamically opens and closes. Our mutation analysis further shows that the Get1/2 channel activity is required to release TA proteins from Get3 for insertion into the membrane. Hence, we propose that the Get1/2 channel functions as an insertase for insertion of TMDs and as a translocase for translocation of C-terminal hydrophilic segments.

A second chance for protein targeting/folding: Ubiquitination and deubiquitination of nascent proteins.

Molecular chaperones in cells constantly monitor and bind to exposed hydrophobicity in newly synthesized proteins and assist them in folding or targeting to cellular membranes for insertion. However, proteins can be misfolded or mistargeted, which often causes hydrophobic amino acids to be exposed to the aqueous cytosol. Again, chaperones recognize exposed hydrophobicity in these proteins to prevent nonspecific interactions and aggregation, which are harmful to cells. The chaperone-bound misfolded proteins are then decorated with ubiquitin chains denoting them for proteasomal degradation. It remains enigmatic how molecular chaperones can mediate both maturation of nascent proteins and ubiquitination of misfolded proteins solely based on their exposed hydrophobic signals. In this review, we propose a dynamic ubiquitination and deubiquitination model in which ubiquitination of newly synthesized proteins serves as a "fix me" signal for either refolding of soluble proteins or retargeting of membrane proteins with the help of chaperones and deubiquitinases. Such a model would provide additional time for aberrant nascent proteins to fold or route for membrane insertion, thus avoiding excessive protein degradation and saving cellular energy spent on protein synthesis. Also see the video abstract here: https://youtu.be/gkElfmqaKG4.

Deubiquitinases USP20/33 promote the biogenesis of tail-anchored membrane proteins.

Numerous proteins that have hydrophobic transmembrane domains (TMDs) traverse the cytosol and posttranslationally insert into cellular membranes. It is unclear how these hydrophobic membrane proteins evade recognition by the cytosolic protein quality control (PQC), which typically recognizes exposed hydrophobicity in misfolded proteins and marks them for proteasomal degradation by adding ubiquitin chains. Here, we find that tail-anchored (TA) proteins, a vital class of membrane proteins, are recognized by cytosolic PQC and are ubiquitinated as soon as they are synthesized in cells. Surprisingly, the ubiquitinated TA proteins are not routed for proteasomal degradation but instead are handed over to the targeting factor, TRC40, and delivered to the ER for insertion. The ER-associated deubiquitinases, USP20 and USP33, remove ubiquitin chains from TA proteins after their insertion into the ER. Thus, our data suggest that deubiquitinases rescue posttranslationally targeted membrane proteins that are inappropriately ubiquitinated by PQC in the cytosol.

Membrane Protein Biogenesis: PAT Complex Pats Membrane Proteins into Shape.

Membrane proteins with multiple transmembrane domains play essential roles in the cell, but little is known about the machinery involved in the assembly of these domains into functional proteins. Two recent studies report the discovery of novel membrane protein chaperone complexes for the biogenesis of multi-pass membrane proteins.

Tau Binds to Multiple Tubulin Dimers with Helical Structure.

Understanding the mechanism by which tau binds to and promotes microtubule (MT) assembly as part of its native function may also provide insight into its loss of function that occurs in neurodegenerative disease. Both mechanistic and structural studies of tau have been hindered by its intrinsic disorder and highly dynamic nature. Here, we combine fluorescence correlation spectroscopy and acrylodan fluorescence screening to study the stoichiometry and structural features of tau-tubulin assemblies. Our results show that tau binds to multiple tubulin dimers, even when MT assembly is inhibited. Moreover, we observe helical structure in the repeat regions of the MT binding domain of tau in the tau-tubulin complex, reflecting partial folding upon binding. Our findings support a role for tau's intrinsic disorder in providing a flexible scaffold for binding tubulin and MTs and a disorder-to-order transition in mediating this important interaction.